Biology 1001A Lecture Notes - Lecture 12: Disruptive Selection, Directional Selection, Genetic Variation

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

Q49. Which of the following is NOT true?

If a genetic disease reduces fertility and the allele thatcauses the disease offers no other advantage, the allele willlikely eventually disappear, due to natural selection.

Natural selection does not favor individuals who are homozygousfor the sickle-cell allele, because these individuals typically diebefore they are old enough to reproduce.

Individuals who are heterozygous HbA/HbS areprotected from malaria, and this is why sickle-cell diseasepersists in wetter, mosquito-prone regions in Africa.

In regions where malaria does not occur, individuals who areheterozygous HbA/HbS have a fitness advantageover those who are homozygous for the normal hemoglobin allele(HbA).

Q50. AFTER malaria is cured, the frequency of the HbSallele should decrease in regions with lots of mosquitoesbecause:

People will no longer die from sickle-cell disease in theseregions.

Having one copy of the HbS allele will no longer beadvantageous in these regions.

Natural selection will no longer act on the HbS alleleat all in these regions.

All alleles associated with genetic diseases eventuallydisappear.

Q52. If the frequency ofthe HbS allele is 0.4 in a population, what is thefrequency of the HbAallele (assuming this is atwo-allele system)?

Q53. Which of the following would be sufficient for theHardy-Weinberg equation to accurately predict genotype frequenciesfrom allele frequencies?

p + q = 1

The population is not evolving due to natural selection.

The population is not evolving due to any of the conditions thatdisrupt Hardy-Weinberg equilibrium.

The population is infinitely large.

Q54. In a village, if the proportion of individuals who havesickle-cell disease is 0.25, and the population is assumed to be atHardy-Weinberg equilibrium, what is the expected frequency of theHbS allele? (Hint: What is the genotype of people withsickle-cell disease, and how is that genotype represented in theHardy-Weinberg equation?)

0.1250.250.50.75

Q55. In the same village, what proportion of the populationshould be heterozygous HbA/HbS, according to theHardy-Weinberg equation?

Use the following passage to answer the nextthree questions.

It has been hypothesized that people who are heterozygous forthe allele that causes the deadly genetic condition cystic fibrosis(which, among other symptoms, reduces fertility) are more resistantto the deadly disease tuberculosis.

Q56. If the cystic fibrosis allele protects against tuberculosisthe same way the sickle-cell allele protects against malaria, thenwhich of the following should be true of a comparison betweenregions with and without tuberculosis?

Cystic fibrosis deaths should be more common in regions withtuberculosis.

Cystic fibrosis deaths should be less common in regions withtuberculosis.

Cystic fibrosis deaths should be equally common in both types ofregions.

Regional differences in the cystic fibrosis death rate should bepurely random and unpredictable.

Q57. A person who is heterozygous for the cystic fibrosis allelemoves to a small, isolated community where no one previouslycarried the allele. If the cystic fibrosis allele protects againsttuberculosis the same way the sickle-cell allele protects againstmalaria, what should happen to the frequency of the cystic fibrosisallele in the community over time, and why?

The cystic fibrosis allele should disappear from the population,because a single individual with the allele is not enough for it toproliferate.

The cystic fibrosis allele should increase to a relatively highfrequency, because heterozygotes with the allele will be morelikely to survive than others.

The cystic fibrosis allele should become fixed in thepopulation, due to genetic drift.

The cystic fibrosis allele should either disappear or increasein frequency, depending on chance as well as on tuberculosisprevalence and death rate.

Use the following additional passage to answer the nextquestion.

Suppose you travel to the future, to a time when neithercystic fibrosis nor tuberculosis have caused any deaths for manygenerations. In all of these future populations, thecystic fibrosis allele still exists at a low frequency.

Q58. You visit a huge city with millions of people. If you wereto start sampling the cystic fibrosis allele from one generation tothe next, what should happen to its frequency over the next fewgenerations, and why?

The allele frequency should change a lot from one generation tothe next due to random genetic drift.

The allele frequency should not change much from one generationto the next because the population is large.

The allele frequency should steadily increase due to naturalselection.

The allele frequency should steadily decrease due to naturalselection.