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Gregor Mendel’s Discoveries
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1.
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Explain how Mendel’s particulate mechanism differed from
the blending theory of inheritance.
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2.
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Define the following terms: true-breeding, hybridization,
monohybrid cross, P generation, F1 generation, and F2 generation.
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3.
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List and explain the four components of Mendel’s
hypothesis that led him to deduce the law of segregation.
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4.
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Use a Punnett square to predict the results of a
monohybrid cross, stating the phenotypic and genotypic ratios of the F2
generation.
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5.
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Distinguish between the following pairs of terms: dominant
and recessive; heterozygous and homozygous; genotype and phenotype.
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6.
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Explain how a testcross can be used to determine if an
individual with the dominant phenotype is homozygous or heterozygous.
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7.
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Use a Punnett square to predict the results of a dihybrid
cross and state the phenotypic and genotypic ratios of the F2 generation.
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8.
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State Mendel’s law of independent assortment and describe
how this law can be explained by the behavior of chromosomes during meiosis.
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9.
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Use the rule of multiplication to calculate the
probability that a particular F2 individual will be homozygous recessive or
dominant.
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10.
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Given a Mendelian cross, use the rule of addition to
calculate the probability that a particular F2 individual will be
heterozygous.
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11.
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Use the laws of probability to predict, from a trihybrid
cross between two individuals that are heterozygous for all three traits,
what expected proportion of the offspring would be:
a. homozygous dominant for the three traits
b. heterozygous for all three traits
c. homozygous recessive for two specific traits and heterozygous for the
third
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12.
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Explain why it is important that Mendel used large sample
sizes in his studies.
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Extending Mendelian Genetics
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13.
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Give an example of incomplete dominance and explain why it
does not support the blending theory of inheritance.
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14.
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Explain how phenotypic expression of the heterozygote
differs with complete dominance, incomplete dominance, and codominance.
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15.
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Explain why Tay-Sachs disease is considered recessive at
the organismal level but codominant at the molecular level.
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16.
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Explain why genetic dominance does not mean that a
dominant allele subdues a recessive allele. Illustrate your explanation with
the use of round versus wrinkled pea seed shape.
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17.
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Explain why dominant alleles are not necessarily more
common in a population. Illustrate your explanation with an example.
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18.
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Describe the inheritance of the ABO blood system and
explain why the IA and IB alleles are said to be codominant.
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19.
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Define and give examples of pleiotropy and epistasis.
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20.
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Describe a simple model for polygenic inheritance and
explain why most polygenic characters are described in quantitative terms.
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21.
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Describe how environmental conditions can influence the
phenotypic expression of a character. Explain what is meant by “a norm of
reaction.”
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22.
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Distinguish between the specific and broad interpretations
of the terms phenotype and genotype.
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Mendelian Inheritance in Humans
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23.
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Explain why studies of human inheritance are not as easily
conducted as Mendel’s work with his peas.
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24.
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Given a simple family pedigree, deduce the genotypes for
some of the family members.
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25.
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Explain how a lethal recessive allele can be maintained in
a population.
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26.
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Describe the inheritance and expression of cystic
fibrosis, Tay-Sachs disease, and sickle-cell disease.
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27.
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Explain why lethal dominant genes are much rarer than
lethal recessive genes.
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28.
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Give an example of a late-acting lethal dominant gene in
humans and explain how it can escape elimination by natural selection.
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29.
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Define and give examples of multifactorial disorders in
humans.
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30.
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Explain how carrier recognition, fetal testing, and
newborn screening can be used in genetic screening and counseling.
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