Flies with a dominant mutation in a particular gene have an additional set of wings. Through mapping techniques, you identify a candidate gene, gene X, on an autosomal chromosome that you think results in extra wings when mutated. When you sequence gene X in the mutant fly with extra wings, you notice a missense mutation in the middle of the coding region of gene X. What is the best way to verify that the mutation in gene X is responsible for the dominant phenotype?

a. Starting with a wild-type fly, knockout gene X to generate a null allele and see if flies that are heterozygous or homozygous for the null allele have extra wings.

b. Starting with the mutant fly that is heterozygous for the dominant allele, insert a wild type copy of gene X (complete with its own promoter) elsewhere in the genome of the fly and see if it rescues the mutant and results in normal/wild-type wings.

c. Starting with a mutant fly that is heterozygous for the dominant allele, replace the dominant mutant allele with a wild type version of the gene via homologous recombination and see whether flies with the replacement have normal/wild type wings.

d. Starting with a homozygous wild-type fly, replace one copy of wild-type gene X with a version carrying the dominant mutation via homologous recombination, and see whether flies with the replacement have extra wings.

e. either C or D

You have a strain of flies that are homozygous for a deletion of 2 neighboring genes, A and B (genotype aabb). Wild type flies have transparent wings but these aabb flies have rainbow-colored wings. Which of the following experiments would provide you with more information about which of these genes (if either) is responsible for the rainbow-colored wings?

a. Starting with a wild-type fly, create a transgenic fly that is homozygous for deletion in both genes A and B and see if you get the rainbow-colored wings.

b. Delete gene A alone and gene B alone in 2 independent wild-type flies and see whether flies homozygous for either deletion have rainbow-colored wings.

c. Starting with a mutant fly with rainbow-colored wings, introduce both wildtype genes A and B into a new place in the genome of the fly and see if normal wing color is restored.

d. non of the above

Wild type Drosophila have grey bodies (B+), long wings (dp+),and non-hooked bristles (hk+). Recessive mutant alleles for two ofthese genes produce flies with dumpy wings (dp), and hookedbristles (hk). A dominant mutation in the body color gene createsflies that are black (B). An F1 female heterozygous for these threegenes is test-crossed and 1000 progeny are produced as follows:

wild type - 134

Black - 38

Black, hooked - 301

dumpy, hooked - 42

hooked - 20

hooked, dumpy, Black - 145

dumpy, Black - 16

dumpy - 304

A. What are the parental genotypes and phenotypes? (You mayassume that the parents are true breeding)

B. What is the genotype andphenotype of the tester fly?

C. Draw a map of the three genesthat indicates their positions and distances betweenthem

D. Draw the alleles in theirproper positions on the chromosome(s) of the triple heterozygote F1female.

Thank you very much.

Drosophila has four pairs of chromosomes: the sexchromosomes (XX in the females; XY in the males) and three pairs ofautosomes. You are studying a new mutant strain with blue eyes. Youwish to know if blue eye colour is a dominant mutation and on whichchromosome the blue eye locus can be found. When you crossa pure‐breeding female blue‐eyed fly with vestigial wings andspineless bristles to a male fly with wild type eye colour, wings,and bristles, all of the F1 progeny are completely wild type. An F1male is backcrossed to a triple mutant female, producing thefollowing progeny (remember that there is no crossing over inDrosophila males):

Wild type eyes, wings, andbristles: 72 females, 69 males

Wild type eyes and bristles,vestigial: 83 females, 77 males

Wild type wings, blue eyes,spineless: 60 females, 65 males

Blue eyes, spineless,vestigial: 62 females, 58males

Is the mutation dominant or recessive?Explain.

Since you know that the locus for vestigial wings is onchromosome 2 and the locus for spineless bristles is on chromosome3, what chromosome carries the locus for blue eyes? Showyour work, including the step‐by‐step reasoning you used to arriveat your answer.

When an F1 female is backcrossed to a triple mutant male, thefollowing 1,000 progeny are produced:

Wild type eyes, wings, andbristles: 90 females, 89 males

Wild type eyes and bristles,vestigial: 83 females, 98 males

Wild type eyes and wings, spineless:37 females, 35 males

Wild type wings and bristles, blueeyes: 36 females, 34 males

Wild type wings, blue eyes,spineless: 92 females, 88 males

Wild type eyes, spineless,vestigial: 34 females, 39 males

Wild type bristles, vestigial, blueeyes: 33 females, 37 males

Blue eyes, spineless,vestigial: 90 females, 85 males

Calculate the map distance betweenblue eye and any linked genes. Show your work

You identify mutations in a separate gene, gene R. Homozygous rr mutant females form a partial vulva because the mutant r allele produces only 15% as much R protein as the WT allele.

You decide to take advantage of this partial loss of function mutation to isolate mutations in other genes that affect vulva development.

Starting with the rr mutant, you screen for mutations that, in combination with rr, result in complete loss of vulva. You isolate a dominant, gain of function, mutation in a different gene (gene E) that in combination with rr result in a complete loss of vulva. You call the dominant allele E*.

Worms of genotype rr E*E do not form vulvas whereas rr single mutants form partial vulvas and E*E single mutants form normal vulvas.

Which of the following terms is the best description of E* in relation to rr?

a. E* is a suppressor mutation

b. E* is an epistatic mutation

c. E* is an enhancer mutation

d. E* is a resistant mutation

e. E* is a dominant mutation

f. both B and E

What does gene E's specific interaction with gene R suggest about what gene E normally does in wild-type worms?

a. Gene E's normal wild-type function is to inhibit vulva formation.

b. Gene E's normal wild-type function is to promote vulva formation.

c. Gene E can’t have any function in vulva formation because we didn’t look at complete loss of function alleles.

Starting with the rr mutant, you screen for mutations that, in combination with rr, result in normal vulvas. You isolate a dominant, gain of function, mutation in a different gene (gene S) that in combination with rr result in a completely normal vulva. You call the dominant allele S*.

Worms of genotype rr S*S form normal vulvas, whereas rr single mutants form partial vulvas and S*S single mutants form normal vulvas.

Which of the following terms is the best description of S* in relation to rr?

a. S* is a suppressor mutation

b. S* is an epistatic mutation

c. S* is an enhancer mutation

d. S* is a resistant mutation

e. S* is a dominant mutation

f. both A and B

What does gene S's specific interaction with gene R suggest about what gene S normally does in wild-type worms?

a. Gene S's normal wild-type function is to inhibit vulva formation.

b. Gene S's normal wild-type function is to promote vulva formation.

c. Gene S can’t have any function in vulva formation because we didn’t look at complete loss of function alleles