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Genetic diversity and evolution

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Title: Genetic diversity and evolution


1
Genetic diversity and evolution
2
Content
  • Summary of previous class
  • H.W equilibrium
  • Effect of selection
  • Genetic Variance
  • Drift, mutations and migration

3
Hardy-Weinberg assumptions
  • If all assumptions were met, the population would
    not evolve
  • Real populations do in general not meet all the
    assumptions
  • Mutations may change allele frequencies or create
    new alleles
  • Selection may favour particular alleles or
    genotypes
  • Mating not random -gt Changes in genotype
    frequencies
  • Population not infinite -gt random changes in
    allele frequencies Genetic drift
  • Immigrants may import alleles with different
    frequencies (or new alleles)

4
Fitness
  • The average fitness is
  • W(1-r)p22pq(1-s)q21-rp2-sq2
  • DP((1-r)p2pq/W)-ppqs-(rs)p/W

5
Hetrozygote Advantage
  • Pn1-(s/(rs))(1-r)pn2pnq/W -(s/(rs))
  • (1-r)pn2pnq-(s/(rs))W/W
  • (1-r)pn2pnq-(s/(rs)) (1-rpn2-sqn2)/W
  • (1-rpn-sqn)/Wpn-(s/(rs)
  • The difference decreases to zero only for
    positive r and s. Thus the scenario in which both
    alleles can survive is Hetrozygote Advantage

6
Recessive diseases
  • If rgt0, and s0, the disadvantage appears only
    homozygotic A1.
  • In this case pn1pn(1-rpn)/(1-rpn2)
  • 1/pn1-1/pn1/pn(1-rpn2)/(1-rpn)-1
  • r(1-pn2)/(1-rpn)
  • 1/pn-1/p0nr

7
Fitness Summary
  • Third fix point is in the range 0,1 only if r
    and s have the same sign.
  • It is stable only of both r and s are positive
  • In all other cases one allele is extinct.
  • If rgt0 and s0 then the steady state is still
    p0, but is is obtained with a rate
    pn1/(nr1/p0)

8
New Concepts
  • Genetic Variation
  • Genetic drift
  • Founder effects
  • Bottleneck effect
  • Mutations
  • Selection
  • Non Random Mating
  • Migration

9
Genetic Variation
  • Three fundamental levels and each is a genetic
    resource of potential importance to conservation
  • Genetic variation within individuals
    (heterozygosity)
  • Genetic differences among individuals within a
    population
  • Genetic differences among populations
  • Species rarely exist as panmictic population
    single, randomly interbreeding population
  • Typically, genetic differences exist among
    populationsthis geographic genetic
    differencesCrucial component of overall genetic
    diversity

10
heterozygosity
  • Several measures of heterozygosity exist. The
    value of these measures will range from zero (no
    heterozygosity) to nearly 1.0 (for a system with
    a large number of equally frequent alleles).  We
    will focus primarily on expected heterozygosity
    (HE, or gene diversity, D). The simplest way to
    calculate it for a single locus is as
  •                                                  
                                                      
        
  • Eqn 4.1where pi is the frequency of the ith of k
    alleles. Note that p1, p2, p3 etc. may
    correspond to what you would normally think of as
    p, q, r, s etc.. If we want the gene diversity
    over several loci we need double summation and
    subscripting as follows

11
Heterozygosity
  • In H.W heterozygosity is given by 2pq. The rest
    of the expression (p2 q2) is the homozygosity.
  • What does heterozygosity tell us and what
    patterns emerge as we go to multi-allelic
    systems? Lets take an example. Say p q 0.5.
    The heterozgosity for a two-allele system is
    described by a concave down parabola that starts
    at zero (when p 0) goes to a maximum at p 0.5
    and goes back to zero when p 1. In fact for any
    multi-allelic system, heterozygosity is greatest
    when
  • p1 p2 p3 .pk                               
                                         
  • The maximum heterozygosity for a 10-allele system
    comes when each allele has a frequency of 0.1 --
    D or HE then equals 0.9.  Later, we will see that
    the simplest way to view FST (a measure of the
    differentiation of subpopulations) will be as a
    function of the difference between the Observed
    heterozygosity, Ho, and the Expected
    heterozygosity, HE, 

12
Genetic Variation
  • HT HP DPT
  • where HT total genetic variation
    (heterozygosity) in the species
  • HP average diversity within populations
    (average heterozygosity)
  • DPT average divergence among populations across
    total species range
  • Divergence arise among populations from random
    processes (founder effects, genetic drift,
    bottlenecks, mutations) and from local selection).

13
Genetic differentiation
  • Inbreeding coefficients can be used to measure
    genetic diversity at different hierachical levels

Individual
Subpopulation
Total population
14
Wrights F statistics
  • Used to measure genetic differentiation
  • Sometimes called fixation index
  • Defines reduction in heterozygosity at any one
    level of population hierachy relative to any
    other
  • levels Individual - Subpopulation - Total

15
Wrights F statistics
  • Heterozygosity based on allele frequencies, H
    2pq.
  • HI, HS, HT refer to the average heterozygosity
    within individuals, subpopulations and the total
    population, respectively

16
Wrights F statistics
  • Drop in heterozygosity defined as

17
Example
  • 2 subpopulations, gene frequencies p1 0.8, p2
    0.3.
  • Gene frequency in total population midway between
    them pt 0.55
  • HS1 2p1q1 2 x 0.8 x (1-0.8) 0.32
  • HS2 2p2q2 2 x 0.3 x (1-0.3) 0.42
  • HS average(HS1, HS2) (0.32 0.42)/2 0.37
  • HT 2 x 0.55 x (1 - 0.55) 0.495

18
Identity by descent
  • Imagine self-fertilising plant
  • A - A 1,2 - 1,2 X
    ?
  • 1/4 of offspring will be of genotype 1,1
  • 1/2 of offspring will be of genotype 1,2
  • 1/4 of offspring will be of genotype 2,2
  • FX (inbreeding coefficient) is probability of IBD
    1/2
  • equivalently, let fAA be the probability of 2
    gametes taken at random from A being IBD.

19
Mutation occurred once
  • Every mutation creates a new allele
  • Identity in state identity by descent (IBD)

20
The same mutation arises independently
21
Identity by descent
  • A - B C - D P - Q
    X
  • Let fAC be the coancestry of A with C etc., i.e.
    the probability of 2 gametes taken at random, 1
    from A and one from B, being IBD.
  • Probability of taking two gametes, 1 from P and
    one from Q, as IBD, FX

22
Identity by descent
  • Example, imagine a full-sib matingA - B /
    \P - Q X
  • Indv. X has 2 alleles, what is the probability of
    IBD?

23
Identity by descent
  • Example, imagine a half-sib matingA - B - C
    P - Q X

24
Mutations
m0.0001
A mutates to a at the rate m a reverts back to A
at the rate v The equilibrium value for the
frequency of A is given by
25
SNP
  • Single Nucleotide Polymorphism (SNP) naturally
    occuring variants that affect a single nucleotide
       -predominant form of segregating variation at
    the molecular level
  • SNPs are classified according to the nature of
    the nucleotide that is affected       
    -Noncoding SNP
  • 5' or 3' nontranscribed region (NTR)
  • 5' or 3' untranslated region (UTR)
  • introns
  • intergenic spacers
  • Coding SNPs
  • replacement polymorphisms
  • synonymous polymorphisms
  •        Transitions          A to G  OR C to T
  •        Transversions A/G to C/T OR C/T to A/G

26
Natural Selection
  • Tuberculosis (TB) infections have historically
    swept across susceptible populations killing
    many.
  • TB epidemic among Plains Indians of QuAppelle
    Valley Reservation
  • annual deaths
  • 1880s 10
  • 1921 7
  • 1950 0.2

27
Nonrandom mating
  • Random mating occurs when individuals of one
    genotype mate randomly with individuals of all
    other genotypes.
  • Nonrandom mating indicates individuals of one
    genotype reproduce more often with each other
  • Ethnic or religious preferences
  • Isolate communities
  • Worldwide, 1/3 of all marriages are between
    people born within 10 miles of each other
  • Cultures in which consanguinity is more prominent
  • Consanguinity is marriage between relatives
  • e.g. second or third cousins
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