Biology 1001A Lecture Notes - Lecture 10: Mendelian Inheritance, Chromosome, Y Chromosome
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In what phases is the genetic material in the cell correctly referred to as chromatids?
A. | metaphase and telophase | |
B. | anaphase and metaphase | |
C. | interphase and telophase | |
D. | interphase and prophase | |
E. | metaphase and prophase |
Consider two traits for an organism, determined by two genes, each of which is governed by at least two alleles. In the case of a dihybrid individual, the gametes formed will be of either the parental type or the recombinant type. Recombinant type gametes are formed because of
A. | the principle of dihybrids. | |
B. | multiple alleles. | |
C. | heterozygosity. | |
D. | incomplete dominance. | |
E. | independent assortment. |
An allele is
A. | an alternate form of a gene. | |
B. | always recessive. | |
C. | the main factor determining a trait. | |
D. | always one of a pair. | |
E. | the dominant form of a gene. |
After the DNA is replicated, and it condenses in prophase, two identical rods of DNA are seen. These are
A. | spindle fibers. | |
B. | kinetochores. | |
C. | chromatids. | |
D. | chromatin. | |
E. | centromeres. |
Special cells found in the gonads that give rise to gametes upon division are called
A. | egg cells. | |
B. | somatic cells. | |
C. | germ cells. | |
D. | stem cells. | |
E. | basal cells. |
1. Characters that show a continuous range of variation, such as height and eye color, usually are controlled:
a. | by a single gene with two alleles that are codominant. |
b. | by many genes with an additive effect. |
c. | by epistatic interactions between two genes. |
d. | mainly by the environment, with only a small genetic component. |
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.
a. | Her mother must be red-green colorblind. |
b. | All of her brothers must be red-green colorblind. |
c. | Her father must be red-green colorblind. |
d. | All of the above statements must be true if a woman is red-green colorblind. |
3. The x-ray crystallography data collected by Rosalind Franklin suggested to Watson and Crick that the:
a. | structure of DNA is a double helix. |
b. | two strands of the DNA molecule are joined by hydrogen bonds between the bases. |
c. | four bases within DNA pair in a specific way. |
d. | two strands of the DNA molecule are joined by covalent bonds between the bases. |
4. In the genetic code, _________ one amino acid.
a. | one nucleotide specifies |
b. | two nucleotides specify |
c. | three nucleotides specify |
d. | four nucleotides specify |
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:
a. | independent assortment. |
b. | nondisjunction. |
c. | segregation. |
d. | crossing over. |
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:
a. | 0.16 (16%) |
b. | 0.24 (24%) |
c. | 0.36 (36%) |
d. | 0.48 (48%) |
7. Natural selection acts at the level of the:
a. | phenotype. |
b. | gene. |
c. | population. |
d. | nucleotide. |
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?
a. | This plant would produce only RY and ry gametes. |
b. | This plant would produce only RrYy gametes. |
c. | This plant would produce RY, Ry, rY, and ry gametes. |
d. | You cannot determine which gametes this plant can produce without knowing the genotypes of its parents. |
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:
a. | percentage of A nucleotides = the percentage of T nucleotides, and the percentage of C nucleotides = the percentage of G nucleotides. |
b. | four bases all occur in an equal frequency (25%) within each organism. |
c. | percentage of A nucleotides = the percentage of G nucleotides, and the percentage of C nucleotides = the percentage of T nucleotides. |
d. | genetic material is composed of proteins, not DNA. |
10. During DNA replication:
a. | each strand of the double helix acts as a template for the synthesis of a new strand. |
b. | the enzyme DNA polymerase adds nucleotides to the strand being synthesized. |
c. | the bases A,C,G and T are required. |
d. | All of the above are true of DNA replication. |
11. During translation, amino acids are joined by peptide bonds to make polypeptides. The formation of these peptide bonds is catalyzed by:
a. | DNA. |
b. | mRNA. |
c. | tRNA. |
d. | rRNA. |
12. If an allele (R) at a gene with two alleles shows complete dominance, individuals with the genotypes ______ will have the same phenotype.
a. | RR and rr. |
b. | RR and Rr |
c. | Rr and rr |
d. | Each of the three possible genotypes will have a different phenotype. |
These all relate to exceptions to the inheritance patterns encountered by Mendel.â
Why do multiple and lethal alleles often result in modifications of the classic Mendelian monohybrid and dihybrid ratios?
Select the four correct statements.
-When an essential gene is mutated, it can result in a lethal phenotype. There are no classic Mendelian monohybrid and dihybrid ratios. |
-In the case of codominance, heterozygotes produce gene products from both alleles of a gene. Classic Mendelian monohybrid and dihybrid ratios are modified by codominance. |
-In the case of incomplete dominance, the phenotype of the heterozygote is distinct from and often intermediate to the phenotypes of homozygous individuals. Classic Mendelian monohybrid and dihybrid ratios are modified by incomplete dominance. |
-Genes exist in a large number of allelic versions and a diploid organism has two homologous gene loci that may be occupied by different alleles of the same gene. This can result in many different phenotypes for traits, which may not follow typical Mendelian ratios. |
-When an essential gene is mutated, it can result in a lethal phenotype. This results in a modification of classic Mendelian ratios. |
-The phenotype of the heterozygous genotype is distinct from and often intermediate to the phenotypes of the homozygous genotypes. The joint expression of both alleles in a heterozygote is called codominance. There are no classic Mendelian monohybrid and dihybrid ratios. |
-Genes exist in a large number of allelic versions, but in a diploid organism, only one allele of the gene can occupy one homologous gene loci. Classic Mendelian inheritance cannot explain this phenomenon. |
-Each gene produces a unique gene product. The effect of one allele in a heterozygote completely masks the effect of the other. Classic Mendelian genetics cannot explain this phenomenon. |