Deck 10: Patterns of Inheritance

A)dominant.
B)recessive.
C)homologous.
D)homozygous.
E)heterozygous.

A)a gene.
B)a chromosome.
C)a chromatid.
D)a centromere.
E)a kinetochorE.

A)two identical sets of chromosomes.
B)two different sets of chromosomes.
C)one set of chromosomes.
D)one chromosome.
E)two chromosomes.

A)chromatids.
B)centromeres.
C)chromosomes.
D)alleles.
E)traits.

A)Charles Darwin.
B)Robert Hooke.
C)King George III.
D)Frederick Griffith.
E)Gregor Mendel.

A)the wild type.
B)the dominant population.
C)the recessive population.
D)the P generation.
E)the F1 generation.

A)they cannot be expressed in males.
B)they are masked by a dominant allele.
C)they cannot be expressed in females.
D)they cannot be expressed in successive generations.
E)they are lost by mutation.

A)the number of gametes in an individual.
B)the number of chromosomes in an individual.
C)the combination of alleles in an individual.
D)the genes an individual has.
E)the observable expression of the genes in an individual.

A)homologous.
B)heterozygous.
C)homozygous.
D)dominant.
E)recessivE.

A)develops slowly.
B)produces only a few offspring.
C)is easy to control which plants mate with each other.
D)has only a few traits that appear in two easily distinguishable forms.
E)All answers are correct.

A)recessive.
B)dominant.
C)homologous.
D)homozygous.
E)heterozygous.

A)homozygous.
B)heterozygous.
C)dominant.
D)recessive.
E)None of the answers are correct.

A)0%,because cystic fibrosis is not an inherited illness.
B)25%.
C)10%.
D)50%.
E)100%.

A)the number of gametes in an individual.
B)the combination of alleles in an individual.
C)the number of chromosomes in an individual.
D)the observable expression of the genes in an individual.
E)the genes an individual has.

A)did not grow and reproduce.
B)were always short.
C)were always tall.
D)were always medium height.
E)were mostly tall individuals and a few short individuals.

A)females only (mothers).
B)males only (fathers).
C)males and females (one allele from each parent).
D)males and females (two alleles from each parent).
E)None of the answers are correct.

A)each parent contributed a different allele for that trait.
B)each parent contributed the same allele for that trait.
C)one parent contributed two different alleles for that trait.
D)one parent contributed two copies of the same allele for that trait.
E)a mutation must have occurred.

A)homozygous.
B)homologous.
C)heterozygous.
D)dominant.
E)recessivE.

A)each parent contributed a different allele for that trait.
B)one parent contributed two different alleles for that trait.
C)each parent contributed the same allele for that trait.
D)one parent contributed two copies of the same allele for that trait.
E)a mutation must have occurred.

A)wild type generation.
B)F1 generation.
C)genotype.
D)F2 generation.
E)phenotypE.

A)are found on the same chromosome.
B)have no alleles.
C)are found in the same species.
D)have more alleles than usual.
E)are alleles that are found in different daughter cells.

A)would have had different results.
B)would have produced more offspring.
C)would have produced fewer offspring.
D)would have exhibited a typical phenotypic ratio of 9:3:3:1.
E)would have produced sterile offspring.

A)homozygous,one
B)homozygous,two
C)homologous,two
D)heterozygous,one
E)heterozygous,two

A)are chromosomes that are the same for both sexes.
B)include the Y chromosome in humans.
C)include the X chromosome in humans.
D)are the sex chromosomes.
E)All answers are correct.

A)homozygous for one gene.
B)heterozygous for two genes.
C)homozygous for two genes.
D)heterozygous for one gene.
E)None of the answers are correct.

A)three phenotypes.
B)two phenotypes.
C)one phenotype.
D)four phenotypes.
E)type A and type B blood types only.

A)codominance.
B)independent assortment.
C)linkage.
D)incomplete dominance.
E)polygenic.

A)dominant
B)codominant
C)recessive
D)homologous
E)heterologous

A)Tt x TT
B)Tt x tt
C)TT x TT
D)Tt x tt
E)Tt x Tt

A)three;one
B)one;one
C)one;two
D)two;one
E)one;three

A)heterozygous.
B)homozygous dominant.
C)homozygous recessive.
D)a clone of the other test cross individual.
E)heterozygous recessivE.

A)law of segregation.
B)law of random fertilization.
C)law of population dynamics.
D)law of crossing over.
E)law of independent assortment.

A)dominant.
B)recessive.
C)pleiotropiC.
D)codominant.
E)incomplete dominant.

A)is heterozygous.
B)is homozygous dominant.
C)is homozygous recessive.
D)has any known genotype.
E)is the wild typE.

A)pure breeding.
B)parental.
C)potential offspring.
D)recessive allele.
E)All answers are correct.

A)the wild type.
B)homozygous dominant.
C)heterozygous.
D)homozygous recessive.
E)mutant.

A)polygenic.
B)pleiotropic.
C)codominant.
D)recessive.
E)incomplete dominant traits.

A)law of independent assortment.
B)law of random fertilization.
C)law of population dynamics.
D)law of crossing over.
E)law of segregation.

A)1:1.
B)1:2.
C)2:1.
D)3:1.
E)1:3.

A)9:3:3:1.
B)2:1.
C)3:1.
D)1:1.
E)1:1:1:1.

A)appear only in males.
B)appear only in females.
C)appear in every generation.
D)seem to disappear in one generation,only to reappear in the next generation.
E)occur every third generation.

A)the X chromosome.
B)chromosome number 21.
C)the group of autosomes known as the SRY group.
D)chromosome number 22.
E)the Y chromosomE.

A)random fertilization.
B)linkage.
C)independent assortment.
D)crossing over.
E)mutation.

A)an X-linked recessive disorder causing a defective blood clotting protein.
B)an Y-linked recessive disorder.
C)a defective neuron response.
D)an X-linked dominant disorder causing a defective blood clotting protein.
E)an X-linked dominant disorder.

A)14 pairs of homologous chromosomes.
B)7 pairs of homologous chromatids.
C)14 pairs of homologous chromatids.
D)7 pairs of homologous chromosomes.
E)14 alleles.

A)a new reoccurring mutation.
B)an autosomal recessive disorder.
C)a chromosomal abnormality.
D)an autosomal dominant disorder.
E)having an extra set of chromosomes.

A)theoretically pass the allele for hemophilia to half of their offspring.
B)theoretically pass the allele for hemophilia to half of their daughters who become at least "carriers" for this disorder.
C)All answers are correct.
D)theoretically pass the allele for hemophilia to half of their sons who become hemophiliacs.
E)usually do not show any symptoms of hemophilia.

A)is homozygous for the disease.
B)cannot produce gametes.
C)is termed a carrier.
D)is termed a linkage group.
E)has the disease but cannot pass this disease to their offspring.

A)both have the same alleles for pea color.
B)both have the same gene for pea color.
C)have different genes for pea color.
D)have different loci for pea color.
E)have different numbers of chromosomes.

A)the father only,not the mother.
B)the mother only,not the father.
C)the mother or the father.
D)the parent who does not exhibit the disease.
E)All answers are correct.

A)the same genes but can have different alleles.
B)the same genes and alleles.
C)different genes and alleles.
D)different genes,but can have the same alleles.

A)genotypes and phenotypes.
B)phenotypes.
C)linkage maps.
D)genotypes.
E)metabolic maps.

A)only the dominant alleles on his X chromosome.
B)both the dominant and recessive alleles on his X chromosome.
C)only the homozygous recessive alleles on his X chromosome.
D)none of the alleles on his X chromosome.
E)only the homozygous dominant alleles on his X chromosomE.

A)green is dominant over yellow.
B)yellow and green are codominant.
C)yellow is incompletely dominant over green.
D)yellow is dominant over green.
E)color is random in pea plants.

A)linkage maps.
B)pedigree charts.
C)genotype maps.
D)Punnett squares.
E)bell-shaped curves.

A)the father only.
B)the mother only.
C)only the parent having the disease.
D)only one parent who is homozygous recessive for the disease.
E)both parents.

A)appear in every generation.
B)appear only in males.
C)appear only in females.
D)seem to disappear in one generation,only to reappear in the next generation.
E)occur every third generation.

A)the yellow parent was homozygous for the recessive allele.
B)the yellow parent was homozygous for the dominant gene.
C)the yellow parent was homozygous for the dominant allele.
D)the yellow parent was homozygous for the recessive gene.
E)the yellow parent was heterozygous.

A)close together.
B)far apart.
C)recessive genes.
D)dominant genes.
E)mutated genes.

A)Rr or Yy
B)RY or ry
C)RrYy
D)RY,Ry,rY,or ry
E)R or r

A)autosomal dominant.
B)X-linked recessive.
C)autosomal recessive.
D)X-linked dominant.
E)pleiotropic.

A)100%
B)75%
C)25%
D)0%
E)50%

A)50%
B)75%
C)25%
D)0%
E)100%

A)a phenotype.
B)a genotype.
C)an allele.
D)a gene.
E)a loci.

A)RR or yy
B)Ry
C)RY or ry
D)RRyy
E)R or y

A)multiple genes each with a single allele.
B)multiple genes each with multiple alleles.
C)a single gene with a single allele.
D)a single gene with multiple alleles.

A)autosomal recessive.
B)X-linked recessive.
C)X-linked dominant.
D)autosomal dominant.
E)pleiotropic.

A)Y only
B)Y or y
C)y only
D)Yy
E)YYyy

A)25%
B)75%
C)50%
D)0%
E)100%

A)Y only
B)Y or y
C)y only
D)Yy
E)YYyy

A)Height is a polygenic trait.
B)Height is influenced by an X-linked gene.
C)Height is influenced by environmental changes like improvements in diet.
D)Height is influenced by a Y-linked gene.
E)Height is influenced by crossing over.

A)I^A i,and I^B i
B)both are i i
C)I^A I^A,and I^B I^B
D)I^A i,and i i
E)i i,and I^B i

A)50%
B)75%
C)100%
D)25%
E)0%

A)Y only
B)y only
C)Yy
D)YYyy
E)Y or y

A)codominant
B)dominant
C)recessive
D)homozygous
E)incompletely dominant

A)a phenotype.
B)linkage.
C)a genotype.
D)a gene.
E)a loci.

A)25%
B)50%
C)0%
D)100%
E)75%

A)50%
B)75%
C)25%
D)0%
E)100%

A)50%
B)25%
C)0%
D)100%
E)75%