name:______

student ID:______

Genetics L311 exam 1

February 5, 2016

Directions: Please read each question carefully. Answer questions as concisely as possible. Excessively long answers, particularly if they include any inaccuracies, may result in deduction of points. You may use the back of the pages as work sheets, but please write your answer in the space allotted and please show all your work. Clearly define your genetic symbols. We will not make guesses as to what a particular symbol is intended to mean. Also, don’t assume that strains are true-breeding unless this is stated in the question. Finally, show all your work. Good luck.

page 2______(20 points possible)

page 3______(24points possible)

page 4______(14points possible)

page 5______(22points possible)

page 6______(20 points possible)

total______(of 100 points possible)

1. Short answers (2 points each, 20 points total)

A. is when both alleles in a heterozygote are expressed.

B.A cross of an individual of unknown genotype by homozygous recessive is called a(n).

C. The failure of proper chromosome segregation, called , can lead to offspring with abnormal chromosome complements.

D. The serves to hold sister chromatids together and provides the point of attachment for the spindle during cell division.

E. The pairing of homologous chromosomes during meiosis is called .

F. The physical manifestations of crossing over are called the .

G. The genetic makeup of an individual is referred to as its .

For the following, please provide a brief definition of the term given:

H. heterozygous:

I. alleles:

J. pleiotropy:

2. Wiskott-Aldrich syndrome (WAS) is a very rare disorder affecting about 1/500,000, characterized by eczema, low platelet count in the blood and immune deficiency. The pedigree below shows a family in which WAS is segregating.

A. What mode of inheritance does WAS show (3 points)?

B. Obligate carriers are individuals who must carry the mutation that produces the trait but who are not affected (i.e. do not have the disease). Please list the obligate carriers in the pedigree at right (3 points).

C. What is the probability that III-3and III-4’s next child will be affected (will have the disease, 3 points)?

D.Please provide the genotypes of the following individuals (3 points):

I-1

II-3

IV-4

3. A new species of fruit fly, J. gavadeae, is found to have two true breeding strains. Strain A has a bluethorax and short wings, while strain B has a black thorax and long wings. A cross of strain A males with strain B females results in offspring that all have black thoraxes and long wings. Crossing the F1 animals results in the following:

752 black thorax, long winged females

373 black thorax, long winged males

377 blue thorax, long winged males

249 black thorax, short winged females

123 black thorax, short winged males

127blue thorax, short winged males

A. Fill in the genotypes of the F2 progeny (6 points).

B. What do you expect from a cross of black thorax, long winged female F1 X blue thorax, short winged F2 males? Please provide the genotypes, phenotypes and relative frequencies (6 points).

4.During an expedition to Madagascar, you find a new species of singing sea robin that you name A. millerae. A. millerae is diploid with 3 pairs of chromosomes - one long, one medium and one short. Usually singing sea robin offspring are produced from the fusion of two haploid gametes, which are formed via normal meiosis. Furthermore, you find that your favorite A. millerae specimen, named Sarah, is heterozygous for three genes, A, B and C, where A is on the long chromosome, B is on the medium chromosome and C is on the short chromosome.

A. Draw one of Sarah's somatic cells in prophase of mitosis including chromosomes and genes (4 points).

B. Show one of Sarah's cells in anaphase I of meiosis. Circle one pair of homologues. Draw a box around one pair of sister chromatids. You need not include genes (4 points).

C. Occasionally in A. millerae, unfertilized egg cells can develop into viable offspring. The offspring of this process, called parthenogenesis, are diploid. Diagram the four steps of meiosis II in the atypical meiosis that could create these offspring. Assume that meiosis I was normal. Please label each step. You need not include genes (6 points).

5.In your studies of the unusual flying fish species A. farlowae you find two true breeding strains. Strain 1 has light blue skin and light blue fins. The second strain has lavender-hued skin with lavender-hued fins. A cross of strain 1 females with strain 2 males produces F1 that all have dark blue skin and dark blue fins. Crossing F1s produces:

183 light blue skin and light blue fins

187 lavender-hued skin and lavender-hued fins

371 dark blue skin and dark blue fins

A. Please give the genotypes of the F2s on the lines above (6 points).

B. From a cross of light blue skinned, light blue finned X dark blue skinned, dark blue finned animals, what is the probability of obtaining animals with dark blue skin and dark blue fins (4 points)?

6.You find two populations of mice inhabiting a local park. Some mice have red fur and big ears. Others have orange fur and small ears. You cross a true-breeding red-furred big-eared male mouse with an orange furred small-eared female. You find that the F1s are all orange with big ears. You then cross the F1s and see the following phenotypes in the offspring:

243 males are orange with big ears

245 females are orange with big ears

79 males are red with big ears

81 females are red with big ears

82 males are orange with small ears

78 females are orange with small ears

26 males are red with small ears

27 females are red with small ears

A. Please fill in the genotypes of the F2 mice on the lines above (8 points).

B. What is the probability of obtaining a red, small-eared mouse from a cross of red, big-eared F2 male mice with red, small-eared F2 female (4 points)?

7. You wish to study nervous system development in Drosophila. To begin these studies, you use a genetic screen to find mutations that alter development of a particular neuron. You find 8 different mutations, initially numbered one through eight. You perform crosses between your mutants in all possible pairwise combinations, producing the results shown in the table.

A. What is the name given to the general procedure described here (2 points)?

B. Please indicate which mutations are allelic to one another (4 points).

C. How many different genes were identified in this screen (4 points)?

D. Using gene names of your choosing (eg. gene1+ or geneA+, etc.), please give the genotype of the progeny of the cross of homozygous mutant 1 X homozygous mutant 2 (4 points).

8. Consider a cross between two tropical frogs with the following genotype:

AABbCcddEeFfGg X aaBbCCddEeFfGg

A. What is the probability of producing AaBbCCddEeffgg offspring (2 points)?

B. What is the probability that a child will NOT have the AaBBCCddeeffgg genotype (2 points)?

C. What is the probability of producing offspring with the phenotype ABCdEfg, where A is the phenotype produced by AA or Aa and a is the phenotype produced by aa, etc. (2 points).

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