Deck 11: Observing Patterns in Inherited Traits

A)have corresponding alleles on homologous chromosomes.
B)are usually the result of the fusion of two haploid gametes.
C)have two sets of chromosomes.
D)have pairs of homologous chromosomes.
E)have all of these qualities.

A)wrinkled seed
B)yellow pod
C)dwarf plant height
D)yellow seed
E)white flower

A)P₁
B)G₁
C)A₁
D)F₁
E)F₂

A)He was simply lucky to work out the laws of genetics.
B)He focused on contrasting phenotypic characteristics.
C)He demonstrated that the blending theory of inheritance was wrong.
D)He kept exact mathematical data and was one of the first scientists to analyze results numerically.
E)He was a monk, a science teacher, and a plant breeder.

A)genes.
B)dominant.
C)loci.
D)alleles.
E)recessive.

A)flowers
B)petals
C)pistils
D)stamens
E)stigmas

A)kinetochores.
B)alleles.
C)autosomes.
D)loci.
E)chromatids.

A)the fruit fly
B)the rose
C)the garden pea
D)the chicken
E)E.coli

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

A)All people have about the same number of melanosomes.
B)The color of the melanosome dictates skin color.
C)Excess sunlight decreases melanin.
D)White Europeans lack melanosomes.
E)All of these are true.

A)AaBB
B)aABB
C)aaBB
D)aaBb
E)AaBb

A)He did not know about chromosomes.
B)He was not aware of Darwin's theory of evolution.
C)He was well trained in agriculture and mathematics.
D)His work was widely recognized..
E)His work established a basic understanding of the principles of heredity.

A)carpels
B)stamen
C)eggs
D)fertilized pea seeds
E)none of these are correct

A)Darwin did not know what mechanisms were responsible for the variation he saw.
B)The blending theory of inheritance provides excellent support for evolution.
C)Darwin received Mendel's paper but did not understand its significance.
D)The explanation for genetics had no implications for evolution.
E)All of these are true.

A)all genetic traits bred true.
B)only certain forms of domesticated plants and animals bred true.
C)the characteristics of parents were blended in the offspring.
D)the mother contributed all the hereditary material for the new generation.
E)the father contributed all the hereditary material for the new generation.

A)100
B)40
C)10
D)1
E)1000

A)true-breeding varieties were available.
B)the plant can self-fertilize.
C)it can be cross-fertilized.
D)true-breeding varieties were available, and it can be cross-fertilized.
E)true-breeding varieties were available, the plant can self-fertilize, and it can be cross-fertilized.

A)used only pure-breeding parents.
B)examined several different traits at the same time.
C)kept careful records and analyzed the data statistically.
D)worked on plants rather than animals.
E)confirmed the blending theory of inheritance.

A)a recessive gene.
B)an unmatched allele.
C)a sex chromosome.
D)the location of an allele on a chromosome.
E)a dominant gene.

A)LL.
B)Ll.
C)ll.
D)all of these.
E)none of these.

A)all intermediate forms
B)all tall
C)all dwarf
D)1/2 tall, 1/2 dwarf
E)3/4 tall, 1/4 dwarf

A)of two pure-breeding forms to find out which form of a gene is dominant.
B)between two unknown forms to determine their genotypes.
C)between an offspring and its homozygous dominant parent.
D)of an organism of dominant phenotype but unknown genotype to an individual that is homozygous recessive for that trait.
E)of two F₂ individuals to produce an F₃ generation.

A)AA x aa.
B)Aa x Aa.
C)Aa x aa.
D)AA x Aa.
E)none of these.

A)sex-linked
B)dominant
C)recessive
D)codominant
E)lethal

A)the genes for the traits he studied have to be located on the same chromosome.
B)the combination of gametes at fertilization has to be due to chance.
C)genes cannot be transmitted independently of each other.
D)only diploid organisms demonstrate inheritance patterns.
E)none of these apply.

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

A)be homozygous.
B)display the same phenotype as the RR parent.
C)display the same phenotype as the rr parent.
D)have the same genotype as the RR parent.
E)have the same genotype as the rr parent.

A)1/2
B)1/4
C)1/3
D)none (no chance of this offspring)
E)none of these answers is correct

A)concerns alleles governing two different traits.
B)applies only to linked genes.
C)applies only to sex-linked genes.
D)explains the behavior of a pair of alleles during meiosis.
E)none of these.

A)offspring.
B)zygotes.
C)homologous chromosomes.
D)gametes.
E)loci.

A)offspring genotypes.
B)parental genotypes.
C)gametes.
D)offspring phenotypes.
E)parental phenotypes.

A)two F₁ hybrids.
B)an F₁ hybrid and an F₂ offspring.
C)two parental organisms.
D)an F₁ hybrid and the homozygous dominant parent.
E)an organism of dominant phenotype but unknown genotype and an organism that is homozygous recessive for that trait.

A)one type of gamete with this one homozygous allele.
B)two types of gamete with this one homozygous allele.
C)a mixture of gametes with both homozygous and recessive alleles.
D)a single gamete with a single mutant allele.
E)none of these.

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

A)were pure-breeding.
B)appeared only in the first generation of a cross between two pure-breeding plants expressing contrasting forms of a trait.
C)disappeared after the second generation.
D)could be produced only if one of the parents expressed the recessive trait.
E)were none of these.

A)1/2 x 1/2.
B)25 percent.
C)one out of four.
D)1/2.
E)all of these EXCEPT 1/2.

A)the short-haired animal is pure-breeding.
B)the short-haired animal is not pure-breeding.
C)the long-haired animal is not pure-breeding.
D)the long-haired animal is pure-breeding.
E)none of these can be determined with two offspring.

A)P₁
B)H₁
C)A₁
D)F₁
E)F₂

A)parents.
B)genotypes.
C)phenotypes.
D)alleles.
E)genes.

A)produces homozygous offspring.
B)must produce a phenotype different from either pure-breeding parent.
C)results in the disappearance of the recessive traits in the first generation.
D)takes place only in the laboratory under precisely controlled conditions.
E)will result in the immediate formation of another pure-breeding variety.

A)Morgan
B)Mendel
C)Darwin
D)Cuvier
E)Flemming

A)one allele is always dominant to another.
B)hereditary units from the male and female parents are blended in the offspring.
C)the two hereditary units that influence a certain trait segregate during gamete formation.
D)each hereditary unit is inherited separately from other hereditary units.
E)all of these are true.

A)must both have different blood types.
B)must be A and B, but not AB.
C)must both be AB.
D)can be any blood type.
E)can have different blood types, but neither can be blood type O.

A)A
B)B
C)C
D)D
E)none of these

A)is not demonstrated in a monohybrid cross.
B)is illustrated by the behavior of linked genes.
C)indicates that the expression of one gene is independent of the action of another gene.
D)states that alleles for the same characteristic separate during meiosis.
E)is negated by the phenomenon of epistasis.

A)the genes were on the same chromosomes.
B)the P₁ generation was homozygous.
C)purple was dominant to white.
D)more than two traits were traced.
E)all of these are true.

A)pleiotropy.
B)multiple alleles.
C)incomplete dominance.
D)codominance.
E)multiple alleles and codominance.

A)Susan is right, and Craig must pay child support.
B)Craig is right and doesn't have to pay child support.
C)Susan cannot be the real mother of the child; there must have been an error made at the hospital.
D)it is impossible to reach a decision based on the limited data available.
E)none of these is true.

A)4
B)6
C)8
D)12
E)16

A)independent assortment
B)dominance
C)linkage
D)presence of two factors in parents and offspring
E)segregation of factors

A)type A mother and type B father
B)type A mother and type O father
C)type AB mother and type O father
D)type O mother and type O father
E)type O mother and type B father

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

A)Aa
B)Ab
C)AB
D)aB
E)ab

A)4.
B)6.
C)9.
D)undetermined.
E)3.

A)sex-linked genes.
B)linked genes.
C)incompletely dominant genes.
D)multiple alleles.
E)none of these.

A)All offspring with the same phenotype have the same genotype.
B)All offspring with the same genotype possess the same phenotype.
C)It is not possible to determine the genotype of some individuals by their phenotype.
D)It is possible to tell the genotype of some offspring by looking at their phenotypes.
E)Nine genotypes and four phenotypes are produced.

A)pure-breeding.
B)recessive.
C)hybrid.
D)dihybrid.
E)heterozygous.

A)pleiotropy
B)polygenic inheritance
C)complete dominance
D)codominance
E)a multiple allele system

A)some genes are linked together.
B)the two alleles controlling a trait are divided equally among the gametes.
C)alleles for different traits are inherited independently.
D)one of the pair of alleles is dominant to the other.
E)the crossing of two different homozygous forms will not produce any offspring in the first generation that will look like either of the parents.

A)the most common phenotype is drooping ears and barking.
B)all droopy-eared, silent offspring are pure-breeding.
C)the least common phenotype is drooping ears and barking.
D)there will be no phenotypes or genotypes that resemble the original parents.
E)there will be no offspring that resemble the F₁ generation.

A)dominance
B)recessiveness
C)incomplete dominance
D)pleiotropy
E)linkage

A)black and spotted pure-breeding forms
B)black and solid pure-breeding forms
C)red and solid pure-breeding forms
D)red and spotted pure-breeding forms
E)all of these

A)9:3:3:1.
B)100 percent of one phenotype.
C)1:1.
D)1:2:1.
E)none of these.

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

A)9:3:3:1.
B)1:1:1:1.
C)1:2:1.
D)3:1.
E)of none of these.

A)1
B)2
C)4
D)8

A)LL BB.
B)ll BB.
C)ll Bb.
D)ll bb.
E)LL bb.

A)complete dominance
B)incomplete dominance
C)multiple alleles
D)continuous variation
E)epistasis

A)black and solid.
B)black and spotted.
C)red and solid.
D)red and spotted.
E)none of these.

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

A)only AB
B)A and AB
C)B and AB
D)A, B, AB, and O
E)only O

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

A)Bb Ss x Bb Ss.
B)bb Ss x Bb Ss.
C)bb ss x Bb Ss.
D)bb Ss x Bb ss.
E)Bb ss x Bb ss

A)a mutation.
B)an X-linked gene.
C)an incompletely dominant gene.
D)a lethal gene.
E)chromosomal aberration.

A)one allele is not dominant to another allele.
B)the genotype can be determined by the phenotype.
C)the heterozygote is somewhat intermediate to the two homozygotes.
D)the intermediate phenotype may be the result of enzyme insufficiency.
E)all of these are true.

A)multiple alleles.
B)autosomal dominance.
C)codominance.
D)incomplete dominance.
E)codominance and incomplete dominance.

A)DD RR.
B)Dd RR.
C)Dd Rr.
D)dd RR.
E)dd Rr.

A)BB SS.
B)Bb SS.
C)Bb Ss.
D)BB Ss.
E)none of these.

A)blood type A, AB, or O, but not B.
B)blood type O only.
C)blood type A or B only.
D)blood type A, B, or O, but not AB.
E)any blood type other than A.