Chapter 6 - Evol Biology PDF

Summary

This document covers Mendelian Genetics in Populations, Population Genetics, and Hardy-Weinberg Equilibrium, explaining concepts like allele and genotype frequencies and calculations.

Full Transcript

Mendelian Genetics in Populations:
Rocky Mountain bighorn sheep (Ovis canadensis). A population of bighorn sheep at
the National Bison Range suffered the loss of genetic variation owing to genetic drift; the
introduction of sheep from other populations dramatically increased genetic variation
and the fitness of the sheep
CCR5 Gene
CCR5-∆32 mutation
CCR5 mutation: CCR5-∆32
 individuals homozygous
for CCR5-∆32 are much
less likely to contract HIV

M global AIDS epidemic will
cause an increase in the
frequency of the ∆32 allele
O in human populations.

D
E
If so, how fast will it
L happen?
Population genetics

It begins with a model of what happens to
allele and genotype frequencies in an
idealized population.
Once we know how Mendelian genes
behave in the idealized population, we will
be able to explore how they behave in real
populations.
All organisms exhibit genetic variation:
Frequencies of genotypes and alleles in a population
more genetic variation exists in populations than is
visible in the phenotype.
 Before we can explore the A frequency is simply a proportion or a
evolutionary processes that percentage, usually expressed as a
shape genetic variation, we decimal fraction
must be able to describe the
genetic structure of a For example, if 20%
population. of the alleles at a
particular locus in a
population are A,

The usual way of doing so is we would say that
to enumerate the types and the frequency of the
frequencies of genotypes and A allele in the
alleles in a population. population is 0.20
Genotypic and Allelic Frequencies
Are Used to Describe the Gene Pool
of a Population
Allele and Genotype
Calculating Genotypic
Frequencies
To calculate a genotypic frequency, we simply add up the number of
individuals possessing the genotype and divide by the total number
of individuals in the sample (N).
For a locus with three genotypes AA, Aa, and aa, the frequency (f )
of each genotype is

The sum of all the genotypic
frequencies always equals 1
 Calculating Allelic Frequencies

Allelic frequencies can be calculated
from:
(1) numbers of genotypes
(2) the frequencies of the genotypes
Calculating Allelic Frequencies
Allelic frequencies can be calculated from:
(1) numbers of genotypes

1

2
Calculating Allelic Frequencies
Allelic frequencies can be calculated from:
(2) the frequencies of the genotypes
Calculating Allelic Frequencies
Loci with multiple alleles
To calculate the allelic frequencies from the numbers of genotypes, we count up
the number of copies of an allele by adding twice the number of homozygotes to
the number of heterozygotes that possess the allele and divide this sum by twice
the number of individuals in the sample.
For a locus with three alleles (A1, A2, and A3) and six genotypes (A1A1, A1A2,
A2A2, A1A3, A2A3, and A3A3), the frequencies (p, q, and r) of the alleles are:
Calculating Allelic Frequencies
Loci with multiple alleles
Alternatively, we can calculate the frequencies of multiple alleles from the
genotypic frequencies by extending.
Add the frequency of the homozygote to half the frequency of each
heterozygous genotype that possesses the allele:
 The human MN blood-type antigens are determined by two codominant
alleles, LM and LN. The MN blood types and corresponding genotypes of
398 Finns in Karjala are tabulated here.

The genotypic frequencies for the population are calculated with the
following formula:
 The human MN blood-type antigens are determined by two codominant
alleles, LM and LN. The MN blood types and corresponding genotypes of
398 Finns in Karjala are tabulated here.

To calculate allelic frequencies from numbers of genotypes, we add the
number of copies of the allele and divide by the number of copies of all
alleles at that locus.
 The human MN blood-type antigens are determined by two codominant
alleles, LM and LN. The MN blood types and corresponding genotypes of
398 Finns in Karjala are tabulated here.

To calculate the allelic frequencies from genotypic frequencies, we add the
frequency of the homozygote for that genotype to half the frequency of
each heterozygote that contains that allele:
Evolutionary Forces Potentially Cause Changes in
Allelic Frequencies
Mutation

Genetic
Selection EVOLUTION
Drift

Migration
Mendelian Genetics
in Populations:
Hardy–Weinberg
Equilibrium
The life cycle of an idealized
population
 We want to track the fate of Mendelian genes in a population
Imagine that the mice in the figure have in their genome a
Mendelian locus, the A locus, with two alleles: A and a.
We can begin tracking these alleles at any point in the life
cycle.
We then follow them through one complete turn of the cycle,
from one generation to the next, to see if their frequencies
change.
Simulation: adults choose their
mates at random
Simulation: adults choose their
mates at random
Imagine that
60% of the eggs
and sperm
received a copy
of allele A, and
40% received a
copy of allele a.

That is, the
frequency of
allele A in the
gene pool is 0.6,
and the
frequency of
allele a is 0.4
Simulation: adults choose their
mates at random
We can close our eyes and put a finger down
on the previous figure to choose an egg.
Perhaps it carries a copy of allele A.

Now we close our eyes and put down a
finger to choose a sperm. Perhaps it carries a
copy of allele a.

If we combine these gametes, we get a
zygote with genotype Aa.

100 zygotes we made, 34 had genotype AA,
57 had Aa, and 9 had aa
Simulation: adults choose their mates at random

imagine that all Imagine, We can choose any
these zygotes furthermore, that number of gametes
develop into when the adults we like for the
juveniles, and that reproduce, they all standard donation,
all the juveniles donate the same so we will choose
survive to number of gametes 10 to make the
adulthood. to the gene pool. arithmetic easy

Summing the gametes carrying copies of each allele, we get 625 carrying A
and 375 carrying a, for a total of 1,000. The frequency of allele A in the new
gene pool is 0.625; the frequency of allele a is 0.375.
Simulation: adults choose their
mates at random

Allele and genotype frequencies throughout the life cycle in a numerical
simulation
Simulation: adults choose their
mates at random
The fact that blind luck can cause a population to evolve
unpredictably is an important result of population genetics.
This mechanism of evolution is called genetic drift.

We want to know what would
have happened in our simulations
if chance had played no role.
A Numerical Calculation:
Punnett square
When blind luck plays no role, random mating in the gene
pool of our model mouse population produces zygotes
with predictable genotype frequencies
A Numerical Calculation:
Punnett square
imagine that all Imagine, We can choose any
these zygotes furthermore, that number of gametes
develop into when the adults we like for the
juveniles, and that reproduce, they all standard donation,
all the juveniles donate the same so we will choose
survive to number of gametes 10 to make the
adulthood. to the gene pool. arithmetic easy

Summing the gametes carrying each allele, we get 600 carrying copies
of A and 400 carrying copies of a, for a total of 1,000. The frequency of
allele A in the new gene pool is 0.6; the frequency of allele a is 0.4.
A Numerical Calculation:
Punnett square

When blind luck plays no role, the allele frequencies for A and a in our
population are in equilibrium: They do not change from one generation
to the next. The population does not evolve.
The primary goal of population genetics is
to understand the processes that shape a
population’s gene pool. First, we must ask what effects
reproduction and Mendelian principles
have on the genotypic and allelic
frequencies:

How do the segregation of alleles in
gamete formation and the combining of
alleles in fertilization influence the gene
pool?
 Hardy–Weinberg law
The Hardy–Weinberg law was formulated
independently by both Godfrey H. Hardy
and Wilhelm Weinberg in 1908.
The law is actually a mathematical model
that evaluates the effect of reproduction
on the genotypic and allelic frequencies of
a population.
 The Hardy–Weinberg equilibrium principle yields
two fundamental conclusions:
Assumption: If a population is large, randomly mating,
and not affected by mutation, migration, or natural
selection, then:
Conclusion 1: The allele frequencies in a population
will not change, generation after generation.
Conclusion 2: the genotypic frequencies stabilize (will
not change) after one generation in the proportions
p2 (the frequency of AA), 2pq (the frequency of Aa),
and q2 (the frequency of aa), where p equals the
frequency of allele A and q equals the frequency of
allele a.

Genotypic Frequencies at
Hardy–Weinberg Equilibrium

How do the conditions of the Hardy–Weinberg
law lead to genotypic proportions of p2, 2pq,
and q2?
The Hardy–Weinberg
equilibrium principle
Random mating will produce genotypes of the next generation in proportions p2(AA),
2pq(Aa), and q2(aa)
assumptions that it makes about a
population
it assumes that the population is large
members of the population mate randomly,
which means that each genotype mates relative
to its frequency.
the allelic frequencies of the population are not
affected by natural selection, migration, and
mutation.
Hardy– Weinberg law apply to a single locus.
What Use Is the Hardy–Weinberg Equilibrium
Principle?

There is no selection.
There is no mutation
There is no migration
There are random matings
Implications of the Hardy–Weinberg Law

population cannot evolve if it meets the Hardy–
Weinberg assumptions, because evolution
consists of change in the allelic frequencies of a
population.
the genotypic frequencies are determined by the
allelic frequencies. The heterozygote frequency
never exceeds 0.5 when the population is in
Hardy–Weinberg equilibrium.
single generation of random mating produces
the equilibrium frequencies of p2, 2pq, and q2.
Summary of the mechanisms
of evolution
 Hardy–Weinberg principle serves as a null model.
Biologists can measure allele and genotype frequencies in
nature, and determine whether the Hardy–Weinberg
conclusions holds.
If a population is not in Hardy–Weinberg equilibrium then one
or more of the Hardy–Weinberg model’s assumptions are
being violated.
Such a discovery does not, by itself, tell us which assumptions
are being violated, but it indicates that further research may
be rewarded with interesting discoveries.
Testing the Hardy-Weinberg
Principle
1. Calculate the allele frequencies

2. Calculate the genotype frequencies expected
under Hardy–Weinberg equilibrium (p2, 2pq, and
q2)
Testing the Hardy-Weinberg
Principle

3. Calculate the expected number of infants/offsprings of
each genotype under Hardy–Weinberg equilibrium.

4. Calculate chi square
Testing the Hardy-Weinberg
Principle
5. Determine whether the test statistic is significant
Will the Frequency of the
CCR5-∆32 Allele Change?
As long as individuals of all CCR5 genotypes survive and
reproduce at equal rates;
as long as no mutations convert some CCR5 alleles into
others,
as long as no one moves from one population to another,
as long as populations are infinitely large, and
as long as people choose their mates at random…..

then no, the frequency of the CCR5@∆32 allele will not
change
Incorporating
Selection in the
Hardy-Weinberg
Equation
Natural selection
Natural selection takes place when individuals with
adaptive traits produce a greater number of offspring
than that produced by others in the population.
If the adaptive traits have a genetic basis, they are
inherited by the offspring and appear with greater
frequency in the next generation.

Natural selection produces adaptations, such
as those seen in the polar bears that inhabit
the extreme Arctic environment.
Selection: Violation of the
Hardy–Weinberg equilibrium
principle
Selection happens when individuals with particular
phenotypes survive to sexual maturity at higher rates than
those with other phenotypes,
or when individuals
with particular
phenotypes produce
more offspring
during reproduction
than those with
other phenotypes
Adding Selection to the Hardy–Weinberg
Analysis: Changes in Allele Frequencies

Selection can cause allele frequencies to change across generations
Assume that the frequency of allele B1 in the gene pool is 0.6 and the frequency of
allele B2 is 0.4. After random mating, we get genotype frequencies for

We incorporate selection by stipulating that the genotypes differ in survival. All of
the B1B1 individuals survive, 75% of the B1B2 individuals survive, and 50% of the
B2B2 individuals survive
If we assume that each survivor donates 10 gametes to the new gene pool, then

Calculating the allele frequencies

The frequency of allele B2 has dropped by the
same amount.

Violation of the no-selection assumption has
resulted in violation of conclusion 1 of the Hardy–
Weinberg analysis. The population has evolved.
Research on Allele Frequency Change by
Selection: ADH locus: AdhF and AdhS
Fruit flies, like most other animals, make an enzyme that
breaks down ethanol, the poisonous active ingredient in beer,
wine, and rotting fruit. This enzyme is called alcohol
dehydrogenase, or ADH.
Cavener and Clegg
worked with
populations of flies
that had two alleles
at the ADH locus:
AdhF and AdhS.
Hardy–Weinberg conclusion 1 appears to hold
true in the control populations, but is clearly
not valid in the experimental populations. Frequencies of the allele in four
populations of fruit flies over 50
generations
Selection to the Hardy–Weinberg Analysis:
The Calculation of Genotype Frequencies

Selection can change genotype frequencies so that they cannot be calculated by
multiplying the allele frequencies
 assume that the initial frequency of each allele in the gene pool is 0.5. After
random mating, we get genotype frequencies for B1B1, B1B2, and B2B2 of 0.25,
0.5, and 0.25.

we incorporate selection this time, 60% of the B1B1 individuals survive, all of
the B1B2 individuals survive, and 60% of the B2B2 individuals survive
If we assume that each surviving adult donates 10 gametes to the next
generation’s gene pool, then:

Summing the gametes carrying each allele, we get 400 carrying B1 and 400
carrying B2, for a total of 800. Both alleles are still at a frequency of 0.5.

Let us calculate frequencies of the three genotypes
These genotype frequencies reveal that violation of the no-selection assumption
has resulted in violation of conclusion 2 of the Hardy–Weinberg analysis.
Research on Selection and Genotype
Frequencies: sVEGFR1 and Malaria
Research on Selection and Genotype
Frequencies: sVEGFR1 and Malaria
When a pregnant woman contracts the disease, the parasites invade
the placenta via the mother’s circulatory system
This triggers placental inflammation and may also interfere with
placental development.
The potential complications include spontaneous abortion,
premature delivery, low birth weight, and higher risk of infant death.
VEGFR
Research on Selection and Genotype
Frequencies: sVEGFR1 and Malaria
Fetal cells in the placenta release a soluble form of this
protein, sVEGFR1, into the mother’s circulation. By interacting
with vascular endothelial growth factor, VEGFR1 influences
both placental development and inflammation

VEGFR1 with alleles cluster into a short group (S alleles) and a
long group (L alleles).
Cultured cord blood cells with genotypes SS and SL produce
more VEGFR1 than do LL cells
Research on Selection and Genotype
Frequencies: sVEGFR1 and Malaria
The researchers first determined the allele frequencies among 163 infants born
from October through April, when the rate of placental malaria was at its
annual low. The frequencies were

The true frequency of heterozygotes is slightly higher than predicted, and the
frequencies of homozygotes are slightly lower, but the discrepancies are
modest. The infants thus conform to conclusion 2 of the Hardy–Weinberg
analysis.
Research on Selection and Genotype
Frequencies: sVEGFR1 and Malaria
Researchers then determined the allele frequencies among 76 infants born
from May through September, when the rate of placental malaria was at its
annual high. The frequencies were nearly the same as among the off- season
newborns:

There are substantially more heterozygotes than expected, and substantially
fewer homozygotes. The genotypes of the infants born during peak malaria
season are in violation of Hardy–Weinberg conclusion 2
The researchers surveyed Tanzanian infants born to first-time mothers during
malaria season. The genotype counts (provided by Atis Muehlenbachs and Patrick
Duffy, personal communication) were:

Calculate the allele frequencies

S

L
Calculate the genotype frequencies expected. frequencies of two alleles
are p and q, then the expected frequencies of the genotypes are p2, 2pq, and q2

Calculate the expected number of infants of each genotype under Hardy–
Weinberg equilibrium.
Calculate the statistics

The x2 test tells us that among
infants born during malaria
season, the alleles of the gene
for VEGFR1 are not in Hardy–
Weinberg equilibrium. This
indicates that one or more
assumptions of the Hardy–
Weinberg analysis has been
violated.
Fitness and Selection
Coefficient
Fitness is defined as the relative reproductive success of a genotype.
Fitness (W) ranges from 0 to 1.
Suppose the average number of viable offspring produced by three
genotypes is

To calculate fitness for each
genotype
Fitness and Selection
Coefficient
overdominance or heterozygote advantage.
Here, the heterozygote has higher fitness than
the fitnesses of the two homozygotes
(W11 < W12 > W22)
underdominance
underdominance, in which the heterozygote has
lower fitness than both homozygotes
(W11 > W12 < W22).
Underdominance leads to an unstable
equilibrium;
Allelic frequencies will not change as long as
they are at equilibrium but, if they are disturbed
from the equilibrium point by some other
evolutionary force, they will move away from
equilibrium until one allele eventually becomes
fixed.
Mutation
Recurrent mutation changes allelic frequencies

Mutation can influence
the rate at which one
genetic variant increases
at the expense of another.
Reaching Equilibrium of
Allelic Frequencies
 The mutation rates for most genes are low; so
change in allelic frequency due to mutation in
one generation is very small, and long periods of
time are required for a population to reach
mutational equilibrium.
Nevertheless, if mutation is the only force acting
on a population for long periods of time,
mutation rates will determine allelic frequencies.
Adding Mutation to the Hardy–Weinberg
Analysis: Mutation as an Evolutionary
Mechanism
 mutation (in the example) converts 1 of every
10,000 copies of allele A into a new copy of allele
a. The frequency of A after mutation is given by
the frequency before mutation minus the fraction
lost to mutation; the frequency of a after mutation
is given by the frequency before mutation plus the
fraction gained by mutation. That is,
 The new allele frequencies are almost identical to the
old allele frequencies. As a mechanism of evolution,
mutation has had almost no effect.
Almost no effect is not the same as exactly no effect.
Could mutation of A into a, occurring at the rate of
1 copy per 10,000 every generation for many
generations, eventually result in an appreciable change
in allele frequencies?

Over very long periods of time, mutation can
eventually produce appreciable changes in
allele frequency
Cystic Fibrosis
Cystic fibrosis is among the most common serious genetic diseases
among people of European ancestry, affecting approximately 1 newborn
in 2,500.
Cystic fibrosis is inherited as an autosomal recessive trait.
Affected individuals suffer chronic infections with the bacterium
Pseudomonas aeruginosa and ultimately sustain severe lung damage
Cystic Fibrosis
Although cystic fibrosis was lethal for most of human history,
in some populations as many as 4% of individuals are carriers.
How can alleles that cause a lethal genetic disease remain this
common?

heterozygote superiority

new disease alleles are
constantly introduced into
populations by mutation
Adding Mutation to the Hardy–Weinberg
Analysis: Mutation as an Evolutionary
Mechanism
Return to our model population of mice. Imagine a
locus with two alleles, A and a, with initial
frequencies of 0.9 and 0.1. A is the wild-type allele,
and a is a recessive loss-of-function mutation.
Furthermore, imagine that copies of A are converted
by mutation into new copies of a at the rate of 1
copy per 10,000 per generation
Mutation is a weak mechanism of evolution
Almost no effect is not the same as exactly no
effect
Are the Alleles That Cause Cystic Fibrosis Maintained
by a Balance between Mutation and Selection?
Are the Alleles That Cause Cystic Fibrosis Maintained
by a Balance between Mutation and Selection?
Are the Alleles That Cause Cystic Fibrosis Maintained
by a Balance between Mutation and Selection?
Are the Alleles That Cause Cystic Fibrosis Maintained
by a Balance between Mutation and Selection?
 In individuals with cystic fibrosis, P. aeruginosa cause chronic
lung infections that eventually lead to severe lung damage.

Selection against the alleles that cause cystic fibrosis appears
to be strong. Until recently, few affected individuals survived
to reproductive age; those that do survive are often infertile.
And yet the alleles that cause cystic fibrosis have a collective
frequency of approximately 0.02 among people of European
ancestry.

Could cystic fibrosis alleles be maintained at a frequency of
0.02 by mutation– selection balance?
Steady supply of new mutations cannot, by itself, explain the
maintenance of cystic fibrosis alleles at a frequency of 0.02.