Deck 11: Mechanisms of Evolution

A)genetic drift.
B)mutation.
C)natural selection.
D)gene flow.

A)gene flow.
B)genetic drift.
C)convergent evolution.
D)divergent evolution.

A)Because the use of antibiotics lowers the effectiveness of the immune system, the student continually reinfected himself with the bacteria. The third time, the student happened to be reinfected with a resistant strain.
B)When the student stopped taking the drug, a small number of bacteria-those that were more drug resistant-still survived in his body. Those bacteria repopulated his throat and over time, drug-resistant alleles became more common.
C)The student must have eaten produce that had been genetically engineered with antibiotic-resistant genes. When he consumed them, the bacteria in the student's throat picked up these genes through horizontal gene transfer.
D)The antibiotic caused mutations in the bacterium. The more exposure to the antibiotic, the more mutations.

A)predesigned change in the genetic characteristics of a population of organisms over time.
B)sudden shifts in the genetic characteristics of an individual in a population.
C)a change in the genetic characteristics of a population of organisms over time.
D)isolation of populations due to geologic forces.

A)Only changes in the DNA sequence of an organism can be inherited. Traits acquired throughout life generally do not involve DNA.
B)The environment chooses which traits are necessary for survival rather than the individual.
C)Changes in a species occur at the individual level rather than at the population level.
D)The inheritance of acquired traits would not lead to speciation because it would cause all of the individuals in a population to become more similar.

A)genetic drift.
B)lines of common descent.
C)homologous characteristics.
D)analogous characteristics.

A)natural selection is disrupted by genetic drift.
B)there is a balanced gene pool.
C)only the smallest individuals survive.
D)both extremes of the phenotype are more successful.

A)An insect with a random mutation is not killed by the insecticide and reproduces.
B)Exposing insects to insecticides leads to mutations, which make the insects resistant.
C)Human interference with natural processes leads to genetic drift, which results in resistant insects.
D)Insecticides kill all the insects in a population, and a different species of resistant insects colonizes the available resources.

A)continental drift
B)natural selection
C)weather
D)mutation

A)Mutations occur in response to environmental pressures.
B)Mutations are more common in slowly growing organisms.
C)Mutations appear without regard to environmental pressures.
D)Several mutations must occur at one time for a new phenotype to appear.

A)nonrandom mating.
B)allele frequency.
C)genetic drift.
D)mutation.

A)0.2
B)0.4
C)0.64
D)0.8
D) The frequency of the D allele is 0.2. What is the frequency of the d allele?

A)genetic drift.
B)the founder effect.
C)a bottleneck.
D)descent from a common ancestor.

A)evolve into the same species despite the fact that they are members of separate populations.
B)merge into one continuous population because of reversals in continental drift.
C)evolve both analogous and homologous characteristics.
D)evolve similar structures in response to similar environmental challenges.

A)a chameleon changing colors as it moves from a leaf of one color to a leaf of another color.
B)increased resistance of bacteria to an antibiotic that is used to kill them.
C)chimpanzees learning sign language.
D)humans teaching dogs to obey certain commands.

A)50
B)100
C)200
D)400

A)0.1
B)0.3
C)0.5
D)0.7

A)genotypes
B)allele frequencies
C)bottlenecks
D)phenotypes

A)bottleneck.
B)gene flow.
C)genetic drift.
D)mutation.

A)evolved from a lineage of birds other than finches that ate insects.
B)learned their habits from local birds.
C)switched to insects because they tasted better than their usual food.
D)fill roles that birds other than finches would fill in other places.

A)convergent evolution.
B)divergent evolution.
C)disruptive selection.
D)directional selection.

A)chance events alter the gene pool of a population.
B)new individuals contribute their alleles to the gene pool of a population.
C)alleles that make an individual more successful move from one population to another.
D)crossing-over creates new combinations of alleles during gamete formation.

A)Pollen from a population A plant lands on the same plant (mating with itself).
B)Pollen from a population A plant lands on another population A plant.
C)Pollen from a population A plant lands on a population B plant.
D)Pollen from a population B plant lands on a population B plant.

A)No, because evolution acts upon phenotypes.
B)Yes, because evolution acts upon phenotypes.
C)Yes, because mutations do contribute to evolution
D)No, because mutations do not contribute to evolution.

A)1 to 0.75.
B)0 to 0.25.
C)0 to 0.75.
D)1 to 0.25.

A)homologous, because they evolved from the same body part
B)analogous, because birds' flight requires feathers and bats use skin; both are wings, but they evolved differently
C)both; they are homologous because they both evolved from a front appendage, but analogous because they evolved differently
D)neither, because birds and bats do not share a recent common ancestor

A)mutation
B)gene flow
C)stable environmental conditions
D)sexual selection

A)stopped evolving at different times in Earth's history.
B)evolved from different ancestors.
C)cannot breed.
D)faced different environmental challenges during evolutionary time.

A)Mutation results in the formation of new alleles, and sexual reproduction results in new combinations of alleles.
B)New genes are introduced into a population when members of that population mate with members of other species and produce offspring.
C)Genetic variation is inherited by the next generation of a population.
D)Genetic drift, gene flow, and/or natural selection cause allele frequencies to change over time.

A)Natural selection increases the frequency of alleles that contribute to survival, but sexual selection may increase the frequency of alleles that are not beneficial to survival.
B)Natural selection contributes to genetic drift, but sexual selection contributes to gene flow.
C)Natural selection is more random than sexual selection.
D)Natural selection increases the fitness of an allele, but sexual selection increases the dimorphism of an allele.

A)makes the genetic composition of the two populations more similar.
B)eliminates harmful alleles.
C)magnifies the effects of genetic drift.
D)creates genetic differences between the populations.

A)the inheritance of alleles accumulated during the lifetime of an individual.
B)differences in genotypes between the individuals in a population.
C)the accumulation of mutations in somatic cells (as opposed to gametes).
D)the formation of new combinations of alleles during asexual reproduction.

A)as a result of genetic drift.
B)when an individual migrates between two otherwise isolated populations of a species.
C)as a result of mutations in one population but not in another.
D)when individuals within a population interbreed.

A)genetic drift.
B)natural selection.
C)gene flow.
D)sexual selection.

A)Yes. UV light is always present outside and can produce both favorable and harmful mutations in skin cells. Only the favorable mutations will be passed on to the next generation.
B)Yes. A mutation in the skin cell will result in an organism that is better protected from the sun. This individual will be more likely to survive and pass on this mutation to the next generation.
C)No. Only mutations in gametes will be passed on to the next generation. Only mutations that are passed on to offspring contribute to evolution.
D)No. Only mutations that have a favorable adaptive quality will be passed on to the next generation. UV light produces only harmful mutations.

A)gene flow.
B)genetic drift.
C)natural selection.
D)mutation.

A)may be harmful to the individual's survival but is always beneficial to its reproductive rate.
B)are always beneficial to the individual's survival but may be harmful to its reproductive rate.
C)are always beneficial to both the individual's survival and reproductive rate.
D)may be harmful to both the individual's survival and reproductive rate.

A)a changing environment
B)an organism that exhibits a rapid rate of mutation
C)an organism that reproduces very slowly
D)the immigration of individuals carrying a new allele that significantly increases reproductive success

A)mutation.
B)a change in an organism's behavior.
C)natural selection.
D)common descent.

A)gene mutation within, or between, populations
B)chance evolutionary change occurring in small populations
C)natural selection acting on large populations
D)shifts in allelic frequencies due to mutation

A)prevent the development of nonheritable mutations in
B)introduce genetic variation back into
C)induce stabilizing selection in
D)cause genetic drift in

A)less important because there is less variation with which to work.
B)less important because only a few individuals do all the breeding.
C)more important because of a smaller gene pool.
D)more important because of the absence of competition.

A)horizontal gene transfer.
B)gene flow.
C)founder effect.
D)a bottleneck.

A)Natural selection requires variation in the population.
B)An individual that is better adapted than others in a population will always be more reproductively successful.
C)Genetic drift causes little evolutionary change in large populations.
D)Evolution involves a change of frequency of alleles in the gene pool.

A)genetic drift.
B)mutation.
C)natural selection.
D)gene flow.

A)Pond A; the fisherman has a greater likelihood of completely removing alleles from the gene pool by taking a fish from the smaller population.
B)Pond A; fewer fish are able to move into a small pond and find mates.
C)Pond B; the fisherman is more likely to catch a fish that is undergoing evolution in a bigger population.
D)Pond B; the process of evolution occurs more slowly in large populations and removing a fish speeds up the process.