1.In a randomly-interbreeding population, p = 0.55 and q = 0.45. What will the genotype frequencies...

Consider a racoon population that exhibits variation at the G locus, which has two possible alleles:...

Consider a racoon population that exhibits variation at the G locus, which has two possible alleles: G1 and G2. The population starts out at Hardy Weinberg Equilibrium and the frequency of the G1 allele in the original population is 0.3. The relative fitness of each genotype during this generation is listed below. Use information to answer the following questions. w11 = 0.8 w12 = 1.0 w22 = 0.5 Calculate the average fitness for the population. Calculate the genotype frequencies in...

Question 2 The allele frequencies for a population are A = 0.6 and a = 0.4....

Question 2 The allele frequencies for a population are A = 0.6 and a = 0.4. Conditions change and fitness values are now AA = 0.3, Aa = 0.7 and aa = 1.0. What is the allele frequency of A in the next generation? A. between 0.6 and 0.7 B. between 0.5 and 0.6 C. between 0.4 and 0.5 D. 0.6 E. between 0.3 and 0.4 Question 7 A gene exists in two alleles designated P and p. If 65...

1a) Genotype frequencies in two populations are as follows: Population 1: AA = 0.1764, AB =...

1a) Genotype frequencies in two populations are as follows: Population 1: AA = 0.1764, AB = 0.4872, BB = 0.3364 Population 2: AA= 0.3969, AB = 0.4662, BB = 0.1369 What are the frequencies of alleles A and B in each population? b) A population geneticist genotyped 200 individuals in a population of smallmouth bass (the smallmouth bass is a popular Ontario sportfish), and the following numbers of genotypes were revealed: AA = 50, BB = 18, CC = 8,...

On a separate sheet of paper, plug in the following values for p and q into...

On a separate sheet of paper, plug in the following values for p and q into the Hardy-Weinberg equation (p2+2pq+q2=1): p=0.5, q=0.5 p=0.6, q=0.4 p=0.7, q=0.3 p=0.8, q=0.2 p=0.9, q=0.2 p=1.0, q=0.0 You have just modeled genetic drift acting on a population. After you have plugged these values in, what trend do you see with regards to the frequencies of the homozygous q (q2) and heterozygous (2pq) genotypes? What does this tell you about genetic drift?

In a population of 10,000 beavers, three genotypes, A1A1, A1A2, and A2A2, have different probabilities of...

In a population of 10,000 beavers, three genotypes, A1A1, A1A2, and A2A2, have different probabilities of survival to reproductive age lA1A1 = 0.5; lA1A2 = 0.8; and lA2A2 = 1.0. At time (t) the frequency of the homozygous recessive individuals = 0.25. Natural selection resulting from differences in survival to reproductive age is the only form of evolution occurring in this population—assume 2m = 5 for all genotypes What is the absolute fitness (W) of each genotype? Use equation 9...

p+q =1 All of the allele frequencies p2 + 2pq + q2 =1 All of the...

p+q =1 All of the allele frequencies p2 + 2pq + q2 =1 All of the genotype frequencies together equals 1 p2 and q2 Frequencies for each homozygotes 2pq Frequencies for Heterozygotes. p2 + 2pq= + q2 Homozygous Dominant Heterozygous Homozygous recessive If the frequencies of the color in Homozygous recessive frequencies pea plants are 30% in the population what are the genotype and phenotype frequencies in the populations. A homozygous recessive plant would be (pp) and a Homozygous dominant...

1. If the frequencies of three alleles at a locus in a population are A1= 0.5,...

1. If the frequencies of three alleles at a locus in a population are A1= 0.5, A2= 0.45, and A3= 0.05 what is the expected frequency of the A2A3 genotype? Show work that supports your answer. a. 0.0225 b. 0.05 c. 0.075. d. 0.045 e=0.5 2a. If a new mutant allele were to arise in a single individual heterozygous for the mutation within a population of a diploid species (Ne=300 individuals in the population) the probability that the new mutant...

1. if P(A)=0.4P(A)=0.4, P(B)=0.55P(B)=0.55 and P(A∩B)=0.15P(A∩B)=0.15, calculate 1. P(Ac)P(Ac) : 0.6 0.8 0.55 0.45 2. P(A∩B)cP(A∩B)c...

1. if P(A)=0.4P(A)=0.4, P(B)=0.55P(B)=0.55 and P(A∩B)=0.15P(A∩B)=0.15, calculate 1. P(Ac)P(Ac) : 0.6 0.8 0.55 0.45 2. P(A∩B)cP(A∩B)c 0.95 0.85 0.75 0.45 3. P(B/A)P(B/A) 0.57 0.38 0.75 0.45 4. P(A∪B)P(A∪B) 0.9 0.5 0.8 0.7 5. P(Ac∪B)P(Ac∪B) 0.95 0.55 0.85 0.75 2.The regression model Y = 1.78 + 0.56X has been estimated. Where (Y) is the level of consumption and (X) the income of the inhabitants of a city. 1. What consumption is predicted for someone who earns $ 37,000? 22.5 16.9 28.4...

6. A researcher performs an experiment on fruit flies to monitor the change in allele frequency...

6. A researcher performs an experiment on fruit flies to monitor the change in allele frequency of an allele called “A.” She starts with 24 populations, each with an initial starting frequency for A of 0.5. Flies are maintained for 10 generations by transferring the offspring from each generation to a new vial, where they produce the next generation. For half of the populations she randomly selects 20 flies to transfer (treatment 1), while for the other half she randomly...

A hypothetical population ofcats has two alleles, TL and TS, for a gene that codes for...

A hypothetical population ofcats has two alleles, TL and TS, for a gene that codes for tail length. The allele frequency of TL is 0.7 and the allele frequency of TS is 0.3. TLTL individuals have long tails. TLTS individuals have medium tails. TSTS individuals have short tails. The equation for Hardy-Weinberg equilibrium states that at a locus with two alleles, as in this cat population, the three genotypes will occur in specific proportions, described by the equation p2 +...