Red-green colorblindness is the most common form of colorblindnessand is caused by two closely linked genes located near the tip ofthe human X chromosome. Red blindness, or protanopia, and greenblindness, or deutanopia, are recessive conditions caused by mutantalleles p and d, respectively. Between these two genes lies thelocus for glucose-6-phosphate dehydrogenase (G6PD), an importantenzyme found in erythrocytes. A deficient form of this enzyme iscaused by the recessive allele (g).

A woman, who is phenotypically normal, marries a man who hasdeutanopia and protanopia and is G6PD deficient.

The couple have a daughter who is green colorblind like her father,and they have a son who is red colorblind and G6PD deficient.

(a) What is the genotype of the father?
(b) What is the most likely genotypic arrangement of the genes inthe mother?
(c) The woman then has an illegitimate son with a completely normalman. The son is protanopic, deutanopic, and G6PD deficient. How isthis possible?

1. If you had a fruitfly with phenotype A, what test would you make to determine if it was Aa or AA? Explain the different outcomes expected if the fly in question is AA or Aa.

2.The sex of birds, some insects, and other organisms is determined by a ZW chromosomal arrangement in which the males have like sex chromosomes (ZZ) and females are ZW (similar to XY in humans). Assume that a recessive lethal allele on the Z chromosome causes death of an embryo in birds. What sex ratio would result in the offspring if a cross were made between a male heterozygous for the lethal allele and a normal female?

3.A recessive gene for red-green color blindness is located on the X chromosome in humans. Assume that a woman with normal vision (her father is color-blind) marries a color-blind male. What is the likelihood that this couple's first son will be color-blind?

4. One form of hemophilia is caused by a sex-linked recessive gene. Assume that a man with hemophilia marries a phenotypically normal woman whose father had hemophilia. What is the probability that they will have a daughter with hemophilia? (Note: In this problem, you must include the probability of having a daughter in your computation of the final probability.)

5. One form of hemophilia is caused by a sex-linked recessive gene. Assume that a man with hemophilia marries a phenotypically normal woman whose father had hemophilia. What is the probability that their first son will have hemophilia?

1) You perform a 3pt testcross and find one of your double crossover offspring classes is Abc and one of your parental classes is abc. You find that the RF for ab is 15% and the RF for bc is 30%. What is the distance between genes A and C?

2)You cross LM/lm × lm/lm individuals and find 30% of your offspring are lM/lm. How far apart are your genes. What proportion of the offspring should be lm/lm?In humans, the genes for red-green color blindness (R = normal, r = color-blind) and hemophilia A (H = normal, h = hemophilia) are both X-linked and 5 map units apart.

3)Suppose a woman has 15 sons, and 7 are colorblind with haemophilia, 7 are phenotypically normal, and one has hemophilia but normal color vision. Show the genotypes of her offspring. What is the chromosomal arrangement of alleles of the woman?

4)Waxy endosperm (wx), shrunken endosperm (sh), and yellow seedling (v) are encoded by three recessive genes in corn that are linked on chromosome 5. The F1 from an unknown true breeding parental cross is then crossed with a plant homozygous for the recessive genes. Following are the progeny of the testcross. What is the order of the genes and the distance between the genes?
wx sh V 1400
Wx Sh v 1500
Wx Sh V 3500
wx sh v 3400
Wx sh V 292
wx Sh v 280
wx Sh V 90
Wx sh v 80

1. Characters that show a continuous range of variation, such as height and eye color, usually are controlled:

2. In humans, red-green colorblindness is inherited as a sex-linked recessive trait. In order for a woman to be red-green colorblind, which of the following statements must be true.

3. The x-ray crystallography data collected by Rosalind Franklin suggested to Watson and Crick that the:

4. In the genetic code, _________ one amino acid.

5. During Meiosis I, a homologous pair of chromosomes may not separate, resulting in daughter cells that have extra chromosomes or are missing chromosomes. This can lead to genetic disorders, including Down Syndrome. This phenomenon is called:

6. You are a human geneticist studying the incidence of retinitis pigmentosa in the residents of Tristan de Cunha, a group of small islands in the middle of the southern Atlantic Ocean. The allele for retinitis pigmentosa, which causes a form of blindness, is inherited as an autosomal recessive. You have determined that the frequency of this allele (r) in the population is 0.4 (40%). Using the principles of the Hardy-Weinberg rule, you would estimate the frequency of individuals who are heterozygous for this allele (Rr) in the population to be:

7. Natural selection acts at the level of the:

8. You are working with pea plants, trying to recreate the experiments that Mendel performed. You are doing a dihybrid cross with a plant that is heterozygous for both seed shape and seed color, with the genotype RrYy. Which allelic combinations would you expect to find in the gametes produced by this plant?

9. Biochemist Erwin Chargaff found that in DNA there is a special relationship between the four bases that we now call Chargaff's rule. His observation was that, in an organism's genome the:

10. During DNA replication:

11. During translation, amino acids are joined by peptide bonds to make polypeptides. The formation of these peptide bonds is catalyzed by:

12. If an allele (R) at a gene with two alleles shows complete dominance, individuals with the genotypes ______ will have the same phenotype.