Lecture 1 Powerpoint Notes
Questions addressed by Evolutionary Biology
Why are there so many different kinds of organisms?
Why are there so many species of flies and so few species of elephants? How have
they become good at what they do? Find food, mates, avoid predators? What is
related to what? And where do new species come from? How old are they?
Overview: Darwin Introduces a Revolutionary Theory
A new era of biology began on November 24, 1859
The day Charles Darwin published On the Origin of Species by Means of Natural
Selection
The Origin of Species
Focused biologists’ attention on the great diversity of organisms
The Origin of Species
Darwin developed two main ideas
Evolution explains life’s unity and diversity
Natural selection is a cause of adaptive evolution
Descent with Modification
The phrase descent with modification
Summarized Darwin’s perception of the unity of life
States that all organisms are related through descent from an ancestor that
lived in the remote past
In the Darwinian view, the history of life is like a tree
With multiple branchings from a common trunk to the tips of the youngest twigs
that represent the diversity of living organisms
Natural Selection and Adaptation
Evolutionary biologist Ernst Mayr
Has dissected the logic of Darwin’s theory into three inferences based on five
observations
Observation #1: For any species, population sizes would increase exponentially
If all individuals that are born reproduced successfully
Observation #2: Nonetheless, populations tend to be stable in size
Except for seasonal fluctuations
Observation #3: Resources are limited
Inference #1: Production of more individuals than the environment can support
Leads to a struggle for existence among individuals of a population, with only a
fraction of their offspring surviving
Observation #4: Members of a population vary extensively in their
characteristics
No two individuals are exactly alike
Observation #5: Much of this variation is heritable
Inference #2: Survival depends in part on inherited traits
Individuals whose inherited traits give them a high probability of surviving and
reproducing are likely to leave more offspring than other individuals
Inference #3: This unequal ability of individuals to survive and reproduce
Will lead to a gradual change in a population, with favorable characteristics
accumulating over generations
Artificial Selection
In the process of artificial selection
Humans have modified other species over many generations by selecting and
breeding individuals that possess desired traits
Summary of Natural Selection
Natural selection is differential success in reproduction
That results from the interaction between individuals that vary in heritable
traits and their environment
Natural selection can produce an increase over time
In the adaptation of organisms to their environment
If an environment changes over time
Natural selection may result in adaptation to these new conditions
Darwin’s theory explains a wide range of observations
Darwin’s theory of evolution
Continues to be tested by how effectively it can account for additional
observations and experimental outcomes
Natural Selection in Action
Two examples
Provide evidence for natural selection
Differential Predation in Guppy Populations
Researchers have observed natural selection
Leading to adaptive evolution in guppy populations
The Evolution of Drug-Resistant HIV
In humans, the use of drugs
Selects for pathogens that through chance mutations are resistant to the drugs’
effects
Natural selection is a cause of adaptive evolution
Researchers have developed numerous drugs to combat HIV
But using these medications selects for viruses resistant to the drugs
The ability of bacteria and viruses to evolve rapidly
Poses a challenge to our society
Homology, Biogeography, and the Fossil Record
Evolutionary theory
Provides a cohesive explanation for many kinds of observations
Homology
Homology
Is similarity resulting from common ancestry
Anatomical Homologies
Homologous structures between organisms
Are anatomical resemblances that represent variations on a structural theme that
was present in a common ancestor
Comparative embryology
Reveals additional anatomical homologies not visible in adult organisms
Vestigial organs
Are some of the most intriguing homologous structures
Are remnants of structures that served important functions in the organism’s
ancestors
Molecular Homologies
Biologists also observe homologies among organisms at the molecular level
Such as genes that are shared among organisms inherited from a common ancestor
Homologies and the Tree of Life
The Darwinian concept of an evolutionary tree of life
Can explain the homologies that researchers have observed
Anatomical resemblances among species
Are generally reflected in their molecules, their genes, and their gene products
Biogeography
Darwin’s observations of the geographic distribution of species, biogeography
Formed an important part of his theory of evolution
Some similar mammals that have adapted to similar environments
Have evolved independently from different ancestors
The Fossil Record
The succession of forms observed in the fossil record
Is consistent with other inferences about the major branches of descent in the
tree of life
The Darwinian view of life
Predicts that evolutionary transitions should leave signs in the fossil record
Paleontologists
Have discovered fossils of many such transitional forms
What Is Theoretical about the Darwinian View of Life?
In science, a theory
Accounts for many observations and data and attempts to explain and integrate a
great variety of phenomena
Darwin’s theory of evolution by natural selection
Integrates diverse areas of biological study and stimulates many new research
questions
Overview: The Smallest Unit of Evolution
One common misconception about evolution is that individual organisms evolve, in
the Darwinian sense, during their lifetimes
Natural selection acts on individuals, but populations evolve
EVOLUTION
A genetic change in a population of organisms that occurs over time, often
adapting to an environment or way of life.
Evolutionary changes must be genetically inherited, not acquired.
Evolution of Evolutionary thinking (Pre-Darwinian)
Jean-Baptiste Lamarck (1744-1829) – French naturalist, proposed a theory that
organisms were driven by some inner force toward greater complexity. But thought
that org. could pass on traits to their offspring that they acquired during
their lives. (“Lamarckism”, proposed in 1809)
Lamarckism
Lamarckism holds that traits acquired (or diminished) during the lifetime of an
organism can be passed to its offspring.
Lamarck based his theory on two observations thought to be true in his day:
“Use it or lose it” - Individuals lose characteristics they do not require and
develop those which are useful.
Inheritance of acquired traits - Individuals inherit the acquired traits of
their ancestors.
Lamarckism
Examples include: the stretching by giraffes to reach leaves leads to offspring
with longer necks;
Strengthening of muscles in a blacksmith's arm leads to sons with like muscular
development.
Charles Darwin
Charles Darwin (1809-1882)
Born in England, studied Theology…
Takes a 5-year trip around the world as a naturalist on the HMS Beagle.
Observes plant and animal species in Galapagos Islands, Australia, NZ, etc.
Observed: Island animals are similar to mainland animal species (descended), but
they show differences due to the conditions on their island.
On the Origin of Species…
Came home, worked for 16 years analyzing his data
Darwin publishes the most influential text of all times: On the Origin of
Species by Means of Natural Selection in November 24, 1859.
(The entire printing (2500 copies) was sold that same day!)
Controversy…
The Origin of Species… caused great arguments between scientists and
philosophers – both noting the theories failures and strengths.
Darwin’s revolutionary thoughts
Darwin thought of organisms not as constant, unchanging or “specially created
beings”.
Could not believe that organisms today appeared as they have always appeared
Darwin changed biological thought forever with the concept of Natural Selection!
Natural Selection
Has four premises:
1) Variation – Members of a population have individual differences that are
inheritable
2) Overproduction – Natural populations reproduce geometrically
3) Competition – Individuals compete for limited resources
4) Survival to reproduce – Only those individuals that are better suited to the
environment survive and reproduce
Natural Selection
1. Variation: Member within a species exhibit individual differences – these
differences must be inheritable
Natural selection won’t work in a population of clones! Remember that a key to
variation is sexual reproduction.
Natural Selection
2. Overproduction: Natural populations increase geometrically, producing much
more offspring than will survive…
Natural Selection
3. Competition: Individuals compete for the same, limited natural resources.
Darwin called it: “Struggle for existence”
Natural Selection
4. Survival to reproduce: Only those individuals that are better suited to the
environment will survive and reproduce (Survival of the fittest).
Fit individuals pass on to a portion of their offspring the advantageous
characteristics.
Natural Selection
Works on the individual phenotype which in turn changes the population gene
pool.
Time – long periods of time must be available in order to change to a completely
different species; changes are slow..
Natural Selection
Offspring that inherit the advantageous traits (“favorable genes”) are selected
for
Their chances of survival are greater
May live to reproductive age
May pass on those desirable attributes to future generations
Natural Selection
Those that do not inherit these traits (“unfavorable genes”), are not likely to
survive/reproduce.
Gradually, the species evolves (changes) as more individuals carry these traits.
Over time, enough changes New species
Artificial Selection
Selective breeding as practiced by humans on domesticated plants and animals….
For example: Dogs
Plant artificial selection
Teosinte vs. modern corn
Rates of evolution
Two interpretations about the pace/speed of evolution – based on the fossil
record:
1. Gradualism (a traditional view) states that
Evolution occurs as a slow and steady accumulation of changes in organism
(Darwinian evolution)… Not much evidence.
Rates of evolution
2. Punctuated Equilibrium – evolution proceeds with periods of inactivity,
followed by periods of very rapid evolution (Gould & Eldridge model).
Punctuated Equilibrium
Fossil record supports this view:
Long periods of stasis (no change in species)
Followed by rapid change
However, fossil record is evidence only of Morphology (structure), while
evolution encompasses: morphology, ecology, biochemistry, and behavioral
changes…
That is, there may be stasis in morphology, while there is still active
evolutionary changes going on…
Part II
Evidence for evolution: extant and extinct organisms
Adaptations
Coevolution
2. Mimicry and protective coloration
Mimicry: a harmless species may resemble a dangerous species.
Ex. Some moths resemble wasps
Monarch butterfly is toxic, Viceroy is not,
But Viceroy mimics the Monarch
Protective coloration
Coloration that allows an organism to blend with environment
Moths in bark in polluted England
3. Developmental Biology
Early embryos of different mammal species look very much alike – they share
common features (gills, tail, etc.).
3. Developmental Biology
4. Biogeography
Unequal distribution of organisms on earth
Kangaroos in Australia;
Saguaro Cacti in southwestern U.S. deserts
Each species originated only once, in one place – point of origin…
Species spread out until they encounter a barrier (physical, environmental,
ecological)
5. Biochemistry & Molecular Biology
Our genes provide an ‘evolutionary record’
If we evolved from a common ancestor:
We should have same genetic molecule (DNA)
We should use the DNA in the same way (dogma)
Portions of our DNA should be the same
Closely related organisms share large portions of DNA sequence…
FOSSIL EVIDENCE FOR EVOLUTION
Fossils – any trace left by a previous organism
Rocks, ice, amber, bogs, tar, etc.
Most are preserved in sedimentary rocks
Oldest rocks (fossils) have simplest life forms
Most recent rocks – have more complex life forms
ADAPTATIONS
Adaptation: A process by which genetic changes occur…
ADAPTATIONS are traits that promote the survival and reproductive success of an
organism in a particular environment.
Specific anatomical, physiological or biochemical structures/mechanisms that
arise during evolution, as a response to specific environmental pressures.
Adaptations
Adaptations may originate as mutations in one individual organism.
Adaptations are universal: life occurs in everywhere on earth…
Organisms adapt to a specific niche (place in the environment)
Without adaptations, species can become extinct.
Examples of plant adaptations
Plants try to avoid predation by herbivores. For example: desert plants with
thorns; fruits distasteful when not ripe.
Coloration: Different flower colors attract different pollinators.
Morphological adaptations. For example: Strawberries grow underground stems (stolons)
that break so that a new plant grows asexually. Also, some leaves of desert
plants are hairy, to reduce water loss, leaves in tropics are smooth
Plant adaptations
Leaves: Adapted to many functions in different plants
Coevolution
Coevolution: the long term evolutionary adjustment of one group of organisms to
another.
Coevolution is a reciprocal process in which characteristics of one organism
evolve in response to specific characteristics of another
Examples of co-evolution
There’s ANTS in PLANTS!
Acacia and ants – coevolution.
Flowers & insects – coevolution for pollination.
Bluejays & monarch/viceroy butterflies
More than just Human Cognition
A Brief History of Life
Basics of Darwinian Evolution
“Fitter?”
Simple beginnings
Multicellular
Commonwealth of interests
Cognition?
Plant Cognition
Speeding up …
Social behavior and Trust
Insects
A strange species
Continuity of Cognition
A population is a group of organisms of the same species living in the same
place at the same time
Millions of different populations all evolving according to their own self
interest in a particular environment.
But each population is a part of the environment of its neighbors, so any
evolutionary change has a ripple effect.
A Population
Group of organisms of the same species living in the same place at the same time
Individuals may come and go, but the population can remain the same
The Nakuru Flamingos each year, for Example
Population Growth
Since each organism of a population is governed by the selfish gene, populations
tend to grow
If unlimited resources are present, growth will be exponential
It will proceed very quickly for rapidly reproducing organisms and more slowly
for slowly reproducing ones
The curve, however, will always be a “J” curve or an exponential growth curve
Population Growth 2
Resources are never unlimited, though.
As population rises, resources decline.
If the growth is too rapid, resources are rapidly depleted and a population
crash can occur
This pattern occurs often with many populations (including humans)
For example...
Population Growth 3
More often what happens is that the resources slowly decrease, the growth rate
slowly decreases, and they meet.
This point that they oscillate around is the carrying capacity of the
environment for that particular organism
So when would you “harvest” these individuals? (1,2,3,4,or 5)
Population Mortality
Organisms differ on strategies of reproduction and differ on types of predation
Those organisms that put much care into their few young tend to have good
survivorship of young
Those organisms that spread their young all over tend to have poor survivorship
of their young
A graphic representation of the rates of survival at different ages is called a
survivorship curve
Population Density and Dispersion
Population density is simply the number of individuals measured per unit of area
or volume
Additionally, the population can clump in different ways
Random
Clumped
Regular
Growth Rate Limiting Factors (effecting birth or mortality rates)
Density-Dependent
Predation
Increased competition for scarce resources
Sickness
Others?...
Density-Independent
Weather
Ice Age
Global Warming
Flood
El Nino
Etc.
Human Growth Patterns
Microevolution
A change in a populations gene pool over a succession of generations
Population is the smallest unit of evolution
A population is a localized group of individuals of the same species
Species is a group of populations whose members are capable of interbreeding.
The gene pool is the term for all the genes present in a population at any given
time.
Diploids two alleles at each locus
If all individuals are homozygous for the same allele “fixed”
More often see alleles in some relative proportion or frequency
The Evolution of Populations
1900’s many geneticists believed Darwin’s focus on inheritance of quantitative
traits that vary on a continuum could not be explained by the inheritance of
discrete Mendelian traits
1930’s population genetics – emphasis on quantitative inheritance and genetic
variation in populations Mendelism + Darwinism
1940’s modern synthesis – comprehensive theory of evolution – emphasized
importance of populations as units of evolution, the essential role of natural
selection and the gradualness of evolution
The Darwinian Evolution
The Voyage of the Beagle
1844 essay on the origin of species and natural selection
1858 Darwin + Wallace presented identical theories of natural selection
1859 “On The Origin of Species” published
Darwin’s Focus on Adaptation
The Origin of Species
Developed two main points
The occurrence of evolution
Natural selection as its mechanism
Descent with Modification
All organisms were related through descent from some unknown ancestor and had
developed increasing modifications as they adapted to various environments
Natural Selection and Adaptation
Ernst Mayr (biological species concept) summarized Darwin’s theory
Observation 1: Species have the potential for their population size to increase
exponentially.
Observation 2: Most population sizes are stable.
Observation 3: Environmental resources are limited.
Inference 1: Since only a fraction of offspring survive, there is a struggle for
limited resources.
Natural Selection and Adaptation
Observation 4: Individuals vary within a population.
Observation 5: Much of the variation is inherited.
Inference 2: Individuals whose inherited characteristics fit them best to the
environment are likely to leave more offspring.
Inference 3: Unequal reproduction leads to the gradual accumulation of favorable
characteristics in a population over generations.
Support for Natural Selection
Artificial Selection breeding of domesticated plants and animals for specific
traits
Natural Selection measured only as a change in the relative proportions of
variations in a population over time
Affects only those traits that are heritable (acquired characteristics cannot
evolve)
Local and temporal, depending on specific environmental factors present at a
given time and place
Natural Selection in Action
Favor some heritable traits over others, changes populations over successive
generations
The Peppered Moth
Snails
Light-colored and striped well-lighted areas
Dark-colored, lacking stripes shady places
Natural Selection in Action
Examples provide evidence for evolution Directed Selection
Evolution of insect resistant strains
Evolution of antibiotic resistant bacteria
Evolution of drug-resistant HIV
Other Evidence of Evolution
Biogeography + Fossil Record
Comparative Anatomy
Comparative Embryology
Molecular Biology
Darwinism
What is theoretical about the Darwinian view of life?
The evolution of modern species from ancestral forms is supported by facts –
fossils, biogeography, comparative anatomy and embryology and molecular biology.
The second of Darwin’s claims, that natural selection is the main mechanism of
evolution, is a theory that explains the historical facts.
The Evolution of Populations
Although it is individuals that are selected for or against by natural selection
it is populations that actually evolve.
Hardy-Weinberg Equilibrium
In the absence of selection pressure, the gene pool of a population will remain
constant from one generation to the next
Equation: p2 + 2pq + q2 = 1
Also (p + q = 1)
Population Genetics & Public Health
If know the frequency of individuals born with a certain inherited disease
(homozygous, recessive) estimate the frequency of a harmful allele in a
population
The q2 = genotype frequency of affected individual (1 in 10,000 births)
PKU q2 = 0.0001 then q = 0.01
Carriers 2pq = 2 (0.99) (0.01) = 0.02 2% of the population are carriers
Hardy-Weinberg Equilibrium
Five conditions are required to maintain:
The population is very large.
The population is isolated no migration in or out.
Mutations do not alter the gene pool.
Mating is random.
All individuals are equal in reproductive success no natural selection.
These 5 conditions are rarely (if ever) met in nature.
Causes of Microevolution
Five causes correspond to a deviation of the 5 causes that maintain
Hardy-Weinberg Equilibrium.
Genetic drift
Gene flow
Mutation
Nonrandom mating
Natural selection
Genetic Drift
Change in the gene pool of a small population due to chance
Chance event can have a disproportionately large effect
Genetic drift is most likely to play a role in populations with 100 or fewer
individuals
Genetic Drift
Bottleneck genetic drift resulting from an event that drastically reduces
population size natural or man-made disasters small surviving population
unlikely to have the same genetic make-up as original population reduces
genetic variation
Founder Effect colonization of a new location by a small number of individuals
reduces genetic variation
Genetic Drift
Statistically, the smaller a sample
The greater the chance of deviation from a predicted result
Genetic drift
Describes how allele frequencies can fluctuate unpredictably from one generation
to the next
Tends to reduce genetic variation
Gene Flow
Gain or loss of alleles from a population by the movement of individuals or
gametes
Occurs when fertile individuals move into or out of a population, or transfer of
gametes, (pollen), from one population to another
Gene flow tends to reduce genetic differences between populations
Gene Flow
Gene flow
Causes a population to gain or lose alleles
Results from the movement of fertile individuals or gametes
Tends to reduce differences between populations over time
: Natural selection is the primary mechanism of adaptive evolution
Natural selection
Accumulates and maintains favorable genotypes in a population
Mutation
Random change in an organism’s DNA that creates a new allele
Rare event – alone usually does not have much impact on a population
Natural selection or genetic drift may increase the frequency of the allele
Mutation
Mutations
Are changes in the nucleotide sequence of DNA
Cause new genes and alleles to arise
Point Mutations
A point mutation
Is a change in one base in a gene
Can have a significant impact on phenotype
Is usually harmless, but may have an adaptive impact
Mutations That Alter Gene Number or Sequence
Chromosomal mutations that affect many loci
Are almost certain to be harmful
May be neutral and even beneficial
Gene duplication
Duplicates chromosome segments
Mutation Rates
Mutation rates
Tend to be low in animals and plants
Average about one mutation in every 100,000 genes per generation
Are more rapid in microorganisms
Nonrandom Mating
Selection of mates other than by chance
Nonrandom mating is more the rule in populations “like” tends to mate with
“like”
Stationary organisms or geographically restricted organisms tend to mate with
their neighbors rather than more distant members of the population tends to
promote interbreeding
Natural Selection
Differential success in reproduction
Factor most likely to result in adaptive changes in a gene pool
The Bottleneck Effect
In the bottleneck effect
A sudden change in the environment may drastically reduce the size of a
population
The gene pool may no longer be reflective of the original population’s gene pool
Understanding the bottleneck effect
Can increase understanding of how human activity affects other species
Hardy Weinberg Principle:
The work of mathematician G.H. Hardy and German doctor W. Weinberg, it explains
some basic properties of populations and how to describe them mathematically.
The Law:
"The frequencies of alleles that make up a gene will remain the same in a
stable population. When p and q stand for the frequency of each allele in a
gene then: p+q=1
The Hardy-Weinberg Theorem
The Hardy-Weinberg theorem
Describes a population that is not evolving
States that the frequencies of alleles and genotypes in a population’s gene pool
remain constant from generation to generation provided that only Mendelian
segregation and recombination of alleles are at work
Mendelian inheritance
Preserves genetic variation in a population
Preservation of Allele Frequencies
In a given population where gametes contribute to the next generation randomly,
allele frequencies will not change
Hardy-Weinberg Equilibrium
Hardy-Weinberg equilibrium
Describes a population in which random mating occurs
Describes a population where allele frequencies do not change
A population in Hardy-Weinberg equilibrium
If p and q represent the relative frequencies of the only two possible alleles
in a population at a particular locus, then
p2 + 2pq + q2 = 1
And p2 and q2 represent the frequencies of the homozygous genotypes and 2pq
represents the frequency of the heterozygous genotype
Conditions for Hardy-Weinberg Equilibrium
The Hardy-Weinberg theorem
Describes a hypothetical population
In real populations
Allele and genotype frequencies do change over time
The five conditions for non-evolving populations are rarely met in nature
Extremely large population size
No gene flow
No mutations
Random mating
No natural selection
Population Genetics and Human Health
We can use the Hardy-Weinberg equation
To estimate the percentage of the human population carrying the allele for an
inherited disease
: Mutation and sexual recombination produce the variation that makes evolution
possible
Two processes, mutation and sexual recombination
Produce the variation in gene pools that contributes to differences among
individuals
p + q= 1 (100% for homozygous matings)
p 2 + 2pq + q 2 = 1
( heterozygous matings)
In a sexually reproducing population, the frequencies will stay the same in
generation after generation provided these conditions are met:
1. mutations can not occur
2. matings are at random
3. natural selection can not occur
4. no genes may enter or leave the population
5. the population must be large.
Hardy- Weinberg Worksheet
The Hardy- Weinberg model is much easier to teach if the students calculate gene
frequencies along with the instructor. This means that you (me) must pause
frequently to allow plenty of time for students (you) to actively process the
information and practice the calculations.
In the absence of other factors, the segregation and recombination of alleles
during meiosis and fertilization will not alter the overall genetic makeup of a
population.
·
The frequencies of alleles in the gene pool will remain constant unless
acted upon by other agents; this is known as the Hardy- Weinberg theorem.
The Hardy-Weinberg model describes the genetic structure of nonevolving
populations. This theorem can be tested with theoretical population models.
To test the Hardy-Weinberg theorem, imagine an isolated population of
wildflowers with the following characteristics:
· It is a diploid species with both pink and white flowers.
The population size is 500 plants: 480_ plants have pink flowers, 20 plants have
white flowers.
· Pink flower color is coded for by the dominant allele "A," white flower
color is coded for by the recessive allele "a."
Of the 480 pink-flowered plants, 320 are homozygous (AA) and 160 are
heterozygous (Aa). Since white color is recessive, all white flowered plants are
homozygous aa.
· There are 1000 genes for flower color in this population, since each of the
500 individuals has two genes (this is a diploid species).
A total of 320 genes are present in the 160 heterozygotes (Aa): half are
dominant (160 A) and half are recessive (160 a).
·800 of the 1000 total genes are dominant.
The frequency of the A allele is 80% or 0.8 (800/1000).
· 200 of the 1000 total genes are recessive.
The frequency of the a allele is 20% or 0.2 (200/1000).
Assuming that mating in the population is completely random (all male-female
mating combinations have equal chances), the frequencies of A and a will remain
the same in the next generation.
· Each gamete will carry one gene for flower color, either A or a.
Since mating is random, there is an 80% chance that any particular gamete will
carry the A allele and a 20% chance that any particular gamete will carry the a
allele.
The frequencies of the three possible genotypes of the next generation can be
calculated using the rule of multiplication.
The probability of two A alleles joining is 0.8 x 0.8 = 0.64; thus, 64% of the
next generation will be AA.
The probability of two a alleles joining is 0.2 x 0.2 = 0.04; thus, 4% of the
next generation will be aa.
· Heterozygotes can be produced in two ways, depending upon whether the
sperm or ovum contains the dominant allele (Aa or aA). The probability of a
heterozygote being produced is thus (0.8 x 0.2) + (0.2 x 0.8) = 0.16 + 0.16 =
0.32.
The frequencies of possible genotypes in the next generation are 64% AA, 32% Aa
and 4% aa.
The frequency of the A allele in the new generation is 0.64 + (0.32/2) = 0.8,
and the frequency of the a allele is 0.04 + (0.32/2) = 0.2. Note that the
alleles are present in the gene pool of the new population at the same
frequencies they were in the original gene pool.
· Continued sexual reproduction with segregation, recombination and random
mating would not alter the frequencies of these two alleles: the gene pool of
this population would be in a state of equilibrium referred to as Hardy-Weinberg
equilibrium.
If our original population had not been in equilibrium, only one generation
would have been necessary for equilibrium to become established.
From this theoretical wildflower population, a general formula, called the
HardyWeinberg equation, can be derived to calculate allele and genotype
frequencies.
The Hardy-Weinberg equation can be used to consider loci with three or more
alleles.
· By way of example, consider the simplest case with only two alleles
with one dominant to the other.
· In our wildflower population, let p represent allele A and q represent
allele a, thus p = 0.8 and q = 0.2.
The sum of frequencies from all alleles must equal 100% of the genes for that
locus in the population: p + q = 1.
• Where only two alleles exist, only the frequency of one must be known since
the other can be derived:
1 -p=q or 1 -q=p
When gametes fuse to form a zygote, the probability of producing the AA genotype
is p2; the probability of producing aa is q2; and the probability of producing
an Aa heterozygote is 2pq (remember heterozygotes may be formed in two ways Aa
or aA).
· The sum of these frequencies must equal 100%, thus:
p2 + 2pq + q2 = 1
Frequency Frequency Frequency
of AA of Aa of aa
The Hardy-Weinberg equation permits the calculation of allelic frequencies in a
gene pool, if the genotype frequencies are known. Conversely, the genotype can
be calculated from known allelic frequencies.
For example, the Hardy-Weinberg equation can be used to calculate the frequency
of inherited diseases in humans (e.g., phenylketonuria):
· 1 of every 10,000 babies in the United States is born with phenylketonuria (PKU),
a metabolic disorder that, if left untreated, can result in mental retardation.
· The allele for PKU is recessive, so babies with this disorder are homozygous
recessive = q2.
Thus q2 = 0.0001,
with q = 0.01
(the square root of 0.0001).
· The frequency of p can be determined since p = 1 - q:
p = I - 0.01 = 0.99
· The frequency of carriers (heterozygotes) in the population is 2pq.
2pq = 2(0.99)(0.01) = 0.0198
Thus, about 2% of the U.S. population are carriers for PKU.
http://science.nhmccd.edu/biol/hwe/q1d.html
Chapter 23
The Evolution of Populations
Genetic variations in populations
Contribute to evolution
: Population genetics provides a foundation for studying evolution
Microevolution
Is change in the genetic makeup of a population from generation to generation
The Modern Synthesis
Population genetics
Is the study of how populations change genetically over time
Reconciled Darwin’s and Mendel’s ideas
The modern synthesis
Integrates Mendelian genetics with the Darwinian theory of evolution by natural
selection
Focuses on populations as units of evolution
Gene Pools and Allele Frequencies
A population
Is a localized group of individuals that are capable of interbreeding and
producing fertile offspring
The gene pool
Is the total aggregate of genes in a population at any one time
Consists of all gene loci in all individuals of the population
Sexual Recombination
In sexually reproducing populations, sexual recombination
Is far more important than mutation in producing the genetic differences that
make adaptation possible
: Natural selection, genetic drift, and gene flow can alter a population’s
genetic composition
Three major factors alter allele frequencies and bring about most evolutionary
change
Natural selection
Genetic drift
Gene flow
Natural Selection
Differential success in reproduction
Results in certain alleles being passed to the next generation in greater
proportions
The Founder Effect
The founder effect
Occurs when a few individuals become isolated from a larger population
Can affect allele frequencies in a population
Genetic Variation
Genetic variation
Occurs in individuals in populations of all species
Is not always heritable
Variation Within a Population
Both discrete and quantitative characters
Contribute to variation within a population
Discrete characters
Can be classified on an either-or basis
Quantitative characters
Vary along a continuum within a population
Polymorphism
Phenotypic polymorphism
Describes a population in which two or more distinct morphs for a character are
each represented in high enough frequencies to be readily noticeable
Genetic polymorphisms
Are the heritable components of characters that occur along a continuum in a
population
Measuring Genetic Variation
Population geneticists
Measure the number of polymorphisms in a population by determining the amount of
heterozygosity at the gene level and the molecular level
Average heterozygosity
Measures the average percent of loci that are heterozygous in a population
Variation Between Populations
Most species exhibit geographic variation
Differences between gene pools of separate populations or population subgroups
Some examples of geographic variation occur as a cline, which is a graded change
in a trait along a geographic axis
A Closer Look at Natural Selection
From the range of variations available in a population
Natural selection increases the frequencies of certain genotypes, fitting
organisms to their environment over generations
Evolutionary Fitness
The phrases “struggle for existence” and “survival of the fittest”
Are commonly used to describe natural selection
Can be misleading
Reproductive success
Is generally more subtle and depends on many factors
Fitness
Is the contribution an individual makes to the gene pool of the next generation,
relative to the contributions of other individuals
Relative fitness
Is the contribution of a genotype to the next generation as compared to the
contributions of alternative genotypes for the same locus
Directional, Disruptive, and Stabilizing Selection
Selection
Favors certain genotypes by acting on the phenotypes of certain organisms
Three modes of selection are
Directional
Disruptive
Stabilizing
Directional selection
Favors individuals at one end of the phenotypic range
Disruptive selection
Favors individuals at both extremes of the phenotypic range
Stabilizing selection
Favors intermediate variants and acts against extreme phenotypes
The three modes of selection
The Preservation of Genetic Variation
Various mechanisms help to preserve genetic variation in a population
Diploidy
Diploidy
Maintains genetic variation in the form of hidden recessive alleles
Balancing Selection
Balancing selection
Occurs when natural selection maintains stable frequencies of two or more
phenotypic forms in a population
Leads to a state called balanced polymorphism
Heterozygote Advantage
Some individuals who are heterozygous at a particular locus
Have greater fitness than homozygotes
Natural selection
Will tend to maintain two or more alleles at that locus
The sickle-cell allele
Causes mutations in hemoglobin but also confers malaria resistance
Exemplifies the heterozygote advantage
Frequency-Dependent Selection
In frequency-dependent selection
The fitness of any morph declines if it becomes too common in the population
An example of frequency-dependent selection
Neutral Variation
Neutral variation
Is genetic variation that appears to confer no selective advantage
Sexual Selection
Sexual selection
Is natural selection for mating success
Can result in sexual dimorphism, marked differences between the sexes in
secondary sexual characteristics
Intrasexual selection
Is a direct competition among individuals of one sex for mates of the opposite
sex
Intersexual selection
Occurs when individuals of one sex (usually females) are choosy in selecting
their mates from individuals of the other sex
May depend on the showiness of the male’s appearance
The Evolutionary Enigma of Sexual Reproduction
Sexual reproduction
Produces fewer reproductive offspring than asexual reproduction, a so-called
reproductive handicap
If sexual reproduction is a handicap, why has it persisted?
It produces genetic variation that may aid in disease resistance
Why Natural Selection Cannot Fashion Perfect Organisms
Evolution is limited by historical constraints
Adaptations are often compromises
Chance and natural selection interact
Selection can only edit existing variations