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Deck 23: Population Genetics

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Question
In a given population of Drosophila,curly wings (c )is recessive to the wild-type condition of straight wings (c⁺ ).You isolate a population of 35 curly winged flies,70 flies that are heterozygous for straight wings,and 45 that are homozygous for straight wings.What is the total number of alleles in the gene pool?

A) 2
B) 150
C) 230
D) 300
E) None of these choices are correct
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Question
Given the allele frequency for a gene in population A is 0.3 and the frequency for the same allele in population B is 0.5 and that 25 individuals from A migrate to and mate randomly with the 475 individuals in population B,what is the new allele frequency (PC)in the conglomerate?

A) 0.052
B) 0.2
C) 0.8
D) 0.49
Question
Most natural populations are in Hardy-Weinberg equilibrium.
Question
Which of the following types of selection creates two phenotypic classes from a single original distribution?

A) disruptive selection
B) stabilizing selection
C) directional selection
D) balancing selection
Question
Which of the following is NOT an assumption of the Hardy-Weinberg equation?

A) There is no migration into or out of the population.
B) Individuals of the population mate randomly.
C) The population size is very large.
D) Selection favors the dominant allele.
E) There is no mutation occurring in the population.
Question
A SNP would best be described as 

A) a gene that comes in multiple different alleles.
B) a balanced polymorphism system.
C) a single nucleotide difference between two DNA sequences.
D) the least frequent type of mutation.
E) None of these choices are correct.
Question
Which type of selection would lead to two distinct phenotypes?

A) stabilizing selection
B) phenotype selection
C) fitness selection
D) disruptive selection
E) directional selection
Question
The term for the mating for two genetically unrelated individuals is

A) outbreeding.
B) inbreeding.
C) disassortative mating.
D) assertive mating.
Question
Which of the following types of selection is typically associated with quantitative traits?

A) disruptive selection only
B) both stabilizing and disruptive selection
C) stabilizing selection only
D) balancing selection
Question
Which of the following types of selection favors one extreme of a phenotypic distribution?

A) disruptive selection
B) stabilizing selection
C) directional selection
D) balancing selection
Question
In the equation p² + 2pq + q² = 1,what does the term 2pq represent?

A) the genotypic frequency of homozygous recessive individuals
B) the genotypic frequency of homozygous dominant individuals
C) the genotypic frequency of heterozygous individuals
D) the sum of the phenotypic frequencies in the population
E) None of these choices are correct.
Question
Natural selection occurs when

A) individuals whose phenotypes are best suited for environmental conditions have higher reproductive success and contribute more alleles to the next generation.
B) humans breed certain individuals with the most desirable phenotypes.
C) individuals whose phenotypes are best suited for environmental conditions have lower reproductive success but live longer.
D) the genotype of an individual does not determine whether or not is has reproductive success.
Question
If a gene has more than one allele and each allele has a frequency that is less than 99%,then the gene is considered to be 

A) monomorphic.
B) polymorphic.
C) bialleleic.
D) polyallelic.
Question
In a given population of Drosophila,curly wings (c )is recessive to the wild-type condition of straight wings (c⁺ ).You isolate a population of 35 curly winged flies,70 flies that are heterozygous for straight wings,and 45 that are homozygous for straight wings.What is the frequency of alleles in this population?

A) 35% c; 45% c⁺
B) 46.7% c; 53.3% c⁺
C) 50% c; 50% c⁺
D) 55% c; 45% c⁺
E) None of these choices are correct.
Question
Migration of a random few individuals from one population to a new area to establish a new population is an example of 

A) bottleneck effect.
B) mutation.
C) founder effect.
D) selection.
Question
A natural disaster that resulted in the loss of genetic diversity in a population would be an example of a

A) founder effect.
B) genetic drift.
C) bottleneck effect.
D) natural selection.
Question
Genetic drift has the greatest influence on allele frequencies for which population size?

A) small
B) large
C) Genetic drift has the same impact on both large and small populations.
D) Genetic drift has no effect on the allele frequencies.
Question
The probability that two alleles will be identical for a given gene in an individual because the alleles are from the same ancestor is estimated by

A) the calculation of average heterozygosity.
B) the Hardy-Weinberg equation.
C) the inbreeding coefficient.
D) the chi-square test.
Question
The formula p² + 2pq + q² = 1 is associated with which of the following?

A) calculations of heterozygosity
B) Hardy-Weinberg equilibrium
C) calculations of recombination frequencies
D) degrees of freedom
E) None of these choices are correct.
Question
The term for a group of individuals from the same species that can interbreed with one another is 

A) species.
B) population.
C) race.
D) community.
E) kingdom.
Question
If the allele frequency of the dominant allele is 0.4,what value is used for the term p² in the equation p² + 2pq + q² = 1?

A) 0.4
B) 0.2
C) 0.16
D) 16
Question
How does inbreeding affect the Hardy-Weinberg equilibrium?

A) It makes it more likely for the population to remain in Hardy-Weinberg equilibrium.
B) It has no effect on the Hardy-Weinberg equilibrium.
C) It results in a higher level of either dominant or recessive homozygotes.
D) It results in a higher level of heterozygotes.
Question
If in a population the rate of mutation that converts the A allele to the a allele is 10⁻⁶ and the current frequency of the A allele is 0.75 and the a allele is 0.25,then the frequency of the A and a alleles in the next generation will be

A) A: 0.75
A: 0.25
B) A: 0.7499993
A: 0.2500007
C) A: 0.750007
A: 0.2499993
D) A: 0.74
A: 0.26
Question
The mechanism that results in a change in allele frequencies due to random processes is known as

A) genetic drift.
B) natural selection.
C) migration.
D) nonrandom mating.
Question
Microevolution is defined as

A) changes in the gene pool from one generation to the next.
B) changes in gene flow from one generation to the next.
C) the ability of different genotypes to succeed in a particular environment.
D) morphological changes that occur from one generation to the next.
Question
Horizontal gene transfer occurs

A) within and between species of eukaryotes and prokaryotes.
B) between prokaryotic species only.
C) between eukaryotic species only.
D) only from prokaryotes to eukaryotes.
Question
Consider a hypothetical gene B for which there are two alleles in the population.For every ten BB individuals that survive,six Bb individuals survive,and one bb individual survives.What are the relative fitness values for each genotype?

A) wBB = 1.0; wBb = 0.6; wbb = 0.1
B) wBB = 100; wBb = 0.6; wbb = 0.01
C) wBB = 0.59; wBb = 0.35; wbb = 1.0
D) wB = 26; wb = 7
Question
A population with an allele for a gene that constitutes 99% of the alleles in the population means that the population is called monomorphic for that gene.
Question
Repetitive sequences are useful for DNA fingerprinting because they

A) are not inherited and so are unique to every individual.
B) are unique to every individual and change from generation to generation.
C) are inherited and can show significant variability between individuals.
D) never undergo mutation.
Question
You are preparing to perform DNA fingerprinting by PCR for the first time.Select the reagent that would result in complications in the interpretation of your results.

A) PCR primers that anneal to the repetitive region of the microsatellites
B) PCR primers that anneal to regions flanking the microsatellites
C) Human DNA
D) Taq polymerase
Question
At equilibrium the allelic and genotypic frequencies of a population change over time.
Question
Which term describes all the alleles of every gene in the population?

A) conglomerate
B) gene pool
C) polymorphisms
D) genotype frequency
Question
The probability that a gene will be altered by a mutation is called the mutation rate.
Question
Select the definition of genetic drift.

A) Changes in allele frequencies in a population due to random fluctuations
B) Changes in allele frequencies in a population due to migration
C) Changes in genotype frequencies in a population due to new mutations
D) Changes in genome size in a species due to random mutations
Question
Mutations represent

A) a minor part of microevolution.
B) an essential part of microevolution.
C) deleterious changes to the fitness of an individual.
D) advantageous changes to genes.
Question
The prevalence of the allele for sickle cell anemia in some populations is an example of which of the following?

A) heterogeneous environments
B) balancing selection
C) inverted selection
D) non-Darwinian selection
E) nonrandom mating
Question
If two individuals of a population,who vary in their phenotype,preferentially mate,it is called ________.

A) Outbreeding
B) Inbreeding
C) Negative assortative mating
D) Positive assortative mating
Question
Calculate the inbreeding coefficient of an individual given an n of 4 (excluding the inbred offspring)with one common ancestor. The inbreeding of the common ancestor is unknown.

A) 25%
B) 3.125%
C) 6.25%
D) 50%
Question
Which of the following is NOT an assumption of the Hardy-Weinberg equation?

A) The population is large.
B) There is no migration into or out of the population.
C) There is no selection against a given genotype.
D) There is no mutation in the gene being studied.
E) There is nonrandom mating.
Question
Match between columns
Premises:
Responses:
Exons of preexisting genes are rearranged to make a new combination
new alleles
Exons of preexisting genes are rearranged to make a new combination
prokaryotic gene transfer
Exons of preexisting genes are rearranged to make a new combination
interspecies crosses
Exons of preexisting genes are rearranged to make a new combination
crossing over
Exons of preexisting genes are rearranged to make a new combination
exon shuffling
Exons of preexisting genes are rearranged to make a new combination
independent assortment
Exons of preexisting genes are rearranged to make a new combination
gene duplications
Exons of preexisting genes are rearranged to make a new combination
chromosome structure and number
Exons of preexisting genes are rearranged to make a new combination
horizontal gene transfer
Exons of preexisting genes are rearranged to make a new combination
changes in repetitive sequences
Genes from one species introduced into another species
new alleles
Genes from one species introduced into another species
prokaryotic gene transfer
Genes from one species introduced into another species
interspecies crosses
Genes from one species introduced into another species
crossing over
Genes from one species introduced into another species
exon shuffling
Genes from one species introduced into another species
independent assortment
Genes from one species introduced into another species
gene duplications
Genes from one species introduced into another species
chromosome structure and number
Genes from one species introduced into another species
horizontal gene transfer
Genes from one species introduced into another species
changes in repetitive sequences
Recombination to produce new combinations of alleles
new alleles
Recombination to produce new combinations of alleles
prokaryotic gene transfer
Recombination to produce new combinations of alleles
interspecies crosses
Recombination to produce new combinations of alleles
crossing over
Recombination to produce new combinations of alleles
exon shuffling
Recombination to produce new combinations of alleles
independent assortment
Recombination to produce new combinations of alleles
gene duplications
Recombination to produce new combinations of alleles
chromosome structure and number
Recombination to produce new combinations of alleles
horizontal gene transfer
Recombination to produce new combinations of alleles
changes in repetitive sequences
Increase or decrease in the number of repetitive sequences
new alleles
Increase or decrease in the number of repetitive sequences
prokaryotic gene transfer
Increase or decrease in the number of repetitive sequences
interspecies crosses
Increase or decrease in the number of repetitive sequences
crossing over
Increase or decrease in the number of repetitive sequences
exon shuffling
Increase or decrease in the number of repetitive sequences
independent assortment
Increase or decrease in the number of repetitive sequences
gene duplications
Increase or decrease in the number of repetitive sequences
chromosome structure and number
Increase or decrease in the number of repetitive sequences
horizontal gene transfer
Increase or decrease in the number of repetitive sequences
changes in repetitive sequences
Production of hybrid offspring
new alleles
Production of hybrid offspring
prokaryotic gene transfer
Production of hybrid offspring
interspecies crosses
Production of hybrid offspring
crossing over
Production of hybrid offspring
exon shuffling
Production of hybrid offspring
independent assortment
Production of hybrid offspring
gene duplications
Production of hybrid offspring
chromosome structure and number
Production of hybrid offspring
horizontal gene transfer
Production of hybrid offspring
changes in repetitive sequences
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
new alleles
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
prokaryotic gene transfer
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
interspecies crosses
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
crossing over
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
exon shuffling
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
independent assortment
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
gene duplications
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
chromosome structure and number
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
horizontal gene transfer
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
changes in repetitive sequences
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
new alleles
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
prokaryotic gene transfer
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
interspecies crosses
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
crossing over
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
exon shuffling
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
independent assortment
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
gene duplications
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
chromosome structure and number
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
horizontal gene transfer
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
changes in repetitive sequences
Conjugation, transduction and transformation
new alleles
Conjugation, transduction and transformation
prokaryotic gene transfer
Conjugation, transduction and transformation
interspecies crosses
Conjugation, transduction and transformation
crossing over
Conjugation, transduction and transformation
exon shuffling
Conjugation, transduction and transformation
independent assortment
Conjugation, transduction and transformation
gene duplications
Conjugation, transduction and transformation
chromosome structure and number
Conjugation, transduction and transformation
horizontal gene transfer
Conjugation, transduction and transformation
changes in repetitive sequences
Point mutations, small deletions and insertions
new alleles
Point mutations, small deletions and insertions
prokaryotic gene transfer
Point mutations, small deletions and insertions
interspecies crosses
Point mutations, small deletions and insertions
crossing over
Point mutations, small deletions and insertions
exon shuffling
Point mutations, small deletions and insertions
independent assortment
Point mutations, small deletions and insertions
gene duplications
Point mutations, small deletions and insertions
chromosome structure and number
Point mutations, small deletions and insertions
horizontal gene transfer
Point mutations, small deletions and insertions
changes in repetitive sequences
Additional copies of a gene occur through misaligned crossing over
new alleles
Additional copies of a gene occur through misaligned crossing over
prokaryotic gene transfer
Additional copies of a gene occur through misaligned crossing over
interspecies crosses
Additional copies of a gene occur through misaligned crossing over
crossing over
Additional copies of a gene occur through misaligned crossing over
exon shuffling
Additional copies of a gene occur through misaligned crossing over
independent assortment
Additional copies of a gene occur through misaligned crossing over
gene duplications
Additional copies of a gene occur through misaligned crossing over
chromosome structure and number
Additional copies of a gene occur through misaligned crossing over
horizontal gene transfer
Additional copies of a gene occur through misaligned crossing over
changes in repetitive sequences
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Deck 23: Population Genetics
1
In a given population of Drosophila,curly wings (c )is recessive to the wild-type condition of straight wings (c⁺ ).You isolate a population of 35 curly winged flies,70 flies that are heterozygous for straight wings,and 45 that are homozygous for straight wings.What is the total number of alleles in the gene pool?

A) 2
B) 150
C) 230
D) 300
E) None of these choices are correct
D
2
Given the allele frequency for a gene in population A is 0.3 and the frequency for the same allele in population B is 0.5 and that 25 individuals from A migrate to and mate randomly with the 475 individuals in population B,what is the new allele frequency (PC)in the conglomerate?

A) 0.052
B) 0.2
C) 0.8
D) 0.49
D
3
Most natural populations are in Hardy-Weinberg equilibrium.
False
4
Which of the following types of selection creates two phenotypic classes from a single original distribution?

A) disruptive selection
B) stabilizing selection
C) directional selection
D) balancing selection
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
5
Which of the following is NOT an assumption of the Hardy-Weinberg equation?

A) There is no migration into or out of the population.
B) Individuals of the population mate randomly.
C) The population size is very large.
D) Selection favors the dominant allele.
E) There is no mutation occurring in the population.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
6
A SNP would best be described as 

A) a gene that comes in multiple different alleles.
B) a balanced polymorphism system.
C) a single nucleotide difference between two DNA sequences.
D) the least frequent type of mutation.
E) None of these choices are correct.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
7
Which type of selection would lead to two distinct phenotypes?

A) stabilizing selection
B) phenotype selection
C) fitness selection
D) disruptive selection
E) directional selection
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
8
The term for the mating for two genetically unrelated individuals is

A) outbreeding.
B) inbreeding.
C) disassortative mating.
D) assertive mating.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
9
Which of the following types of selection is typically associated with quantitative traits?

A) disruptive selection only
B) both stabilizing and disruptive selection
C) stabilizing selection only
D) balancing selection
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
10
Which of the following types of selection favors one extreme of a phenotypic distribution?

A) disruptive selection
B) stabilizing selection
C) directional selection
D) balancing selection
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
11
In the equation p² + 2pq + q² = 1,what does the term 2pq represent?

A) the genotypic frequency of homozygous recessive individuals
B) the genotypic frequency of homozygous dominant individuals
C) the genotypic frequency of heterozygous individuals
D) the sum of the phenotypic frequencies in the population
E) None of these choices are correct.
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Unlock for access to all 40 flashcards in this deck.
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k this deck
12
Natural selection occurs when

A) individuals whose phenotypes are best suited for environmental conditions have higher reproductive success and contribute more alleles to the next generation.
B) humans breed certain individuals with the most desirable phenotypes.
C) individuals whose phenotypes are best suited for environmental conditions have lower reproductive success but live longer.
D) the genotype of an individual does not determine whether or not is has reproductive success.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
13
If a gene has more than one allele and each allele has a frequency that is less than 99%,then the gene is considered to be 

A) monomorphic.
B) polymorphic.
C) bialleleic.
D) polyallelic.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
14
In a given population of Drosophila,curly wings (c )is recessive to the wild-type condition of straight wings (c⁺ ).You isolate a population of 35 curly winged flies,70 flies that are heterozygous for straight wings,and 45 that are homozygous for straight wings.What is the frequency of alleles in this population?

A) 35% c; 45% c⁺
B) 46.7% c; 53.3% c⁺
C) 50% c; 50% c⁺
D) 55% c; 45% c⁺
E) None of these choices are correct.
Unlock Deck
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k this deck
15
Migration of a random few individuals from one population to a new area to establish a new population is an example of 

A) bottleneck effect.
B) mutation.
C) founder effect.
D) selection.
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k this deck
16
A natural disaster that resulted in the loss of genetic diversity in a population would be an example of a

A) founder effect.
B) genetic drift.
C) bottleneck effect.
D) natural selection.
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k this deck
17
Genetic drift has the greatest influence on allele frequencies for which population size?

A) small
B) large
C) Genetic drift has the same impact on both large and small populations.
D) Genetic drift has no effect on the allele frequencies.
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18
The probability that two alleles will be identical for a given gene in an individual because the alleles are from the same ancestor is estimated by

A) the calculation of average heterozygosity.
B) the Hardy-Weinberg equation.
C) the inbreeding coefficient.
D) the chi-square test.
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k this deck
19
The formula p² + 2pq + q² = 1 is associated with which of the following?

A) calculations of heterozygosity
B) Hardy-Weinberg equilibrium
C) calculations of recombination frequencies
D) degrees of freedom
E) None of these choices are correct.
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20
The term for a group of individuals from the same species that can interbreed with one another is 

A) species.
B) population.
C) race.
D) community.
E) kingdom.
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21
If the allele frequency of the dominant allele is 0.4,what value is used for the term p² in the equation p² + 2pq + q² = 1?

A) 0.4
B) 0.2
C) 0.16
D) 16
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22
How does inbreeding affect the Hardy-Weinberg equilibrium?

A) It makes it more likely for the population to remain in Hardy-Weinberg equilibrium.
B) It has no effect on the Hardy-Weinberg equilibrium.
C) It results in a higher level of either dominant or recessive homozygotes.
D) It results in a higher level of heterozygotes.
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23
If in a population the rate of mutation that converts the A allele to the a allele is 10⁻⁶ and the current frequency of the A allele is 0.75 and the a allele is 0.25,then the frequency of the A and a alleles in the next generation will be

A) A: 0.75
A: 0.25
B) A: 0.7499993
A: 0.2500007
C) A: 0.750007
A: 0.2499993
D) A: 0.74
A: 0.26
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24
The mechanism that results in a change in allele frequencies due to random processes is known as

A) genetic drift.
B) natural selection.
C) migration.
D) nonrandom mating.
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Unlock Deck
k this deck
25
Microevolution is defined as

A) changes in the gene pool from one generation to the next.
B) changes in gene flow from one generation to the next.
C) the ability of different genotypes to succeed in a particular environment.
D) morphological changes that occur from one generation to the next.
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k this deck
26
Horizontal gene transfer occurs

A) within and between species of eukaryotes and prokaryotes.
B) between prokaryotic species only.
C) between eukaryotic species only.
D) only from prokaryotes to eukaryotes.
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27
Consider a hypothetical gene B for which there are two alleles in the population.For every ten BB individuals that survive,six Bb individuals survive,and one bb individual survives.What are the relative fitness values for each genotype?

A) wBB = 1.0; wBb = 0.6; wbb = 0.1
B) wBB = 100; wBb = 0.6; wbb = 0.01
C) wBB = 0.59; wBb = 0.35; wbb = 1.0
D) wB = 26; wb = 7
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28
A population with an allele for a gene that constitutes 99% of the alleles in the population means that the population is called monomorphic for that gene.
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29
Repetitive sequences are useful for DNA fingerprinting because they

A) are not inherited and so are unique to every individual.
B) are unique to every individual and change from generation to generation.
C) are inherited and can show significant variability between individuals.
D) never undergo mutation.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
30
You are preparing to perform DNA fingerprinting by PCR for the first time.Select the reagent that would result in complications in the interpretation of your results.

A) PCR primers that anneal to the repetitive region of the microsatellites
B) PCR primers that anneal to regions flanking the microsatellites
C) Human DNA
D) Taq polymerase
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k this deck
31
At equilibrium the allelic and genotypic frequencies of a population change over time.
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k this deck
32
Which term describes all the alleles of every gene in the population?

A) conglomerate
B) gene pool
C) polymorphisms
D) genotype frequency
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33
The probability that a gene will be altered by a mutation is called the mutation rate.
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34
Select the definition of genetic drift.

A) Changes in allele frequencies in a population due to random fluctuations
B) Changes in allele frequencies in a population due to migration
C) Changes in genotype frequencies in a population due to new mutations
D) Changes in genome size in a species due to random mutations
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35
Mutations represent

A) a minor part of microevolution.
B) an essential part of microevolution.
C) deleterious changes to the fitness of an individual.
D) advantageous changes to genes.
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
36
The prevalence of the allele for sickle cell anemia in some populations is an example of which of the following?

A) heterogeneous environments
B) balancing selection
C) inverted selection
D) non-Darwinian selection
E) nonrandom mating
Unlock Deck
Unlock for access to all 40 flashcards in this deck.
Unlock Deck
k this deck
37
If two individuals of a population,who vary in their phenotype,preferentially mate,it is called ________.

A) Outbreeding
B) Inbreeding
C) Negative assortative mating
D) Positive assortative mating
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Unlock Deck
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38
Calculate the inbreeding coefficient of an individual given an n of 4 (excluding the inbred offspring)with one common ancestor. The inbreeding of the common ancestor is unknown.

A) 25%
B) 3.125%
C) 6.25%
D) 50%
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39
Which of the following is NOT an assumption of the Hardy-Weinberg equation?

A) The population is large.
B) There is no migration into or out of the population.
C) There is no selection against a given genotype.
D) There is no mutation in the gene being studied.
E) There is nonrandom mating.
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40
Match between columns
Premises:
Responses:
Exons of preexisting genes are rearranged to make a new combination
new alleles
Exons of preexisting genes are rearranged to make a new combination
prokaryotic gene transfer
Exons of preexisting genes are rearranged to make a new combination
interspecies crosses
Exons of preexisting genes are rearranged to make a new combination
crossing over
Exons of preexisting genes are rearranged to make a new combination
exon shuffling
Exons of preexisting genes are rearranged to make a new combination
independent assortment
Exons of preexisting genes are rearranged to make a new combination
gene duplications
Exons of preexisting genes are rearranged to make a new combination
chromosome structure and number
Exons of preexisting genes are rearranged to make a new combination
horizontal gene transfer
Exons of preexisting genes are rearranged to make a new combination
changes in repetitive sequences
Genes from one species introduced into another species
new alleles
Genes from one species introduced into another species
prokaryotic gene transfer
Genes from one species introduced into another species
interspecies crosses
Genes from one species introduced into another species
crossing over
Genes from one species introduced into another species
exon shuffling
Genes from one species introduced into another species
independent assortment
Genes from one species introduced into another species
gene duplications
Genes from one species introduced into another species
chromosome structure and number
Genes from one species introduced into another species
horizontal gene transfer
Genes from one species introduced into another species
changes in repetitive sequences
Recombination to produce new combinations of alleles
new alleles
Recombination to produce new combinations of alleles
prokaryotic gene transfer
Recombination to produce new combinations of alleles
interspecies crosses
Recombination to produce new combinations of alleles
crossing over
Recombination to produce new combinations of alleles
exon shuffling
Recombination to produce new combinations of alleles
independent assortment
Recombination to produce new combinations of alleles
gene duplications
Recombination to produce new combinations of alleles
chromosome structure and number
Recombination to produce new combinations of alleles
horizontal gene transfer
Recombination to produce new combinations of alleles
changes in repetitive sequences
Increase or decrease in the number of repetitive sequences
new alleles
Increase or decrease in the number of repetitive sequences
prokaryotic gene transfer
Increase or decrease in the number of repetitive sequences
interspecies crosses
Increase or decrease in the number of repetitive sequences
crossing over
Increase or decrease in the number of repetitive sequences
exon shuffling
Increase or decrease in the number of repetitive sequences
independent assortment
Increase or decrease in the number of repetitive sequences
gene duplications
Increase or decrease in the number of repetitive sequences
chromosome structure and number
Increase or decrease in the number of repetitive sequences
horizontal gene transfer
Increase or decrease in the number of repetitive sequences
changes in repetitive sequences
Production of hybrid offspring
new alleles
Production of hybrid offspring
prokaryotic gene transfer
Production of hybrid offspring
interspecies crosses
Production of hybrid offspring
crossing over
Production of hybrid offspring
exon shuffling
Production of hybrid offspring
independent assortment
Production of hybrid offspring
gene duplications
Production of hybrid offspring
chromosome structure and number
Production of hybrid offspring
horizontal gene transfer
Production of hybrid offspring
changes in repetitive sequences
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
new alleles
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
prokaryotic gene transfer
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
interspecies crosses
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
crossing over
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
exon shuffling
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
independent assortment
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
gene duplications
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
chromosome structure and number
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
horizontal gene transfer
Independent segregation of different homologous chromosomes gives rise to new combinations of alleles
changes in repetitive sequences
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
new alleles
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
prokaryotic gene transfer
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
interspecies crosses
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
crossing over
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
exon shuffling
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
independent assortment
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
gene duplications
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
chromosome structure and number
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
horizontal gene transfer
Chromosome structure changed by deletion, duplications, inversions, translocations or there is a change in ploidy
changes in repetitive sequences
Conjugation, transduction and transformation
new alleles
Conjugation, transduction and transformation
prokaryotic gene transfer
Conjugation, transduction and transformation
interspecies crosses
Conjugation, transduction and transformation
crossing over
Conjugation, transduction and transformation
exon shuffling
Conjugation, transduction and transformation
independent assortment
Conjugation, transduction and transformation
gene duplications
Conjugation, transduction and transformation
chromosome structure and number
Conjugation, transduction and transformation
horizontal gene transfer
Conjugation, transduction and transformation
changes in repetitive sequences
Point mutations, small deletions and insertions
new alleles
Point mutations, small deletions and insertions
prokaryotic gene transfer
Point mutations, small deletions and insertions
interspecies crosses
Point mutations, small deletions and insertions
crossing over
Point mutations, small deletions and insertions
exon shuffling
Point mutations, small deletions and insertions
independent assortment
Point mutations, small deletions and insertions
gene duplications
Point mutations, small deletions and insertions
chromosome structure and number
Point mutations, small deletions and insertions
horizontal gene transfer
Point mutations, small deletions and insertions
changes in repetitive sequences
Additional copies of a gene occur through misaligned crossing over
new alleles
Additional copies of a gene occur through misaligned crossing over
prokaryotic gene transfer
Additional copies of a gene occur through misaligned crossing over
interspecies crosses
Additional copies of a gene occur through misaligned crossing over
crossing over
Additional copies of a gene occur through misaligned crossing over
exon shuffling
Additional copies of a gene occur through misaligned crossing over
independent assortment
Additional copies of a gene occur through misaligned crossing over
gene duplications
Additional copies of a gene occur through misaligned crossing over
chromosome structure and number
Additional copies of a gene occur through misaligned crossing over
horizontal gene transfer
Additional copies of a gene occur through misaligned crossing over
changes in repetitive sequences
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