Deck 3: The Modern Synthesis

A) whenever mutation occurs.
B) whenever allelic frequencies change from one generation to the next.
C) whenever genetic drift is eliminated.
D) Both a and

A) Natural selection
B) Hardy-Weinberg forces
C) Mutation
D) Random genetic drift

A) a = .2 and A = .8
B) a = .4 and A = .6
C) a = .5 and A = .5
D) a = .6 and A = .4

A) of blending inheritance.
B) genetic transmission involves faithful copying of the genes themselves and their reassembly into different combinations in zygotes.
C) mutation is constantly introducing new alleles, some of which will produce new phenotypes.
D) natural selection reduces variation.

A) primatology.
B) evolutionary ecology.
C) human variation.
D) population genetics.

A) discontinuous traits.
B) mating strategies.
C) maladaptations.
D) canalized behaviors.

A) AA = .2, Aa = 0, and aa = .8
B) AA = .40, Aa = .16, and aa = .44
C) AA = .04, Aa = .32, and aa = .64
D) AA = .40, Aa = .30, and aa = .60

A) Selection can produce change when no variation is present in a population.
B) Selection cannot change the frequency of different phenotypes.
C) The strength and direction of selection depend on the environment.
D) The strength of selection is determined by dominant alleles.

A) 25% aa, 50% Aa, and 25% AA
B) All AA
C) 4% aa, 16% Aa, and 64% AA
D) None of the above.

A) Hidden variation is not always present in continuously evolving traits.
B) Selection causes genotypic frequencies to reach equilibrium in one generation, and the distribution of phenotypes does not change.
C) Selection can lead to cumulative, long-term change.
D) Genetic variation is always expressed as phenotypic variation.

A) aa = 0, Aa = 1.0, and AA = 0
B) aa = .20, Aa = .60, and AA = .20
C) aa = .20, Aa = .50, and AA = .30
D) aa = .25, Aa = .50, and AA = .25

A) A = .6 and a = .4
B) A = .5 and a = .5
C) A = .3 and a = .7
D) A = .4 and a = .6

A) 30% AA, 60% Aa, and 10% aa
B) 60% A and 40% a
C) 60% AA, 120% Aa, and 20% aa
D) None of the above.

A) 50% A and 50% a
B) 0% A and 100% a
C) 25% A and 75% a
D) 33% A and 67% a

A) thought that inheritance was fundamentally discontinuous.
B) argued that Mendelian genetics supported Darwin's idea that adaptation occurs through the accumulation of small variations.
C) agreed that evolution proceeded by the gradual accumulation of small changes.
D) believed that genes had no discernible effect on phenotypes.

A) All AA individuals
B) All aa individuals
C) 50% AA and 50% aa individuals
D) 25% AA and 75% aa individuals

A) the combination of Mendelian and blending inheritance.
B) the combination of anthropology and biology.
C) the combination of modern genetics and Darwinism.
D) the combination of modern anthropology with animal behavior.

A) results from change in the environment only.
B) reflects change in the underlying genetic composition of a population.
C) cannot be passed from parent to offspring.
D) Both a and

A) can change allelic frequencies.
B) can cause evolutionary change.
C) can change genotypic frequencies.
D) both b and

A) males must cooperate with other males to guard females.
B) flexibility requires longer appendages.
C) males will sometimes make mistakes about the local sex ratio and behave inappropriately.
D) flexible males have to grow larger and therefore need more food.

A) every mutation results in adaptation.
B) directional selection is constantly working.
C) a considerable amount of variation is protected from selection.
D) the rates of mutation are very high.

A) to protect the females from harassment by other females.
B) to protect the females from predators.
C) to stop other males from mating with them.
D) to stop the females from eating.

A) mutation.
B) fixation.
C) hidden variation.
D) both a and

A) stabilizing
B) disruptive
C) directional
D) All of the above.

A) affects genotypic expression of characters.
B) tends to blur together the phenotypes associated with different genotypes.
C) does not direct selection.
D) has no effect on phenotype.

A) there are no environmental effects.
B) they are affected by alleles at more than one locus.
C) inheritance is blending rather than particulate.
D) there are only two alleles.

A) are affected by genes at only one locus.
B) have a large effect on the phenotype.
C) can be greatly affected by the environment.
D) do not help to explain how variation is maintained.

A) Mutation
B) Selection
C) Recombination
D) Gene flow

A) females are relatively abundant.
B) females are relatively scarce.
C) the sex ratio is skewed toward females.
D) the sex ratio is balanced.

A) behavioral canalization.
B) behavioral plasticity.
C) behavioral localization.
D) behavioral control.

A) there is hidden variation.
B) alleles for extreme phenotypes are not concentrated in any one individual.
C) there is no hidden variation.
D) both a and

A) increases genetic variation because adaptations are produced.
B) decreases genetic variation because the most adapted individuals transmit the most characters to the next generation.
C) decreases genetic variation if selection is directional but increases genetic variation if selection is stabilizing.
D) decreases genetic variation if selection is stabilizing but increases genetic variation if selection is directional.

A) selection can move a population beyond its initial range of variation.
B) there is plenty of hidden variation.
C) selection is weak.
D) Both a and b are correct.

A) hidden variation.
B) environmental variation.
C) sampling variation.
D) mutational variation.

A) Mutation
B) Selection
C) Recombination
D) Both a and c

A) genetic drift.
B) disequilibrium.
C) mutation.
D) hidden variation.

A) behavioral canalization.
B) behavioral plasticity.
C) behavioral localization.
D) both a and

A) the trait is more likely to occur in a smooth distribution.
B) natural selection cannot act on the character.
C) the environment is less likely to affect the character.
D) both a and c are correct.

A) There is blending during sexual reproduction.
B) Mutations are deleterious.
C) New variation is slowly added by mutation.
D) The genetic composition of offspring is a replica of their parents.

A) there is no genetic control of the behavior.
B) the behavior is seen in a variety of environments.
C) the behavior is seen in environments that are the same.
D) phenotypes vary.

A) uncorrelated characters.
B) equilibrium.
C) local adaptations.
D) population genetics.

A) cause isolated populations to become more similar to one another.
B) cause isolated populations to diverge from one another.
C) lead to genotyping of populations.
D) lead to karyotyping of populations.

A) a correlated response to selection.
B) disequilibrium.
C) physical constraints on natural selection.
D) fixation.

A) disequilibrium has occurred.
B) it has lost one of the two alleles that code for a character.
C) the mean value of a correlated character has changed.
D) mutation has added new variation to the population.

A) positively correlated
B) fixated
C) maladaptive
D) plastic

A) small populations.
B) large populations.
C) medium-size populations.
D) populations out of equilibrium.

A) natural selection does not change adaptations.
B) the compound eye is always superior to the camera-type eye.
C) the compound eye is a local optimum.
D) the camera-type eye is a local optimum.

A) changes in gene frequencies that are random with respect to adaptation.
B) adaptive changes in gene frequencies.
C) maladaptive changes in gene frequencies.
D) no change in gene frequencies.

A) affected reproductive success.
B) occurs only in stable environments.
C) was not passed down from father to son.
D) made behaviorally flexible males stronger.

A) behavioral plasticity
B) physical constraints
C) genetic drift
D) gene flow

A) a local optimum.
B) disequilibrium.
C) environmental drift.
D) genetic drift.

A) we are in perfect equilibrium with regard to such appetites.
B) these appetites are always adaptive.
C) such appetites were adaptive in ancient environments.
D) these appetites are adaptive in our modern environment.

A) indirectly increases a trait that has no effect on survival.
B) directly increases a trait that has a negative effect on survival.
C) is disruptive.
D) is stabilizing.

A) can occur because some genes affect more than one character.
B) change independently.
C) are always positively related.
D) make natural selection longer.

A) in places where the environment is stable.
B) in places where the environment is variable.
C) in colder climates.
D) in wetter climates.

A) optimal
B) fixed
C) developmental
D) genetic