Deck 4: Heredity and Evolution

A)dominant.
B)codominant.
C)recessive.
D)homozygous dominant.
E)segregated.

A)were heterozygous for the allele for tallness.
B)were heterozygous at the locus-controlling height.
C)could NOT be crossed with short plants.
D)were homozygous for the allele for shortness.
E)were homozygous for the allele for tallness.

A)developed theories of evolutionary change.
B)discovered the structure of the DNA molecule.
C)studied characteristics that are influenced by several genetic loci.
D)discovered the fundamental principles of how traits are inherited.
E)developed the theory of inheritance of acquired characteristics.

A)ABO blood type
B)Marfan syndrome
C)Achondroplasia
D)Phenylketonuria
E)Skin color

A)6
B)4
C)3
D)2
E)5

A)3/4
B)1/2
C)All
D)1/4
E)2/3

A)3/4
B)1/2
C)All
D)1/4
E)2/3

A)principle of segregation.
B)principle of independent assortment.
C)concept of dominance.
D)concept of codominance.
E)blending theory of inheritance.

A)3/4
B)1/2
C)All
D)1/4
E)2/3

A)genotype.
B)phenotype.
C)phenotypic ratio.
D)genotypic ratio.
E)independent assortment.

A)phenotype.
B)homozygosity.
C)recessiveness.
D)phenotypic ratio.
E)genotype.

A)15 to 1.
B)3 to 1.
C)1 to 1.
D)4 to 1.
E)5 to 1.

A)published his results and won the Nobel Prize for his discoveries.
B)was trained as a geneticist.
C)died before the importance of his research was recognized.
D)was a professor at the University of Vienna.
E)never published his work.

A)all the offspring were tall.
B)half the offspring were tall, the other half were short.
C)all the offspring were short.
D)the offspring were intermediate in height relative to the two parent plants.
E)about 90 percent were tall, but the rest were short.

A)3/4
B)All
C)1/4
D)2/3

A)9/16
B)8/16
C)12/16
D)3/16
E)1/16

A)They are simpler.
B)Plants don't have alleles.
C)There are no differences because the basic principles are the same.
D)There are no Mendelian traits in humans.
E)The number of chromosomes is different; therefore, the genetic principles are different.

A)two copies of the recessive allele.
B)two copies of the dominant allele.
C)an autosomal trisomy.
D)a recessive allele on the X chromosome only.
E)a recessive allele on the Y chromosome only.

A)usually cause the underproduction of an enzyme.
B)always produce the most desirable phenotype.
C)can mask the expression of other alleles at the same locus.
D)are always the most common allele in a population.
E)were discovered by Charles Darwin.

A)are discrete.
B)have a continuous range of expression.
C)are controlled by only one genetic locus.
D)include the ABO blood type system and cystic fibrosis.
E)are also called Mendelian traits.

A)have their loci on all chromosomes.
B)are expressed more often in females than in males.
C)are expressed in females in the same fashion as autosomal traits.
D)are carried mainly on the Y chromosome.
E)includes albinism.

A)Stature
B)Skin color
C)Eye color
D)ABO blood type
E)Hair color

A)BB
B)OO
C)BO
D)AB
E)none of these

A)Natural selection
B)Recombination
C)Mutation
D)Migration
E)Genetic drift

A)recessiveness.
B)codominance.
C)dominance.
D)homozygosity.
E)X-linkage.

A)MC1R
B)OCA2
C)DELTA23
D)FOXP2
E)HOX

A)are governed by several genetic loci.
B)are more likely to have identifiable loci than polygenic traits.
C)have continuous distributions.
D)can be described by statistics such as the average and standard deviation.
E)have phenotypic expressions that are often the result of genetic and environmental interactions.

A)They are governed by more than one genetic locus.
B)Their expression is often influenced by genetic/environmental interactions.
C)They account for most observable phenotypic variation in humans.
D)They are not affected by environmental factors.
E)They are continuous.

A)the appearance of new species.
B)the change from one species to another in one generation.
C)a change in allele frequencies from one generation to the next.
D)any type of genetic mutation.
E)genetic drift.

A)occur in a gamete.
B)be beneficial.
C)occur in a somatic cell.
D)result in additional chromosomes.
E)be a point mutation only.

A)genetic drift followed by migration.
B)natural selection followed by migration.
C)recombination followed by mutation.
D)variation followed by natural selection.
E)mutation and gene drift.

A)Type O
B)Type AB
C)Type A
D)Type AO
E)A codominant type

A)are governed by more than one genetic locus.
B)occur only in some people.
C)are always dominant.
D)are discrete or discontinuous.
E)are always recessive.

A)4
B)2
C)3
D)6
E)1

A)1/16
B)1/8
C)1/4
D)3/4
E)1/2

A)1/3
B)1/2
C)3/4
D)1/4
E)1/8

A)codominance.
B)blending.
C)recessiveness.
D)dominance.
E)polygenic inheritance.

A)macroevolution.
B)plieotropy.
C)microevolution.
D)speciation.
E)natural selection.

A)Polygenic
B)Dominant
C)Mendelian
D)Recessive
E)Pleiotropic

A)mutations.
B)genetic drift.
C)founder effect.
D)migration.
E)natural selection.

A)production of new alleles.
B)production of new genetic material.
C)chance loss of alleles in a population.
D)exchange of genes between populations.
E)differential reproductive success of individuals.

A)sickle-cell anemia.
B)genetic drift.
C)migration.
D)increased mutation rates.
E)natural selection.

A)There is no geographic correlation between the distribution of the Hb^S allele and malaria.
B)Heterozygotes have greater resistance to malaria than homozygous individuals.
C)The malarial parasite does not reproduce very well in the red blood cells of heterozygotes.
D)Malaria is caused by the Plasmodium parasite.
E)The Hb^S mutation probably occurs occasionally in all human populations.

A)migrations.
B)an increase in population.
C)genetic diseases.
D)mutations.
E)a small population.