Deck 15: Evolution on a Small Scale

A) Too few humans have died of malaria to end the disease.
B) Multiple phenotypes survive in a balanced polymorphism.
C) Malaria is a recessive disease and few humans are ever sick.
D) Humans are protected from the malaria parasite.
E) The disease is under stabilizing selection.

A) Individual that has the longest canine teeth within the group
B) Individual that has the greatest number of breeding opportunities
C) Individual that has the best camoflauge to avoid predators
D) Individual that controls the largest territory
E) Individual that has the greatest number of offspring

A) That extreme individual will likely not survive and reproduce.
B) That extreme individual will be more likely to survive and reproduce.
C) That extreme individual will have neither an advantage nor a disadvantage than other individuals.
D) All phenotypes have equal likelihood of surviving and reproducing.
E) The average phenotype is less likely to survive and reproduce.

A) frequency of the dominant allele
B) frequency of the recessive allele
C) frequency of the heterozygotes
D) frequency of the homozygous dominants
E) frequency of the homozygous recessives

A) Crosses between biological species cannot produce fertile offspring, crosses between subspecies can produce fertile offspring.
B) Subspecies are "races" within a single species.
C) Gene flow exists among different subspecies but not among species.
D) Greater degrees of allelic frequencies exist between species than among subspecies.
E) Phenotypes of different species are easily recognizable; little to no phenotypic variation exists among subspecies.

A) genetic recombination
B) independent assortment of alleles
C) sexual reproduction
D) mutations
E) adaptation

A) Dark moths would continue to be the predominant phenotype.
B) Birds would now see the dark moths easier than the lighter color moths.
C) Dark- and light-colored moths would survive in equal numbers.
D) Both dark and light color moths would be preyed upon equally by birds.

A) A forest fire kills all plant life south of a highway.
B) Rabbits with longer fur survive the winter.
C) Insects resistant to insecticide survive crop dusting.
D) Colorful lizards living on brown leaves are most often eaten by predators.
E) Flowers with larger flowers attract more butterflies than smaller flowers.

A) no mutations
B) no natural selection
C) random mating
D) no genetic drift
E) no gene flow

A) Prokaryotes are smaller in size than eukaryotes.
B) Prokaryotes sexually reproduce, eukaryotes do not.
C) Eukaryotes sexually reproduce, prokaryotes do not.
D) Eukaryotes possess a nucleus, prokaryotes do not.
E) Prokaryotes are single-celled, eukaryotes are multicellular.

A) The recovered population is as likely to go extinct as is the population prior to the bottleneck.
B) The bottleneck subjected the population to directional selection.
C) The recovered population shows less genetic diversity that the population prior to the bottleneck.
D) The recovered population shows more genetic diversity than the population prior to the bottleneck.
E) The recovered population is more likely to go extinct as is the population prior to the bottleneck

A) genotype.
B) gene flow.
C) gene pool.
D) genome.
E) Hardy-Weinberg equilibrium.

A) Mutations must not occur.
B) Natural selection must not occur.
C) Random mating must not occur.
D) Genetic drift must not occur.
E) Assortative mating must not occur.

A) directional selection
B) stabilizing selection
C) disruptive selection
D) genetic drift
E) bottleneck effect

A) microevolution.
B) natural selection.
C) genetic drift.
D) nonrandom mating.
E) gene flow.

A) Both encounter a population crash.
B) Both involve a portion of a population becoming isolated.
C) Both involve a decrease in a population's genetic diversity.
D) Both affect the entire population.
E) Both are a type of natural selection.

A) disruptive selection.
B) stabilizing selection.
C) directional selection.
D) genetic drift.
E) bottleneck effect.

A) 0.5
B) 0.707
C) 0.25
D) 0.293
E) 0.1

A) 0.6
B) 0.4
C) 0.36
D) 0.15
E) 0

A) gene flow.
B) genetic drift.
C) Hardy-Weinberg equilibrium.
D) assortive mating.

A) individuals choose the most attractive mate.
B) there is no influence on mate choice.
C) breeding occurs between two different species.
D) breeding occurs between two different subspecies.
E) fertile offspring are not produced.

A) past gene flow.
B) a past bottleneck event.
C) a history of directional selection.
D) a history of few genetic mutations.
E) assortative mating.

A) 1/100,000
B) 1/1000
C) 1/10,000
D) 1/100
E) 1/10

A) 0.04
B) 0.2
C) 0.32
D) 0.64
E) 0.8

A) random mating.
B) assortative mating.
C) sexual selection.
D) gene flow.
E) natural selection.

A) most likely to survive.
B) most likely to reproduce.
C) most likely to migrate.
D) most likely to mutate.
E) most likely to be physically fit.

A) mutation
B) random mating
C) gene flow
D) natural selection
E) genetic drift

A) the gradual decrease in size over time.
B) the rapid decrease in size over time.
C) the gradual increase in size over time.
D) the rapid increase in size over time.
E) the extinction of other horse species.

A) stabilizing selection.
B) disruptive selection.
C) directional selection.
D) genetic drift.

A) A random small group of a bird population migrates to an island and then returns to breed.
B) A random large group of a bird population migrates to an island and then returns to breed.
C) A selected small group of a bird population migrates to an island and then returns to breed.
D) A random small group of a bird population migrates to an island and does not return to breed.
E) A random large group of a bird population migrates to an island and does not return to breed.

A) competition
B) predation
C) parasitism
D) weather
E) disease

A) stabilizing selection.
B) disruptive selection.
C) directional selection.
D) genetic drift.

A) genetic drift.
B) founder effect.
C) industrial melanism.
D) assortative mating.
E) stabilizing selection.

A) stabilizing selection.
B) disruptive selection.
C) directional selection.
D) genetic drift.

A) most individuals are white, few individuals are pink.
B) most individuals are white, few individuals are yellow.
C) most individuals are yellow, few individuals are pink.
D) most individuals are pink, few individuals are yellow or white.
E) most individuals are yellow and white, few individuals are pink.

A) directional selection to insecticide resistance in the insects.
B) stabilizing selection to insecticide resistance in the insects.
C) disruptive selection to insecticide resistance in the insects.
D) genetic drift to insecticide resistance in the insects.
E) no change in the insect population.

A) large populations.
B) small populations.
C) populations that mate randomly.
D) populations that are undergoing natural selection.
E) populations in which the frequency of mutations is high.

A) Hb^AHb^A
B) Hb^AHb^S
C) Hb^SHb^S
D) Hb^S Hb^s
E) Hb^A Hb^a

A) New individuals who are recessive for sickle cell will migrate into the area.
B) Spontaneous mutations will occur on Homozygous individuals that causes them to develop a recessive allele.
C) The recessive allele will not persist within the population. It is always weeded out.
D) Each generation some individuals will be born that by chance will inherit the recessive allele.
E) Individuals who are heterozygous for the sickle cell trait have an advantage in certain environments.

A) natural selection.
B) genetic drift.
C) founder effect.
D) industrial melanism.

A) Any evolution at any scale is considered microevolution.
B) Large-scale changes over a long period of time.
C) Small-scale changes over a long period of time.
D) Small-scale changes over a short period of time.
E) Changes of any scale within microorganisms.

A) natural selection.
B) genetic drift.
C) founder effect.
D) industrial melanism.

A) The recessive allele is responsible for susceptibility of the bacteria to the antibiotic.
B) The dominant allele is responsible for susceptibility of the bacteria to the antibiotic.
C) The recessive allele is responsible for resistance of the bacteria to the antibiotic.
D) The population is experiencing gene flow.
E) The population is experiencing disruptive selection.

A) An environment that has malaria.
B) An environment that is malaria free.
C) Environment that is exposed to a large amount of sunlight year round.
D) Environments that are degraded.
E) Cold and rainy environments favor the heterozygote.

A) directional selection.
B) stabilizing selection.
C) disruptive selection.
D) genetic drift.
E) mutation.