Deck 12: Mendel, Genes, and Inheritance

A)A dihybrid cross; a monohybrid cross
B)Epistasis; polygenic inheritance ​
C)A testcross; cross-pollination ​
D)Self-pollination; cross-pollination ​
E)A dihybrid cross; self-pollination ​

A)heterozygous
B)homozygous ​
C)self-fertilized ​
D)self-pollinated ​
E)recessive ​

A)The malformed red blood cells cannot transport oxygen.
B)The malformed red blood cells can block capillaries. ​
C)The malformed blood cells have a higher affinity for CO₂ than for oxygen. ​
D)The mutant hemoglobin polypeptide cannot bind O₂ due to a change in three amino acids. ​
E)More cells assume the sickle shape as oxygen concentration in the tissues increases. ​

A)heterozygous or homozygous dominant
B)heterozygous or homozygous recessive ​
C)homozygous dominant ​
D)homozygous recessive ​
E)heterozygous ​

A)RrMM * Rrmm
B)RRMM * rrmm ​
C)RrMm * RrMm ​
D)rrMM * RRmm ​
E)RrMm * rrmm ​

A)yellow is usually the dominant color, but sometimes green can be dominant
B)green is the dominant color ​
C)yellow is the dominant color ​
D)yellow is the recessive color ​
E)yellow and green are codominant ​

A)1/2
B)1/4 ​
C)1/8 ​
D)1/16 ​
E)1 ​

A)alleles; gene markers
B)genes; loci ​
C)alleles; genes ​
D)genes; alleles ​
E)gene markers; genes ​

A)RrMM * Rrmm
B)RRMM * rrmm
C)Rr * Rr ​
D)rr * RR ​
E)Rr * rr ​

A)P = X² + Y²
B)P = X²Y² ​
C)P = XY ​
D)P = X + Y ​
E)P = (X + Y)² ​

A)all white flowers in the F₁ generation
B)all purple flowers in the F₁ generation ​
C)all purple flowers in the F₁ generation but a lighter purple than in the parents ​
D)mostly purple flowers in the F₁ generation, with an occasional white flower ​
E)half of the plants having purple flowers and half having white flowers ​

A)1/2
B)1/4 ​
C)3/4 ​
D)1/8 ​
E)0 ​

A)(1/4)² + (1/5)² = (1/16)+ (1/25)= (25/400)+ (16/400)= 41/400
B)(1/4)+ (1/5)= (5/20)+ (4/20)= 9/20 ​
C)(1/4)²(1/5)² = (1/16)(1/25)= 1/400 ​
D)(1/4)(1/5)= 1/20 ​
E)(1/4 + 1/5)² = (5/20 + 4/20)² = (9/20)² = 81/400 ​

A)heterozygous; recessive
B)homozygous dominant; recessive ​
C)homozygous recessive; dominant ​
D)heterozygous; dominant ​
E)heterozygous; recessive ​

A)R-MM * R-mm
B)RRMM * rrmm ​
C)R-M- * R-M- ​
D)rrMM * RRmm ​
E)R-M- * rrmm ​

A)determine if a parent with a dominant trait is heterozygous or homozygous
B)determine which allele is dominant ​
C)determine if the progeny of an experimental cross will have a random assortment of alleles ​
D)prove an organism is true-breeding ​
E)cross an individual with a dominant phenotype with a homozygous dominant individual to prove the alleles are dominant ​

A)We inherit traits from only one parent.
B)Traits are inherited via a mixing of parental blood. ​
C)Parental chromosomes undergo recombination to produce blended chromosomes in their offspring. ​
D)Traits may skip a generation due to the blending of paternal and maternal phenotypes. ​
E)Paternal and maternal chromosomes separate independently in meiosis, creating gametes with a blend of paternal and maternal chromosomes. ​

A)gene; gametes
B)base; homozygous genes ​
C)nucleotide; genes ​
D)locus; homologous chromosomes ​
E)sister chromatid; homologous chromosomes ​

A)Characters are heritable characteristics; traits are variations of characters.
B)Traits are heritable characteristics; characters are variations of traits. ​
C)Characters are the unknown packages transferred to the next generation; traits result from this transfer. ​
D)Characters are passed to the next generation; traits are never passed to the next generation. ​
E)Characters and traits are synonymous in Mendel's writings. ​

A)genes on chromosomes always assort independently
B)paternal chromosomes determine the offspring's phenotype ​
C)maternal chromosomes determine the offspring's phenotype ​
D)genes and their alleles are carried on chromosomes ​
E)genes are carried on chromosomes and alleles are the product of gene expression ​

A)1/4
B)1/2 ​
C)3/4 ​
D)1
E)0

A)1/4
B)1/2 ​
C)3/4 ​
D)1 ​
E)0 ​

A)Cross plants having round peas with plants having wrinkled peas. Select round pea plants from the progeny because they are now true-breeding.
B)Cross plants having round peas with other plants having round peas. Do this for multiple generations. ​
C)Cross plants having round peas with plants having wrinkled peas. Select round pea plants from the progeny and do a testcross to determine which parental plants were homozygous dominant. ​
D)Cross plants having round peas with plants having wrinkled peas. This will tell you which round pea plants are homozygous dominant and are thus true-breeding. ​
E)It's not possible. You can only get true-breeding plants that have wrinkled peas. ​

A)1/4
B)1/2 ​
C)3/4 ​
D)1 ​
E)0 ​

A)1/4
B)1/2 ​
C)3/4 ​
D)1 ​
E)impossible to determine without knowing your father's genotype ​

A)Segregation
B)Independent Assortment ​
C)Punnett Squares ​
D)Chromosome Theory ​
E)Segregation and Independent Assortment ​

A)Plants with normal stem length have higher levels of gibberellic acid.
B)Plants with short stem length have higher levels of gibberellic acid. ​
C)Plants with normal stem length have the dominant allele Le that encodes an enzyme to degrade gibberellic acid.
D)Plants with short stem length have the dominant allele Le that encodes an enzyme to degrade gibberellic acid. ​
E)Plants with short stem length are homozygous recessive for the allele le that encodes an enzyme to degrade gibberellic acid. ​

A)achondroplasia
B)cystic fibrosis ​
C)albinism ​
D)sickle-cell anemia ​
E)Down syndrome ​

A)1/4
B)3/4 ​
C)9/16 ​
D)9/64 ​
E)27/64 ​

A)1/8
B)1/4 ​
C)3/8 ​
D)3/16
E)9/16

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

A)1/4
B)1/2 ​
C)3/4
D)1
E)0

A)all progeny will be homozygous for pea texture
B)you are conducting a dihybrid cross ​
C)you are conducting a reciprocal cross
D)all progeny will have wrinkled peas
E)you will be able to determine if the plant with round peas is homozygous or heterozygous for this trait

A)1/4
B)1/2 ​
C)3/4 ​
D)1 ​
E)0 ​

A)character
B)marker ​
C)locus ​
D)trait ​
E)homologue ​

A)0%
B)25% ​
C)50% ​
D)75%
E)100% ​

A)all are yellow and round
B)8 yellow and round: 8 green and wrinkled ​
C)9 green and wrinkled: 4 yellow and round: 3 green and round ​
D)9 green and round: 3 yellow and round: 3 yellow and wrinkled: 1 green and wrinkled ​
E)9 yellow and round: 3 green and round: 3 yellow and wrinkled: 1 green and wrinkled ​

A)1/3
B)1/4 ​
C)1/8 ​
D)1/18 ​
E)1/36 ​

A)25%
B)50% ​
C)75% ​
D)100% ​
E)25% if your three siblings are healthy; 75% if your siblings also have the disorder ​

A)incomplete dominance
B)codominance ​
C)epistasis ​
D)polygenic inheritance ​
E)pleiotropy ​

A)1/16
B)3/16
C)4/16 ​
D)9/16 ​
E)10/16 ​

A)1/16
B)3/8 ​
C)1/8 ​
D)1/4 ​
E)0 ​

A)100% pink
B)100% red ​
C)50% white, 50% red ​
D)25% red, 50% pink, 25% white ​
E)25% pink, 50% white, 25% red ​

A)3/4
B)9/64 ​
C)1/64 ​
D)27/64 ​
E)1/2 ​

A)type O only
B)type AB only ​
C)type A only ​
D)types A and B, not O ​
E)types A and AB ​

A)You father is homozygous for type B blood.
B)Your mother is heterozygous for type O blood. ​
C)Your father's genotype is I ^B i and your mother's genotype is ii . ​
D)Your father's genotype is I ^B I ^B and your mother's genotype is ii .
E)Your father's genotype is I ^A I ^B and your mother's genotype is ii . ​

A)incomplete dominance only
B)codominance only
C)dominance and codominance
D)dominance and incomplete dominance
E)dominance, codominance, and incomplete dominance

A)10
B)20 ​
C)25 ​
D)30 ​
E)50 ​

A)dominance
B)incomplete dominance ​
C)epistasis ​
D)pleiotropy ​
E)polygenic inheritance ​

A)0%
B)25% ​
C)50% ​
D)75% ​
E)100% ​

A)1/16
B)3/8 ​
C)1/8 ​
D)9/16 ​
E)0 ​

A)type O only
B)type B only ​
C)type A only ​
D)type AB only ​
E)types A, B, AB, and O ​

A)BBdd only
B)Bbdd only ​
C)bbDD only ​
D)bbDd only ​
E)BBdd and Bbdd ​

A)pink with pink
B)pink with red ​
C)red with white ​
D)pink with white ​
E)a true-breeding pink snapdragon cannot be created ​

A)0
B)1/16 ​
C)1/4 ​
D)1/2 ​
E)3/4 ​

A)0
B)1/4 ​
C)1/2 ​
D)3/4 ​
E)1 ​

A)9/16 black, 3/16 brown, 4/16 white
B)9/16 white, 3/16 brown, 4/16 black ​
C)9/16 black, 6/16 brown, 1/16 white ​
D)9/16 white, 6/16 brown, 1/16 black ​
E)All black mice ​

A)1/16
B)1/8 ​
C)1/4 ​
D)1/2 ​
E)0 ​

A)In incomplete dominance, the recessive allele cannot be detected; in codominance, the expression of the recessive allele is apparent.
B)In incomplete dominance, it is possible to detect the expression of a recessive allele; in codominance, both alleles contribute equally to the phenotype.
C)In codominance, it is possible to detect the expression of a recessive allele; in incomplete dominance, both alleles contribute equally to the phenotype. ​
D)In incomplete dominance, it is possible to detect the expression of the dominant allele; in codominance, two different genes contribute to a single phenotype. ​
E)The two terms are synonymous. ​

A)multiple alleles; epistasis
B)incomplete dominance; multiple alleles ​
C)polygenic inheritance; pleiotropy ​
D)pleiotropy; polygenic inheritance ​
E)incomplete dominance; pleiotropy ​

A)caused by a mutation to the same common allele
B)believed to be diseases carried on the Y chromosome ​
C)caused only by environmental factors ​
D)caused by a single gene mutation ​
E)considered to involve complex traits ​

A)Recombination via the synaptonemal complex occurred during mitosis.
B)Recombination via the synaptonemal complex occurred during meiosis. ​
C)The law of independent assortment applies to all alleles regardless of their arrangement on chromosomes. ​
D)Mendel was a good enough mathematician to design experiments that would result in the predicted ratios.
E)Independent assortment occurred during mitosis.

A)the environment
B)gene blending ​
C)epistasis ​
D)dihybrid crosses ​
E)pleiotropy ​

A)cystic fibrosis
B)albinism ​
C)sickle-cell anemia ​
D)achondroplasia ​
E)schizophrenia ​

A)only two alleles of the gene exist in the population
B)more than two alleles of the gene are present in any given individual ​
C)more than two alleles of the gene are present in the population ​
D)one or more of the alleles is epistatic to the other(s)​
E)the alleles must be incompletely dominant ​

A)epistasis
B)incomplete dominance ​
C)polygenic inheritance ​
D)multiple alleles ​
E)pleiotropy ​

A)quantitative phenotypes; quantitative trait markers
B)quantitative genotypes; quantitative trait loci ​
C)quantitative traits; quantitative trait markers ​
D)quantitative traits; quantitative trait loci ​
E)quantitative markers; quantitative trait markers ​

A)Multiple alleles control flood-tolerance.
B)The alleles for flood-tolerance and flood-intolerance are codominant.
C)The allele for flood-tolerance is incompletely dominant. ​
D)The allele for flood-intolerance is dominant, while the allele for flood-tolerance is recessive. ​
E)The allele for flood-tolerance is dominant, while the allele for flood-intolerance is recessive. ​

A)1000 genomes of closely related species, because animals exhibit disease symptoms more clearly than humans do
B)1000 genomes of closely related species, because it is easier to sequence animal genomes than human genomes ​
C)1000 human genomes, because this would give a better indication of the evolutionary history of disease-causing genes ​
D)1000 human genomes, because this would give a better indication of the link between specific human genes and genetic disorders ​
E)neither would be beneficial because human disease is almost entirely caused by environmental factors ​