1. Population Genetics
Chapter 23

2. What is evolution?
Evolution is about changes in populations, species, or groups of species (NOT changes in individuals!!)
On the genetic level, it is about a change in allele frequencies over time
To study evolution, we study changes in POPULATION GENETICS to understand changes that occur within a species

3. Population Genetics
To study evolution, we study changes in POPULATION GENETICS… the study of how populations change genetically over time

4. What is a population?
All the individuals of a species that live in an area (localized) sharing the same resources.

5. What’s a species?
Individuals that can breed with one another and produce fertile offspring

6. Gene Pool
The collection of all alleles at all gene loci in all individuals of a population
Variety exists among organisms and among species

7. Why does this variety persist??
Godfrey Hardy, a mathematician.
Wilhelm Weinberg, MD

8. By Jove,
I think I’ve got it!
Ach du lieber!
Ich denke,
dass ich es habe!
Independently, the two men devised what would come to be called the Hardy-Weinberg Theorem

9. H-W Theorem
Frequencies of alleles and genotypes in a population’s gene pool do not change over the generations unless acted upon by agents other than Mendelian segregation and recombination of alleles
In short, this means that the population has achieved genetic equilibrium and no evolution is occurring

10. H-W Equilibrium
Allele frequencies and genotypes in a population’s gene pool stay the same generation to generation

11. Conditions that must be true for H-W equilibrium to apply
H-W describes a hypothetical population in which all of the following conditions are met:
Extremely large population size

12. 2) No Gene Flow
The population is isolated from other populations and there is no transfer of alleles b/w populations

13. 3) No mutations
4) Random mating
5) No natural selection – all traits are selectively neutral

14. Is this really possible?? Why is this useful??
Even though natural populations are rarely, if ever, in H-W equilibrium, it allows us to estimate allele and genotype frequencies in populations where the rate of evolutionary change is so slow that populations appear to be close to equilibrium

15. Hardy-Weinberg Equation
p2 + 2pq + q2 = 1
Where:
p2 represents homozygous dominant individuals (AA)
2pq represents individuals heterozygous for alleles A and a, so Aa
q2 represents homozygous recessive for alleles a, so aa.

16. A few things you need to know about the H-W equation
Allele frequencies are p and q
Genotype frequencies are p2, q2, and 2pq
And the following must always be true: p + q = 1

17. Now, let’s work on some examples….

18. 5 Agents of evolutionary change
Mutation
Gene Flow
Non-random mating
Genetic Drift
Selection

19. Forces of evolutionary change
Natural selection
traits that improve survival or reproduction will accumulate in the population
adaptive change
Genetic drift
frequency of traits can change in a population due to chance events
random change

20. Selection Directional: favors one of the extremes
There are 3 ways natural selection can change the frequency distribution of heritable traits:
Directional: favors one of the extremes
Stabilizing: removes extremes and favors intermediates
Disruptive: favors variants at both ends, selecting against intermediates

21. Predation Selection Predation selection act on both predator & prey
behaviors
camouflage & mimicry
speed
defenses (physical & chemical)

22. Physiological Selection
Acting on body functions
disease resistance
physiology efficiency (using oxygen, food, water)
biochemical versatility
protection from injury
HOT STUFF! Some fish had the variation of producing anti-freeze protein
5.5 mya The Antarctic Ocean freezes over

23. Sexual Selection Natural selection for mating success
Example: females choose males based on appearance or behavior.
Only beneficial if the chosen mate actually enables the production of a more fit offspring

24. Genetic Drift
A random increase or decrease in allele frequencies from 1 generation to the next
Has a greater effect if the population is very small.

25. Genetic Drift, examples
Bottleneck: the population experiences a huge decrease in size (due to disaster, etc.)
Result: severe reduction in diversity of the original gene pool.
Endangered species can experience this.

26. Genetic Drift, example
Founder effect: a new population is started by only a few individuals
some rare alleles may be at high frequency; others may be missing
skews the gene pool of new population

27. Distribution of blood types
Distribution of the O type blood allele in native populations of the world reflects original settlement
South & Central American Indians were nearly 100% type O for the ABO blood system. Since nothing in nature seems to strongly select for or against this trait, it is likely that most of these people are descendants of a small band of closely related "founders" who also shared this blood type

28. Distribution of blood types
Distribution of the B type blood allele in native populations of the world reflects original migration
The global frequency patterns of the type B blood allele: Note that it is highest in central Asia and lowest in the Americas and Australia. However, there are relatively high frequency pockets in Africa as well. Overall in the world, B is the rarest ABO blood allele.

29. Gene Flow
Introduction or removal of alleles from a population that occurs when individuals enter (immigrate) or leave (emigrate) that population.
Example: seed & pollen distribution by wind & insect bb BB BB BB BB BB

30. Mutations
Mutations (in DNA) introduce new alleles that can be selectively advantageous, but most are harmful.
Polydactyly, or extra digits.

31. Balanced Polymorphisms
Polymorphism: multiple physical forms of one trait
Heterozygote advantage: heterozygotes more likely to survive than homozygotes
Sickle-cell anemia and malaria resistance

32. What is Darwinian fitness?
An individual’s ability to contribute to the gene pool of the next generation in relation to others