Deck 13: How Populations Evolve

A) There is a great deal of variation for the trait (barking).
B) The tendency to bark is not a heritable trait.
C) The selection was artificial, not natural, so it did not produce evolutionary change.
D) Quiet dogs have fewer pups than barkers.

A) Lyell
B) Wallace
C) Aristotle
D) Malthus

A) Earth's surface is shaped mainly by occasional catastrophic events.
B) Meteorite impacts may have been a major cause of periodic mass extinctions.
C) Earth's surface is shaped by natural forces that act gradually and are still acting.
D) The processes that shape Earth today are very different from those that were at work in the past.

A) genetics.
B) ecology.
C) evolution.
D) metabolism.

A) Species change over time.
B) Living species have arisen from earlier life-forms.
C) Descent with modification occurs through inheritance of acquired characteristics.
D) Descent with modification occurs by natural selection.

A) Whether an organism survives and reproduces is almost entirely a matter of random chance.
B) Heritable traits that promote successful reproduction should gradually become more common in a population.
C) Populations produce more offspring than their environment can support.
D) Organisms compete for limited resources.

A) resembled species on the nearest mainland.
B) resembled species in Europe.
C) resembled species from Australia.
D) were identical to South American species.

A) Natural selection depends on the local environment at the current time.
B) Natural selection starts with the creation of new alleles that are directed toward improving an organism's fitness.
C) Natural selection and evolutionary change can occur in a short period of time (a few generations).
D) Natural selection can be observed working in organisms alive today.

A) molecular biology
B) comparative anatomy
C) geographic distribution
D) paleontology

A) an example of a trait that is poorly adapted.
B) the outcome of a trade-off: Webbed feet perform poorly on land but are very helpful in diving for food.
C) an example of a trait that has not evolved.
D) a curiosity that has little to teach us regarding evolution.

A) It is fully decomposed by bacteria and fungi.
B) It is buried in fine sediments at the bottom of a lake.
C) It gets trapped in sap.
D) It is frozen in ice.

A) Charles Lyell
B) Thomas Malthus
C) Godfrey Hardy
D) Gregor Mendel

A) species evolve through natural selection and other mechanisms.
B) an individual's use of a body part causes it to further evolve.
C) species are fixed (permanent) and perfect.
D) the best evidence for change within species is seen in fossils.

A) artificial selection.
B) natural selection.
C) genetic drift.
D) inheritance of acquired characteristics.

A) experiments in artificial selection
B) anatomical or molecular homologous structures
C) the number of genes present in an organism
D) an overall assessment of general similarities between organisms

A) reproductive success influenced by inherited characteristics
B) inheritance of acquired characteristics
C) change in response to need
D) a process of constant improvement, leading eventually to perfection

A) Yes; the wheat probably evolved better cold tolerance over time through inheritance of characteristics the individuals gained during their lifetime.
B) No, because Lysenko took his wheat seeds straight to Siberia instead of exposing them incrementally to cold.
C) No, because there was no process of selection based on inherited traits. Lysenko assumed that exposure could induce a plant to develop additional cold tolerance and that this tolerance would be passed to the plant's offspring.
D) Yes, because this is generally the method used by plant breeders to develop new crops.

A) The currently available fossil record shows that the earliest fossils of life are about 3.5 billion years old.
B) The currently available fossil record shows that younger strata were laid down on top of older strata.
C) The currently available fossil record documents gradual evolutionary changes that link one group of organisms to another.
D) The currently available fossil record shows that the first life-forms were eukaryotes.

A) the wing of a bat and the scales of a fish
B) the wing of a bird and the front legs of a horse
C) the antennae of an insect and the eyes of a bird
D) the wing of a bat and the wing of a butterfly

A) q or p.
B) p2.
C) 2pq.
D) 2p.

A) genetic drift
B) gene flow
C) natural selection
D) the founder effect

A) gene flow.
B) mutation.
C) the founder effect.
D) natural selection.

A) records of breeding in domesticated animals.
B) records of lineages in humans (also known as a family tree).
C) evidence-based hypotheses regarding our understanding of patterns of evolutionary descent.
D) groupings of organisms based on overall similarity.

A) founder effect
B) bottleneck effect
C) high rates of mutation
D) natural selection

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

A) p
B) q
C) 2pq
D) q2

A) intersexual selection.
B) intrasexual selection.
C) disruptive selection.
D) stabilizing selection.

A) natural selection.
B) gene flow.
C) the bottleneck effect.
D) the founder effect.

A) Only the strongest survive.
B) The strong eliminate the weak in the race for survival.
C) Organisms change by random chance.
D) Heritable traits that promote reproduction become more frequent in a population from one generation to the next.

A) directional selection
B) stabilizing selection
C) a bottleneck effect that resulted in low genetic diversity
D) a high rate of gene flow

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

A) an individual's traits change in response to environmental factors.
B) a community of organisms changes due to the extinction of several dominant species.
C) a new species arises from an existing species.
D) a population's allele frequencies change over a span of generations.

A) a small population size
B) little gene flow with surrounding populations
C) a tendency on the part of females to mate with the healthiest males
D) mutations that alter the gene pool

A) disruptive selection.
B) directional selection.
C) stabilizing selection.
D) sexual selection.

A) (0.02)2 = 0.0004
B) 0.02
C) (0.98)2 = 0.9604
D) 2(0.02 × 0.98)= 0.0392

A) a group of individuals of the same species that live in the same area and interbreed.
B) all individuals of a species, regardless of location or time period in which they live.
C) a group of individuals of different species living in the same place at the same time.
D) a group of individuals of a species plus all of the other species with which they interact.

A) p will increase; the dominant allele will eventually take over and become most common in the population.
B) p will neither increase nor decrease; it will remain more or less constant under the conditions described.
C) p will decrease because of genetic drift.
D) p will fluctuate rapidly and randomly because of genetic drift.

A) Assuming that no new birds come to the island and no mutations occur, future generations of this population will contain both green and yellow birds.
B) The hurricane has caused a population bottleneck and a loss of genetic diversity.
C) This situation illustrates the effect of a mutation event.
D) The 10 remaining birds will mate only with each other, and this will contribute to gene flow in the population.

A) mutation.
B) chromosomal duplication.
C) genetic drift.
D) natural selection.

A) a harmful allele in an asexual, haploid population
B) a harmful recessive allele in a sexual, diploid population
C) a harmful recessive allele in a sexual, polyploid population
D) any harmful allele, regardless of the system of inheritance in a population

A) Dogs' DNA mutated so that they could eat wheat, rice, barley, corn, and potatoes.
B) Some wolves may have had variants in their digestion that allowed them to eat wheat, rice, barley, corn, and potatoes and so were able to survive with humans.
C) Being around humans represented an advantage, so wolves were able to take advantage of that by changing their digestion to be able to eat wheat, rice, barley, corn, and potatoes.
D) Dogs were created at the same time as wolves.

A) Butterflies that stored the chemicals were never eaten by predators, so those butterflies survived.
B) Butterflies developed a mutation that led them to be able to store the chemical because they needed to avoid being eaten.
C) Milkweed plants wanted the butterflies to ingest the chemical so they would no longer feed on the plant, but the butterflies fooled the milkweed by storing the toxic chemicals.
D) Any butterfly allele that allowed milkweed toxin storage would be likely to persist because butterflies that had it were more likely to survive.

A) She should save the drug for later, because if she keeps taking it the bacteria will evolve resistance.
B) She should save the drug for use the next time the illness strikes.
C) She should save the drug because antibiotics are in short supply, and she may need it to defend herself against a bioterrorism incident.
D) She should continue taking the drug until her immune system can completely eliminate the infection. Otherwise, some bacteria may remain in her system, and they will probably be resistant.

A) An individual who has learned how to survive cold winters has become adapted to the cold.
B) A population that has an increase in frequency of alleles for thicker fur has become adapted to the cold.
C) Adaptation results when cold temperatures cause mutations for longer fur.
D) Adaptation is possible when all the alleles in a gene pool are the same.

A) intersexual selection.
B) artificial selection.
C) disruptive selection.
D) stabilizing selection.

A) Some blue alleles are always hidden in heterozygotes.
B) The population is likely in Hardy-Weinberg equilibrium for that locus.
C) Brown-eyed people sometimes have a blue-eyed parent.
D) People with brown eyes tend to choose mates with brown eyes, and blue-eyed people tend to choose mates with blue eyes.

A) lungfishes and amphibians
B) amphibians and lizards
C) mammals and crocodiles
D) lizards and ostriches

A) Because they are all genetically alike, they will all remain alike even though the ponds are different.
B) Because each population started off genetically identical, any mutation that occurs in one pond will also occur in the others.
C) Because the ponds are different and the populations are likely to experience different mutations, the populations will likely diverge evolutionarily, but only over many generations.
D) The increase in genetic diversity caused by sexual reproduction will promote evolutionary divergence over time.

A) The allele for Tay-Sachs is always selected against.
B) This situation is an example of heterozygote advantage if tuberculosis is present in a population.
C) This situation is an example of disruptive selection.
D) Heterozygotes will be more fit than either homozygote regardless of environmental conditions.

A) Dominant alleles generally increase in frequency over time.
B) The recessive alleles were all masked by the dominant alleles.
C) Directional selection favored plants with notched leaves.
D) Genetic drift caused a steady movement toward a greater proportion of plants with notched leaves.

A) The population is in Hardy-Weinberg equilibrium because the number of B alleles is equal to the number of b alleles.
B) The population is in Hardy-Weinberg equilibrium because half of the heterozygotes are B and half are b.
C) The population is not in Hardy-Weinberg equilibrium because p2 and 2pq are different.
D) The population is not in Hardy-Weinberg equilibrium because the genotype frequency of bb is greater than it would be in equilibrium.

A) They evolve through natural selection.
B) They evolve through genetic drift and other chance processes.
C) They evolve to be more useful by taking on new functions.
D) They evolve by gradually being eliminated from the gene pool.

A) There are breeds with long ears and breeds with short legs, but no breeds with both.
B) There does not seem to be any genetic variation in sense of smell.
C) Artificial selection is artificial and cannot change the genetics of a breed like natural selection.
D) Most dogs with black fur have long legs.

A) Fins evolved so that fish could swim better.
B) Fins came about because animals couldn't live in water without them.
C) Fins are an adaptation that aid in swimming.
D) Fins resulted from a mutation caused by a movement from land to water.

A) stabilizing selection, changing the average color of the population over time
B) directional selection, favoring the average individual
C) directional selection, changing the average color of the population over time
D) disruptive selection, favoring the average individual

A) hospital, where most of the bacteria are probably already weakened by antibiotics in the environment.
B) livestock barn where the animals have been treated with antibiotics.
C) big city where antibiotics are routinely prescribed by doctors.
D) remote, sparsely populated area where the bacteria have not been exposed to antibiotic drugs.

A) Because they actually would not be beneficial to the fitness of individuals who possessed them. Natural selection always produces the most beneficial traits for a particular organism in a particular environment.
B) Because every time they have arisen before, the individual mutants bearing these traits have been killed by chance events. Chance and natural selection interact.
C) Because these variations have probably never appeared in a healthy human. As tetrapods, we are pretty much stuck with a four-limbed, two-eyed body plan; natural selection can only edit existing variations.
D) Because humans are a relatively young species. If we stick around and adapt for long enough, it is inevitable that the required adaptations will arise.

A) Natural selection is a positive force, so it does not eliminate alleles.
B) In populations where endemic malaria is present, heterozygotes have an important advantage: They are resistant to malaria and therefore are more likely to survive and produce offspring that carry the allele.
C) Mutations keep bringing the allele back into circulation.
D) Natural selection occurs very slowly, but elimination of the sickle-cell allele is expected to occur soon.

A) eliminate rare alleles and favor whichever allele is initially most frequent.
B) maintain two phenotypes in a dynamic equilibrium in a population.
C) produce random changes in allele frequencies.
D) stimulate new mutations.

A) being homozygous.
B) sexual selection.
C) genetic drift.
D) heterozygous advantage.

A) Because oxygen was low where these pupfish lived, a new allele for an effective blood pigment arose.
B) This population was lucky to have an individual with a random mutation for an effective blood pigment, and the frequency of this allele was increased in subsequent generations through natural selection.
C) The ancestral population probably had this type of blood pigment, but it was lost through genetic drift in the other 29 populations.
D) The other populations did not need this pigment, so they did not evolve it.

A) The frequency of genotypes reached equilibrium.
B) New genes entered the population through migration.
C) The isolated populations had restricted gene pools.
D) Each new species contains all the original genotypes of the larger populations.

A) nonrandom mating.
B) genetic drift.
C) a population in Hardy-Weinberg equilibrium.
D) gene flow between populations.

A) a decrease in genetic variation in a population of mice.
B) the appearance of a new allele for darker color in a population of mice.
C) a shift in the range of genetic variation in a population of mice.
D) a lack of genetic variation for light fur color in the original population of mice.

A) Females prefer males that spend little time in courtship.
B) Male fish spend less than a minute courting females that do show a preference toward them.
C) Males generally spend more time courting females that show an interest in them (demonstrate a preference).
D) The redness of a male's throat predicts how much a female is likely to prefer him.

A) the bottleneck effect.
B) directional selection.
C) random mating.
D) Hardy-Weinberg equilibrium.