Consider two populations of guppies living in a tropical stream. One is upstream of a waterfall, and the other is downstream. In both populations, homozygous individuals have either blue or red stripes, depending on the allele they carry: R for the red allele and B for the blue. RB heterozygotes have purple stripes.

In the downstream population only, there are crayfish that feed on the guppies. Because the crayfish can't see red colors, the red-striped guppies have higher fitness than blue or purple. Comparison to the upstream population, where there are no crayfish, indicates that the selection coefficient on purple and blue guppies is 0.25.

The current frequency of the R allele is 0.64. Your job is to calculate the percent change in allele frequency that occurs in the next generation due to crayfish predation. To do this you should:

a) Use the Hardy-Weinberg principle to determine expected genotype frequencies in the generation without selection

b) Determine the relative fitness of each genotype

c) Calculate the genotype frequencies in the new population following selection.

d) Find the percent change in allele frequency of the resistant R allele.

Mutations can sometimes add genetic diversity to populations. Explain why new mutations in somatic (body) cells are NOT a source of genetic diversity in populations.

Why might a traight (like height in humans) show continuous variation?

Explain why most RARE recessive alles in populations are deleterious (disease-causing)?

Hair color in a new breed of goats is controlled by two alleles: A and a. Goats that have genotype AA or Aa have brown hair and goats that have genotype aa have red hair. (a) If goats that have brown hair have higher fitness than goats with red hair, what will happen to the frequency of the a allele in this population? (b) will the a allele disappear completely from the population if there is negative selection on it? Why or why not? (c) Is hair color in these goats considered a polyphenism? Why or why not?

PLEASEANSWER ALL QUESTIONS, SHOWING ALL FORMULAS, EQUATIONS AND STEPSUSED TO GET ANSWER. THANKS

1.A newspaper story on AIDS reports that an allele (R) conferscomplete resistance to HIV when homozygous and that 2% of the humanpopulation is resistant (RR). The story also states that 18% of thepopulation carries one copy of the resistamnce allele (i.e., isheterozygous). Is this a guess, an approximation, or an exactfrequency, assuming that the population is at Hardy-Weinbergequilibirum? Show calcualtions indicating the values of p and q andall work.

2.A new kind of tulip is produced that develops only purple orpink flowers. Assume that flower color is controlled by asingle-gene locus , and that the purple allele (C) is dominant tothe pink (c). A random sample of1000 tulips from a large cultivatedfeild yeilds 812 purple flowers and 188 pink flowers.

A) Determine the frequency of the purple and pink alleles in thisfield population.

B) Estimate the proportion of all purple flowering plants that areheterozygotes and homozygotes.SHOW ALL CALCULATIONS.

3. You are studying a single-gene locus with two alleles inapopulation that is in Hardy-Weinberg equilibrium. Examination of alarge sample of individuals from the population reveals there arefive times as many heterozygotes as there are homozygote recessiveindividuals in this population. What is the frequency of therecessive allele? SHOW ALL CALCULATIONS.

1. If an individual has a genotype of Bb, what types of gametes (sperm/egg) could they produce?
A) B
B) b
C) B or b
D) Bb, BB, bb
E) Bb

2. Which of the following statements is true about phenotypic plasticity, i.e., phenotype variation that is the result of genotype by environment interactions?
A. Phenotypic plasticity is only favored when the parental environment is a good predictor of the offspring environment
B. Since the trait expression of a genotype varies across environments, it cannot respond to selection
C. A variable environment is required for phenotypic plasticity to be selected for
D. A single trait can only ever be plastic or non-plastic within a species
E. Phenotypic plasticity can only occur within a single generation, never across generations

3. With large numbers of genes contributing to variation for a phenotypic trait (e.g. height in humans), the population approaches what kind of distribution for that trait?
A. Mendelian
B. Exponential
C. Binomial
D. Normal
E. Continuous

4. A classic example of phenotypic plasticity is caste determination in social insects. Whether a female ant becomes a worker, soldier, or queen is determined by the food she is fed. Would you say this this an example of G, E, or GxE?

5. In an infinite population, the frequency of the A allele is 0.3 and the frequency of the a allele is 0.7. What is the frequency of heterozygotes?
A. .10
B. .21
C. .30
D. .42
E. .70

6. Blue eyes are a recessive trait caused by an autosomal allele. If there are 180 people with blue eyes in a population of 500 people, what is the frequency of the brown-eye allele? (Assume HWE)
A. .36
B. .40
C. .50
D. .60
E. .64

7. Imagine flower color in diploid roses is determined by a single gene with two alleles, white and red, which are co-dominant so that heterozygotes are pink. Frank is colorblind and can only discriminate between white and colored roses, and knows that his population has 18 white roses and 182 non-white roses. How many of Frank’s roses are pink? (Assume HWE.)
A. 18
B. 21
C. 42
D. 84
​E. 100

8. Imagine flower color in diploid roses is determined by a single gene with two alleles, white and red, which are co-dominant. If Eva's population has 250 white roses, 500 pink roses, and 250 red roses, what is true about this population?

A. It is not in Hardy-Weinberg equilibrium
B. It is under balancing selection
C. It is connected to another population by migration
D. It is in Hardy-Weinberg equilibrium
​​E. White is a recessive lethal

9. 9% of a population is unable to taste the compound PTC, which is a recessive trait. Assuming HWE, if two carriers of the non-tasting allele had a baby what is the probability that it would be unable to taste PTC?
A. 0.09
B. 0.25
C. 0.30
D. 0.50
E. 0.70

10. (Adapted from: Christensen, A. C. (2000). Cats as an aid to teaching genetics. Genetics, 155(3), 999-1004.) ss cats have no white fur, Ss cats generally have <50% white fur, and SS cats generally have >50% white fur (cats who are 100% white are scored as dominant white and can't be scored for piebald spotting). The S allele is incompletely dominant, but variably expressed, so there is a more-or-less continuous gradient of white pigmentation in populations. You and your friends score all non-white cats up for adoption: http://www.adoptapet.com/cat-adoption/search/50/miles/48824 and find there are 160 with >50% white fur, 350 with <50% white fur, and 490 with no white fur. Which of the following statements is definitely true:

A. The population is in Hardy-Weinberg equilibrium
B. The population is not in Hardy-Weinberg equilibrium
C. There is selection acting on the population
D. It is impossible to know if the population is in Hardy-Weinberg equilibrium
E. Fur color is not a heritable trait and therefore cannot evolve