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CAMPBELL BIOLOGY IN FOCUS Urry • Cain • Wasserman • Minorsky • Jackson • Reece 12 The Chromosomal Basis of Inheritance Questions prepared by Brad Stith, University of Colorado Denver Janet Lanza, University of Arkansas at Little Rock Louise Paquin, McDaniel College © 2014 Pearson Education, Inc. Why did the improvement of microscopy techniques in the late 1800s set the stage for the emergence of modern genetics? A. It revealed new and unanticipated features of Mendel's pea plant varieties. B. It allowed the study of meiosis and mitosis, revealing parallels between behaviors of the Mendelian concept of the gene and the movement/pairing of chromosomes. C. It allowed scientists to see the nucleotide sequence of DNA. D. It led to the discovery of mitochondria. E. It showed genes functioning to direct the formation of enzymes. © 2014 Pearson Education, Inc. Why did the improvement of microscopy techniques in the late 1800s set the stage for the emergence of modern genetics? A. It revealed new and unanticipated features of Mendel's pea plant varieties. B. It allowed the study of meiosis and mitosis, revealing parallels between behaviors of the Mendelian concept of the gene and the movement/pairing of chromosomes. C. It allowed scientists to see the nucleotide sequence of DNA. D. It led to the discovery of mitochondria. E. It showed genes functioning to direct the formation of enzymes. © 2014 Pearson Education, Inc. Morgan and his colleagues worked out a set of symbols to represent fly genotypes. Which of the following are representative? A. AaBb AaBb B. 46 or 46w C. w or w on X D. 2 3 © 2014 Pearson Education, Inc. Morgan and his colleagues worked out a set of symbols to represent fly genotypes. Which of the following are representative? A. AaBb AaBb B. 46 or 46w C. w or w on X D. 2 3 © 2014 Pearson Education, Inc. Imagine that Morgan had chosen a different organism for his genetics experiments. What kind of species would have made a better choice than fruit flies? © 2014 Pearson Education, Inc. Imagine that Morgan had used a grasshopper (2n 24, and sex is determined as follows: male has X, and female has XX) to study sex linkage. Predict where the first mutant would have been discovered. A. on the O chromosome of a male B. on the X chromosome of a male C. on the X chromosome of a female D. on the Y chromosome of a male © 2014 Pearson Education, Inc. Imagine that Morgan had used a grasshopper (2n 24, and sex is determined as follows: male has X, and female has XX) to study sex linkage. Predict where the first mutant would have been discovered. A. on the O chromosome of a male B. on the X chromosome of a male C. on the X chromosome of a female D. on the Y chromosome of a male © 2014 Pearson Education, Inc. Think about bees and ants where there are no X and Y sex chromosomes. Males are haploid, whereas fertilization results in females, as diploid cells become females. Which of the following are accurate statements about bee and ant males when they are compared to species in which males are XY and diploid for the autosomes? A. Bee males have half the DNA of bee females, whereas human males have nearly the same amount of DNA that human females have. B. Considered across the genome, harmful (deleterious) recessives will negatively affect bee males more than Drosophila males. C. Human and Drosophila males have sons, but bee males do not. D. Inheritance in bees is like inheritance of sex-linked characteristics in humans. E. none of the above © 2014 Pearson Education, Inc. Think about bees and ants where there are no X and Y sex chromosomes. Males are haploid, whereas fertilization results in females, as diploid cells become females. Which of the following are accurate statements about bee and ant males when they are compared to species in which males are XY and diploid for the autosomes? A. Bee males have half the DNA of bee females, whereas human males have nearly the same amount of DNA that human females have. B. Considered across the genome, harmful (deleterious) recessives will negatively affect bee males more than Drosophila males. C. Human and Drosophila males have sons, but bee males do not. D. Inheritance in bees is like inheritance of sex-linked characteristics in humans. E. none of the above © 2014 Pearson Education, Inc. Determination of sex in Drosophila is similar to that in humans. In some species of Drosophila, there are genes on the Y chromosome that do not occur on the X chromosome. Imagine that a mutation of one gene on the Y chromosome reduces the size by half of individuals with the mutation. Which of the following statements is accurate with regard to this situation? A. This mutation occurs in all offspring of a male with the mutation. B. This mutation occurs in all male but no female offspring of a male with the mutation. C. This mutation occurs in all offspring of a female with the mutation. D. This mutation occurs in all male but no female offspring of a female with the mutation. E. This mutation occurs in all offspring of both males and females with the mutation. © 2014 Pearson Education, Inc. Determination of sex in Drosophila is similar to that in humans. In some species of Drosophila, there are genes on the Y chromosome that do not occur on the X chromosome. Imagine that a mutation of one gene on the Y chromosome reduces the size by half of individuals with the mutation. Which of the following statements is accurate with regard to this situation? A. This mutation occurs in all offspring of a male with the mutation. B. This mutation occurs in all male but no female offspring of a male with the mutation. C. This mutation occurs in all offspring of a female with the mutation. D. This mutation occurs in all male but no female offspring of a female with the mutation. E. This mutation occurs in all offspring of both males and females with the mutation. © 2014 Pearson Education, Inc. In cats, a sex-linked gene affects coat color. The O allele produces an enzyme that converts eumelanin, a black or brown pigment, into phaeomelanin, an orange pigment. The o allele is recessive to O and produces a defective enzyme, one that does not convert eumelanin into phaeomelanin. Which of the following statements is/are accurate? A. The phenotype of o-Y males is black/brown because the nonfunctional allele o does not convert eumelanin into phaeomelanin. B. The phenotype of OO and Oo males is orange because the functional allele O converts eumelanin into phaeomelanin. C. The phenotype of Oo males is mixed orange and black/brown because the functional allele O converts eumelanin into phaeomelanin in some cell groups (orange) and because in other cell groups the nonfunctional allele o does not convert eumelanin into phaeomelanin. D. The phenotype of O-Y males is orange because the nonfunctional allele O does not convert eumelanin into phaeomelanin, while the phenotype of o-Y males is black/brown because the functional allele o converts eumelanin into phaeomelanin. © 2014 Pearson Education, Inc. In cats, a sex-linked gene affects coat color. The O allele produces an enzyme that converts eumelanin, a black or brown pigment, into phaeomelanin, an orange pigment. The o allele is recessive to O and produces a defective enzyme, one that does not convert eumelanin into phaeomelanin. Which of the following statements is/are accurate? A. The phenotype of o-Y males is black/brown because the nonfunctional allele o does not convert eumelanin into phaeomelanin. B. The phenotype of OO and Oo males is orange because the functional allele O converts eumelanin into phaeomelanin. C. The phenotype of Oo males is mixed orange and black/brown because the functional allele O converts eumelanin into phaeomelanin in some cell groups (orange) and because in other cell groups the nonfunctional allele o does not convert eumelanin into phaeomelanin. D. The phenotype of O-Y males is orange because the nonfunctional allele O does not convert eumelanin into phaeomelanin, while the phenotype of o-Y males is black/brown because the functional allele o converts eumelanin into phaeomelanin. © 2014 Pearson Education, Inc. Imagine two species of cats that differ in the timing of Barr body formation during development. Both species have genes that determine coat color, O for the dominant orange fur and o for the recessive black/brown fur, on the X chromosome. In species A, the Barr body forms during week 1 of a 6-month pregnancy, whereas in species B, the Barr body forms during week 3 of a 5-month pregnancy. What would you predict about the coloration of heterozygous females (Oo) in the two species? A. Both species will have similar sized patches of orange and black/brown fur. B. Species A will have smaller patches of orange or black/brown fur than will species B. C. The females of both species will show the dominant fur color, orange. © 2014 Pearson Education, Inc. Imagine two species of cats that differ in the timing of Barr body formation during development. Both species have genes that determine coat color, O for the dominant orange fur and o for the recessive black/brown fur, on the X chromosome. In species A, the Barr body forms during week 1 of a 6-month pregnancy, whereas in species B, the Barr body forms during week 3 of a 5-month pregnancy. What would you predict about the coloration of heterozygous females (Oo) in the two species? A. Both species will have similar sized patches of orange and black/brown fur. B. Species A will have smaller patches of orange or black/brown fur than will species B. C. The females of both species will show the dominant fur color, orange. © 2014 Pearson Education, Inc. Imagine a species with three loci thought to be on the same chromosome. The recombination rate between locus A and locus B is 35%, and the recombination rate between locus B and locus C is 33%. Predict the recombination rate between A and C. A. The recombination rate between locus A and locus C is either 2% or 68%. B. The recombination rate between locus A and locus C is probably 2%. C. The recombination rate between locus A and locus C is either 2% or 50%. D. The recombination rate between locus A and locus C is either 2% or 39%. E. The recombination rate between locus A and locus C cannot be predicted. © 2014 Pearson Education, Inc. Imagine a species with three loci thought to be on the same chromosome. The recombination rate between locus A and locus B is 35%, and the recombination rate between locus B and locus C is 33%. Predict the recombination rate between A and C. A. The recombination rate between locus A and locus C is either 2% or 68%. B. The recombination rate between locus A and locus C is probably 2%. C. The recombination rate between locus A and locus C is either 2% or 50%. D. The recombination rate between locus A and locus C is either 2% or 39%. E. The recombination rate between locus A and locus C cannot be predicted. © 2014 Pearson Education, Inc. Triploid species are usually sterile (unable to reproduce), whereas tetraploids are often fertile. Which of the following is likely a good explanation of these facts? Hint: synapsis. A. In mitosis, some chromosomes in triploids have no partner at synapsis, but chromosomes in tetraploids do have partners. B. In meiosis, some chromosomes in triploids have no partner at synapsis, but chromosomes in tetraploids do have partners. C. In mitosis, some chromosomes in tetraploids have no partner at synapsis, but chromosomes in triploids do have partners. D. In meiosis, some chromosomes in tetraploids have no partner at synapsis, but chromosomes in triploids do have partners. © 2014 Pearson Education, Inc. Triploid species are usually sterile (unable to reproduce), whereas tetraploids are often fertile. Which of the following is likely a good explanation of these facts? Hint: synapsis. A. In mitosis, some chromosomes in triploids have no partner at synapsis, but chromosomes in tetraploids do have partners. B. In meiosis, some chromosomes in triploids have no partner at synapsis, but chromosomes in tetraploids do have partners. C. In mitosis, some chromosomes in tetraploids have no partner at synapsis, but chromosomes in triploids do have partners. D. In meiosis, some chromosomes in tetraploids have no partner at synapsis, but chromosomes in triploids do have partners. © 2014 Pearson Education, Inc. Chromosomal rearrangements can occur after chromosomes break. Which of the following statements is most accurate with respect to alterations in chromosome structure? A. Chromosomal rearrangements are more likely to occur in mammals than in other vertebrates. B. Translocations and inversions are not deleterious because no genes are lost in the organism. C. Chromosomal rearrangements are more likely to occur during mitosis than during meiosis. D. An individual that is homozygous for a deletion of a certain gene is likely to be more damaged than one that is homozygous for a duplication of that same gene because loss of a function can be lethal. © 2014 Pearson Education, Inc. Chromosomal rearrangements can occur after chromosomes break. Which of the following statements is most accurate with respect to alterations in chromosome structure? A. Chromosomal rearrangements are more likely to occur in mammals than in other vertebrates. B. Translocations and inversions are not deleterious because no genes are lost in the organism. C. Chromosomal rearrangements are more likely to occur during mitosis than during meiosis. D. An individual that is homozygous for a deletion of a certain gene is likely to be more damaged than one that is homozygous for a duplication of that same gene because loss of a function can be lethal. © 2014 Pearson Education, Inc. Imagine that you could create medical policy for a country. In this country it is known that the frequency of Down syndrome increases with increasing age of the mother and that the frequency of schizophrenia and autism increases with the age of the father. In both, the severity of characteristics varies enormously and unpredictably among affected individuals. Furthermore, financial resources are severely limited, both for testing of pregnant women and for supplemental training of children with Down syndrome. What kind of policy regarding fetal testing would you implement? © 2014 Pearson Education, Inc.