Title: RAPDs and AFLPs
1RAPDs and AFLPs
- Good for distinguishing between populations
- Often used for trait mapping studies because they
are variable between the populations that are
crossed
2VNTR variable number tandem repeats
- Non-coding regions
- Several to many copies of the same sequence
- Large amount of variation among individuals in
the number of copies
3Microsatellites
- Not a tiny orbiting space craft
- Most useful VNTRs
- 2, 3, or 4 base-pair repeats
- A few to 100 tandem copies
- Highly variable
- Many different microsatellite loci (1000s) in any
species
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5Microsatellites
- Design primers to flanking regions
6Microsatellite Gels
7Microsatellites
- Advantages highly variable, fast evolving,
co-domininant - Relatively expensive and time consuming to develop
8Microsatellites
- Used for within-population studies not as much
for between-population studies b/c they evolve
too fast - Paternity analysis and other studies of kinship
9Microsatellites
- Questions
- Is the locus represented by the bands at the
arrow polymorphic? - If it is polymorphic, how many individuals are
heterozygous? - How many individuals are homozygous for the
short allele?
10Sequencing
11Sequencing
- Often used for phylogenetics (especially
sequences of mitochondrial genes). - Also used for studies of molecular evolution
(e.g., compare rates of synonymous vs.
non-synonymous substitution)
12Quantifying variation (single locus)
- Allele frequency (gene frequency)
- Genotype frequency
13Example using allozyme (protein) data
14 Protein (allozyme) data
- PGM locus, Daphnia obtusa,
- Ojibway Pond (Spitze 1993)
- Genotypes Number
- MM 57
- MS 53
- SS 18
- Q Calculate genotype and allele frequencies
15 Genotype Number MM 57
MS 53 SS 18 128
- Genotype freqs
- MM
- MS
- SS
- Allele freqs
- Freq of M
- Freq of S
16Allele frequency
- If there are two alleles at a specific locus, we
usually designate the frequency of one allele p
and the frequency of the other as q. - When there are only two alleles q1-p.
- If there is a third allele, its frequency is
usually designated as r.
17Microsatellite Data Ridleys sea turtle
- How many alleles?
- Which individuals are homozygous for a short
allele which for a long allele? - Genotype and allele frequencies?
18Where does genetic variation come from?
19What is the ultimate source of all genetic
variation?
20Given that that variation arises, what happens to
it over time?
21- A population of light brown deer mice is
monomorphic for genotype bb at a locus
controlling coat color. A mutation occurs and a
single deer mouse is born with dominant melanic
mutation genotype Bb. Lets start a new
population with the black female mouse and a
single light brown male. What will happen to the
new B allele in this population if mice of all
colors have equal fitness (e.g., there is no
selection on color)? Assume no genetic drift. - What is the initial allele frequency of the B
allele in the new population (one Bb mouse
and one bb mouse)? - What are the genotype frequencies?
- What will be the genotype frequencies in the F1
offspring of these parents? - What will be the allele frequencies in the F1
offspring of these parents?
22Allele frequency in F2?
- Random mating in a population in which
- p freq of b allele 0.75 and
- q freq of B allele 0.25
- Expected freq of bb homozygotes?
- Expected freq of BB homozygotes?
- Expected freq of Bb heterozygotes?
23p2 bb 2pq Bb q2 BB
24Will the allele frequencies change after another
generation of random mating?Will the genotype
frequencies change?
25Hardy-Weinberg Principle
- Allele frequencies remain constant from
generation to generation unless some outside
force is acting to change them - After the first generation of random mating,
genotype frequencies also remain constant
26Assumptions of H-W
- Mating (union of gametes) is random across the
entire populationno segregation distortion and
no subpopulations that differ in allele
frequencies - All genotypes have equal viability and fertility
(no selection) - Migration into the population can be ignored
- Mutation does not occur, or is so rare it can be
ignored - Population is large enough that the allele
frequencies do not change from generation to
generation due to chance (random genetic drift). - Allele frequencies are the same in females and
males.
27Usefulness of H-W
- If you know the allele frequencies, you can
predict the genotype frequencies
One implication homozygotes for a rare allele
will be ____________.
28Usefulness of H-W
- If you know the frequency of one of the
homozygous genotypes, you can estimate allele
frequencies, and predict the frequencies of the
other genotypes
29Northern Leopard Frog
Rana pipiens-normal phase burnsi
phase (wild type) Burnsi allele dominant to
normal. In a sample of 2000 frogs 200 were
burnsi, and 1800 were normal. What are the
allele frequencies and expected genotype
frequencies?
30R. pipiens Data
31Why do we care?
- What if you can actually genotype the individuals
at a locus that controls the color pattern?
32R. pipiens Data, p0.95, q0.05
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34Why do we care?
- If we can conclude that the observed genotype
frequencies are really different from expected,
what can we infer?
35Review use of HW w/ sex linked genes
36Multiple Alleles ABO blood types
- p freq of A allele
- q freq of B allele
- r freq of O allele
- Expansion of p q r2
- p2 q2 r2 2pq 2pr 2qr
-
37Calculate allele frequencies and expected
genotype frequencies from the following observed
genotype frequencies
- AA Aa Aa aa aa aa
- 8 38 121 27 252 401
Is the population in H-W equilibrium? Do this
before next class period.
38Summary measures of variation
- Single loci
- Heterozygosity Obs Het/Tot Ind
- Expected Heterozygosity 1-?pi2
- Multiple loci
- Polymorphism proportion loci that are
polymorphic in a sample
39Grad students
- Read section of lecture notes on
- Measures of variation for DNA sequence data