Forces evolution
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Chapter-04Explorations.pdf
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EXPLORATIONS: AN OPEN INVITATION TO BIOLOGICAL ANTHROPOLOGY
Editors: Beth Shook, Katie Nelson, Kelsie Aguilera and Lara Braff
American Anthropological Association Arlington, VA
2019
CC BY-NC 4.0 International, except where otherwise noted
ISBN – 978-1-931303-63-7
www.explorations.americananthro.org
Chapter 4: Forces of Evolution
Andrea J. Alveshere, Ph.D., Western Illinois University
Learning Objectives
• Describe the history and contributions of the Modern Synthesis.
• Define populations and population genetics as well as the methods used to study them.
• Identify the forces of evolution and become familiar with examples of each.
• Discuss the evolutionary significance of mutation, genetic drift, gene flow, and natural selection.
• Explain how allele frequencies can be used to study evolution as it happens.
• Contrast micro- and macroevolution.
It’s hard for us, with our typical human life spans of less than 100 years, to imagine all the way back, 3.8 billion years ago,
to the origins of life. Scientists still study and debate how life came into being and whether it originated on Earth or in some other region of the universe including some scientists who believe that studying evolution can reveal the complex
processes that were set in motion by God or a higher power). What we do know is that a living single-celled organism
was present on Earth during the early stages of our planet’s existence. This organism had the potential to reproduce
by making copies of itself, just like bacteria, many amoebae, and our own living cells today. In fact, with today’s genetic
and genomic technologies, we can now trace genetic lineages, or phylogenies, and determine the relationships between all of today’s living organisms—eukaryotes animals, plants, fungi, etc.), archaea, and bacteria—on the branches of the
phylogenetic tree of life Figure 4.1).
Looking at the common sequences in modern genomes, we can even make educated guesses about what the genetic
sequence of the first organism, or universal ancestor of all living things, would likely have been. Through a wondrous series of mechanisms and events, that first single-celled organism gave rise to the rich diversity of species that fill
the lands, seas, and skies of our planet. This chapter explores the mechanisms by which that amazing transformation
occurred and considers some of the crucial scientific experiments that shaped our current understanding of the
evolutionary process.
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Figure 4.1 Phylogenetic tree of life.
THE MODERN SYNTHESIS
Historical Framework
When learning about biological sciences today, we always recognize the contributions of Charles Darwin and Gregor
Mendel, so it may be surprising to learn that for a time, before we arrived at today’s understanding of genetics and
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inheritance, both Darwin’s and Mendel’s work fell out of favor. Neither Darwin’s theory of natural selection, nor Mendel’s
particulate inheritance were individually sufficient to fully explain all the phenomena being observed in the natural
world. It would take many decades, and many careful scientific experiments to solve the puzzle of evolution.
Rethinking Darwin
Figure 4.2B The Modern Synthesis perspective: The ancestral population had a range of variation in neck length. Those individuals with the longest necks would be the most likely to survive to pass on their longer-neck alleles to future generations.
Figure 4.2A The Lamarckian hypothesis: If a short-necked parent often stretched its neck to reach higher branches, each generation of offspring would be born with somewhat longer necks.
As noted in Chapter 2, Darwin’s 1859 book On the Origin of Species made a big splash;
however, as other researchers began doing
what scientists do—testing whether or not the
concept of natural selection could
consistently account for the variation seen in
organisms—they began to find many
exceptions. One reason for this is that, as we
now know, natural selection is only one of the
forces of evolution. Another challenge was a
general lack of understanding about how
variation is initiated and how inheritance
works. Many scientists of the day subscribed
to the concept known as Lamarckian inheritance, which posited that offspring would inherit characteristics that were acquired during their parents’ lifetimes Figure
4.2).Darwin himself, in 1868, promoted an idea called pangenesis, which combines the Lamarckian idea of inheriting acquired characteristics with the idea that particles
from different parts of the body make their way to the sex cells. Alfred Russell Wallace, evolution. Another researcher,
August Weismann, also rejected the idea that acquired characteristics could be passed on. Weismann 1892) devised an
experiment to directly test whether offspring inherited acquired characteristics: he cut the tails off mice, bred them,
and then waited eagerly to find out if the offspring had tails. All the baby mice were born with tails intact, demonstrating
Lamarckian inheritance of acquired characteristics to be incorrect Figure 4.3).
Figure 4.3 Weismann’s mouse-tail experiment showing that offspring do not inherit traits that the parents acquired during their lifetimes.who had arrived at the concept of natural selection independently of Darwin, rejected Lamarckian
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Rediscovering Mendel
Figure 4.4 The continuous range of variation observed in hooded rat coat patterns after five generations.
In 1900, two scientists named Hugo de Vries and Carl
Correns, who were independently studying the
mechanisms of inheritance, rediscovered Gregor
Mendel’s work. Mendel’s pea plant experiments provided
the concepts of dominant and recessive traits, which
explained retention of certain characteristics in a way
that Darwin’s idea, blending inheritance, didn’t. The
debate that unfolded was between the Mutationists, who believed that variation was caused by mutations in
distinct, inherited cells, and Biometricians, who believed that individual mutations of discrete hereditary units
could never account for the continuous spectrum of
variation seen in many traits. One set of experiments that helped resolve this debate was a five-year study carried out
by William Castle and John Phillips on laboratory rats Castle and Phillips 1914). The dominant coat color was the gray
wild type, and the piebald or “hooded” color was recessive. He cross-bred the rats multiple ways for five generations
and proved that he could achieve a continuous range of variation; in fact, he even achieved coat pattern variations that
were more extreme than the original maximums of the parent groups Figure 4.4).
Another scientist, Thomas Hunt Morgan, conducted studies in which he induced genetic mutations in populations of
the fruit fly, Drosophila melanogaster Figure 4.5). His work demonstrated that most mutations merely increased
variation within populations, rather than creating new species Morgan 1911).
Figure 4.5 Examples of mutations producing phenotypic variation in a single species of fruit fly.
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Tying It All Together
While the biggest leap forward in understanding how evolution works came with the joining synthesis) of Darwin’s
concept of natural selection with Mendel’s insights about particulate inheritance, there were some other big
contributions that were crucial to making sense of the variation that was being observed. R.A. Fisher 1919) and John
Burdon Sanderson Haldane 1924) developed and tested mathematical models for evolutionary change that provided the
tools to study variation and became the basis for the study of population genetics. Sewall Wright 1932) and Theodosius
Dobzhansky 1937) performed studies that revealed the existence of chromosomes as carriers of collections of genes. Edmund Brisco Ford 1949) conducted studies on wild butterflies that confirmed Fisher’s mathematical predictions and
also led to his definition of the concept of polymorphisms to describe alternative phenotypes, or multiple forms of a trait. Ford 1942) also correctly predicted that human blood type polymorphisms were maintained in the population
because they were involved in disease resistance. Julian Huxley’s 1942 book, Evolution: The Modern Synthesis, provided
an easy-to-read summary of the evolutionary studies that had come before. It was with this book that the term Modern Synthesis was first used to describe the integration of Darwin’s, Mendel’s, and subsequent research into a unified theory of evolution. In appealing to the general public, Huxley’s book also found new success establishing a wide acceptance of
the process of evolution.
POPULATION GENETICS
Defining Species and Populations and the Variations Within Them
One of the major breakthroughs in understanding the mechanisms of evolutionary change came with the realization
that evolution takes place at the level of populations, not within individuals. In the biological sciences, a population is defined as a group of individuals of the same species who are geographically near enough to one another that they can
breed and produce new generations of individuals. Species are organisms whose individuals are capable of breeding because they are biologically and behaviorally compatible to produce viable, fertile offspring. Viable offspring are those offspring who are healthy enough to survive to adulthood. Fertile offspring can reproduce successfully to have offspring of their own. Both conditions must be met for individuals to be considered part of the same species. As you can imagine,
these criteria complicate the identification of distinct species in fossilized remains of extinct populations. In those cases,
we must examine how much phenotypic variation is typically found within a comparable modern-day species, and then
determine whether the fossilized remains fall within the expected range of variation for a single species.
Some species have subpopulations that are regionally distinct. These are classified as separate subspecies because they have their own unique phenotypes and are geographically isolated from one another, but if they do happen to encounter
one another, they are still capable of successful interbreeding.
There are many examples of sterile hybrids that are offspring of parents from two different species. For example, horses
and donkeys can breed and have offspring together. Depending on which species is the mother and which is the father,
the offspring are either called mules, or hennies. Mules and hennies can live full life spans but are not able to have
offspring of their own. Likewise, tigers and lions have been known to mate and have viable offspring. Again, depending
on which species is the mother and which is the father, these offspring are called either ligers or tigons. Like mules and
hennies, ligers and tigons are unable to reproduce. In each of these cases, the mismatched set of chromosomes that the
offspring inherit still produce an adequate set of functioning genes for the hybrid offspring, but, once mixed and divided
in meiosis, the gametes don’t contain the full complement of genes needed for survival in the third generation.
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For the purpose of studying evolution, we recognize populations by their even smaller units: genes. Each individual,
for genetic inheritance purposes, carries a collection of genes that can be passed down to future generations. For this
reason, in population genetics, we think of populations as gene pools, which refers to the entire collection of genetic material in a breeding community that can be passed on from one generation to the next.
Remember, a gene is the basic unit of information that encodes the proteins needed to grow and function as a living organism. Each gene can have multiple alleles, or variants, each of which may produce a slightly different protein. For example, there are brown- or blue-pigment alleles for eye color green is a slight variant of the brown type). The set
of alleles that an individual inherits for a given gene is known as the genotype e.g., inheriting both brown and blue eye pigments gives a genotype of Bb); while the observable traits that are produced by a genotype is known as the
phenotype e.g., a Bb individual exhibiting the dominant brown eye trait). For genes carried on our human chromosomes our nuclear DNA), we inherit two copies of each, one from each parent. This means we may carry two of the same
alleles a homozygous genotype; eye pigment genotypes BB or bb) or two different alleles a heterozygous genotype; eye pigment genotype Bb) for each nuclear gene. Only one of each of our alleles will get passed on to each of our
children the other will come from the child’s other parent). This means that children often inherit new genotypes and
likely express unique phenotypes, compared to their parents. A common example is when two brown-eyed parents who
happen to be heterozygous for the pigment alleles) have a blue-eyed baby genotype bb; who has inherited the recessive
b alleles from both parents).
Defining Evolution
In order to understand evolution, it’s crucial to remember that evolution is always studied at the population level. Also,
if a population were to stay exactly the same from one generation to the next, it would not be evolving. So evolution
requires both a population of breeding individuals and some kind of a genetic change occurring within it. Thus, the
simple definition of evolution is a change in the allele frequencies in a population over time. What do we mean by allele frequencies? Allele frequencies refer to the ratio, or percentage, of one allele one variant of a gene) compared to the other alleles for that gene within the study population. By contrast, genotype frequencies are the ratios or percentages of the different homozygous and heterozygous genotypes in the population. Because we carry two alleles
per genotype, the total count of alleles in a population will usually be exactly double the total count of genotypes in the
same population with the exception being rare cases in which an individual carries a different number of chromosomes
than the typical two; e.g., Down syndrome results when a child carries three copies of Chromosome 21).
THE FORCES OF EVOLUTION
Today, we recognize that evolution takes place through a combination of mechanisms: mutation, genetic drift, gene
flow, and natural selection. These mechanisms are called the “forces of evolution” and together they can account for all
the genotypic variation observed in the world today. Keep in mind that each of these forces was first defined and then
tested—and re-tested—through the experimental work of the many scientists who contributed to the Modern Synthesis.
Mutation
The first force of evolution we will discuss is mutation, and for good reason: Mutation is the original source of all the
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genetic variation found in every living thing. Let’s try again to imagine all the way back in time to the very first single-
celled organism, floating in Earth’s primordial sea. Based on what we observe in simple, single-celled organisms today,
that organism probably spent its lifetime absorbing nutrients and dividing to produce cloned copies of itself. While the
numbers of individuals in that population would have grown as long as the environment was favorable), nothing would
have changed in that perfectly cloned population. There would not have been variety among the individuals. It was only
through a copying error—the introduction of a mutation, or change, into the genetic code—that each new allele was introduced into the population.
When we think of genetic mutation, we often first think of deleterious mutations—the ones associated with negative effects such as the beginnings of cancers or heritable disorders. The fact is, though, that every genetic adaptation that
has helped our ancestors survive since the dawn of life is directly due to a beneficial mutation—a changes in the DNA that provided some sort of advantage to a given population at a particular moment in time. For example, a beneficial
mutation allowed chihuahuas and other tropical-adapted dog breeds to have much thinner fur coats than their cold-
adapted cousins the northern wolves, malamutes, and huskies.
Every one of us has genetic mutations. Yes, even you. The DNA in some of your cells today differs from the original
DNA that you inherited when you were a tiny, fertilized egg. Mutations occur all the time in the cells of our skin and
other organs, due to chemical changes in the nucleotides. Exposure to the UV radiation in sunlight is one common cause
of skin mutations. Interaction with UV light causes UV crosslinking, in which adjacent thymine bases bind with one another Figure 4.6). Many of these mutations are detected and corrected by DNA repair mechanisms, enzymes that patrol and repair DNA in living cells, while other mutations may cause a new freckle or mole or, perhaps, an unusual hair
to grow. For people with the autosomal recessive disease xeroderma pigmentosum, these repair mechanisms do not function correctly, resulting in a host of problems, especially related to sun exposure, including severe sunburns, dry
skin, heavy freckling, and other pigment changes.
Figure 4.6 A crosslinking mutation in which a UV photon induces a bond between two thymine bases.
Most of our mutations exist in somatic cells, which are the cells of our organs and other body tissues. Those will not be passed on to future generations and so will not affect the population over time. Only mutations that occur in the
gametes, the reproductive cells i.e., the sperm or egg cells), will be passed on to future generations. When a new mutation pops up at random in a family lineage, it is known as a spontaneous mutation. If the individual born with
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this spontaneous mutation passes it on to his offspring, those offspring receive an inherited mutation. Geneticists have identified many classes of mutations and the causes and effects of many of these.
Point Mutations
A point mutation is a single-letter single-nucleotide) change in the genetic code resulting in the substitution of one nucleic acid base for a different one. As you learned in Chapter 3, the DNA code in each gene is translated through three-
letter “words” known as codons. So depending on how the point mutation changes the “word,” the effect it will have on the protein may be major or minor, or may make no difference at all. One of the most common causes of point mutations
is a chemical change called cytosine methylation. In cytosine methylation, a methyl group is added to a cytosine base, which further converts to thymine after hydrolytic deamination water-induced removal of an amine group; Figure 4.7).
If this mutation is not detected before replication, half of the daughter cells will inherit a thymine T) in the sequence
where a cytosine C) is usually located. This is one of the most common causes of the autosomal dominant disorder
neurofibromatosis type 1 NF1), discussed in Case Study #1 see below).
If a mutation does not change the resulting protein, then
it is called a synonymous mutation. Synonymous mutations do involve a letter nucleic acid) change, but
that change results in a codon that codes for the same
“instruction” the same amino acid or stop code) as the
original codon. Mutations that do cause a change in the
protein are known as non-synonymous mutations. There are several classes of non-synonymous mutations, which
are defined by their effects on the encoded protein:
missense, nonsense, and splice site mutations Figure 4.8). Figure 4.7 The mechanism by which a cytosine-to-thymine point mutation can occur.
A missense mutation produces a change in a single amino acid. In this case, the protein is assembled correctly, both before and after the point mutation, but one amino acid,
encoded by the codon containing the point mutation, is incorrect. This may impact how the finished protein functions
by, for example, preventing it from folding correctly and/or disrupting an enzyme binding site. Nonsense mutations convert codons that encode amino acids into stop codons, meaning that the protein will be assembled correctly up until
the codon containing the mutation and then assembly will be prematurely terminated. Depending on where in the gene
the nonsense mutation falls, this may have a major or very minor impact. A splice site mutation changes the genetic code so that the process of removing the intron sequences from the mRNA is disrupted. This can result in the erroneous
inclusion of an intron sequence or the exclusion of one of the exons that should have been retained.
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Mutation Type Illustration Result
No mutation normal DNA) Normal protein produced
Synonymous silent) mutation
Normal protein produced
Missense mutation Slight difference in amino acid sequence
Nonsense mutation Protein terminates early
Chart continued on next page
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Mutation Type Illustration Result
Frameshift insertion Major difference in amino acid sequence
Frameshift deletion Major difference in amino acid sequence
Figure 4.8 Examples and results of point and frameshift mutations.
Insertions and Deletions
In addition to point mutations, another class of mutations are insertions and deletions, or indels, for short. As the name suggests, these involve the addition insertion) or removal deletion) of one or more coding sequence letters nucleic
acids). These typically first occur as an error in DNA replication, wherein one or more nucleotides are either duplicated
or skipped in error.
Frameshift mutations are types of indels that involve the insertion or deletion of any number of nucleotides that is not a multiple of three. Because these indels are not consistent with the codon numbering, they “shift the reading frame,”
causing all the codons beyond the mutation to be misread. These mutations can create extensive changes to the protein
sequence, potentially not only causing it to lose function but also possibly creating new enzyme-binding sites, leading
to new interactions between the protein and other components of the cellular environment. Like point mutations, small
indels can also disrupt splice sites. Entire codons or sets of codons may also be removed or added if the indel is a
multiple of three nucleotides.
Transposable Elements, or transposons, are fragments of DNA that can “jump” around in the genome. There are two types of transposons: Class I transposons, or retrotransposons, which are transcribed from DNA into RNA and then “reverse transcribed,” to insert the copied sequence into a new location in the DNA; and Class II transposons, or DNA
transposons, which do not involve RNA— instead, DNA transposons are clipped out of the DNA sequence itself and inserted elsewhere in the genome. Because transposable elements insert themselves into and, in the case of Class II
transposons, remove themselves from) existing DNA sequences, they are frequent gene disruptors. At certain times, and
in certain species, it appears that transposons became very active, likely accelerating the mutation rate and thus, the
genetic variation) in those populations during the active periods.
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Chromosomal Alterations
The final major category of genetic mutations are changes at the chromosome level: crossover events, nondisjunction
events, and translocations. Crossover events occur when DNA is swapped between homologous chromosomes while they are paired up during meiosis I. Crossovers are thought to be so common that some DNA swapping may happen
every time chromosomes go through meiosis I. Crossovers don’t necessarily introduce new alleles into a population, but
they do make it possible for new combinations of alleles to exist on a single chromosome that can be passed to future
generations. This also enables new combinations of alleles to be found within siblings who share the same parents. Also,
if the fragments that cross over don’t break at exactly the same point, they can cause genes to be deleted from one of
the homologous chromosomes and duplicated on the other.
Nondisjunction events occur when the homologous chromosomes in meiosis I) or sister chromatids in meiosis II and mitosis) fail to separate after pairing. The result is that both chromosomes or chromatids end up in the same daughter
cell, leaving the other daughter cell without any copy of that chromosome. Most nondisjunctions at the gamete level
are fatal to the embryo. The most widely known exception is Trisomy 21, or Down syndrome, which results from an
embryo that inherits three copies of Chromosome 21: two from one parent due to a nondisjunction event) and one from
the other. Trisomies triple chromosome conditions) of Chromosomes 18 Edwards syndrome) and 13 Patau syndrome) are also known to result in live births, but the children usually have severe complications and rarely survive beyond
the first year of life. Sex chromosome trisomies XXX, XXY, XYY) and X chromosome monosomies inheritance of an X chromosome from one parent and no sex chromosome from the other) are also survivable and fairly common. The
symptoms vary but often include atypical sexual characteristics, either at birth or at puberty, and often result in sterility.
The X chromosome carries unique genes that are required for survival; therefore, Y chromosome monosomies are
incompatible with life.
Chromosomal translocations involve transfers of DNA between non-homologous chromosomes. This may involve swapping large portions of two or more chromosomes. The exchanges of DNA may be balanced or unbalanced. In
balanced translocations, the genes are swapped, but no genetic information is lost. In unbalanced translocations, there is an unequal exchange of genetic material resulting in duplication or loss of genes. Translocations result in
new chromosomal structures called derivative chromosomes, because they are derived or created from two different chromosomes. Translocations are often found to be linked to cancers and can also cause infertility. Even if the
translocations are balanced in the parent, the embryo often won’t survive unless the baby inherits both of that parent’s
derivative chromosomes to maintain the balance).
Case Study #1: Neurofbromatosis Type 1 (NF1)
Neurofibromatosis Type 1, also known as NF1, is a surprisingly common genetic disorder, affecting more people than cystic fibrosis and muscular dystrophy combined. Even more surprising, given how common it is, is how few people
have heard of it. One in every 3,000 babies is born with NF1, and this holds true for all populations worldwide Riccardi
1992). This means that, for every 3,000 people in your community, there is likely at least one community member living
with this disorder. Approximately half of these cases are due to spontaneous mutations—that is, the person is the first
in their family to have the disorder. The other half of the NF1 cases are inherited from a parent with this disorder. NF1
syndrome is an autosomal dominant condition, which means that everyone born with a mutation in the gene, whether inherited or spontaneous, has a 50:50 chance of passing the NF1 syndrome on to each of their children.
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Figure 4.9 Photo of a woman with many cutaneous neurofibromas, a common symptom of Neurofibromatosis Type 1.
The NF1 disorder results from disruption of the NF1 gene on Chromosome
17. Studies of individuals with NF1 have identified over 3,000 different
mutations within the gene including small and large indels, point
mutations, and translocations). The NF1 gene is one of the largest known
genes, containing at least 60 exons protein-encoding sequences) in a span of about 300,000 nucleotides. It encodes a correspondingly large protein
called neurofibromin. Neurofibromin is a fascinating protein, and we are
still learning about all its functions.
Studying the symptoms in people who have mutations in an NF1 gene can
provide important insights. There are two other types of
Neurofibromatosis Type 2 and Schwannomatosis) that involve some of the
same symptoms but are much less common than NF1 and are not due to mutations in the same gene or even the same
chromosome).
We know that neurofibromin plays an important role in preventing tumor growth because, when a mutation occurs
causing the NF1 disorder, one of the most common symptoms is the growth of benign non-cancerous) tumors, called neurofibromas. Neurofibromas sprout from nerve sheaths—the tissues that encase our nerves—throughout the body. There is no way to predict where the tumors will occur, or when or how quickly they will grow, although only about 15%
turn malignant cancerous).
Figure 4.10A Photo of a man with large plexiform neurofibroma, another symptom of Neurofibromatosis Type 1.
Figure 4.10B Childhood photo of the same man, illustrating the progressive nature of the NF1 disorder.
The two types of neurofibromas
that are typically most visible are
cutaneous neurofibromas, which are spherical bumps on, or just
under, the surface of the skin
Figure 4.9), and plexiform neurofibromas, growths involving whole branches of nerves, often
giving the appearance that the
surface of the skin is “melting”
Figure 4.10).
Unfortunately, although research is ongoing, there is currently no cure for
NF1. Surgical removal of neurofibromas risks paralysis, due to the high
potential for nerve damage, and often results in the tumors growing back
even more vigorously. This means that patients are often forced to live with disfiguring and often painful neurofibromas.
People who are not familiar with NF1 often mistake neurofibromas for something contagious. This makes it especially
hard for people living with NF1 to get jobs working with the public or even to enjoy spending time away from home.
Raising public awareness about NF1 and its symptoms can be a great help in improving the quality of life for people living
with this condition.
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Figure 4.11 Child with café-au-lait macules (birthmarks) typical of the earliest symptoms of NF1.
Babies who have NF1 rarely have neurofibromas, which often begin to grow
during puberty. One of the first symptoms of NF1 in a small child is usually
the appearance of café-au-lait spots, or CALS, which are flat, brown birthmark-like spots on the skin Figure 4.11). CALS are often light brown,
like the color of coffee with cream, which is the reason for the name,
although the shade of the pigment depends on a person’s overall
complexion. Some babies are born with CALS, but for others the spots
appear within the first few years of life. Having six or more CALS larger than
five millimeters mm) across is a strong indicator that a child may have NF1
the required size increases to 15 mm for diagnosis after puberty).
A second sign is always needed to confirm a clinical diagnosis of NF1. The
second sign often comes in the form of freckles in unusual areas, such as
the groin or underarms, or with the first appearance of neurofibromas.
Other common symptoms include gliomas tumors) of the optic nerve,
which can cause vision loss; thinning of bones and failure to heal if they
break often requiring amputation); low muscle tone poor muscle
development, often delaying milestones such as sitting up, crawling, and
walking); hearing loss, due to neurofibromas on auditory nerves; and
learning disabilities, especially those involving spatial reasoning.
Approximately 50 % of people with NF1 have some type of speech and/or
learning disability and often benefit greatly from early intervention services. Intellectual disability, however, is not
common with NF1, so most people with NF1 live independently as adults. Many people with NF1 live full and successful
lives, as long as their symptoms can be managed.
Based on the wide variety of symptoms, it’s clear that neurofibromin plays important roles in many biochemical
pathways. While everyone who has NF1 will exhibit some symptoms during their lifetime, there is a great deal of variation
in the types and severity of symptoms, even between individuals from the same family who share the exact same NF1
mutation. It seems crazy that a gene with so many important functions would be so susceptible to mutation. Part of this
undoubtedly has to do with its massive size—a gene with 300,000 nucleotides has ten times more nucleotides available
for mutation than does a gene of 30,000 bases. This also suggests that the mutability of this gene might provide some
benefits, which is a possibility that we will revisit later in this chapter.
Genetic Drift
The second force of evolution is commonly known as genetic drift. This is an unfortunate misnomer, as this force
actually involves the drifting of alleles, not genes. Genetic drift refers to random changes “drift”) in allele frequencies from one generation to the next. The genes are remaining constant within the population; it is only the alleles of the
genes are changing in frequency. The random nature of genetic drift is a crucial point to understand: it specifically
occurs when none of the variant alleles confer an advantage.
Let’s imagine far back in time, again, to that first population of living cells, subsisting and occasionally dividing, in the
primordial sea. Many generations have passed, and mutations have created distinct chromosomes. The cells are now
amoeba-like, larger than many of their tiny bacterial neighbors, who have long since become their favorite source of
nutrients. A mutation occurs in one of the cells that changes the texture of the cell membrane from a relatively smooth
surface to a highly ruffled one. This has absolutely no effect on the cell’s quality of life or ability to reproduce. In fact,
eyes haven’t evolved yet, so no one in the world at the time would even notice the difference. The cells in the population
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continue to divide, and the offspring of the ruffled cell inherit the ruffled membrane. The frequency %) of the ruffled
allele in the population, from one generation to the next, will depend entirely on how many offspring that first ruffled
cell ends up having, and the random events that might make the ruffled alleles more common or more rare such as
population bottlenecks and founder effects, discussed below).
Sexual Reproduction and Random Inheritance
Tracking alleles gets a bit more complicated in our primordial cells when, after a number of generations, a series of
mutations have created populations that reproduce sexually. These cells go through an extra round of cell-division
meiosis) to create haploid gametes. The combination of two gametes, each containing half a set of homologous
chromosomes, is required to produce each new diploid offspring. In the earlier population, which reproduced via
asexual reproduction, a cell either carried the smooth allele or the ruffled allele. With sexual reproduction, a cell inherits one allele from each parent, so there are homozygous cells that contain two smooth alleles, homozygous cells
that contain two ruffled alleles, and heterozygous cells that contain one of each allele. If the new, ruffled allele happens
to be dominant and we’ll imagine that it is), the heterozygotes will have ruffled cell phenotypes, but will have a 50:50
chance of passing on a smooth allele to each offspring.
In sexually reproducing populations including humans and many other animals and plants in the world today), that
50:50 chance of inheriting one or the other allele from each parent plays a major role in the random nature of genetic
drift.
Population Bottlenecks
A population bottleneck occurs when the number of individuals in a population drops dramatically due to some random event. The most obvious, familiar examples are natural disasters. Tsunamis and hurricanes devastating island and coastal
populations and forest fires and river floods wiping out populations in other areas are all too familiar. When a large
portion of a population is randomly wiped out, the allele frequencies i.e., the percentages of each allele) in the small
population of survivors are often much different from the frequencies in the pre-disaster, or “parent,” population. If
such an event happened to our primordial ocean cell population—perhaps a volcanic fissure erupted in the ocean floor
and only the cells that happened to be farthest from the spewing lava and boiling water survived—we might end up, by
random chance, with a surviving population that had mostly ruffled alleles, in contrast to the parent population, which
had only a small percentage of ruffles.
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One of the most famous examples of a population bottleneck is
the prehistoric disaster that led to the extinction of dinosaurs,
the Cretaceous–Paleogene extinction event often abbreviated K–Pg; previously K-T). This occurred approximately 66 million
years ago. Dinosaurs and all their neighbors were going about
their ordinary routines when a massive asteroid zoomed in
from space and crashed into what is now the Gulf of Mexico,
creating an impact so enormous that populations within
hundreds of miles of the crash site were likely immediately
wiped out. The skies filled with dust and debris, causing
temperatures to plummet worldwide. It’s estimated that 75% of
the world’s species went extinct as a result of the impact and
the deep freeze that followed Jablonski and Chaloner 1994).
The populations that emerged from the K-Pg extinction were
markedly different from their pre-disaster communities.
Surviving mammal populations expanded and diversified, and
other new creatures appeared. The ecosystems of Earth filled with new organisms and have never been the same Figure
4.12).
Figure 4.12 The Cretaceous–Paleogene extinction event. Fall of the dinosaurs and rise of the mammals.
Much more recently in geological time, during the colonial period, many human populations experienced bottlenecks
as a result of the fact that imperial powers were inclined to slaughter communities who were reluctant to give up
their lands and resources. This effect was especially profound in the Americas, where indigenous populations faced the
compounded effects of brutal warfare, exposure to new bacteria and viruses against which they had no immunity), and
ultimately segregation on resource-starved reservations. The populations in Europe, Asia, and Africa had experienced
regular gene flow during the 10,000-year period in which most kinds of livestock were being domesticated, giving them
many generations of experience building up immunity against zoonotic diseases those that can pass from animals to
humans). In contrast, the residents of the Americas had been almost completely isolated during those millennia, so
all these diseases swept through the Americas in rapid succession, creating a major loss of genetic diversity in the
indigenous American population. It is estimated that between 50% and 95% of the indigenous American populations
died during the first decades after European contact, around 500 years ago Livi-Bacci 2006).
An urgent health challenge facing humans today involves human-induced population bottlenecks that produce
antibiotic-resistant bacteria. Antibiotics are medicines prescribed to treat bacterial infections. The typical prescription includes enough medicine for ten days. People often feel better after less than ten days and sometimes decide to
quit taking the medicine ahead of schedule. This is often a big mistake. The antibiotics have quickly killed off a large
percentage of the bacteria—enough to reduce the symptoms and make you feel much better. However, this has created
a bacterial population bottleneck. There are usually a small number of bacteria that survive those early days. If you take
the medicine as prescribed for the full ten days, it’s quite likely that there will be no bacterial survivors. If you quit early,
though, the survivors—who were the members of the original population who were most resistant to the antibiotic—will
begin to reproduce again. Soon the infection will be back, possibly worse than before, and now all of the bacteria are
resistant to the antibiotic that you had been prescribed.
Other activities that have contributed to the rise of antibiotic-resistant bacteria include the use of antibacterial cleaning
products and the inappropriate use of antibiotics as a preventative measure in livestock or to treat infections that are
viral instead of bacterial viruses do not respond to antibiotics). In 2017, the World Health Organization published a list
of twelve antibiotic-resistant pathogens that are considered top priority targets for the development of new antibiotics
World Health Organization 2017).
Forces of Evolution | 123
Founder Effects
Founder effects occur when members of a population leave the main or “parent” group and form a new population that no longer interbreeds with the other members of the original group. Similar to survivors of a population bottleneck, the
newly founded population often has allele frequencies that are different from the original group. Alleles that may have
been relatively rare in the parent population can end up being very common due to founder effect. Likewise, recessive
traits that were seldom seen in the parent population may be seen frequently in the descendants of the offshoot
population. One striking example of founder effect was first noted in the Dominican Republic in the 1970s. During
a several-year period, eighteen children who had been born with female genitalia and raised as girls suddenly grew
penises at puberty. This culture tended to value sons over daughters, so these transitions were generally celebrated.
They labeled the condition guevedoces, which translates to “penis at twelve,” due to the average age at which this occurred. Scientists were fascinated by the phenomenon.
Genetic and hormonal studies revealed that the condition, scientifically termed 5-alpha reductase deficiency, is an autosomal recessive syndrome that manifests when a child having both X and Y sex chromosomes inherits two
nonfunctional mutated) copies of the SRD5A2 gene Imperato-McGinley and Zhu 2002). These children develop testes
internally, but the 5-alpha reductase 2 steroid, which is necessary for development of male genitals in babies, is not
produced. In absence of this male hormone, the baby develops female-looking genitalia in humans, “female” is the
default infant body form, if the full set of the necessary male hormones are not produced). At puberty, however, a
different set of male hormones are produced by other fully functional genes. These hormones complete the male genital
development that did not happen in infancy. This condition became quite common in the Dominican Republic during
the 1970s due to founder effect—that is, the mutated SRD5A2 gene happened to be much more common among the
Dominican Republic’s founding population than in the parent populations [the Dominican population derives from a
mixture of indigenous Native American Taino) peoples, West Africans, and Western Europeans]. Five-alpha reductase
syndrome has since been observed in other small, isolated populations around the world.
Founder effect is closely linked to the concept of inbreeding, which in population genetics does not necessarily mean
breeding with immediate family relatives. Instead, inbreeding refers to the selection of mates exclusively from within a small, closed population—that is, from a group with limited allelic variability. This can be observed in small, physically
isolated populations but also can happen when cultural practices limit mates to a small group. As with founder effect,
inbreeding increases the risk of inheriting two copies of any nonfunctional mutant) alleles.
The Amish in the United States are a population that, due to their unique history and cultural practices, emerged
from a small founding population and have tended to select mates from within their groups. The Old Order Amish population of Lancaster County, Pennsylvania, has approximately 50,000 current members, all of whom can trace their
ancestry back to a group of approximately 80 individuals. This small founding population immigrated to the United
States from Switzerland in the mid-1700s to escape religious persecution. Keeping to themselves, and selecting mates
almost exclusively from their own communities, the Amish have become familiar with far more recessive traits than are
seen in their parent population.
124 | Forces of Evolution
Figure 4.13 Photo of a man with polydactyly.
One of the genetic conditions that has been observed
much more frequently in the Lancaster County Amish
population is Ellis-van Creveld syndrome, which is an autosomal recessive disorder characterized by short
stature dwarfism), polydactyly [the development of more
than five digits fingers or toes) on the hands or feet],
abnormal tooth development, and heart defects see
Figure 4.13). Among the general world population, Ellis-
van Creveld syndrome is estimated to affect
approximately 1 in 60,000 individuals; among the Old
Order Amish of Lancaster County, the rate is estimated to
be as high as 1 in every 200 births D’Asdia et al. 2013). One
of the great insights that has come from the study of
founder effects is that a limited gene pool carries a much
higher risk for genetic diseases. Genetic diversity in a
population tends to greatly reduce these risks.
Gene Flow
The third force of evolution is traditionally called gene flow. As with genetic drift, this is a misnomer, because it refers to
flowing alleles, not genes. All populations of the same species share the same genes; it is the alleles of those genes that
may vary.) Gene flow refers to the movement of alleles from one population to another. In most cases, gene flow can be considered synonymous with migration between populations.
Returning again to the example of our primordial cell population, let’s imagine that, after the volcanic fissure opened
up in the ocean floor, wiping out the majority of the parent population, two surviving populations developed in the
waters on opposite sides of the fissure. Ultimately, the lava from the fissure grew into a chain of islands that continued
to provide a physical barrier between the populations, even after the lava had cooled.
In the initial generations after the eruption, due to founder effect, isolation, and random inheritance genetic drift),
the population to the west of the islands contained a vast majority of the ruffled membrane alleles while the eastern
population predominantly carried the smooth alleles. Ocean currents in the area typically flowed from west to east,
sometimes carrying cells facilitating gene flow) from the western ruffled) population to the eastern smooth)
population. Due to the ocean currents, it was almost impossible for any cells from the eastern population to be carried
westward. Thus, for inheritance purposes, the western ruffled) population remained isolated. In this case, the gene flow
is uni-directional going only in one direction) and unbalanced only one population is receiving the new alleles).
Admixture
Among humans, gene flow is often described as admixture. In forensic cases, anthropologists and geneticists are often asked to estimate the ancestry of unidentified human remains to help determine whether they match any
missing persons’ reports. This is one of the most complicated tasks in these professions because, while “race” or
“ancestry” involves simple checkboxes on a missing person’s form, among humans today there are no truly distinct
genetic populations. All modern humans are members of the same fully breeding-compatible species, and all human
Forces of Evolution | 125
communities have experienced multiple episodes of gene flow admixture), leading all humans today to be so genetically
similar that we are all members of the same and only surviving) human subspecies: Homo sapiens sapiens.
Gene flow between otherwise isolated non-human populations is often termed hybridization. One example of this involves the hybridization and spread of Africanized honey bees a.k.a., “killer bees”) in the Americas. All honey bees worldwide are classified as Apis mellifera. Due to distinct adaptations to various environments around the world, there
are 28 different subspecies of Apis mellifera.
During the 1950s, a Brazilian biologist named Warwick E. Kerr experimented with hybridizing African and European
subspecies of honey bees to try to develop a strain that was better suited to tropical environments than the European
honey bees that had long been kept by North American beekeepers. Dr. Kerr was careful to contain the reproductive
queens and drones from the African subspecies, but in 1957, a visiting beekeeper accidentally released 26 queen bees
of the subspecies Apis mellifera scutellate from southern Africa into the Brazilian countryside. The African bees quickly
interbred with local European honey bee populations. The hybridized bees exhibited the more aggressively defensive
behavior of the African strain, fatally or near-fatally attacking many humans and livestock that ventured too close to
their hives. The Africanized bees spread throughout South America and reached Mexico and California by 1985. By 1990,
permanent colonies had been established in Texas, and by 1997, 90% of trapped bee swarms around Tucson, Arizona,
were found to be Africanized Sanford 2006).
Another example involves the introduction of the Harlequin ladybeetle, Harmonia axyridis, native to East Asia, to other parts of the world as a “natural” form of pest control. Harlequin ladybeetles are natural predators of some of the aphids
and other crop-pest insects. First introduced to North America in 1916, the “biocontrol” strains of Harlequin ladybeetles
were considered to be quite successful in reducing crop pests and saving farmers substantial amounts of money. After
many decades of successful use in North America, biocontrol strains of Harlequin ladybeetles were also developed in
Europe and South America in the 1980s.
Over the seven decades of biocontrol use, the Harlequin ladybeetle had never shown any potential for development of
wild colonies outside of its native habitat in China and Japan. New generations of beetles always had to be reared in the
lab. That all changed in 1988, when a wild colony took root near New Orleans, Louisiana. Either through admixture with
a native ladybeetle strain, or due to a spontaneous mutation, a new allele was clearly introduced into this population that
suddenly enabled them to survive and reproduce in a wide range of environments. This population spread rapidly across
the Americas and had reached Africa by 2004. In Europe, the invasive, North American strain of Harlequin ladybeetle
admixed with the European strain Figure 4.14), causing a population explosion Lombaert et al. 2010). Even strains
specifically developed to be flightless to curtail the
spreading) produced flighted offspring after admixture
with members of the North American population Facon
et al. 2011). The fast-spreading, invasive strain has quickly
become a disaster, out-competing native ladybeetle
populations some to the point of extinction), causing
home infestations, decimating fruit crops, and
contaminating many batches of wine with their bitter
flavor after being inadvertently harvested with the grapes
Pickering et al. 2004).
Figure 4.14 Gene flow between two populations of ladybeetles (ladybugs).
Natural Selection
The final force of evolution is natural selection. This is the evolutionary process that Charles Darwin first brought to
126 | Forces of Evolution
light, and it is what the general public typically evokes when considering the process of evolution. Natural selection occurs when certain phenotypes confer an advantage or disadvantage in survival and/or reproductive success. The
alleles associated with those phenotypes will change in frequency over time due to this selective pressure. It’s also
important to note that the advantageous allele may change over time with environmental changes) and that an
allele that had previously been benign may become advantageous or detrimental. Of course, dominant, recessive,
and codominant traits will be selected upon a bit differently from one another. Because natural selection acts upon
phenotypes rather than the alleles themselves, deleterious disadvantageous) recessive alleles can be retained by
heterozygotes without any negative effects.
In the case of our primordial ocean cells, up until now, the texture of their cell membranes has been benign. The
frequencies of smooth to ruffled alleles, and smooth to ruffled phenotypes, has changed over time, due to genetic drift
and gene flow. Let’s now imagine that the Earth’s climate has cooled to a point that the waters frequently become too
cold for survival of the tiny bacteria that are the dietary staples of our smooth and ruffled cell populations. The way
amoeba-like cells “eat” is to stretch out the cell membrane, almost like an arm, to encapsulate, then ingest, the tiny
bacteria. When the temperatures plummet, the tiny bacteria populations plummet with them. Larger bacteria, however,
are better able to withstand the temperature change.
The smooth cells were well-adapted to ingesting tiny bacteria but poorly suited to encapsulating the larger bacteria.
The cells with the ruffled membranes, however, are easily able to extend their ruffles to encapsulate the larger bacteria.
They also find themselves able to stretch their entire membrane to a much larger size than their smooth-surfaced
neighbors, allowing them to ingest more bacteria at a given time and to go for longer periods between feedings. The
smooth and ruffled traits, which had previously offered no advantage or disadvantage while food was plentiful, now are
subject to natural selection. During the cold snaps, at least, the ruffled cells have a definite advantage. We can imagine
that the western population that has mostly ruffled alleles will continue to do well, while the eastern population, which
has a much smaller proportion of ruffled alleles, will gradually shift toward a higher frequency of ruffled alleles in future
generations.
A classic example of natural selection involves the study
of an insect called the peppered moth Biston betularia) in England during the Industrial Revolution in the 1800s.
Prior to the Industrial Revolution, the peppered moth
population was predominantly light in color, with dark
pepper-like) speckles on the wings. The “peppered”
coloration was very similar to the appearance of the bark
and lichens that grew on the local trees Figure 4.15). This
helped to camouflage the moths as they rested on a tree,
making it harder for moth-eating birds to find and snack
on them. There was another phenotype that popped up
occasionally in the population. These individuals were
heterozygotes that carried an overactive, dominant
pigment allele, producing a solid black coloration. As you
can imagine, the black moths were much easier for birds
to spot, making this phenotype a real disadvantage. The
situation changed, however, as the Industrial Revolution
took off. Large factories began spewing vast amounts of
coal smoke into the air, blanketing the countryside,
including the lichens and trees, in black soot. Suddenly, it
was the light-colored moths that were easy for birds to
spot and the black moths that held the advantage. The
Figure 4.15 Dark and light peppered moth variants and their relative camouflage abilities on clean (top) and sooty (bottom) trees.
Forces of Evolution | 127
frequency of the dark pigment allele rose dramatically. By 1895, the black moth phenotype accounted for 98% of
observed moths Grant 1999).
Thanks to new environmental regulations in the 1960s, the air pollution in England began to taper off. As the soot levels
decreased, returning the trees to their former, lighter color, this provided the perfect opportunity to study how the
peppered moth population would respond. Repeated follow-up studies documented the gradual rise in the frequency of
the lighter-colored phenotype. By 2003, the maximum frequency of the dark phenotype was 50% and in most parts of
England had decreased to less than 10% Cook 2003).
Directional, Balancing/Stabilizing, and Disruptive/Diversifying Selection
Natural selection can be classified as directional, balancing/stabilizing, or disruptive/diversifying, depending on how
the pressure is applied to the population Figure 4.16).
Both of the above examples of natural selection involve directional selection: the environmental pressures are favoring one phenotype over the other and causing the frequencies of the associated advantageous alleles ruffled membranes,
dark pigment) to
gradually increase. In the case of the peppered moths, the
direction shifted three times: first, it was selecting for
lighter pigment; then, with the increase in pollution, the
pressure switched to selection for darker pigment; finally,
with reduction of the pollution, the selection pressure
shifted back again to favoring light-colored moths.
Balancing selection a.k.a., stabilizing selection) occurs when selection works against the extremes of a trait and
favors the intermediate phenotype. For example, humans
maintain an average birth weight that balances the need
for babies to be small enough not to cause complications
during pregnancy and childbirth but big enough to
maintain a safe body temperature after they are born.
Another example of balancing selection is found in the
genetic disorder called sickle cell anemia, which is
featured in Case Study #2 see below).
Figure 4.16 Caption: (a) Balancing/Stabilizing, (b) Directional, and (c) Disruptive/Diversifying Selection.
Disruptive selection a.k.a., diversifying selection), the opposite of balancing selection, occurs when both
extremes of a trait are advantageous. Since individuals
with traits in the mid-range are selected against,
disruptive selection can eventually lead to the population
evolving into two separate species. Darwin believed that
the many species of finches small birds) found in the
remote Galapagos Islands provided a clear example of disruptive selection leading to speciation. He observed that seed-
eating finches either had large beaks, capable of eating very large seeds, or small beaks, capable of retrieving tiny seeds.
The islands did not have many plants that produced medium-size seeds. Thus, birds with medium-size beaks would have
trouble eating the very large seeds and would also have been inefficient at picking up the tiny seeds. Over time, Darwin
surmised, this pressure against mid-size beaks may have led the population to divide into two separate species.
128 | Forces of Evolution
Case Study #2 : Sickle Cell Anemia
Sickle cell anemia is an autosomal recessive genetic disorder that affects millions of people worldwide. It is most common in Africa, countries around the Mediterranean Sea, and eastward as far as India. Populations in the Americas
that have high percentages of ancestors from these regions also have high rates of sickle cell anemia. In the United
States, it’s estimated that 72,000 people live with the disease, with one in approximately 1,200 Hispanic-American babies
and one in every 500 African-American babies inheriting the condition World Health Organization 1996).
Figure 4.17 Sickle Cell Anemia. Arrows indicate (a) sickled and (b) normal red blood cells.
Sickle cell anemia affects the hemoglobin protein in red blood
cells. Normal red blood cells are somewhat doughnut-
shaped—round with a depression on both sides of the middle.
They carry oxygen around the bloodstream to cells throughout
the body. Red blood cells produced by the mutated form of the
gene take on a stiff, sickle-like crescent shape when stressed by
low oxygen or dehydration Figure 4.17). Because of their
elongated shape and the fact that they are stiff rather than
flexible, they tend to form clumps in the blood vessels, inhibiting
blood flow to adjacent areas of the body. This causes episodes of
extreme pain and can cause serious problems in the oxygen-
deprived tissues. The sickle cells also break down much more
quickly than normal cells, often lasting only 20 days rather than
the 120 days of normal cells. This causes an overall shortage of
blood cells in the sickle cell patient, resulting in low iron anemia) and problems associated with it such as extreme
fatigue, shortness of breath, and hindrances to children’s growth and development.
The devastating effects of sickle cell anemia made its high frequency a pressing mystery. Why would an allele that is
so deleterious in its homozygous form be maintained in a population at levels as high as the one in twelve African-
Americans estimated to carry at least one copy of the allele? The answer turned out to be one of the most interesting
cases of balancing selection in the history of genetic study.
While looking for an explanation, scientists noticed that the countries with high rates of sickle cell disease also shared a
high risk for another disease called malaria, which is caused by infection of the blood by a Plasmodium parasite. These parasites are carried by mosquitoes and enter the human bloodstream via a mosquito bite. Once infected, the person
will experience flu-like symptoms that, if untreated, can often lead to death. Researchers discovered that many people
living in these regions seemed to have a natural resistance to malaria. Further study revealed that people who carry the
sickle cell allele are far less likely to experience a severe case of malaria. This would not be enough of a benefit to make
the allele advantageous for the sickle cell homozygotes who face shortened life spans due to sickle cell anemia. The real
benefit of the sickle cell allele goes to the heterozygotes.
People who are heterozygous for sickle cell carry one normal allele, which produces the normal, round, red blood cells,
and one sickle cell allele, which produces the sickle-shaped red blood cells. Thus, they have both the sickle and round
blood cell types in their bloodstream. They produce enough of the round red blood cells to avoid the symptoms of sickle
cell anemia, but they have enough sickle cells to provide protection from malaria.
When the Plasmodium parasites infect an individual, they begin to multiply in the liver, but then must infect the red
blood cells to complete their reproductive cycle. When the parasites enter sickle-type cells, the cells respond by taking
on the sickle shape. This prevents the parasite from circulating through the bloodstream and completing its life cycle,
greatly inhibiting the severity of the infection in the sickle cell heterozygotes compared to non-sickle-cell homozygotes.
See chapter 14 for more discussion of sickle cell anemia.
Forces of Evolution | 129
Sexual Selection
Sexual selection is an aspect of natural selection in which the selective pressure specifically affects reproductive success the ability to successfully breed and raise offspring) rather than survival. Sexual selection favors traits that will
attract a mate. Sometimes these sexually appealing traits even carry greater risks in terms of survival.
A classic example of sexual selection involves the brightly colored feathers of the peacock. The peacock is the male sex of the peafowl genera Pavo and Afropavo. During mating season, peacocks will fan their colorful tails wide and strut in
front of the peahens in a grand display. The peahens will carefully observe these displays and will elect to mate with the
male that they find the most appealing. Many studies have found that peahens prefer the males with the fullest, most
colorful tails. While these large, showy tails provide a reproductive advantage, they can be a real burden in terms of
escaping predators. The bright colors and patterns as well as the large size of the peacock tail make it difficult to hide.
Once predators spot them, peacocks also struggle to fly away, with the heavy tail trailing behind and weighing them
down Figure 4.18). Some researchers have argued that the increased risk is part of the appeal for the peahens: only an
especially strong, alert, and healthy peacock would be able to avoid predators while sporting such a spectacular tail.
Figure 4.18 Showy peacock tail advantages (impressing peahens) and disadvantages (becoming easier prey).
It’s important to keep in mind that sexual selection relies on the
trait being present throughout mating years. Reflecting back on
Case Study #1, the examination of the NF1 genetic disorder, some
might find it surprising that half of the babies born with NF1
inherited it from a parent. Given how disfiguring the symptoms can
become, and the fact that the disorder is autosomal dominant and
fully penetrant meaning it has no unaffected carriers), it may seem
surprising that sexual selection doesn’t exert more pressure against
the mutated alleles. One important factor is that, while the
neurofibromas typically begin to appear during puberty, they
usually emerge only a few at a time and may grow very slowly. Many
NF1 patients don’t experience the more severe or disfiguring
symptoms until later in life, long after they have started families of
their own.
Some researchers prefer to classify sexual selection separately, as a
fifth force of evolution. The traits that underpin mate selection are
entirely natural, of course. Research has shown that subtle traits,
such as the type of pheromones hormonal odors related to
immune system alleles) someone emits and how those are
perceived by the immune system genotype of the “sniffer,” may play crucial and subconscious roles in whether we find
someone attractive or not Chaix et al. 2008).
130 | Forces of Evolution
SPECIAL TOPIC: THE REAL PRIMORDIAL CELLS— ICTYOSTELIUM ISCOI EUM
The amoeba-like primordial cells that were used as recurring examples throughout this chapter are inspired
by actual research that is truly fascinating. In 2015, Gareth Bloomfield and colleagues reported on their
genomic study of the social amoeba Dictyostelium discoideum a.k.a., “slime molds,” although technically they are amoebae, not molds). Strains of these amoebae have been grown in research laboratories for many
decades and are useful in studying phagocytosis and micropinocytosis—the mechanisms that amoeboid
single-celled organisms use to ingest food and liquid. For simplification of our examples in this chapter,
our amoeba-like cells remained ocean dwellers. Wild Dictyostelium discoideum, however, live in soil and
feed on soil bacteria by growing ruffles in their membranes that reach out to encapsulate the bacterial cell.
Laboratory strains, however, are typically raised on liquid media agar) in Petri dishes, which is not suitable
for the wild-type amoebae. It was widely known that the laboratory strains must have developed mutations
in one or more genes to allow them to ingest the larger nutrient particles in the agar and larger volumes of
liquid, but the genes involved were not known.
Bloomfield and colleagues performed genomic testing on both the wild and the laboratory strains of
Dictyostelium discoideum. Their discovery was astounding: every one of the laboratory strains carried a
mutation in the NF1 gene, the very same gene associated with Neurofibromatosis Type 1 NF1) in humans. The
antiquity of this massive, easily mutated gene is incredible. It originated in a common ancestor to humans
and these amoebae and has been retained in both lineages ever since. As seen in Dictyostelium discoideum,
breaking the gene can be advantageous. Without a functioning copy of the neurofibromin protein, the cell
membrane is able to form much larger feeding structures, allowing the NF1 mutants to ingest larger particles
and larger volumes of liquid. For these amoebae, this may provide dietary flexibility that functions somewhat
like an insurance policy for times when the food supply is limited.
Dictyostelium discoideum are also interesting in that they typically reproduce asexually, but under certain
conditions, one cell will convert into a “giant” cell, which encapsulates surrounding cells, transforming into
one of three sexes. This cell will undergo meiosis, producing gametes that must combine with one of the
other two sexes in order to produce viable offspring. This ability for sexual reproduction may be what allows
Dictyostelium discoideum to benefit from the advantages of NF1 mutation, while also being able to restore the
wild type NF1 gene in future generations.
What does this mean for humans living with NF1? Well, understanding the role of the neurofibromin protein
in the membranes of simple organisms like Dictyostelium discoideum may help us to better understand
how it functions and malfunctions in the sheaths of human neurons. It’s also possible that the mutability
of the NF1 gene confers certain advantages to humans as well. Alleles of the NF1 gene have been found to
reduce one’s risk for alcoholism Repunte-Canonigo et al. 2015), opiate addiction Sanna et al. 2002), Type 2
diabetes Martins et al. 2016), and hypomusicality a lower-than-average musical aptitude; Cota et al. 2018).
This research is ongoing and will be exciting to follow in the coming years.
Forces of Evolution | 131
STUDYING EVOLUTION IN ACTION
The Hardy-Weinberg Equilibrium
This chapter has introduced you to the forces of evolution, the mechanisms by which evolution occurs. How do we
detect and study evolution, though, in real time, as it happens? One tool we use is the Hardy-Weinberg Equilibrium: a mathematical formula that allows estimation of the number and distribution of dominant and recessive alleles in a
population. This aids in determining whether allele frequencies are changing and, if so, how quickly over time, and in
favor of which allele? It’s important to note that the Hardy-Weinberg formula only gives us an estimate based on the
data for a snapshot in time. We will have to calculate it again later, after various intervals, to determine if our population
is evolving and in what way the allele frequencies are changing. To learn how to calculate the Hardy-Weinberg formula,
see the Special Topic box at the end of the chapter.
Interpreting Evolutionary Change
Once we have detected change occurring in a population, we need to consider which evolutionary processes might be
the cause of the change. It is important to watch for non-random mating patterns, to see if they can be included or
excluded as possible sources of variation in allele frequencies.
Non-Random Mating
Non-Random Mating also known as Assortative Mating) occurs when mate choice within a population follows a non- random pattern. Positive assortative mating patterns result from a tendency for individuals to mate with others who share similar phenotypes. This often happens based on body size. Taking as an example dog breeds, it is easier for two
Chihuahuas to mate and have healthy offspring than it is for a Chihuahua and a St. Bernard to do so. This is especially
true if the Chihuahua is the female and would have to give birth to giant St. Bernard pups.
Negative assortative mating patterns occur when individuals tend to select mates with qualities different from their own. This is what is at work when humans choose partners whose pheromones indicate that they have different and
complementary immune alleles, providing potential offspring with a better chance at a stronger immune system.
Among domestic animals, such as pets and livestock, assortative mating is often directed by humans who decide which
pairs will mate to increase the chances of offspring having certain desirable traits. This is known as artificial selection.
Among humans, in addition to phenotypic traits, cultural traits such as religion and ethnicity may also influence
assortative mating patterns.
Micro- to Macroevolution
Microevolution refers to changes in allele frequencies within breeding populations, that is, within single species. Macroevolution involves changes that result in the emergence of new species, the similarities and differences between
132 | Forces of Evolution
species and their phylogenetic relationships with other taxa. Consider our example of the peppered moth which
illustrated microevolution over time, via directional selection favoring the peppered allele when the trees were clean
and the dark pigment allele when the trees were sooty. Imagine that environmental regulations had cleaned up the
air pollution in one part of the nation, while the coal-fired factories continued to spew soot in another area. If this
went on long enough, it’s possible that two distinct moth populations would eventually emerge—one containing only the
peppered allele and the other only harboring the dark pigment allele.
When a single population divides into two or more separate species, it is called speciation. The changes that prevent successful breeding between individuals who descended from the same ancestral population may involve chromosomal
rearrangements, changes in the ability of the sperm from one species to permeate the egg membrane of the other
species, or dramatic changes in hormonal schedules or mating behaviors that prevent members from the new species
from being able to effectively pair up.
There are two types of speciation: allopatric and sympatric. Allopatric speciation is caused by long-term isolation physical separation) of subgroups of the population Figure 4.19). Something occurs in the environment—perhaps a river
changes its course and splits the group, preventing them from breeding with members on the opposite riverbank. Over
many generations, new mutations and adaptations to the different environments on each side of the river may drive the
two subpopulations to change so much that they can no longer produce fertile, viable offspring, even if the barrier is
someday removed.
Figure 4.19 Isolation leading to speciation: (a) original population before isolation; (b) a barrier divides the population and prevents interbreeding between the two groups; (c) time passes, and the populations become genetically distinct; (d) after many generations, the two populations are no longer biologically or behaviorally compatible, thus can no longer interbreed, even if the barrier is removed.
Sympatric speciation occurs when the population splits into two or more separate species while remaining located together without a physical barrier. This typically results from a new mutation that pops up among some members of
the population that prevents them from successfully reproducing with anyone who does not carry the same mutation.
This is seen particularly often in plants, as they have a higher frequency of chromosomal duplications.
One of the quickest rates of speciation is observed in the case of adaptive radiation. Adaptive radiation refers to the situation in which subgroups of a single species rapidly diversify and adapt to fill a variety of ecological niches. An
ecological niche is a set of constraints and resources that is available in an environmental setting. Evidence for adaptive radiations is often seen after population bottlenecks. A mass disaster kills off many species, and the survivors have
access to a new set of territories and resources that were either unavailable or much coveted and fought over before
Forces of Evolution | 133
the disaster. The offspring of the surviving population will often split into multiple species, each of which stems from
members in that first group of survivors who happened to carry alleles that were advantageous for a particular niche.
The classic example of adaptive radiation brings us back to Charles Darwin and his observations of the many species
of finches on the Galapagos Islands. We are still not sure how the ancestral population of finches first arrived on that
remote Pacific Island chain, but they found themselves in an environment filled with various insects, large and tiny
seeds, fruit, and delicious varieties of cactus. Some members of that initial population carried alleles that gave them
advantages for each of these dietary niches. In subsequent generations, others developed new mutations, some of which
were beneficial. These traits were selected for, making the advantageous alleles more common among their offspring.
As the finches spread from one island to the next, they would be far more likely to find mates among the birds on their
new island. Birds feeding in the same area were then more likely to mate together than birds who have different diets,
contributing to additional assortative mating. Together, these evolutionary mechanisms caused rapid speciation that
allowed the new species to make the most of the various dietary niches Figure 4.20).
Figure 4.20 Darwin’s finches demonstrating Adaptive Radiation.
In today’s modern world, understanding these evolutionary processes is crucial for developing immunizations and
antibiotics that can keep up with the rapid mutation rate of viruses and bacteria. This is also relevant to our food supply,
which relies, in large part, on the development of herbicides and pesticides that keep up with the mutation rates of
pests and weeds. Viruses, bacteria, agricultural pests, and weeds have all shown great flexibility in developing alleles that
make them resistant to the latest medical treatment, pesticide, or herbicide. Billion-dollar industries have specialized in
trying to keep our species one step ahead of the next mutation in the pests and infectious diseases that put our survival
at risk.
134 | Forces of Evolution
SPECIAL TOPIC: CALCULATING THE HARDY-WEINBERG EQUILIBRIUM
In the Hardy-Weinberg formula, p represents the frequency of the dominant allele, and q represents the
frequency of the recessive allele. Remember, an allele’s frequency is the proportion, or percentage, of that
allele in the population. For the purposes of Hardy-Weinberg, we give the allele percentages as decimal
numbers e.g., 42% = 0.42), with the entire population 100% of alleles) equaling 1. If we can figure out the
frequency of one of the alleles in the population, then it is simple to calculate the other. Simply subtract the
known frequency from 1 the entire population). Therefore: 1 – p = q and 1 – q = p
The Hardy-Weinberg formula is p2 + 2pq + q2, where
p2 represents the frequency of the homozygous dominant genotype;
2pq represents the frequency of the heterozygous genotype; and
q2 represents the frequency of the homozygous recessive genotype.
It is often easiest to determine q2 first, simply by counting the number of individuals with the unique,
homozygous recessive phenotype then dividing by the total individuals in the population to arrive at the
“frequency”). If we can do this, we simply need to calculate the square root of the homozygous recessive
phenotype frequency. That gives us q. Remember, 1 – q equals p, so now we have the frequencies for both
alleles in the population. If we needed to figure out the frequencies of heterozygotes and homozygous
dominant genotypes, we’d just need to plug the p and q frequencies back into the p2 and 2pq formulas.
Let’s imagine we have a population of ladybeetles that carries two alleles: a
dominant allele that produces red ladybeetles and a recessive allele that
produces orange ladybeetles. Since red is dominant, we’ll use R to
represent the red allele, and r to represent the orange allele. Our
population has ten beetles, and seven are red and three are orange Figure
4.21). Let’s calculate the number of genotypes and alleles in this population.
We have three orange beetles of our ten, 3/10 = .30 30%) frequency, and
we know they are homozygous recessive rr). So:
rr = .3; therefore, r = √.3 = .5477
R = 1 – .5477 = .4523
Using the Hardy-Weinberg formula:
1=.45232 + 2 x .4523 x .5477 +.54772 = .20 + .50 + .30 = 1
Thus, the genotype breakdown is 20% RR, 50% Rr, and 30% rr
2 red homozygotes, 5 red heterozygotes, and 3 orange homozygotes).
Since we have 10 individuals, we know we have 20 total alleles: 4 red from the RR group, 5 red and 5 orange
from the Rr group, and 6 orange from the rr group, for a grand total of 9 red and 11 orange 45% red and
55% orange, just like we estimated in the 1 – q step).
Figure 4.21 Ladybug population with a mixture of dark (red) and light (orange) individuals.
Forces of Evolution | 135
Reminder: The Hardy-Weinberg formula only gives us an estimate for a snapshot in time. We will have to
calculate it again later, after various intervals, to determine if our population is evolving and in what way the
allele frequencies are changing.
Review Questions
• Devise an argument explaining how we know that the Pangenesis model for evolution is incorrect. Provide examples from the text of experiments that helped prove this wrong.
• You inherit a house from a long-lost relative that contains a fancy aquarium, filled with a variety of snails. The phenotypes include large snails and small snails; red, black, and yellow snails; and solid,
striped, and spotted snails. Devise a series of experiments that would help you determine how many
snail species are present in your aquarium.
• Imagine a population of common house mice Mus musculus). Draw a comic strip illustrating how mutation, genetic drift, gene flow, and natural selection might transform this population over several
or more) generations.
• The many breeds of the single species of domestic dog Canis familiaris) provide an extreme example of microevolution. Discuss why this is the case. What future scenarios can you imagine that could
potentially transform the domestic dog into an example of macroevolution?
• The ability to roll one’s tongue lift the outer edges of the tongue to touch each other, forming a tube) is a dominant trait. In small town of 1,500 people, 500 can roll their tongues. Use the Hardy-Weinberg
formula to determine how many individuals in the town are homozygous dominant, heterozygous, and
homozygous recessive.
• Match the correct force of evolution with the correct real-world example:
a. Mutation
b. Genetic Drift
c. Gene Flow
d. Natural Selection
i. 5-alpha reductase deficiency
ii. Peppered Moths
iii. Neurofibromatosis Type 1
iv. Africanized Honey Bees
Key Terms
5-alpha reductase deficiency: An autosomal recessive syndrome that manifests when a child having both X and Y sex chromosomes inherits two non-functional mutated) copies of the SRD5A2 gene, producing a deficiency in a hormone
necessary for development in infancy of typical male genitalia. These children often appear at birth to have female
genitalia, but they develop a penis and other sexual characteristics when other hormones kick in during puberty.
136 | Forces of Evolution
Adaptive radiation: The situation in which subgroups of a single species rapidly diversify and adapt to fill a variety of ecological niches.
Admixture: A term often used to describe gene flow between human populations. Sometimes also used to describe gene flow between non-human populations.
Africanized honey bees: A strain of honey bees that resulted from the hybridization of African and European honey bee subspecies. These bees were accidentally released into the wild in 1957 in Brazil, and have since spread throughout
South and Central America and into the United States. Also known as “killer bees,” they tend to be very aggressive in
defense of their hives and have caused many fatal injuries to humans and livestock.
Allele frequency: The ratio, or percentage, of one allele compared to the other alleles for that gene within the study population.
Alleles: Variant forms of genes.
Allopatric speciation: Speciation caused by long-term isolation physical separation) of subgroups of the population.
Antibiotics: Medicines prescribed to treat bacterial infections.
Artificial selection: Human-directed assortative mating among domestic animals, such as pets and livestock, designed to increase the chances of offspring having certain desirable traits.
Asexual reproduction: Reproduction via mitosis, whereby offspring are clones of the parents.
Autosomal dominant: A phenotype produced by a gene on an autosomal chromosome that is expressed, to the exclusion of the recessive phenotype, in heterozygotes.
Autosomal recessive: A phenotype produced by a gene on an autosomal chromosome that is expressed only in individuals homozygous for the recessive allele.
Balanced translocations: Chromosomal translocations in which the genes are swapped, but no genetic information is lost.
Balancing selection: A pattern of natural selection that occurs when the extremes of a trait are selected against, favoring the intermediate phenotype a.k.a., stabilizing selection).
Beneficial mutations: Mutations that produce some sort of an advantage to the individual.
Benign: Non-cancerous. Benign tumors may cause problems due to the area in which they are located e.g., they might put pressure on a nerve or brain area), but they will not release cells that aggressively spread to other areas of the body.
Biometricians: A group of early biological scientists who believed that individual mutations of discrete hereditary units could never account for the continuous spectrum of variation seen in many traits.
Café-au-lait spots (CALS): Flat, brown birthmark-like spots on the skin, commonly associated with Neurofibromatosis Type 1.
Chromosomal translocations: The transfer of DNA between non-homologous chromosomes.
Chromosomes: Molecules that carry collections of genes.
Codons: Three-nucleotide units of DNA that function as three-letter “words,” encoding instructions for the addition of one amino acid to a protein or indicating that the protein is complete.
Forces of Evolution | 137
Cretaceous–Paleogene extinction: A mass disaster caused by an asteroid that struck the earth approximately 66 million years ago and killed 75% of life on Earth, including all terrestrial dinosaurs. a.k.a., K-Pg Extinction, Cretatious-Tertiary
Extinction and K-T Extinction).
Crossover events: Chromosomal alterations that occur when DNA is swapped between homologous chromosomes while they are paired up during meiosis I.
Cutaneous neurofibromas: Neurofibromas that manifest as spherical bumps on or just under the surface of the skin.
Cytosine methylation: A type of point mutation in which a cytosine nucleotide is converted to a thymine. A methyl group is added to a cytosine base, changing it to 5-methyl cytosine, which further converts to thymine after hydrolytic
deamination water-induced removal of an amine group).
Deleterious mutation: A mutation producing negative effects to the individual such as the beginnings of cancers or heritable disorders.
Deletions: Mutations that involve removal of one or more nucleotides from a DNA sequence.
Derivative chromosomes: New chromosomal structures resulting from translocations.
Dictyostelium discoideum: A species of social amoebae that has been widely used for laboratory research. Laboratory strains of Dictyostelium discoideum all carry mutations in the NF1 gene, which is what allows them to survive on liquid
media agar) in Petri dishes.
Directional selection: A pattern of natural selection in which one phenotype is favored over the other, causing the frequencies of the associated advantageous alleles to gradually increase.
Disruptive selection: A pattern of natural selection that occurs when both extremes of a trait are advantageous and intermediate phenotypes are selected against a.k.a., diversifying selection).
DNA repair mechanisms: Enzymes that patrol and repair DNA in living cells.
DNA transposons: Transposons that are clipped out of the DNA sequence itself and inserted elsewhere in the genome.
Ecological niche: A set of constraints and resources that are available in an environmental setting.
Ellis-van Creveld syndrome: An autosomal recessive disorder characterized by short stature dwarfism), polydactyly [the development of more than five digits fingers or toes) on the hands or feet], abnormal tooth development, and
heart defects. Estimated to affect approximately one in 60,000 individuals worldwide, among the Old Order Amish of
Lancaster County, the rate is estimated to be as high as one in every 200 births.
Evolution: A change in the allele frequencies in a population over time.
Exons: The DNA sequences within a gene that directly encode protein sequences. After being transcribed into messenger RNA, the introns are clipped out, and the exons are pasted together prior to translation.
Fertile offspring: Offspring that can reproduce successfully to have offspring of their own.
Founder effect: A type of genetic drift that occurs when members of a population leave the main or “parent” group and form a new population that no longer interbreeds with the other members of the original group.
Frameshift mutations: Types of indels that involve the insertion or deletion of any number of nucleotides that is not a multiple of three. These “shift the reading frame” and cause all codons beyond the mutation to be misread.
138 | Forces of Evolution
Gametes: The reproductive cells, produced through meiosis a.k.a., germ cells or sperm or egg cells).
Gene: A sequence of DNA that provides coding information for the construction of proteins.
Gene flow: The movement of alleles from one population to another. This is one of the forces of evolution.
Gene pool: The entire collection of genetic material in a breeding community that can be passed on from one generation to the next.
Genetic drift: Random changes in allele frequencies within a population from one generation to the next. This is one of the forces of evolution.
Genotype: The set of alleles that an individual has for a given gene.
Genotype frequencies: The ratios or percentages of the different homozygous and heterozygous genotypes in the population.
Guevedoces: The term coined locally in the Dominican Republic for the condition scientifically known as 5-alpha reductase deficiency. The literal translation is “penis at twelve.”
Hardy-Weinberg Equilibrium: A mathematical formula p2 + 2pq + q2 ) that allows estimation of the number and distribution of dominant and recessive alleles in a population.
Harlequin ladybeetle: A species of ladybeetle, native to East Asia, that was introduced to Europe and the Americas as a form of pest control. After many decades of use, one of the North American strains developed the ability to reproduce in
diverse environments, causing it to spread rapidly throughout the Americas, Europe, and Africa. It has hybridized with
European strains and is now a major pest in its own right.
Heterozygous genotype: A genotype comprising two different alleles.
Homozygous genotype: A genotype comprising an identical set of alleles.
Hybridization: A term often used to describe gene flow between non-human populations.
Inbreeding: The selection of mates exclusively from within a small, closed population.
Indels: A class of mutations that includes both insertions and deletions.
Inherited mutation: A mutation that has been passed from parent to offspring.
Insertions: Mutations that involve addition of one or more nucleotides into a DNA sequence.
Introns: DNA sequences within a gene that do not directly encode protein sequences. After being transcribed into messenger RNA, the introns are clipped out, and the exons are pasted together prior to translation.
Isolation: Prevention of a population subgroup from breeding with other members of the same species due to a physical barrier or in humans) a cultural rule.
Lamarckian inheritance: An early model for inheritance that predicted that offspring inherit characteristics acquired during their parents’ lifetimes. This has now been proven incorrect.
Macroevolution: Changes that result in the emergence of new species, the similarities and differences between species, and their phylogenetic relationships with other taxa.
Malaria: A frequently deadly mosquito-borne disease caused by infection of the blood by a Plasmodium parasite.
Forces of Evolution | 139
Malignant: Cancerous. Malignant tumors grow aggressively and their cells may metastasize travel through the blood or lymph systems) to form new, aggressive tumors in other areas of the body.
Microevolution: Changes in allele frequencies within breeding populations—that is, within a single species.
Missense mutation: A point mutation that produces a change in a single amino acid.
Modern Synthesis: The integration of Darwin’s, Mendel’s, and subsequent research into a unified theory of evolution.
Monosomies: Conditions resulting from a non-disjunction event, in which a cell ends up with only one copy of a chromosome. In humans, a single X chromosome is the only survivable monosomy.
Mutation: A change in the nucleotide sequence of the genetic code. This is one of the forces of evolution.
Mutationists: A group of early biological scientists who believed that variation was caused by mutations in distinct, inherited cells.
Natural selection: An evolutionary process that occurs when certain phenotypes confer an advantage or disadvantage in survival and/or reproductive success. This is one of the forces of evolution.
Negative assortative mating: A pattern that occurs when individuals tend to select mates with qualities different from their own.
Neurofibromas: Nerve sheath tumors that are common symptoms of Neurofibromatosis Type 1.
Neurofibromatosis Type 1: An autosomal dominant genetic disorder affecting one in every 3,000 people. It is caused by mutation of the NF1 gene on Chromosome 17, resulting in a defective neurofibromin protein. The disorder is
characterized by neurofibromas, café-au-lait spots, and a host of other potential symptoms.
NF1: An abbreviation for Neurofibromatosis Type 1. When italicized, NF1 refers to the gene on Chromosome 17 that encodes the neurofibromin protein.
Nondisjunction events: Chromosomal abnormalities that occur when the homologous chromosomes in meiosis I) or sister chromatids in meiosis II and mitosis) fail to separate after pairing. The result is that both chromosomes or
chromatids end up in the same daughter cell, leaving the other daughter cell without any copy of that chromosome.
Non-random mating: A scenario in which mate choice within a population follows a non-random pattern a.k.a., Assortative Mating).
Nonsense mutation: A point mutation that converts a codon that encodes an amino acid into a stop codon.
Non-synonymous mutation: A point mutation that causes a change in the resulting protein.
Old Order Amish: A culturally isolated population in Lancaster County, Pennsylvania, that has approximately 50,000 current members, all of whom can trace their ancestry back to a group of approximately eighty individuals. This group
has high rates of certain genetics disorders including Ellis-van Creveld syndrome.
Origins of life: How the first living organism came into being.
Pangenesis: An early model for inheritance that combines the Lamarckian idea of inheriting acquired characteristics with the idea that particles from different parts of the body make their way to the sex cells. This has now been proven
to be incorrect.
140 | Forces of Evolution
Peacock: The male sex of the peafowl, famous for its large, colorful tail, which it dramatically displays to attract mates. The female of the species is known as a peahen.)
Peppered moth: A species of moth found in England that has light and dark phenotypes. During the Industrial Revolution, when soot blackened the trees, the frequency of the previously rare dark phenotype dramatically increased,
as lighter-colored moths were easier for birds to spot against the sooty trees. After environmental regulations
eliminated the soot, the lighter-colored phenotype gradually became most common again.
Phenotype: The observable traits that are produced by a genotype.
Phylogenetic tree of life: A family tree of all living organisms, based on genetic relationships.
Phylogenies: Genetically determined family lineages.
Plasmodium: A genus of mosquito-borne parasite. Several Plasmodium species cause malaria when introduced to the human bloodstream via a mosquito bite.
Plexiform neurofibromas: Neurofibromas that involve whole branches of nerves, often giving the appearance that the surface of the skin is “melting.”
Point mutation: A single-letter single-nucleotide) change in the genetic code, resulting in the substitution of one nucleic acid base for a different one.
Polymorphisms: Multiple forms of a trait; alternative phenotypes within a given species.
Population: A group of individuals who are genetically similar enough and geographically near enough to one another that they can breed and produce new generations of individuals.
Population bottleneck: A type of genetic drift that occurs when the number of individuals in a population drops dramatically due to some random event.
Positive assortative mating: A pattern that results from a tendency for individuals to mate with others who share similar phenotypes.
Retrotransposons: Transposons that are transcribed from DNA into RNA, and then are “reverse transcribed,” to insert the copied sequence into a new location in the DNA.
Sexual reproduction: Reproduction via meiosis and combination of gametes. Offspring inherit genetic material from both parents.
Sexual selection: An aspect of natural selection in which the selective pressure specifically affects reproductive success the ability to successfully breed and raise offspring).
Sickle cell anemia: An autosomal recessive genetic disorder that affects millions of people worldwide. It is most common in Africa, countries around the Mediterranean Sea, and eastward as far as India. Homozygotes for the recessive allele
develop the disorder, which produce misshapen red blood cells that cause iron deficiency, painful episodes of oxygen-
deprivation in localized tissues, and a host of other symptoms. In heterozygotes, though, the sickle cell allele confers a
greater resistance to malaria.
Somatic cells: The cells of our organs and other body tissues all cells except gametes) that replicate by mitosis.
Speciation: The process by which a single population divides into two or more separate species.
Forces of Evolution | 141
Species: Organisms whose individuals are capable of breeding because they are biologically and behaviorally compatible to produce viable, fertile offspring.
Splice site mutation: A mutation that changes the genetic code so that the correct area to be modified for mRNA splicing is not recognized by the appropriate enzymes.
Spontaneous mutation: A mutation that occurs due to random chance or unintentional exposure to mutagens. In families, a spontaneous mutation is the first case, as opposed to mutations that are inherited from parents.
Subspecies: A distinct subtype of a species. Most often, this is a geographically isolated population with unique phenotypes; however, it remains biologically and behaviorally capable of interbreeding with other populations of the
same species.
Sympatric speciation: When a population splits into two or more separate species while remaining located together without a physical or cultural) barrier.
Synonymous mutation: A point mutation that does not change the resulting protein.
Transposable elements: Fragments of DNA that can “jump” around in the genome.
Transposon: Another term for “transposable element.”
Trisomies: Conditions in which three copies of the same chromosome end up in a cell, resulting from a non-disjunction event. Down syndrome, Edwards syndrome, and Patau syndrome are trisomies.
Unbalanced translocations: Chromosomal translocations in which there is an unequal exchange of genetic material resulting in duplication or loss of genes.
Universal ancestor: The first living organism, from which all living things are descended.
UV crosslinking: A type of mutation in which adjacent thymine bases bind to one another in the presence of UV light.
Viable Offspring: Offspring that are healthy enough to survive to adulthood.
Xeroderma pigmentosum: An autosomal recessive disease in which DNA repair mechanisms do not function correctly, resulting in a host of problems, especially related to sun exposure, including severe sunburns, dry skin, heavy freckling,
and other pigment changes.
142 | Forces of Evolution
About the Author
Andrea Alveshere
Western Illinois University, [email protected], http://www.wiu.edu/cas/anthropology/faculty-staff/alveshere.php
Dr. Alveshere at the summit of Monk’s Mound at the Cahokia Mississippian site in Collinsville, Illinois. Note the St. Louis, Missouri, skyline in the background.
Dr. Andrea Alveshere is an assistant professor of anthropology and chemistry
at Western Illinois University. Her research focuses on relationships between
humans and their environments, including questions of diet and health;
cultural and biological adaptations; genetic disorders such as
Neurofibromatosis Type 1 NF1); effects of environmental factors on the
preservation of bones, plant remains, and the molecules within them; and the
comparative utility of various field and laboratory techniques to produce
informative archaeological, nutritional, and forensic data.
Dr. Alveshere earned her B.A. in anthropology at the University of Washington
with an emphasis in archaeology and an undergraduate research focus on the
analysis of skeletal remains and geoarchaeological deposits. At the University
of Minnesota, she completed her Ph.D. in anthropology, with a minor in human
genetics. Her graduate thesis investigated factors that influence the
preservation and detection of DNA in ancient and forensic specimens.
In addition to her academic experience, Dr. Alveshere worked for several years as a forensic scientist in the DNA/
Biology section of the Minnesota Bureau of Criminal Apprehension Forensic Science Laboratory. She leads the WIU
Archaeological Field School, which is offered every other summer, and has also conducted archaeological excavations in
Israel, South Africa, and throughout the Midwestern United States.
For Further Exploration
Explore Evolution. HHMI’s Biointeractive. https://www.hhmi.org/biointeractive/evolution-collection
Teaching Evolution Through Human Examples. Smithsonian Museum of Natural History. http://humanorigins.si.edu/
education/teaching-evolution-through-human-examples
References
Bloomfield, Gareth, David Traynor, Sophia P. Sander, Douwe M. Veltman, Justin A. Pachebat, and Robert R. Kay. 2015.
“Neurofibromin Controls Macropinocytosis and Phagocytosis in Dictyostelium.” eLife 4:e04940.
Castle, W. E., and J. C. Phillips. 1914. Piebald Rats and Selection: An Experimental Test of the Effectiveness of Selection
and of the Theory of Gametic Purity in Mendelian Crosses. Carnegie Institute of Washington, No. 195. Washington,
DC: Carnegie Institute of Washington.
Forces of Evolution | 143
Chaix, Raphaëlle, Chen Cao, and Peter Donnelly. 2008. “Is Mate Choice in Humans MHC-Dependent?” PLoS Genetics 4
9): e1000184.
Cook, Laurence M. 2003. “The Rise and Fall of the Carbonaria Form of the Peppered Moth.” The Quarterly Review of
Biology 78 4): 399–417.
Cota, Bruno Cézar Lage, João Gabriel Marques Fonseca, Luiz Oswaldo Carneiro Rodrigues, Nilton Alves de Rezende,
Pollyanna Barros Batista, Vincent Michael Riccardi, Luciana Macedo de Resende. 2018. “Amusia and Its
Electrophysiological Correlates in Neurofibromatosis Type 1.” Arquivos de Neuro-Psiquiatria 76 5): 287–295.
Darwin, Charles. 1859. On the Origin of Species by Means of Natural Selection, or the Preservation of Favoured Races in
the Struggle for Life. London: John Murray.
D’Asdia, Maria Cecilia, Isabella Torrente, Federica Consoli, Rosangela Ferese, Monia Magliozzi, Laura Bernardini,
Valentina Guida, et al. 2013. “Novel and Recurrent EVC and EVC2 Mutations in Ellis-van Creveld Syndrome and Weyers
Acrofacial Dyostosis.” European Journal of Medical Genetics 56 2): 80–87.
Dobzhansky, Theodosius 1937). Genetics and the Origin of Species. Columbia University Biological Series. New York:
Columbia University Press.
Facon, Benoît, Laurent Crespin, Anne Loiseau, Eric Lombaert, Alexandra Magro, Arnaud Estoup. 2011. “Can Things
Get Worse When an Invasive Species Hybridizes? The Harlequin Ladybird Harmonia axyridis in France as a Case
Study.” Evolutionary Applications 4 1): 71–88.
Fisher, Ronald A. 1919). “The Correlation Between Relatives on the Supposition of Mendelian Inheritance.” Transactions
of the Royal Society of Edinburgh 52 2): 399–433.
Ford, E. B. 1942. Genetics for Medical Students. London: Methuen.
Ford, E. B. 1949. Mendelism and Evolution. London: Methuen.
Grant, Bruce S. 1999. “Fine-tuning the Peppered Moth Paradigm.” Evolution 53 3): 980–984.
Haldane, J. B. S. 1924. “A Mathematical Theory of Natural and Artificial Selection Part 1).” Transactions of the Cambridge
Philosophical Society 23:19–41.
Huxley, Julian. 1942. Evolution: The Modern Synthesis. London: Allen & Unwin.
Imperato-McGinley, J., and Y.-S. Zhu. 2002. “Androgens and Male Physiology: The Syndrome of 5 Alpha-Reductase-2
Deficiency.” Molecular and Cellular Endocrinology 198: 51–59.
Jablonski, David, and W. G. Chaloner. 1994. “Extinctions in the Fossil Record [and Discussion].” Philosophical Transactions
of the Royal Society of London B: Biological Sciences 344 1,307): 11–17.
Livi-Bacci, Massimo. 2006. “The Depopulation of Hispanic America After the Conquest.” Population Development and
Review 32 2): 199–232.
Lombaert, Eric, Thomas Guillemaud, Jean-Marie Cornuet, Thibaut Malausa, Benoît Facon, and Arnaud Estoup. 2010.
“Bridgehead Effect in the Worldwide Invasion of the Biocontrol Harlequin Ladybird.” PLoS ONE 5 3): e9743.
Martins, Aline Stangherlin, Ann Kristine Jansen, Luiz Oswaldo Carneiro Rodrigues, Camila Maria Matos, Marcio Leandro
Ribeiro Souza, Juliana Ferreira de Souza, Maria de Fátima Haueisen Sander Diniz, et al. 2016. “Lower Fasting Blood
Glucose in Neurofibromatosis Type 1.” Endocrine Connections 5 1): 28–33.
144 | Forces of Evolution
Morgan, T. H. 1911. “Random Segregation Versus Coupling in Mendelian Inheritance.” Science 34 873): 384.
Pickering, Gary, James Lin, Roland Riesen, Andrew Reynolds, Ian Brindle, and George Soleas. 2004. “Influence
of Harmonia axyridis on the Sensory Properties of White and Red Wine.” American Journal of Enology and
Viticulture 55 2): 153–159.
Repunte-Canonigo Vez, Melissa A. Herman, Tomoya Kawamura, Henry R. Kranzler, Richard Sherva, Joel Gelernter,
Lindsay A. Farrer, Marisa Roberto, and Pietro Paolo Sanna. 2015. “NF1 Regulates Alcohol Dependence-Associated
Excessive Drinking and Gamma-Aminobutyric Acid Release in the Central Amygdala in Mice and Is Associated with
Alcohol Dependence in Humans.” Biological Psychiatry 77 10): 870–879.
Riccardi, Vincent M. 1992. Neurofibromatosis: Phenotype, Natural History, and Pathogenesis. Baltimore: Johns Hopkins
University Press.
Sanford, Malcolm T. 2006. “The Africanized Honey Bee in the Americas: A Biological Revolution With Human Cultural
Implications, Part V—Conclusion.” American Bee Journal 146 7): 597–599.
Sanna, Pietro Paolo, Cindy Simpson, Robert Lutjens, and George Koob. 2002. “ERK Regulation in Chronic Ethanol
Exposure and Withdrawal.” Brain Research 948 1–2): 186–191.
Weismann, August. 1892. Das Keimplasma: Eine Theorie der Vererbung [The Germ Plasm: A Theory of Inheritance]. Jena:
Fischer.
World Health Organization. 1996. “Control of Hereditary Disorders: Report of WHO Scientific meeting 1996).” WHO
Technical Reports 865. Geneva: World Health Organization.
World Health Organization. 2017. “Global Priority List of Antibiotic-Resistant Bacteria to Guide Research, Discovery, and
Development of New Antibiotics.” Global Priority Pathogens List, February 27. Geneva: World Health Organization.
https://www.who.int/medicines/publications/WHO-PPL-Short_Summary_25Feb-ET_NM_WHO.pdf
Wright, Sewall. 1932. “The Roles of Mutation, Inbreeding, Crossbreeding, and Selection in Evolution.” Proceedings of the
Sixth International Congress on Genetics 1 6): 356–366.
Acknowledgment
Many thanks to Dr. Vincent M. Riccardi for sharing his vast knowledge of neurofibromatosis and for encouraging me to
explore it from an anthropological perspective.
Figure Attributions
Figure 4.1 Tree of life SVG by Ivica Letunic: Iletunic, retraced by Mariana Ruiz Villarreal: LadyofHats, has been
designated to the public domain CC0). This item has been modified made grayscale, rotated, labels added).
Figure 4.2A Lamarckian Evolution original to Explorations: An Open Invitation to Biological Anthropology by Mary
Nelson is under a CC BY-NC 4.0 License.
Figure 4.2B Modern Synthesis original to Explorations: An Open Invitation to Biological Anthropology by Mary Nelson is
under a CC BY-NC 4.0 License.
Forces of Evolution | 145
Figure 4.3 Weismann’s mouse-tail experiment original to Explorations: An Open Invitation to Biological Anthropology
by Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.4 Castle’s Hooded Rat Experiment original to Explorations: An Open Invitation to Biological Anthropology by
Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.5 Morgan’s Mutant Fruit Flies original to Explorations: An Open Invitation to Biological Anthropology by Mary
Nelson is under a CC BY-NC 4.0 License.
Figure 4.6 UV-induced Thymine dimer mutation original to Explorations: An Open Invitation to Biological Anthropology
by Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.7 Cytosine-to-thymine point mutation original to An Open Invitation to Biological Anthropology by Mary
Nelson is under a CC BY-NC 4.0 License.
Figure 4.8 Point and frameshift mutations original to An Open Invitation to Biological Anthropology by Mary Nelson is
under a CC BY-NC 4.0 License.
Figure 4.9 Woman with cutaneous neurofibromas syptom of NF1) by Rick Guidotti of Positive Exposure is used by
permission and available here is under a CC BY-NC 4.0 License.
Figure 4.10a Man with plexiform neurofibroma syptom of NF1) is used by permission from Ashok Shrestha and available
here is under a CC BY-NC 4.0 License.
Figure 4.10b Childhood photo of the same man with NF1 disorder is used by permission from Ashok Shrestha and
available here is under a CC BY-NC 4.0 License.
Figure 4.11 Child with café-au-lait macules birthmarks) typical of the earliest symptoms of NF1 by Andrea J. Alveshere is
under a CC BY-NC 4.0 License.
Figure 4.12 The Cretaceous–Paleogene extinction event original to Explorations: An Open Invitation to Biological
Anthropology by Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.13 6 Finger by Wilhelmy is under a CC BY-SA 4.0 License.
Figure 4.14 Ladybug Gene Flow original to Explorations: An Open Invitation to Biological Anthropology by Mary Nelson
is under a CC BY-NC 4.0 License.
Figure 4.15 Peppered moths c2 by Khaydock is under a CC BY-SA 3.0 License.
Figure 4.16 Biology ID: [email protected]) by CNX OpenStax is used under a CC BY 4.0
License.
Figure 4.17 Sickle-cell smear 2015-09-10 by Paulo Henrique Orlandi Mourao, contrast modified and labels added by
Katie Nelson, CC BY-SA 4.0.
Figure 4.18 Peacock tail advantage and disadvantages soriginal to Explorations: An Open Invitation to Biological
Anthropology by Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.19 Isolation Leading to Speciation original to Explorations: An Open Invitation to Biological Anthropology by
Mary Nelson is under a CC BY-NC 4.0 License.
Figure 4.20 Darwin’s finches original to Explorations: An Open Invitation to Biological Anthropology by Mary Nelson is
under a CC BY-NC 4.0 License.
146 | Forces of Evolution
Figure 4.21 Ladybug mix original to Explorations: An Open Invitation to Biological Anthropology by Mary Nelson is
under a CC BY-NC 4.0 License.
Forces of Evolution | 147
- Structure Bookmarks
- EXPLORATIONS: AN OPEN INVITATION TO BIOLOGICAL ANTHROPOLOGY
- EXPLORATIONS: AN OPEN INVITATION TO BIOLOGICAL ANTHROPOLOGY
- Editors: Beth Shook, Katie Nelson, Kelsie Aguilera and Lara Braff
- American Anthropological Association Arlington, VA
- 2019 CC BY-NC 4.0 International, except where otherwise noted
- Figure
- ISBN – 978-1-931303-63-7
- www.explorations.americananthro.org
- Chapter 4: Forces of Evolution
- Andrea J. Alveshere, Ph.D., Western Illinois University
- Learning Objectives
- •
- •
- •
- Describe the history and contributions of the Modern Synthesis.
- •
- •
- Define populations and population genetics as well as the methods used to study them.
- •
- •
- Identify the forces of evolution and become familiar with examples of each.
- •
- •
- Discuss the evolutionary significance of mutation, genetic drift, gene flow, and natural selection.
- •
- •
- Explain how allele frequencies can be used to study evolution as it happens.
- •
- •
- Contrast micro- and macroevolution.
- It’shardforus,withourtypicalhumanlifespansoflessthan100years,toimagineallthewayback,3.8billionyearsago, tothe origins of life.Scientistsstillstudyanddebatehow life came intobeingandwhetheritoriginated onEarth orin someotherregionoftheuniverse(includingsomescientistswhobelievethatstudyingevolutioncanrevealthecomplex processes that were setinmotionbyGod orahigherpower).What we doknow isthat aliving single-celled organism was present on Earth during the early stages of our planet’s existence. This organism had
- Looking at the common sequences in modern genomes, we can even make educated guesses about what the genetic sequence of the first organism, or universal ancestor of all living things, would likely have been. Through a wondrous series of mechanisms and events, that first single-celled organism gave rise to the rich diversity of species that fill the lands, seas, and skies of our planet. This chapter explores the mechanisms by which that amazing transformation occurred and considers some of the crucial scient
- Figure
- Figure 4.1 Phylogenetic tree of life.
- Figure 4.1 Phylogenetic tree of life.
- THE MODERN SYNTHESIS
- Historical Framework
- When learning about biological sciences today, we always recognize the contributions of Charles Darwin and Gregor Mendel, so it may be surprising to learn that for a time, before we arrived at today’s understanding of genetics and
- inheritance,bothDarwin’sandMendel’sworkfelloutoffavor.NeitherDarwin’stheoryofnaturalselection,norMendel’s particulate inheritance were individually sufficient to fully explain all the phenomena being observed in the natural world. It would take many decades, and many careful scientific experiments to solve the puzzle of evolution.
- Rethinking Darwin
- Figure
- Figure 4.2B The Modern Synthesis perspective: The ancestral population had a range of variation in neck length. Those individuals with the longest necks would be the most likely to survive to pass on their longer-neck alleles to future generations.
- Figure
- Figure 4.2A The Lamarckian hypothesis: If a short-necked parent often stretched its neck to reach higher branches, each generation of offspring would be born with somewhat longer necks.
- Figure 4.2A The Lamarckian hypothesis: If a short-necked parent often stretched its neck to reach higher branches, each generation of offspring would be born with somewhat longer necks.
- As noted in Chapter 2, Darwin’s 1859 book On the Origin of Species made a big splash;
- however, as other researchers began doing whatscientistsdo—testingwhetherornotthe concept of natural selection could consistently accountfor thevariation seen in organisms—they began to find many exceptions.One reason for thisis that, aswe nowknow,naturalselectionisonlyoneofthe forces of evolution. Another challenge was a general lack of understanding about how variation is initiated and how inheritance works. Many scientists of the day subscribed
- totheconceptknownasLamarckian inheritance,whichpositedthatoffspringwould inherit characteristics that were acquired during their parents’ lifetimes (Figure 4.2).Darwinhimself,in1868,promotedanideacalledpangenesis,whichcombinesthe
- Lamarckian idea of inheriting acquired characteristics with the idea that particles from differentparts of the bodymake theirwaytothe sex cells.AlfredRussellWallace, evolution. Another researcher, AugustWeismann,also rejectedtheidea that acquiredcharacteristics couldbepassed on.Weismann(1892)devised an experiment to directly test whether offspring inherited acquired characteristics: he cut the tails off mice, bred them, andthenwaitedeagerlytofindoutiftheoffspringhadtails.Allthebabymicewerebornwithtailsintac
- Figure
- Figure 4.3 Weismann’s mouse-tail experiment showing that offspring do not inherit traits that the parents acquired during their lifetimes.who had arrived at the concept of natural selection independently of Darwin, rejected Lamarckian
- Figure 4.3 Weismann’s mouse-tail experiment showing that offspring do not inherit traits that the parents acquired during their lifetimes.who had arrived at the concept of natural selection independently of Darwin, rejected Lamarckian
- Rediscovering Mendel
- Figure
- Figure 4.4 The continuous range of variation observed in hooded rat coat patterns after five generations.
- Figure 4.4 The continuous range of variation observed in hooded rat coat patterns after five generations.
- In 1900, two scientists named Hugo de Vries and Carl Correns, who were independently studying the mechanisms of inheritance, rediscovered Gregor Mendel’s work. Mendel’s pea plant experiments provided the concepts of dominant and recessive traits, which explained retention of certain characteristics in a way that Darwin’s idea, blending inheritance, didn’t. The debatethatunfoldedwasbetweentheMutationists,who believed that variation was caused by mutations in distinct,inherited cells,and Biometricians,whobeli
- Another scientist, Thomas Hunt Morgan, conducted studies in which he induced genetic mutations in populations of the fruit fly,Drosophila melanogaster (Figure 4.5). His work demonstrated that most mutations merely increased variation within populations, rather than creating new species (Morgan 1911).
- Figure
- Figure 4.5 Examples of mutations producing phenotypic variation in a single species of fruit fly.
- Figure 4.5 Examples of mutations producing phenotypic variation in a single species of fruit fly.
- Tying It All Together
- While the biggest leap forward in understanding how evolution works came with the joining (synthesis) of Darwin’s concept of natural selection with Mendel’s insights about particulate inheritance, there were some other big contributions that were crucial to making sense of the variation that was being observed. R.A. Fisher (1919) and John BurdonSandersonHaldane(1924)developedandtestedmathematicalmodelsforevolutionarychangethatprovidedthe toolstostudy variationandbecamethebasisforthestudy ofpopulationgenetic
- POPULATION GENETICS
- Defining Species and Populations and the Variations Within Them
- One of the major breakthroughs in understanding the mechanisms of evolutionary change came with the realization that evolution takes place atthe level of populations, not within individuals. In the biological sciences, a population is defined asagroup ofindividuals ofthe samespecieswho are geographically near enoughto oneanotherthatthey can breed and produce new generations of individuals. Species are organisms whose individuals are capable of breeding becausetheyarebiologicallyandbehaviorallycompatibletopr
- Somespecieshavesubpopulationsthatareregionallydistinct.Theseareclassifiedasseparatesubspecies becausethey havetheirownuniquephenotypesandaregeographicallyisolatedfromoneanother,butiftheydohappentoencounter one another, they are still capable of successful interbreeding.
- Therearemanyexamplesofsterilehybridsthatareoffspringofparentsfromtwodifferentspecies.Forexample,horses anddonkeys canbreedandhave offspringtogether. Dependingonwhichspeciesisthemotherandwhichisthefather, the offspring are either called mules, or hennies. Mules and hennies can live full life spans but are not able to have offspring oftheir own. Likewise,tigersandlionshave been known tomateandhave viableoffspring.Again,depending onwhichspeciesisthemotherandwhichisthefather,theseoffspringarecalledeitherligerso
- For the purpose of studying evolution, we recognize populations by their even smaller units: genes. Each individual, for genetic inheritance purposes,carries acollection ofgenesthat can bepasseddown tofuture generations.Forthis reason, in population genetics, we think of populations as gene pools, which refers to the entire collection of genetic material in a breeding community that can be passed on from one generation to the next.
- Remember, a gene is the basic unit of information that encodes the proteins needed to grow and function as a living organism. Eachgene can have multiple alleles,orvariants, each ofwhich may produce aslightlydifferentprotein.For example, there are brown-or blue-pigment alleles for eye color (green is a slight variant of the brown type). The set of alleles that an individual inherits for a given gene is known as the genotype (e.g., inheriting both brown and blue eye pigments gives a genotype of Bb); while the
- Defining Evolution
- In ordertounderstand evolution,it’s crucialto rememberthat evolutionisalwaysstudied atthepopulationlevel.Also, if a population were to stay exactly the same from one generation to the next, it would not be evolving. So evolution requires both a population of breeding individuals and some kind of a genetic change occurring within it. Thus, the simple definition of evolution is a change in the allele frequencies in a population over time. What do we mean by allele frequencies? Allele frequencies refer to the
- THE FORCES OF EVOLUTION
- Today, we recognize that evolution takes place through a combination of mechanisms: mutation, genetic drift, gene flow,andnaturalselection.These mechanisms are calledthe“forcesof evolution” andtogethertheycan accountforall thegenotypic variationobservedinthe worldtoday. Keepinmindthat each oftheseforces was firstdefinedandthen tested—andre-tested—throughtheexperimentalworkofthemanyscientistswhocontributedtotheModernSynthesis.
- Mutation
- The first force of evolution we will discuss is mutation, and for good reason: Mutation is the original source of all the
- The first force of evolution we will discuss is mutation, and for good reason: Mutation is the original source of all the
- genetic variationfoundin everylivingthing.Let’s tryagaintoimagineallthe waybackintimetothe veryfirstsingle-celled organism,floatinginEarth’sprimordial sea. Based onwhat we observe insimple,single-celled organismstoday, that organismprobablyspentitslifetimeabsorbingnutrientsanddividingtoproduce cloned copies ofitself.Whilethe numbersofindividualsinthatpopulation wouldhave grown (as longastheenvironment was favorable),nothing would have changedinthatperfectlyclonedpopulation.There wouldnothave been was only t
- varietyamongtheindividuals.It
- When we think of genetic mutation, we often first think of deleterious mutations—the ones associated with negative effectssuch asthebeginnings of cancers orheritabledisorders.Thefactis,though,that everygeneticadaptationthat hashelped ourancestors survive since the dawn of life is directlydueto a beneficial mutation—a changes intheDNA that provided some sort of advantage to a given population at a particular moment in time. For example, a beneficial mutation allowed chihuahuas and other tropical-adapted dog
- Every one of us has genetic mutations. Yes, even you. The DNA in some of your cells today differs from the original DNA that you inherited when you were a tiny, fertilized egg. Mutations occur all the time in the cells of our skin and otherorgans,duetochemicalchangesinthenucleotides.ExposuretotheUVradiationinsunlightisonecommoncause of skin mutations. Interaction with UV light causes UV crosslinking, in which adjacent thymine bases bind with one another (Figure 4.6). Many of these mutations are detected and
- Figure
- Figure 4.6 A crosslinking mutation in which a UV photon induces a bond between two thymine bases.
- Figure 4.6 A crosslinking mutation in which a UV photon induces a bond between two thymine bases.
- Most of our mutations exist in somatic cells, which are the cells of our organs and other body tissues. Those will not be passed on to future generations and so will not affect the population over time. Only mutations that occur in the gametes, the reproductive cells (i.e., the sperm or egg cells), will be passed on to future generations. When a new mutation pops up at random in a family lineage, it is known as a spontaneous mutation. If the individual born with
- Most of our mutations exist in somatic cells, which are the cells of our organs and other body tissues. Those will not be passed on to future generations and so will not affect the population over time. Only mutations that occur in the gametes, the reproductive cells (i.e., the sperm or egg cells), will be passed on to future generations. When a new mutation pops up at random in a family lineage, it is known as a spontaneous mutation. If the individual born with
- thisspontaneousmutationpassesitontohisoffspring,thoseoffspringreceiveaninherited mutation.Geneticistshave identified many classes of mutations and the causes and effects of many of these.
- Point Mutations
- A point mutation is a single-letter (single-nucleotide) change in the genetic code resulting in the substitution of one nucleicacidbaseforadifferentone.AsyoulearnedinChapter3,theDNAcodeineachgeneistranslatedthroughthreeletter“words”known as codons.Sodepending onhow thepointmutationchangesthe“word,”theeffectitwillhave on theproteinmaybemajororminor,ormaymakenodifferenceatall.Oneofthemostcommoncausesofpointmutations isachemicalchange called cytosine cytosine methylation,amethylgroupisaddedto acytosinebase, wh
- -
- methylation.In
- If amutationdoesnotchangethe resultingprotein,then it is called a synonymous mutation. Synonymous mutations do involve a letter (nucleic acid) change, but that change results in a codon that codes for the same “instruction” (the same amino acid or stop code) as the original codon. Mutations that do cause a change in the proteinareknownasnon-synonymous mutations.There are several classes of non-synonymousmutations, which are defined by their effects on the encoded protein: missense,nonsense,andsplicesitemuta
- Figure
- Figure 4.7 The mechanism by which a cytosine-to-thymine point mutation can occur.
- Figure 4.7 The mechanism by which a cytosine-to-thymine point mutation can occur.
- Amissense mutation producesachangeinasingleamino acid. In this case, the protein is assembled correctly, both before and after the point mutation, but one amino acid, encodedbythe codon containingthepointmutation,isincorrect.This mayimpacthow thefinishedproteinfunctions by, for example, preventing it from folding correctly and/or disrupting an enzyme binding site. Nonsense mutations convertcodonsthatencodeaminoacidsintostopcodons,meaningthattheproteinwillbeassembledcorrectlyupuntil thecodoncontainingthemuta
- Mutation Type
- Mutation Type
- Mutation Type
- Illustration
- Result
- No mutation (normal DNA)
- No mutation (normal DNA)
- TD
- Figure
- Normal protein produced
- Synonymous (silent) mutation
- Synonymous (silent) mutation
- TD
- Figure
- Normal protein produced
- Missense mutation
- Missense mutation
- TD
- Figure
- Slight difference in amino acid sequence
- Nonsense mutation
- Nonsense mutation
- TD
- Figure
- Protein terminates early
- Chart continued on next page
- Mutation Type
- Mutation Type
- Mutation Type
- Illustration
- Result
- Frameshift insertion
- Frameshift insertion
- TD
- Figure
- Major difference in amino acid sequence
- Frameshift deletion
- Frameshift deletion
- TD
- Figure
- Major difference in amino acid sequence
- Figure 4.8 Examples and results of point and frameshift mutations.
- Figure 4.8 Examples and results of point and frameshift mutations.
- Insertions and Deletions
- Inadditiontopointmutations,anotherclassofmutationsareinsertions anddeletions,orindels,forshort.Asthename suggests, these involve the addition (insertion) or removal (deletion) of one or more coding sequence letters (nucleic acids).ThesetypicallyfirstoccurasanerrorinDNAreplication,whereinoneormorenucleotides areeitherduplicated or skipped in error.
- Frameshift mutations are typesofindelsthatinvolve theinsertion ordeletionof anynumber ofnucleotidesthatisnot a multiple of three. Because these indels are not consistent with the codon numbering, they “shift the reading frame,” causingallthecodonsbeyondthemutationtobemisread.Thesemutationscancreateextensivechangestotheprotein sequence,potentiallynot only causing it to losefunctionbutalso possibly creating new enzyme-binding sites,leading tonewinteractionsbetweentheproteinandothercomponentsofthecellularenvir
- Transposable Elements, or transposons, are fragments of DNA that can “jump” around in the genome. There are two types of transposons: Class I transposons, or retrotransposons, which are transcribed from DNA into RNA and then “reverse transcribed,” to insert the copied sequence into a new location in the DNA; and Class II transposons, or DNA transposons, which do not involve RNA— instead, DNA transposons are clipped out of the DNA sequence itself and inserted elsewhere in the genome. Because transposable ele
- Chromosomal Alterations
- The final major category of genetic mutations are changes at the chromosome level: crossover events, nondisjunction events, and translocations. Crossover events occur when DNA is swapped between homologous chromosomes while they are paired up during meiosis I. Crossovers are thought to be so common that some DNA swapping may happen everytimechromosomesgothroughmeiosisI.Crossoversdon’tnecessarilyintroducenewallelesintoapopulation,but theydomake itpossiblefor new combinations ofallelesto exist onasinglechromo
- Nondisjunction events occur whenthehomologouschromosomes (inmeiosisI) orsisterchromatids(inmeiosisIIand mitosis)failtoseparateafterpairing.The resultisthatbothchromosomes orchromatidsendupinthe samedaughter cell, leaving the other daughter cell without any copy of that chromosome. Most nondisjunctions at the gamete level are fatal to the embryo. The most widely known exception is Trisomy 21, or Down syndrome, which results from an embryothatinheritsthreecopiesofChromosome21:twofromoneparent(duetoanondisjunc
- Chromosomal translocations involve transfers of DNA between non-homologous chromosomes. This may involve swapping large portions of two or more chromosomes. The exchanges of DNA may be balanced or unbalanced. In balanced translocations, the genes are swapped, but no genetic information is lost. In unbalanced translocations, there is an unequal exchange of genetic material resulting in duplication or loss of genes. Translocations result in new chromosomal structures called derivative chromosomes, because the
- Case Study #1: Neurofibromatosis Type 1 (NF1)
- Neurofibromatosis Type 1, also known as NF1, is a surprisingly common genetic disorder, affecting more people than cystic fibrosis and muscular dystrophy combined. Even more surprising, given how common it is, is how few people have heard ofit.Onein every3,000babiesisbornwithNF1,andthisholdstruefor allpopulations worldwide(Riccardi 1992).This means that,for every3,000peopleinyour community, there islikely atleast onecommunitymemberliving with this disorder. Approximatelyhalf ofthese cases are due to spontan
- Figure
- Figure 4.9 Photo of a woman with many cutaneous neurofibromas, a common symptom of Neurofibromatosis Type 1.
- Figure 4.9 Photo of a woman with many cutaneous neurofibromas, a common symptom of Neurofibromatosis Type 1.
- TheNF1disorder resultsfrom disruptionofthe NF1 geneonChromosome
- 17. Studies of individuals with NF1 have identified over 3,000 different mutations within the gene (including small and large indels, point mutations, and translocations). The NF1 gene is one of the largest known genes,containingatleast60exons (protein-encodingsequences)inaspan of about 300,000 nucleotides. It encodes a correspondingly large protein called neurofibromin. Neurofibromin is a fascinating protein, and we are still learning about all its functions.
- Studying the symptoms in people who have mutations in an NF1 gene can provide important insights. There are two other types of Neurofibromatosis(Type2andSchwannomatosis)thatinvolvesomeofthe samesymptomsbut are muchless common thanNF1and are notduetomutationsinthe samegene(or even thesame chromosome).
- We know that neurofibromin plays an important role in preventing tumor growth because, when a mutation occurs causing the NF1 disorder, one ofthe most common symptomsis the growth of benign (non-cancerous) tumors, called neurofibromas. Neurofibromas sprout from nerve sheaths—the tissues that encase our nerves—throughout the body. Thereisnowaytopredictwherethetumorswilloccur,orwhenorhowquicklytheywillgrow,althoughonlyabout15% turn malignant (cancerous).
- Figure
- Figure 4.10A Photo of a man with large plexiform neurofibroma, another symptom of Neurofibromatosis Type 1.
- Figure 4.10A Photo of a man with large plexiform neurofibroma, another symptom of Neurofibromatosis Type 1.
- Figure
- Figure 4.10B Childhood photo of the same man, illustrating the progressive nature of the NF1 disorder.
- Figure 4.10B Childhood photo of the same man, illustrating the progressive nature of the NF1 disorder.
- The two types of neurofibromas that are typically most visible are cutaneous neurofibromas, which are spherical bumps on, or just under, the surface of the skin (Figure 4.9), and plexiform neurofibromas,growthsinvolving whole branches of nerves, often giving the appearance that the surface of the skin is “melting” (Figure 4.10).
- Unfortunately, although research is ongoing, there is currently no cure for NF1. Surgical removal of neurofibromas risks paralysis, due to the high potential for nerve damage, and often results in the tumors growing back evenmorevigorously.Thismeansthatpatientsareoftenforcedtolivewithdisfiguringandoftenpainfulneurofibromas. People who are not familiar with NF1 often mistake neurofibromas for something contagious. This makes it especially hard for people living with NF1 to get jobs working with the public or
- Figure
- Figure 4.11 Child with café-au-lait macules (birthmarks) typical of the earliest symptoms of NF1.
- Figure 4.11 Child with café-au-lait macules (birthmarks) typical of the earliest symptoms of NF1.
- BabieswhohaveNF1rarelyhaveneurofibromas,whichoftenbegintogrow duringpuberty. Oneofthefirstsymptoms ofNF1in asmallchildisusually the appearance of café-au-lait spots, or CALS, which are flat, brown birthmark-like spots on the skin (Figure 4.11). CALS are often light brown, like the color of coffee with cream, which is the reason for the name, although the shade of the pigment depends on a person’s overall complexion. Some babies are born with CALS, but for others the spots appearwithinthefirstfewyearsoflife.
- A second sign is always needed to confirm a clinical diagnosis of NF1. The second sign often comes in the form of freckles in unusual areas, such as the groin or underarms, or with the first appearance of neurofibromas. Other common symptoms include gliomas (tumors) of the optic nerve, which can cause vision loss; thinning of bones and failure to heal if they break (often requiring amputation); low muscle tone (poor muscle development, often delaying milestones such as sitting up, crawling, and walking); he
- Based on the wide variety of symptoms, it’s clear that neurofibromin plays important roles in many biochemical pathways.WhileeveryonewhohasNF1willexhibitsomesymptomsduringtheirlifetime,thereisagreatdealofvariation in the types and severity of symptoms, even between individuals from the same family who share the exact same NF1 mutation.Itseemscrazythatagenewithsomanyimportantfunctionswouldbesosusceptibletomutation.Partofthis undoubtedlyhastodowithitsmassive size—a genewith300,000nucleotideshastentimes more n
- Genetic Drift
- The second force of evolution is commonly known as genetic drift. This is an unfortunate misnomer, as this force actually involves the drifting of alleles, not genes. Genetic drift refers to random changes (“drift”)in allele frequencies from one generation to the next. The genes are remaining constant within the population; it is only the alleles of the genes are changing in frequency. The random nature of genetic drift is a crucial point to understand: it specifically occurs when none of the variant allele
- Let’s imagine far back in time, again, to that first population of living cells, subsisting and occasionally dividing, in the primordial sea. Many generations have passed, and mutations have created distinct chromosomes. The cells are now amoeba-like, larger than many of their tiny bacterial neighbors, who have long since become their favorite source of nutrients.Amutation occurs inoneofthe cellsthatchangesthetextureofthe cellmembranefromarelativelysmooth surface to a highly ruffled one. This has absolutely
- continuetodivide, andthe offspring oftheruffled cell inherittheruffledmembrane. Thefrequency(%) of theruffled allele in thepopulation, from one generation tothe next,will depend entirely on how many offspring thatfirstruffled cell ends up having, and the random events that might make the ruffled alleles more common or more rare (such as population bottlenecks and founder effects, discussed below).
- Sexual Reproduction and Random Inheritance
- Tracking alleles gets a bit more complicated in our primordial cells when, after a number of generations, a series of mutations have created populations that reproduce sexually. These cells go through an extra round of cell-division (meiosis) to create haploid gametes. The combination of two gametes, each containing half a set of homologous chromosomes, is required to produce each new diploid offspring. In the earlier population, which reproduced via asexual reproduction, a cell either carried the smooth al
- In sexually reproducing populations (including humans and many other animals and plants in the world today), that 50:50chance ofinheriting oneortheotherallelefrom eachparentplays amajorroleinthe random nature ofgenetic drift.
- Population Bottlenecks
- Apopulation bottleneck occurswhenthenumberofindividualsinapopulationdropsdramaticallyduetosomerandom event.Themostobvious,familiarexamplesarenaturaldisasters.Tsunamisandhurricanesdevastatingislandandcoastal populations and forest fires and river floods wiping out populations in other areas are all too familiar. When a large portion of a population is randomly wiped out, the allele frequencies (i.e., the percentages of each allele) in the small population of survivors are often much different from the freque
- Oneofthemostfamousexamplesofapopulationbottleneckis theprehistoricdisasterthatledtothe extinction ofdinosaurs, theCretaceous–Paleogene extinction event(oftenabbreviated K–Pg; previously K-T). This occurred approximately 66 million years ago. Dinosaurs and all their neighbors were going about their ordinary routines when a massive asteroid zoomed in from space and crashed into what is now the Gulf of Mexico, creating an impact so enormous that populations within hundreds of miles of the crash site were likel
- Figure
- Figure 4.12 The Cretaceous–Paleogene extinction event. Fall of the dinosaurs and rise of the mammals.
- Figure 4.12 The Cretaceous–Paleogene extinction event. Fall of the dinosaurs and rise of the mammals.
- Much more recently in geological time, during the colonial period, many human populations experienced bottlenecks as a result of the fact that imperial powers were inclined to slaughter communities who were reluctant to give up theirlandsandresources.Thiseffect was especiallyprofoundintheAmericas,whereindigenouspopulationsfacedthe compoundedeffectsofbrutalwarfare,exposuretonewbacteriaandviruses(againstwhichtheyhadnoimmunity),and ultimately segregation on resource-starved reservations. The populations in Eur
- An urgent health challenge facing humans today involves human-induced population bottlenecks that produce antibiotic-resistantbacteria.Antibiotics aremedicinesprescribedtotreatbacterialinfections.Thetypicalprescription includes enough medicine for ten days. People often feel better after less than ten days and sometimes decide to quit taking the medicine ahead of schedule. This is often a big mistake. The antibiotics have quickly killed off a large percentage ofthebacteria—enoughto reduce thesymptomsandmake
- Otheractivitiesthathavecontributedtotheriseofantibiotic-resistantbacteriaincludetheuseofantibacterialcleaning products and the inappropriate use of antibiotics as a preventative measure in livestock or to treat infections that are viralinstead ofbacterial(virusesdonot respondto 2017, theWorldHealthOrganizationpublished alist oftwelveantibiotic-resistantpathogensthatareconsideredtopprioritytargetsfor thedevelopmentofnew antibiotics (World Health Organization 2017).
- antibiotics).In
- Founder Effects
- Founder effects occur whenmembersofapopulationleave themainor“parent”groupandformanewpopulationthat nolongerinterbreedswiththeothermembersoftheoriginalgroup.Similartosurvivorsofapopulationbottleneck,the newlyfoundedpopulation oftenhasallelefrequenciesthat are differentfrom theoriginalgroup.Allelesthat mayhave been relatively rare intheparentpopulation can endupbeing very common duetofoundereffect.Likewise, recessive traits that were seldom seen in the parent population may be seen frequently in the descenda
- Genetic and hormonal studies revealed that the condition, scientifically termed 5-alpha reductase deficiency, is an autosomal recessive syndrome that manifests when a child having both X and Y sex chromosomes inherits two nonfunctional(mutated) copies ofthe SRD5A2 gene(Imperato-McGinleyandZhu2002).Thesechildren developtestes internally, but the 5-alpha reductase 2 steroid, which is necessary for development of male genitals in babies, is not produced. In absence of this male hormone, the baby develops femal
- Founder effect is closely linked to the concept of inbreeding, which in population genetics does not necessarily mean breeding with immediate family relatives. Instead, inbreeding refers to the selection of mates exclusively from within asmall,closedpopulation—thatis,from agroupwithlimitedallelic variability. Thiscan beobservedinsmall,physically isolated populations but also can happen when cultural practices limit mates to a small group. As with founder effect, inbreeding increases the risk of inheriting t
- The Amish in the United States are a population that, due to their unique history and cultural practices, emerged from a small founding population and have tended to select mates from within their groups. The Old Order Amish population ofLancasterCounty, Pennsylvania,hasapproximately50,000 currentmembers,all ofwhom can trace their ancestry back to a group of approximately 80 individuals. This small founding population immigrated to the United States from Switzerland inthe mid-1700s to escape religious perse
- Figure
- Figure 4.13 Photo of a man with polydactyly.
- Figure 4.13 Photo of a man with polydactyly.
- One of the genetic conditions that has been observed much more frequently in the Lancaster County Amish population is Ellis-van Creveld syndrome, which is an autosomal recessive disorder characterized by short stature (dwarfism),polydactyly[thedevelopmentof more than five digits (fingers or toes) on the hands or feet], abnormal tooth development, and heart defects (see Figure 4.13). Among the general world population, Ellis-van Creveld syndrome is estimated to affect approximately 1 in 60,000 individuals; a
- Gene Flow
- Thethirdforceofevolutionistraditionallycalledgeneflow.Aswithgeneticdrift,thisisamisnomer,becauseitrefersto flowingalleles,notgenes.(Allpopulationsofthesamespeciessharethesamegenes;itisthealleles ofthosegenesthat mayvary.)Gene flow referstothemovementofallelesfromonepopulationtoanother.Inmostcases,geneflowcanbe considered synonymous with migration between populations.
- Returning again to the example of our primordial cell population, let’s imagine that, after the volcanic fissure opened up in the ocean floor, wiping out the majority of the parent population, two surviving populations developed in the waters onoppositesides ofthefissure. Ultimately, thelava from thefissure grew into achainofislandsthat continued to provide a physical barrier between the populations, even after the lava had cooled.
- In the initial generations after the eruption, due to founder effect, isolation, and random inheritance (genetic drift), the population to the west of the islands contained a vast majority of the ruffled membrane alleles while the eastern population predominantly carried the smooth alleles. Ocean currents in the area typically flowed from west to east, sometimes carrying cells (facilitating gene flow) from the western (ruffled) population to the eastern (smooth) population.Duetothe ocean currents,it was alm
- Admixture
- Among humans, gene flow is often described as admixture. In forensic cases, anthropologists and geneticists are often asked to estimate the ancestry of unidentified human remains to help determine whether they match any missing persons’ reports. This is one of the most complicated tasks in these professions because, while “race” or “ancestry” involves simple checkboxes on a missing person’s form, among humans today there are no truly distinct genetic populations. All modern humans are members of the same fu
- Among humans, gene flow is often described as admixture. In forensic cases, anthropologists and geneticists are often asked to estimate the ancestry of unidentified human remains to help determine whether they match any missing persons’ reports. This is one of the most complicated tasks in these professions because, while “race” or “ancestry” involves simple checkboxes on a missing person’s form, among humans today there are no truly distinct genetic populations. All modern humans are members of the same fu
- communitieshaveexperiencedmultipleepisodesofgeneflow(admixture),leadingallhumanstodaytobesogenetically similar that we are all members of the same (and only surviving) human subspecies:Homo sapiens sapiens.
- Gene flow between otherwise isolated non-human populations is often termed hybridization. One example of this involves the hybridization and spread of Africanized honey bees (a.k.a., “killer bees”) in the Americas. All honey bees worldwide are classified as Apis mellifera. Duetodistinctadaptationsto various environments aroundthe world,there are 28 different subspecies ofApis mellifera.
- During the 1950s, a Brazilian biologist named Warwick E. Kerr experimented with hybridizing African and European subspecies ofhoneybees totrytodevelop astrain that was bettersuitedtotropical environmentsthantheEuropean honey bees that had long been kept by North American beekeepers. Dr. Kerr was careful to contain the reproductive queens and drones from the African subspecies, but in 1957, a visiting beekeeper accidentally released 26 queen bees ofthesubspecies Apis mellifera scutellate from southernAfrica
- AnotherexampleinvolvestheintroductionoftheHarlequin ladybeetle,Harmoniaaxyridis,nativetoEastAsia,toother partsofthe worldasa“natural”form ofpest control.Harlequinladybeetles are naturalpredators of someoftheaphids andothercrop-pestinsects.FirstintroducedtoNorthAmericain1916,the“biocontrol”strainsofHarlequinladybeetles were consideredtobequite successfulin reducing croppestsand savingfarmerssubstantial amounts of money. After many decades of successful use in North America, biocontrol strains of Harlequin la
- Over theseven decades ofbiocontroluse,theHarlequinladybeetlehad never shown anypotentialfor development of wildcoloniesoutsideofitsnative habitatinChinaandJapan.Newgenerations ofbeetlesalwayshadtobe rearedinthe lab.Thatallchangedin1988,whenawildcolonytookrootnearNewOrleans,Louisiana.Eitherthroughadmixturewith anativeladybeetlestrain,orduetoaspontaneousmutation,anewallelewasclearlyintroducedintothispopulationthat suddenlyenabledthemtosurviveandreproduceinawiderangeofenvironments.Thispopulationspreadrapidlyac
- spreading) produced flighted offspring after admixture with members of the North American population (Facon etal.2011).Thefast-spreading,invasive strainhasquickly become a disaster, out-competing native ladybeetle populations (some to the point of extinction), causing home infestations, decimating fruit crops, and contaminating many batches of wine with their bitter flavorafterbeinginadvertentlyharvestedwiththegrapes (Pickering et al. 2004).
- Figure
- Figure 4.14 Gene flow between two populations of ladybeetles (ladybugs).
- Figure 4.14 Gene flow between two populations of ladybeetles (ladybugs).
- Natural Selection
- The final force of evolution is natural selection. This is the evolutionary process that Charles Darwin first brought to
- The final force of evolution is natural selection. This is the evolutionary process that Charles Darwin first brought to
- light, and it is what the general public typically evokes when considering the process of evolution. Natural selection occurs when certain phenotypes confer an advantage or disadvantage in survival and/or reproductive success. The alleles associated with those phenotypes will change in frequency over time due to this selective pressure. It’s also important to note that the advantageous allele may change over time (with environmental changes) and that an allele that had previously been benign may become adva
- In the case of our primordial ocean cells, up until now, the texture of their cell membranes has been benign. The frequencies ofsmoothtoruffledalleles,andsmoothtoruffledphenotypes,haschanged over time,duetogeneticdrift and gene flow. Let’s now imagine thattheEarth’sclimatehas cooledto apointthat the watersfrequentlybecome too cold for survival of the tiny bacteria that are the dietary staples of our smooth and ruffled cell populations. The way amoeba-like cells “eat” is to stretch out the cell membrane, alm
- The smooth cells were well-adapted to ingesting tiny bacteria but poorly suited to encapsulating the larger bacteria. Thecellswiththeruffledmembranes,however,areeasilyabletoextendtheirrufflestoencapsulatethelargerbacteria. They also find themselves able to stretch their entire membrane to a much larger size than their smooth-surfaced neighbors, allowing them to ingest more bacteria at a given time and to go for longer periods between feedings. The smoothandruffledtraits,whichhadpreviously offered noadvantag
- adefiniteadvantage.We
- Figure
- Figure 4.15 Dark and light peppered moth variants and their relative camouflage abilities on clean (top) and sooty (bottom) trees.
- Figure 4.15 Dark and light peppered moth variants and their relative camouflage abilities on clean (top) and sooty (bottom) trees.
- A classic example of natural selection involves the study ofaninsectcalledthepeppered moth (Bistonbetularia)in England during the Industrial Revolution in the 1800s. Prior to the Industrial Revolution, the peppered moth population was predominantly light in color, with dark (pepper-like) speckles on the wings. The “peppered” coloration was verysimilartotheappearance ofthebark andlichensthatgrew onthelocaltrees (Figure 4.15).This helpedto camouflagethemoths asthey rested onatree, makingit harderfor moth-eati
- A classic example of natural selection involves the study ofaninsectcalledthepeppered moth (Bistonbetularia)in England during the Industrial Revolution in the 1800s. Prior to the Industrial Revolution, the peppered moth population was predominantly light in color, with dark (pepper-like) speckles on the wings. The “peppered” coloration was verysimilartotheappearance ofthebark andlichensthatgrew onthelocaltrees (Figure 4.15).This helpedto camouflagethemoths asthey rested onatree, makingit harderfor moth-eati
- frequency of the dark pigment allele rose dramatically. By 1895, the black moth phenotype accounted for 98% of observed moths (Grant 1999).
- Thankstonewenvironmentalregulationsinthe1960s,theairpollutioninEnglandbegantotaperoff.Asthesootlevels decreased, returning the trees to their former, lighter color, this provided the perfect opportunity to study how the pepperedmothpopulationwouldrespond.Repeatedfollow-upstudiesdocumentedthegradualriseinthefrequencyof thelighter-coloredphenotype.By2003,themaximumfrequency ofthedarkphenotype was 50%andinmostparts of England had decreased to less than 10% (Cook 2003).
- Directional, Balancing/Stabilizing, and Disruptive/Diversifying Selection
- Natural selection can be classified as directional, balancing/stabilizing, or disruptive/diversifying, depending on how the pressure is applied to the population (Figure 4.16).
- Bothoftheaboveexamples of naturalselectioninvolve directional selection:the environmentalpressures arefavoring onephenotype over theotherand causingthefrequencies oftheassociatedadvantageous alleles(ruffledmembranes, dark pigment) to
- graduallyincrease.Inthecaseofthepepperedmoths,the direction shifted three times: first, it was selecting for lighter pigment; then, with the increase in pollution, the pressureswitchedtoselectionfordarkerpigment;finally, with reduction of the pollution, the selection pressure shifted back again to favoring light-colored moths.
- Balancing selection (a.k.a., stabilizing selection) occurs when selection works againstthe extremes of a trait and favors theintermediatephenotype.For example,humans maintain an average birth weight that balances the need for babiestobesmallenoughnotto cause complications during pregnancy and childbirth but big enough to maintain a safe body temperature after they are born. Another example of balancing selection is found in the genetic disorder called sickle cell anemia, which is featured in Case Study #2 (
- Disruptive selection (a.k.a., diversifying selection), the opposite of balancing selection, occurs when both extremes of a trait are advantageous. Since individuals with traits in the mid-range are selected against, disruptive selection can eventuallyleadtothepopulation evolving into two separate species. Darwin believed that the many species of finches (small birds) found in the remoteGalapagosIslandsprovidedaclearexampleofdisruptiveselectionleadingtospeciation.Heobservedthatseedeatingfincheseitherhadlarge
- -
- Figure
- Figure 4.16 Caption: (a) Balancing/Stabilizing, (b) Directional, and (c) Disruptive/Diversifying Selection.
- Figure 4.16 Caption: (a) Balancing/Stabilizing, (b) Directional, and (c) Disruptive/Diversifying Selection.
- Case Study #2 : Sickle Cell Anemia
- Sickle cell anemia is an autosomal recessive genetic disorder that affects millions of people worldwide. It is most common in Africa, countries around the Mediterranean Sea, and eastward as far as India. Populations in the Americas that have high percentages of ancestors from these regions also have high rates of sickle cell anemia. In the United States,it’sestimatedthat72,000peoplelivewiththedisease,withoneinapproximately1,200Hispanic-Americanbabies and one in every 500 African-American babies inheriting t
- Figure
- Figure 4.17 Sickle Cell Anemia. Arrows indicate (a) sickled and (b) normal red blood cells.
- Figure 4.17 Sickle Cell Anemia. Arrows indicate (a) sickled and (b) normal red blood cells.
- Sickle cell anemia affects the hemoglobin protein in red blood cells. Normal red blood cells are somewhat doughnutshaped—round with a depression on both sides of the middle. They carry oxygen around the bloodstream to cells throughout the body. Red blood cells produced by the mutated form of the gene take on a stiff, sickle-like crescent shape when stressed by low oxygen or dehydration (Figure 4.17). Because of their elongated shape and the fact that they are stiff rather than flexible,theytendtoform clumps
- -
- The devastating effects of sickle cell anemia made its high frequency a pressing mystery. Why would an allele that is so deleterious in its homozygous form be maintained in a population at levels as high as the one in twelve African-Americans estimatedto carry atleast one copy of the allele?The answer turned out tobe one ofthemost interesting cases of balancing selection in the history of genetic study.
- Whilelookingforanexplanation,scientistsnoticedthatthecountrieswithhighratesofsicklecelldiseasealsoshareda highriskfor anotherdisease called malaria,whichis causedbyinfection ofthebloodby a Plasmodium parasite.These parasites are carried by mosquitoes and enter the human bloodstream via a mosquito bite. Once infected, the person willexperience flu-like symptomsthat,if untreated, can oftenleadtodeath.Researchersdiscoveredthat manypeople livingintheseregionsseemedtohaveanaturalresistancetomalaria.Furtherstudyr
- Peoplewho are heterozygousfor sicklecell carry onenormalallele,whichproduces thenormal, round, redblood cells, and one sickle cellallele,whichproduces thesickle-shaped redblood cells.Thus,theyhave boththesickleand round bloodcelltypesintheirbloodstream.Theyproduceenoughoftheroundredbloodcellstoavoidthesymptomsofsickle cell anemia, but they have enough sickle cells to provide protection from malaria.
- When the Plasmodium parasites infect an individual, they begin to multiply in the liver, but then must infect the red bloodcellsto completetheirreproductivecycle.Whentheparasitesentersickle-type cells,the cells respondbytaking onthesickleshape. This preventstheparasite from circulating through the bloodstream and completingits life cycle, greatlyinhibitingtheseverityoftheinfectioninthesicklecellheterozygotescomparedtonon-sickle-cellhomozygotes. See chapter 14 for more discussion of sickle cell anemia.
- Sexual Selection
- Sexual selection is an aspect of natural selection in which the selective pressure specifically affects reproductive success (theabilitytosuccessfullybreedand raiseoffspring) ratherthan survival.Sexualselectionfavorstraitsthatwill attract a mate. Sometimes these sexually appealing traits even carry greater risks in terms of survival.
- Aclassic example of sexualselectioninvolves thebrightly coloredfeathers ofthepeacock.The peacock isthemale sex of the peafowlgenera Pavo andAfropavo. Duringmating season,peacocks willfantheir colorful tails wide and strut in frontofthepeahensinagranddisplay.Thepeahenswillcarefullyobservethesedisplaysandwillelecttomatewiththe male that they find the most appealing. Many studies have found that peahens prefer the males with the fullest, most colorful tails. While these large, showy tails provide a reproductiv
- Figure
- Figure 4.18 Showy peacock tail advantages (impressing peahens) and disadvantages (becoming easier prey).
- Figure 4.18 Showy peacock tail advantages (impressing peahens) and disadvantages (becoming easier prey).
- It’s important to keep in mind that sexual selection relies on the trait being present throughout mating years. Reflecting back on Case Study #1, the examination of the NF1 genetic disorder, some might find it surprising that half of the babies born with NF1 inheriteditfromaparent.Givenhowdisfiguringthesymptomscan become, andthefact thatthedisorderis autosomal dominantand fullypenetrant(meaningithasnounaffectedcarriers),itmayseem surprisingthatsexualselectiondoesn’texertmorepressureagainst the mutated allel
- Someresearchersprefertoclassifysexualselectionseparately,asa fifthforce of evolution.Thetraitsthatunderpin mateselection are entirely natural, of course. Research has shown that subtle traits, such as the type of pheromones (hormonal odors related to immune system alleles) someone emits and how those are perceivedbytheimmunesystemgenotype ofthe “sniffer,” mayplaycrucialandsubconscious rolesinwhether we find someone attractive or not (Chaix et al. 2008).
- SPECIAL TOPIC: THE REAL PRIMORDIAL CELLS—DICTYOSTELIUM DISCOIDEUM
- Theamoeba-like primordialcellsthatwere usedasrecurringexamplesthroughoutthischapter areinspired by actual research that is truly fascinating. In 2015, Gareth Bloomfield and colleagues reported on their genomic study of the social amoeba Dictyostelium discoideum (a.k.a., “slime molds,” although technically they are amoebae,notmolds).Strains oftheseamoebaehave been grown inresearchlaboratoriesfor many decades and are useful in studying phagocytosis and micropinocytosis—the mechanisms that amoeboid single-cell
- thewild-typeamoebae.It
- Bloomfield and colleagues performed genomic testing on both the wild and the laboratory strains of Dictyostelium discoideum. Their discovery was astounding: every one of the laboratory strains carried a mutationintheNF1gene,theverysamegeneassociatedwithNeurofibromatosisType1(NF1)inhumans.The antiquity of this massive, easily mutated gene is incredible. It originated in a common ancestor to humans and these amoebae and has been retained in both lineages ever since. As seen in Dictyostelium discoideum, breaki
- Dictyostelium discoideum are also interesting in that they typically reproduce asexually, but under certain conditions, one cell will convert into a “giant” cell, which encapsulates surrounding cells, transforminginto one of three sexes. This cell will undergo meiosis, producing gametes that must combine with one of the othertwosexesinordertoproduceviableoffspring.Thisabilityforsexualreproductionmaybewhatallows Dictyosteliumdiscoideum tobenefitfromtheadvantagesofNF1mutation,whilealsobeingabletorestorethe wi
- Whatdoesthis mean for humanslivingwithNF1?Well,understandingthe role ofthe neurofibrominprotein in the membranes of simple organisms like Dictyostelium discoideum may help us to better understand how it functions and malfunctions in the sheaths of human neurons. It’s also possible that the mutability of the NF1 gene confers certain advantages to humans as well. Alleles of the NF1 gene have been found to reduce one’srisk for alcoholism (Repunte-Canonigo et al.2015),opiateaddiction (Sanna etal. 2002),Type2 di
- STUDYING EVOLUTION IN ACTION
- The Hardy-Weinberg Equilibrium
- This chapter has introduced you to the forces of evolution, the mechanisms by which evolution occurs. How do we detect and study evolution, though, in real time, as it happens? One tool we use is the Hardy-Weinberg Equilibrium: a mathematical formula that allows estimation of the number and distribution of dominant and recessive alleles in a population. This aids in determining whether allele frequencies are changing and, if so, how quickly over time, and in favor of which allele? It’s important to note tha
- Interpreting Evolutionary Change
- Once we have detectedchange occurringin apopulation, we needto considerwhich evolutionaryprocesses mightbe the cause of the change. It is important to watch for non-random mating patterns, to see if they can be included or excluded as possible sources of variation in allele frequencies.
- Non-Random Mating
- Non-Random Mating (alsoknown asAssortative Mating) occurs whenmate choice within apopulation follows anon-random pattern. Positive assortative mating patterns result from a tendency for individuals to mate with others who share similarphenotypes.This oftenhappensbased onbodysize. Taking asanexampledogbreeds,itis easierfor two Chihuahuas to mateand have healthy offspringthan itisfor aChihuahua and aSt.Bernardto do so.Thisisespecially true if the Chihuahua is the female and would have to give birth to giant S
- Negative assortative mating patterns occur when individuals tend to select mates with qualities different from their own. This is what is at work when humans choose partners whose pheromones indicate that they have different and complementary immune alleles, providing potential offspring with a better chance at a stronger immune system.
- Amongdomesticanimals,such aspetsandlivestock, assortative matingis oftendirectedbyhumanswhodecidewhich pairs will mate to increase the chances of offspring having certain desirable traits. This is known asartificial selection.
- Among humans, in addition to phenotypic traits, cultural traits such as religion and ethnicity may also influence assortative mating patterns.
- Micro- to Macroevolution
- Microevolution refers to changes in allele frequencies within breeding populations, that is, within single species. Macroevolution involveschangesthatresultintheemergenceofnew species,thesimilaritiesanddifferences between
- Microevolution refers to changes in allele frequencies within breeding populations, that is, within single species. Macroevolution involveschangesthatresultintheemergenceofnew species,thesimilaritiesanddifferences between
- species and their phylogenetic relationships with other taxa. Consider our example of the peppered moth which illustrated microevolution over time, via directional selection favoring the peppered allele when the trees were clean and the dark pigment allele when the trees were sooty. Imagine that environmental regulations had cleaned up the air pollution in one part of the nation, while the coal-fired factories continued to spew soot in another area. If this wentonlongenough,it’spossiblethattwodistinctmothpo
- When a single population divides into two or more separate species, it is called speciation. The changes that prevent successfulbreedingbetweenindividualswhodescendedfromthesameancestralpopulationmayinvolvechromosomal rearrangements, changes in the ability of the sperm from one species to permeate the egg membrane of the other species, or dramatic changes in hormonal schedules or mating behaviors that prevent members from the new species from being able to effectively pair up.
- There are two types of speciation: allopatric and sympatric. Allopatric speciation is caused by long-term isolation (physicalseparation)ofsubgroupsofthepopulation(Figure4.19).Somethingoccursintheenvironment—perhapsariver changesits course andsplitsthegroup,preventingthemfrom breedingwithmembers ontheoppositeriverbank.Over manygenerations,newmutationsandadaptationstothedifferentenvironmentsoneachsideoftherivermaydrivethe two subpopulations to change so much that they can no longer produce fertile, viable off
- Figure
- Figure 4.19 Isolation leading to speciation: (a) original population before isolation; (b) a barrier divides the population and prevents interbreeding between the two groups; (c) time passes, and the populations become genetically distinct; (d) after many generations, the two populations are no longer biologically or behaviorally compatible, thus can no longer interbreed, even if the barrier is removed.
- Figure 4.19 Isolation leading to speciation: (a) original population before isolation; (b) a barrier divides the population and prevents interbreeding between the two groups; (c) time passes, and the populations become genetically distinct; (d) after many generations, the two populations are no longer biologically or behaviorally compatible, thus can no longer interbreed, even if the barrier is removed.
- Sympatric speciation occurs when the population splits into two or more separate species while remaining located together without a physical barrier. This typically results from a new mutation that pops up among some members of thepopulationthatpreventsthemfrom successfully reproducingwith anyone whodoesnot carrythe samemutation. This is seen particularly often in plants, as they have a higher frequency of chromosomal duplications.
- One of the quickest rates of speciation is observed in the case of adaptive radiation. Adaptive radiation refers to the situation in which subgroups of a single species rapidly diversify and adapt to fill a variety of ecological niches. An ecological niche isasetofconstraintsandresourcesthatisavailableinanenvironmentalsetting.Evidenceforadaptive radiations is often seen after population bottlenecks. A mass disaster kills off many species, and the survivors have access to a new set of territories and resourc
- One of the quickest rates of speciation is observed in the case of adaptive radiation. Adaptive radiation refers to the situation in which subgroups of a single species rapidly diversify and adapt to fill a variety of ecological niches. An ecological niche isasetofconstraintsandresourcesthatisavailableinanenvironmentalsetting.Evidenceforadaptive radiations is often seen after population bottlenecks. A mass disaster kills off many species, and the survivors have access to a new set of territories and resourc
- the disaster. The offspring of the surviving population will often split into multiple species, each of which stems from members in that first group of survivors who happened to carry alleles that were advantageous for a particular niche.
- The classic example of adaptive radiation brings us back to Charles Darwin and his observations of the many species of finches on the Galapagos Islands. We are still not sure how the ancestral population of finches first arrived on that remote Pacific Island chain, but they found themselves in an environment filled with various insects, large and tiny seeds, fruit, and delicious varieties of cactus. Some members of that initial population carried alleles that gave them advantagesforeachofthesedietaryniches.
- Figure
- Figure 4.20 Darwin’s finches demonstrating Adaptive Radiation.
- Figure 4.20 Darwin’s finches demonstrating Adaptive Radiation.
- In today’s modern world, understanding these evolutionary processes is crucial for developing immunizations and antibioticsthatcankeepupwiththerapidmutationrateofvirusesandbacteria.Thisisalsorelevanttoourfoodsupply, which relies, in large part, on the development of herbicides and pesticides that keep up with the mutation rates of pestsandweeds.Viruses,bacteria,agriculturalpests,andweedshaveallshowngreatflexibilityindevelopingallelesthat makethemresistanttothelatestmedicaltreatment,pesticide,orherbicide.Bil
- SPECIAL TOPIC: CALCULATING THE HARDY-WEINBERG EQUILIBRIUM
- In the Hardy-Weinberg formula,p represents the frequency of the dominant allele, andq represents the frequency of the recessive allele. Remember, an allele’s frequency is the proportion, or percentage, of that allele in the population. For the purposes of Hardy-Weinberg, we give the allele percentages as decimal numbers (e.g., 42% = 0.42), with the entire population (100% of alleles) equaling 1. If we can figure out the frequency of one of the alleles in the population, then it is simple to calculate the ot
- The Hardy-Weinberg formula isp+ 2pq + q, where
- 2
- 2
- prepresents the frequency of the homozygous dominant genotype;
- 2
- 2pq represents the frequency of the heterozygous genotype; and
- qrepresents the frequency of the homozygous recessive genotype.
- 2
- It is often easiest to determineqfirst, simply by counting the number of individuals with the unique, homozygous recessive phenotype (then dividing by the total individuals in the population to arrive at the “frequency”). If we can do this, we simply need to calculate the square root of the homozygous recessive phenotype frequency. That gives usq. Remember, 1–q equalsp, so now we have the frequencies for both alleles in the population. If we needed to figure out the frequencies of heterozygotes and homozygo
- 2
- 2
- Let’s imagine we have a population of ladybeetles that carries two alleles: a dominant allele that produces red ladybeetles and a recessive allele that produces orange ladybeetles. Since red is dominant, we’ll useR to represent the red allele, and r to represent the orange allele. Our population has ten beetles, and seven are red and three are orange (Figure 4.21). Let’s calculate the number of genotypes and alleles in this population.
- We have three orange beetles of our ten, 3/10 = .30 (30%) frequency, and we know they are homozygous recessive (rr). So:
- rr = .3; therefore,r = √.3 = .5477
- R = 1– .5477 = .4523
- Using the Hardy-Weinberg formula:
- 1=.4523+ 2 x .4523 x .5477 +.5477= .20 + .50 + .30 = 1
- 2
- 2
- Thus, the genotype breakdown is 20%RR, 50%Rr, and 30%rr
- (2 red homozygotes, 5 red heterozygotes, and 3 orange homozygotes).
- Since we have 10 individuals, we know we have 20 total alleles: 4 red from theRR group, 5 red and 5 orange from theRr group, and 6 orange from therr group, for a grand total of 9 red and 11 orange (45% red and 55% orange, just like we estimated in the 1 –q step).
- Figure
- Figure 4.21 Ladybug population with a mixture of dark (red) and light (orange) individuals.
- Figure 4.21 Ladybug population with a mixture of dark (red) and light (orange) individuals.
- Reminder: The Hardy-Weinberg formula only gives us an estimate for a snapshot in time. We will have to calculate it again later, after various intervals, to determine if our population is evolving and in what way the allele frequencies are changing.
- Review Questions
- •
- •
- •
- Devise an argument explaining how we know that the Pangenesis model for evolution is incorrect. Provide examples from the text of experiments that helped prove this wrong.
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- •
- You inherit a house from a long-lost relative that contains a fancy aquarium, filled with a variety of snails. The phenotypes include large snails and small snails; red, black, and yellow snails; and solid, striped, and spotted snails. Devise a series of experiments that would help you determine how many snail species are present in your aquarium.
- •
- •
- Imagine a population of common house mice (Mus musculus). Draw a comic strip illustrating how mutation, genetic drift, gene flow, and natural selection might transform this population over several (or more) generations.
- •
- •
- The many breeds of the single species of domestic dog (Canisfamiliaris) provide an extreme example of microevolution. Discuss why this is the case. What future scenarios can you imagine that could potentially transform the domestic dog into an example of macroevolution?
- •
- •
- The ability to roll one’s tongue (lift the outer edges of the tongue to touch each other, forming a tube) is a dominant trait. In small town of 1,500 people, 500 can roll their tongues. Use the Hardy-Weinberg formula to determine how many individuals in the town are homozygous dominant, heterozygous, and homozygous recessive.
- •
- •
- Match the correct force of evolution with the correct real-world example:
- a.Mutation
- a.Mutation
- b.Genetic Drift
- c.Gene Flow
- d.Natural Selection
- i.5-alpha reductase deficiency
- ii.Peppered Moths
- iii.Neurofibromatosis Type 1
- iv.Africanized Honey Bees
- Key Terms
- 5-alpha reductase deficiency: An autosomal recessive syndrome that manifests when a child having both X and Y sex chromosomes inheritstwo non-functional(mutated) copies of theSRD5A2gene, producing adeficiency in ahormone necessary for development in infancy of typical male genitalia. These children often appear at birth to have female genitalia, but they develop a penis and other sexual characteristics when other hormones kick in during puberty.
- 136 | Forces of Evolution
- Adaptive radiation: The situation in which subgroups of a single species rapidly diversify and adapt to fill a variety of
- ecological niches. Admixture: Atermoftenusedtodescribegeneflowbetweenhumanpopulations.Sometimesalsousedtodescribegene flow between non-human populations.
- Africanized honey bees: A strain of honey bees that resulted from the hybridization of African and European honey bee subspecies.Thesebees were accidentally releasedintothewildin1957inBrazil,andhave since spreadthroughout South and Central America and into the United States. Also known as “killer bees,” they tend to be very aggressive in defense of their hives and have caused many fatal injuries to humans and livestock.
- Allele frequency: The ratio, or percentage, of one allele compared to the other alleles for that gene within the study population. Alleles: Variant forms of genes. Allopatric speciation: Speciation caused by long-term isolation (physical separation) of subgroups of the population.
- Antibiotics: Medicines prescribed to treat bacterial infections. Artificial selection: Human-directed assortative matingamongdomesticanimals,such aspetsandlivestock,designed to increase the chances of offspring having certain desirable traits.
- Asexual reproduction: Reproduction via mitosis, whereby offspring are clones of the parents.
- Autosomal dominant: Aphenotypeproducedbyageneonanautosomalchromosomethatisexpressed,totheexclusion of the recessive phenotype, in heterozygotes. Autosomal recessive: A phenotype produced by a gene on an autosomal chromosome that is expressed only in
- individuals homozygous for the recessive allele.
- Balanced translocations: Chromosomal translocations in which the genes are swapped, but no genetic information is lost. Balancing selection: Apatternofnaturalselectionthatoccurswhentheextremesofatraitareselectedagainst,favoring
- the intermediate phenotype (a.k.a., stabilizing selection). Beneficial mutations: Mutations that produce some sort of an advantage to the individual. Benign: Non-cancerous. Benigntumors may cause problemsduetothe area inwhichthey are located(e.g.,theymight
- putpressureonanerveorbrainarea),buttheywillnotreleasecellsthataggressivelyspreadtootherareasofthebody.
- Biometricians: Agroupof earlybiologicalscientistswhobelievedthatindividualmutations ofdiscretehereditaryunits could never account for the continuous spectrum of variation seen in many traits. Café-au-lait spots (CALS): Flat,brown birthmark-like spots on the skin, commonly associated withNeurofibromatosis
- Type 1. Chromosomal translocations: The transfer of DNA between non-homologous chromosomes. Chromosomes: Molecules that carry collections of genes. Codons: Three-nucleotideunits ofDNAthatfunction asthree-letter“words,” encodinginstructionsfor theaddition of
- one amino acid to a protein or indicating that the protein is complete.
- Cretaceous–Paleogene extinction: Amassdisastercausedbyanasteroidthatstrucktheearthapproximately66million years agoandkilled75% oflife onEarth,includingallterrestrialdinosaurs. (a.k.a.,K-PgExtinction,Cretatious-Tertiary Extinction and K-T Extinction).
- Crossover events: ChromosomalalterationsthatoccurwhenDNAisswappedbetweenhomologouschromosomeswhile they are paired up during meiosis I.
- Cutaneous neurofibromas: Neurofibromas that manifest as spherical bumps on or just under the surface of the skin. Cytosine methylation: A type of point mutation in which a cytosine nucleotide is converted to a thymine. A methyl groupisaddedto acytosinebase,changingitto5-methyl cytosine,whichfurther convertstothymineafterhydrolytic deamination (water-induced removal of an amine group).
- Deleterious mutation: A mutation producing negative effects to the individual such as the beginnings of cancers or heritable disorders. Deletions: Mutations that involve removal of one or more nucleotides from a DNA sequence.
- Derivative chromosomes: New chromosomal structures resulting from translocations. Dictyostelium discoideum: A species of social amoebae that has been widely used for laboratory research. Laboratory strains of Dictyostelium discoideum allcarry mutationsin the NF1 gene, which iswhatallows themto survive onliquid media (agar) in Petri dishes.
- Directional selection: A pattern of natural selection in which one phenotype is favored over the other, causing the
- frequencies of the associated advantageous alleles to gradually increase. Disruptive selection: A pattern of natural selection that occurs when both extremes of a trait are advantageous and intermediate phenotypes are selected against (a.k.a., diversifying selection).
- DNA repair mechanisms: Enzymes that patrol and repair DNA in living cells. DNA transposons: Transposons that are clipped out of the DNA sequence itself and inserted elsewhere in the genome. Ecological niche: A set of constraints and resources that are available in an environmental setting. Ellis-van Creveld syndrome: An autosomal recessive disorder characterized by short stature (dwarfism), polydactyly
- [the development of more than five digits (fingers or toes) on the hands or feet], abnormal tooth development, and heart defects. Estimated to affect approximately one in 60,000 individuals worldwide, among the Old Order Amish of Lancaster County, the rate is estimated to be as high as one in every 200 births.
- Evolution: A change in the allele frequencies in a population over time.
- Exons: The DNA sequences within a gene that directly encode protein sequences. After being transcribed into messenger RNA, the introns are clipped out, and the exons are pasted together prior to translation. Fertile offspring: Offspring that can reproduce successfully to have offspring of their own. Founder effect: Atype ofgeneticdriftthat occurs whenmembers ofapopulationleave themain or“parent”groupand
- form a new population that no longer interbreeds with the other members of the original group. Frameshift mutations: Typesofindelsthatinvolve theinsertion ordeletion of anynumber ofnucleotidesthatisnot a multiple of three. These “shift the reading frame” and cause all codons beyond the mutation to be misread.
- Gametes: The reproductive cells, produced through meiosis (a.k.a., germ cells or sperm or egg cells). Gene: A sequence of DNA that provides coding information for the construction of proteins. Gene flow: The movement of alleles from one population to another. This is one of the forces of evolution. Gene pool: Theentirecollectionofgeneticmaterialinabreedingcommunitythatcanbepassedonfromonegeneration
- to the next.
- Genetic drift: Randomchangesinallelefrequencieswithin apopulationfromonegenerationtothenext.Thisisoneof the forces of evolution. Genotype: The set of alleles that an individual has for a given gene. Genotype frequencies: The ratios or percentages of the different homozygous and heterozygous genotypes in the
- population.
- Guevedoces: The term coined locally in the Dominican Republic for the condition scientifically known as 5-alpha reductase deficiency. The literal translation is “penis at twelve.” Hardy-Weinberg Equilibrium: A mathematical formula (p+ 2pq + q) that allows estimation of the number and
- 2
- 2
- distribution of dominant and recessive alleles in a population. Harlequin ladybeetle: Aspecies ofladybeetle, native toEastAsia,that was introducedtoEuropeandtheAmericas asa formofpestcontrol.Aftermanydecadesofuse,oneoftheNorthAmericanstrainsdevelopedtheabilitytoreproducein
- diverse environments, causingittospread rapidlythroughouttheAmericas,Europe,andAfrica. Ithashybridizedwith European strains and is now a major pest in its own right. Heterozygous genotype: A genotype comprising two different alleles. Homozygous genotype: A genotype comprising an identical set of alleles. Hybridization: A term often used to describe gene flow between non-human populations. Inbreeding: The selection of mates exclusively from within a small, closed population. Indels: A class of mutations that
- messenger RNA, the introns are clipped out, and the exons are pasted together prior to translation.
- Isolation: Preventionofapopulationsubgroupfrombreedingwithothermembersofthesamespeciesduetoaphysical barrier or (in humans) a cultural rule. Lamarckian inheritance: An early model for inheritance that predicted that offspring inherit characteristics acquired
- during their parents’ lifetimes. This has now been proven incorrect.
- Macroevolution: Changesthatresultintheemergenceofnewspecies,thesimilaritiesanddifferencesbetweenspecies, and their phylogenetic relationships with other taxa. Malaria: A frequently deadly mosquito-borne disease caused by infection of the blood by a Plasmodium parasite.
- Malignant: Cancerous.Malignanttumorsgrowaggressivelyandtheircellsmaymetastasize(travelthroughthebloodor lymph systems) to form new, aggressive tumors in other areas of the body. Microevolution: Changes in allele frequencies within breeding populations—that is, within a single species. Missense mutation: A point mutation that produces a change in a single amino acid.
- Modern Synthesis: The integration of Darwin’s, Mendel’s, and subsequent research into a unified theory of evolution. Monosomies: Conditions resulting from a non-disjunction event, in which a cell ends up with only one copy of a chromosome. In humans, a single X chromosome is the only survivable monosomy.
- Mutation: A change in the nucleotide sequence of the genetic code. This is one of the forces of evolution.
- Mutationists: A group of early biological scientists who believed that variation was caused by mutations in distinct, inherited cells. Natural selection: Anevolutionaryprocess that occurs whencertainphenotypes confer anadvantage ordisadvantage
- in survival and/or reproductive success. This is one of the forces of evolution.
- Negative assortative mating: Apatternthat occurs whenindividualstendtoselect mateswithqualitiesdifferentfrom their own. Neurofibromas: Nerve sheath tumors that are common symptoms of Neurofibromatosis Type 1. Neurofibromatosis Type 1: An autosomal dominant genetic disorder affecting one in every 3,000 people. It is caused
- by mutation of the NF1 gene on Chromosome 17, resulting in a defective neurofibromin protein. The disorder is
- characterized by neurofibromas, café-au-lait spots, and a host of other potential symptoms. NF1: An abbreviation for Neurofibromatosis Type 1. When italicized, NF1 refers to the gene on Chromosome 17 that encodes the neurofibromin protein.
- Nondisjunction events: Chromosomal abnormalities that occur when the homologous chromosomes (in meiosis I) or sister chromatids (in meiosis II and mitosis) fail to separate after pairing. The result is that both chromosomes or chromatids end up in the same daughter cell, leaving the other daughter cell without any copy of that chromosome.
- Non-random mating: A scenario in which mate choice within a population follows a non-random pattern (a.k.a., Assortative Mating). Nonsense mutation: A point mutation that converts a codon that encodes an amino acid into a stop codon.
- Non-synonymous mutation: A point mutation that causes a change in the resulting protein. Old Order Amish: A culturally isolated population in Lancaster County, Pennsylvania, that has approximately 50,000 currentmembers,all ofwhom can trace theirancestrybackto agroup ofapproximatelyeightyindividuals.Thisgroup has high rates of certain genetics disorders including Ellis-van Creveld syndrome.
- Origins of life: How the first living organism came into being. Pangenesis: An early model for inheritance that combines the Lamarckian idea of inheriting acquired characteristics withtheidea thatparticlesfrom differentparts ofthebodymake theirwaytothe sex cells.Thishas now been proven to be incorrect.
- Peacock: Themale sex ofthepeafowl,famousfor itslarge, colorfultail,whichitdramaticallydisplaysto attract mates. (The female of the species is known as a peahen.)
- Peppered moth: A species of moth found in England that has light and dark phenotypes. During the Industrial Revolution,whensootblackenedthetrees,thefrequencyofthepreviouslyraredarkphenotypedramaticallyincreased, as lighter-colored moths were easier for birds to spot against the sooty trees. After environmental regulations eliminated the soot, the lighter-colored phenotype gradually became most common again.
- Phenotype: The observable traits that are produced by a genotype.
- Phylogenetic tree of life: A family tree of all living organisms, based on genetic relationships.
- Phylogenies: Genetically determined family lineages.
- Plasmodium: A genus of mosquito-borne parasite. Several Plasmodium species cause malaria when introduced to the human bloodstream via a mosquito bite.
- Plexiform neurofibromas: Neurofibromas thatinvolve wholebranches of nerves, often givingtheappearance thatthe surface of the skin is “melting.”
- Point mutation: A single-letter (single-nucleotide) change in the genetic code, resulting in the substitution of one nucleic acid base for a different one.
- Polymorphisms: Multiple forms of a trait; alternative phenotypes within a given species.
- Population: A group ofindividuals who are genetically similar enough and geographically near enough to one another that they can breed and produce new generations of individuals.
- Population bottleneck: A type of genetic drift that occurs when the number of individuals in a population drops dramatically due to some random event.
- Positive assortative mating: Apatternthatresultsfromatendencyforindividualstomatewithotherswhosharesimilar phenotypes.
- Retrotransposons: Transposons that are transcribed from DNA into RNA, and then are “reverse transcribed,” to insert the copied sequence into a new location in the DNA.
- Sexual reproduction: Reproduction via meiosis and combination of gametes. Offspring inherit genetic material from both parents.
- Sexual selection: Anaspectofnaturalselectioninwhichtheselectivepressurespecificallyaffectsreproductivesuccess (the ability to successfully breed and raise offspring).
- Sickle cell anemia: Anautosomalrecessivegeneticdisorderthataffectsmillionsofpeopleworldwide.Itismostcommon in Africa, countries around the Mediterranean Sea, and eastward as far as India. Homozygotes for the recessive allele developthedisorder, whichproduce misshapenredblood cellsthat cause iron deficiency, painfulepisodes of oxygen-deprivationinlocalizedtissues,and heterozygotes,though,thesickle cellallele confers a greater resistance to malaria.
- ahostofothersymptoms.In
- Somatic cells: The cells of our organs and other body tissues (all cells except gametes) that replicate by mitosis.
- Speciation: The process by which a single population divides into two or more separate species.
- Species: Organismswhoseindividualsarecapableofbreedingbecausetheyarebiologicallyandbehaviorallycompatible
- to produce viable, fertile offspring. Splice site mutation: A mutation that changes the genetic code so that the correct area to be modified for mRNA splicing is not recognized by the appropriate enzymes.
- Spontaneous mutation: A mutation that occurs due to random chance or unintentional exposure to mutagens. In
- families, a spontaneous mutation is the first case, as opposed to mutations that are inherited from parents. Subspecies: A distinct subtype of a species. Most often, this is a geographically isolated population with unique phenotypes; however, it remains biologically and behaviorally capable of interbreeding with other populations of the same species.
- Sympatric speciation: When a population splits into two or more separate species while remaining located together without a physical (or cultural) barrier. Synonymous mutation: A point mutation that does not change the resulting protein. Transposable elements: Fragments of DNA that can “jump” around in the genome.
- Transposon: Another term for “transposable element.” Trisomies: Conditionsinwhichthreecopiesofthesamechromosomeendupinacell,resultingfromanon-disjunction event. Down syndrome, Edwards syndrome, and Patau syndrome are trisomies.
- Unbalanced translocations: Chromosomal translocations in which there is an unequal exchange of genetic material resulting in duplication or loss of genes. Universal ancestor: The first living organism, from which all living things are descended. UV crosslinking: A type of mutation in which adjacent thymine bases bind to one another in the presence of UV light.
- Viable Offspring: Offspring that are healthy enough to survive to adulthood. Xeroderma pigmentosum: Anautosomal recessive disease inwhichDNA repair mechanismsdonotfunction correctly, resultingin ahostofproblems,especially relatedtosunexposure,including severe sunburns,dryskin,heavyfreckling, and other pigment changes.
- About the Author
- Andrea Alveshere
- Western Illinois University,[email protected],http://www.wiu.edu/cas/anthropology/faculty-staff/alveshere.php
- Figure
- Dr. Alveshere at the summit of Monk’s Mound at the Cahokia Mississippian site in Collinsville, Illinois. Note the St. Louis, Missouri, skyline in the background.
- Dr. Alveshere at the summit of Monk’s Mound at the Cahokia Mississippian site in Collinsville, Illinois. Note the St. Louis, Missouri, skyline in the background.
- Dr. Andrea Alveshere isanassistantprofessor of anthropologyandchemistry atWesternIllinoisUniversity. Her researchfocuses onrelationshipsbetween humans and their environments, including questions of diet and health; cultural and biological adaptations; genetic disorders such as Neurofibromatosis Type 1 (NF1); effects of environmental factors on the preservation ofbones,plant remains,andthemoleculeswithinthem;andthe comparative utility of various field and laboratory techniques to produce informative archaeol
- Dr.AlveshereearnedherB.A.inanthropologyattheUniversityofWashington withanemphasisinarchaeologyand anundergraduate researchfocusonthe analysis ofskeletal remainsandgeoarchaeologicaldeposits.AttheUniversity ofMinnesota,shecompletedherPh.D.inanthropology,withaminorinhuman genetics. Her graduate thesis investigated factors that influence the preservation and detection of DNA in ancient and forensic specimens.
- In addition to her academic experience, Dr. Alveshere worked for several years as a forensic scientist in the DNA/ Biology section of the Minnesota Bureau of Criminal Apprehension Forensic Science Laboratory. She leads the WIU ArchaeologicalFieldSchool,whichisofferedeveryothersummer,andhasalsoconductedarchaeologicalexcavationsin Israel, South Africa, and throughout the Midwestern United States.
- For Further Exploration
- Explore Evolution. HHMI’s Biointeractive.https://www.hhmi.org/biointeractive/evolution-collection
- Teaching Evolution Through Human Examples. Smithsonian Museum of Natural History. education/teaching-evolution-through-human-examples
- http://humanorigins.si.edu/
- References
- Bloomfield, Gareth, David Traynor, Sophia P. Sander, Douwe M. Veltman, Justin A. Pachebat, and Robert R. Kay. 2015. “Neurofibromin Controls Macropinocytosis and Phagocytosis in Dictyostelium.” eLife 4:e04940.
- Castle, W. E., and J. C. Phillips. 1914. Piebald Rats and Selection: An Experimental Test of the Effectiveness of Selection and of the Theory of Gametic Purity in Mendelian Crosses. Carnegie Institute of Washington, No. 195. Washington, DC: Carnegie Institute of Washington.
- Chaix,Raphaëlle,ChenCao,andPeterDonnelly. 2008.“Is MateChoice inHumans MHC-Dependent?”PLoSGenetics4 (9): e1000184.
- Cook, LaurenceM. 2003. “The Rise and Fall of theCarbonariaForm of the Peppered Moth.” The Quarterly Review of Biology 78 (4): 399–417.
- Cota, Bruno Cézar Lage, João Gabriel Marques Fonseca, Luiz Oswaldo Carneiro Rodrigues, Nilton Alves de Rezende, Pollyanna Barros Batista, Vincent Michael Riccardi, Luciana Macedo de Resende. 2018. “Amusia and Its Electrophysiological Correlates in Neurofibromatosis Type 1.” Arquivos de Neuro-Psiquiatria 76 (5): 287–295.
- Darwin,Charles.1859.OntheOriginofSpeciesbyMeansofNaturalSelection,orthePreservation ofFavouredRacesin the Struggle for Life. London: John Murray.
- D’Asdia, Maria Cecilia, Isabella Torrente, Federica Consoli, Rosangela Ferese, Monia Magliozzi, Laura Bernardini, ValentinaGuida,etal.2013.“NovelandRecurrentEVCandEVC2MutationsinEllis-vanCreveldSyndromeandWeyers Acrofacial Dyostosis.” European Journal of Medical Genetics 56 (2): 80–87.
- Dobzhansky, Theodosius (1937). Genetics and the Origin of Species. Columbia University Biological Series. New York: Columbia University Press.
- Facon, Benoît, Laurent Crespin, Anne Loiseau, Eric Lombaert, Alexandra Magro, Arnaud Estoup. 2011. “Can Things Get Worse When an Invasive Species Hybridizes? The Harlequin LadybirdHarmonia axyridisin France as a Case Study.”Evolutionary Applications 4 (1): 71–88.
- Fisher, RonaldA.(1919). “TheCorrelationBetween Relatives ontheSupposition ofMendelianInheritance.” Transactions of the Royal Society of Edinburgh 52 (2): 399–433.
- Ford, E. B. 1942.Genetics for Medical Students. London: Methuen.
- Ford, E. B.1949.Mendelism and Evolution. London: Methuen.
- Grant, Bruce S. 1999. “Fine-tuning the Peppered Moth Paradigm.” Evolution 53 (3): 980–984.
- Haldane,J.B.S.1924.“AMathematicalTheoryofNaturalandArtificialSelection(Part1).”TransactionsoftheCambridge Philosophical Society23:19–41.
- Huxley, Julian. 1942. Evolution: The Modern Synthesis. London: Allen & Unwin.
- Imperato-McGinley, J., and Y.-S. Zhu. 2002. “Androgens and Male Physiology: The Syndrome of 5 Alpha-Reductase-2 Deficiency.”Molecular and Cellular Endocrinology 198: 51–59.
- Jablonski,David,andW.G.Chaloner.1994.“ExtinctionsintheFossilRecord[andDiscussion].”PhilosophicalTransactions of the Royal Society of LondonB: Biological Sciences344 (1,307): 11–17.
- Livi-Bacci, Massimo. 2006. “The Depopulation of Hispanic America After the Conquest.” Population Development and Review 32 (2): 199–232.
- Lombaert, Eric, Thomas Guillemaud, Jean-Marie Cornuet, Thibaut Malausa, Benoît Facon, and Arnaud Estoup. 2010. “Bridgehead Effect in the Worldwide Invasion of the Biocontrol Harlequin Ladybird.” PLoS ONE 5 (3): e9743.
- Martins,AlineStangherlin,AnnKristineJansen,LuizOswaldoCarneiroRodrigues,CamilaMariaMatos,MarcioLeandro Ribeiro Souza, Juliana Ferreira de Souza, Maria de Fátima Haueisen Sander Diniz, et al. 2016. “Lower Fasting Blood Glucose in Neurofibromatosis Type 1.” Endocrine Connections 5 (1): 28–33.
- Morgan, T. H. 1911. “Random Segregation Versus Coupling in Mendelian Inheritance.” Science 34 (873): 384.
- Pickering, Gary, James Lin, Roland Riesen, Andrew Reynolds, Ian Brindle, and George Soleas. 2004.“Influence ofHarmonia axyridison the Sensory Properties of White and Red Wine.”American Journal of Enology and Viticulture55 (2): 153–159.
- Repunte-Canonigo Vez, Melissa A. Herman, Tomoya Kawamura, Henry R. Kranzler, Richard Sherva, Joel Gelernter, Lindsay A. Farrer, Marisa Roberto, and Pietro Paolo Sanna. 2015. “NF1 Regulates Alcohol Dependence-Associated Excessive Drinking and Gamma-Aminobutyric Acid Release in the Central Amygdala in Mice and Is Associated with Alcohol Dependence in Humans.” Biological Psychiatry 77 (10): 870–879.
- Riccardi,VincentM.1992.Neurofibromatosis:Phenotype,NaturalHistory, andPathogenesis.Baltimore:JohnsHopkins University Press.
- Sanford, Malcolm T. 2006.“The Africanized Honey Bee in the Americas: A Biological Revolution With Human Cultural Implications, Part V—Conclusion.”American Bee Journal 146 (7): 597–599.
- Sanna, Pietro Paolo, Cindy Simpson, Robert Lutjens, and George Koob. 2002. “ERK Regulation in Chronic Ethanol Exposure and Withdrawal.” Brain Research 948 (1–2): 186–191.
- Weismann,August.1892.DasKeimplasma:EineTheoriederVererbung[TheGermPlasm:ATheoryofInheritance].Jena: Fischer.
- World Health Organization. 1996. “Control of Hereditary Disorders: Report of WHO Scientific meeting (1996).” WHO Technical Reports 865. Geneva: World Health Organization.
- WorldHealthOrganization.2017.“GlobalPriorityListofAntibiotic-ResistantBacteriatoGuideResearch,Discovery,and Development of New Antibiotics.” Global Priority Pathogens List, February 27. Geneva: World Health Organization.
- https://www.who.int/medicines/publications/WHO-PPL-Short_Summary_25Feb-ET_NM_WHO.pdf
- Wright,Sewall.1932.“TheRolesofMutation,Inbreeding,Crossbreeding,andSelectioninEvolution.”Proceedingsofthe Sixth International Congress on Genetics 1 (6): 356–366.
- Acknowledgment
- ManythankstoDr. VincentM.Riccardifor sharinghis vastknowledge ofneurofibromatosisandfor encouraging meto explore it from an anthropological perspective.
- Figure Attributions
- Figure 4.1Tree of life SVGby Ivica Letunic:Iletunic, retraced by Mariana Ruiz Villarreal:LadyofHats, has been designated to thepublic domain (CC0). This item has been modified (made grayscale, rotated, labels added).
- Figure 4.2A Lamarckian Evolution original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.2B Modern Synthesis original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.3 Weismann’s mouse-tail experiment original to Explorations: An Open Invitation to Biological Anthropology
- byMary Nelsonis under aCC BY-NC 4.0 License. Figure 4.4 Castle’s Hooded Rat Experiment original to Explorations: An Open Invitation to Biological Anthropology by Mary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.5 Morgan’s Mutant Fruit Flies original to Explorations: An Open Invitation to Biological Anthropology byMary
- Nelsonis under aCC BY-NC 4.0 License. Figure 4.6 UV-induced Thymine dimer mutation original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.7 Cytosine-to-thymine point mutation original to An Open Invitation to Biological Anthropology byMary
- Nelsonis under aCC BY-NC 4.0 License. Figure 4.8 Point and frameshift mutations original to An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.9 Woman with cutaneous neurofibromas (syptom of NF1) byRick Guidotti of Positive Exposureis used by
- permission and available here is under aCC BY-NC 4.0 License. Figure 4.10a Man with plexiform neurofibroma (syptom of NF1) is used by permission from Ashok Shrestha and available here is under aCC BY-NC 4.0 License.
- Figure 4.10b Childhood photo of the same man with NF1 disorder is used by permission from Ashok Shrestha and
- available here is under aCC BY-NC 4.0 License. Figure 4.11 Child with café-au-lait macules (birthmarks) typical of the earliest symptoms of NF1 by Andrea J. Alveshere is under aCC BY-NC 4.0 License.
- Figure 4.12 The Cretaceous–Paleogene extinction event original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.136 FingerbyWilhelmyis under aCC BY-SA 4.0 License. Figure 4.14 Ladybug Gene Flow original to Explorations: An Open Invitation to Biological Anthropology byMary Nelson is under aCC BY-NC 4.0 License.
- Figure 4.15Peppered moths c2byKhaydockis under aCC BY-SA 3.0 License.
- Figure 4.16Biology (ID: OpenStaxis used under aCC BY 4.0 License. Figure 4.17Sickle-cell smear 2015-09-10byPaulo Henrique Orlandi Mourao, contrast modified and labels added by
- [email protected])byCNX
- Katie Nelson,CC BY-SA 4.0.
- Figure 4.18 Peacock tail advantage and disadvantages soriginal to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License. Figure 4.19 Isolation Leading to Speciation original to Explorations: An Open Invitation to Biological Anthropology by
- Mary Nelsonis under aCC BY-NC 4.0 License. Figure 4.20 Darwin’s finches original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
- Figure 4.21 Ladybug mix original to Explorations: An Open Invitation to Biological Anthropology byMary Nelsonis under aCC BY-NC 4.0 License.
