Deck 29: Heredity

A) Cystic fibrosis
B) Achondroplasia
C) Albinism
D) Tay-Sachs disease
E) Huntington's disease
A disorder of brain lipid metabolism.

A) Cystic fibrosis
B) Achondroplasia
C) Albinism
D) Tay-Sachs disease
E) Huntington's disease
An unremitting,fatal nervous system disease involving degeneration of the basal nuclei.

A) Homozygous
B) Sex chromosomes
C) Recessive
D) Genotype
Actual genetic makeup.

A) Sex-linked inheritance
B) Polygenic inheritance
C) Dominant-recessive inheritance
D) Multiple-allele inheritance
E) Incomplete dominance
Inherited traits determined by genes on the X or Y chromosomes.

A) Sex-linked inheritance
B) Polygenic inheritance
C) Dominant-recessive inheritance
D) Multiple-allele inheritance
E) Incomplete dominance
The dominant gene is expressed when present; the recessive gene is expressed only in the absence of the dominant gene.

A) Sex-linked inheritance
B) Polygenic inheritance
C) Dominant-recessive inheritance
D) Multiple-allele inheritance
E) Incomplete dominance
Inheritance that results in continuous or qualitative phenotypic variations between two extremes; an example is skin color.

A) Independent assortment
B) Chromosome segregation
C) Chromosome crossover
D) Gene recombination
Distribution of chromosomes to different gametes.

A) Cystic fibrosis
B) Achondroplasia
C) Albinism
D) Tay-Sachs disease
E) Huntington's disease
Rare type of dwarfism resulting from an impaired ability of the fetus to lengthen long bones by endochondrial ossification.

A) Allele
B) Dominant
C) Heterozygous
D) Autosomes
Genes for the same trait that have different expressions.

A) Allele
B) Dominant
C) Heterozygous
D) Autosomes
Chromosomes regulating most body characteristics.

A) Allele
B) Dominant
C) Heterozygous
D) Autosomes
Situation in which an individual has different alleles making up the genotype for a particular trait.

A) Homozygous
B) Sex chromosomes
C) Recessive
D) Genotype
Situation in which an individual has identical alleles for a particular trait.

A) Cystic fibrosis
B) Achondroplasia
C) Albinism
D) Tay-Sachs disease
E) Huntington's disease
A condition of drier excessively sticky mucus production.

A) Allele
B) Dominant
C) Heterozygous
D) Autosomes
The gene allele that suppresses or masks the expression of the other allele.

A) Sex-linked inheritance
B) Polygenic inheritance
C) Dominant-recessive inheritance
D) Multiple-allele inheritance
E) Incomplete dominance
The heterozygote has a phenotype intermediate between those of the homozygous dominant and homozygous recessive.

A) Sex-linked inheritance
B) Polygenic inheritance
C) Dominant-recessive inheritance
D) Multiple-allele inheritance
E) Incomplete dominance
Inheritance of the ABO blood group type is an example of this type of inheritance.

A) Homozygous
B) Sex chromosomes
C) Recessive
D) Genotype
A chromosome pair that may be very different in size.

A) Independent assortment
B) Chromosome segregation
C) Chromosome crossover
D) Gene recombination
Results in chromosomes that have mixed contributions from each parent.

A) Cystic fibrosis
B) Achondroplasia
C) Albinism
D) Tay-Sachs disease
E) Huntington's disease
Lack of skin pigmentation.

A) Independent assortment
B) Chromosome segregation
C) Chromosome crossover
D) Gene recombination
A particular gene's allele received by a gamete has no influence over selection of a different gene's allele.

A) Independent assortment
B) Chromosome segregation
C) Chromosome crossover
D) Gene recombination
Means by which genes trade places,some maternal and some paternal on each chromosome.

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

A) 25% chance the same probability for all subsequent children
B) 0% because the three pervious children have cleft chins already
C) 100% chance because the mother and father both have cleft chins
D) 75% chance the same probability for all subsequent children

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

A) the organism is in the embryonic stage
B) they are coding for skin color
C) they are coding for genetic diseases
D) both alleles are exactly the same, or homozygous

A) only expresses in present in a double dose
B) the least frequently expressed allele in a given population
C) a deleterious or disease causing allele
D) a weakened or attenuated allele

A) the healthy allele sometimes referred to as the wild type allele
B) the allele that is most frequently expressed in a given population
C) the stronger of two matched alleles
D) an allele that stops or hides the expression of the other allele

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

A) Steven has a heterozygous genotype
B) that it is impossible to tell Steven's genotype from this information alone
C) Steven has a homozygous dominant genotype
D) Steven has a homozygous recessive genotype

A) always one allele per gene
B) only two
C) each gene can have a different number of alleles
D) two from each parent

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

A) code for genes that are never considered lethal
B) suppress the expression of other alleles
C) code for desired traits only
D) code for most phenotypic and genotypic expressions of a trait

A) Genes code for a single protein or a single trait while an allele can code for many traits or many proteins.
B) Genes follow Mendelian patterns of inheritance while alleles follow non-Mendelian patterns of inheritance.
C) Alleles are found on chromosomes while genes are independent.
D) Genes express a specific trait while alleles are variations of a particular gene that result in the variation we see in a genetic individual trait.

A) Yes, because the female has two X chromosomes and the male has only one X chromosome.
B) Yes, because genetic diversity is due to the Y influence on the autosomes.
C) Yes, because the male has a Y chromosome.
D) No, because genetic diversity has nothing to do with the sex chromosomes but is due to crossing-over of chromosomes, independent assortment of chromosomes, and segregation of chromosomes.

A) Steven has a homozygous recessive genotype
B) Steven has a heterozygous genotype
C) Steven has a homozygous dominant genotype
D) that it is impossible to tell Steven's genotype from this information alone

A) polyspermic
B) polygenic
C) genotypic
D) phenotypic

A) the person has two dominant alleles for the gene responsible for the trait
B) the person will not have a recessive condition
C) the person has two identical alleles for the gene responsible for the trait
D) the person cannot pass on that trait

A) independent assortment and random crossover
B) recessive inheritance
C) mutation
D) chromosome deletion

A) homozygous
B) monogamous
C) heterozygous
D) hemizygous

A) Genetic screening is rarely done because it yields very little accurate information.
B) Screening can be done only in the first trimester of pregnancy.
C) Screening is illegal in over half of the world.
D) Screening can be done before conception by carrier recognition or during fetal testing.

A) 1:1:1:1
B) 1:2:1
C) 1:3
D) 4:0

A) not form an exact duplicate of itself when the cell divides
B) definitely cause skin cancer
C) replicate itself when the cell divides but will not be passed on to Amy's offspring
D) replicate itself and be passed on to Amy's children

A) chromosome segregation and independent assortment only
B) crossing-over and chromosome segregation only
C) crossing-over and independent assortment only
D) crossing-over, chromosome segregation, and independent assortment

A) genotype
B) phenotype
C) allelic pairs
D) recessive traits

A) incomplete dominance
B) a recessive genetic disorder
C) a dominant genetic disorder
D) a sex-linked genetic disorder

A) dominance
B) recessive inheritance
C) incomplete dominance
D) sex-linked inheritance

A) The only time a gene can be influenced by environmental factors is in the second trimester of pregnancy.
B) Drugs and nutrition can alter normal gene expression.
C) It is impossible to alter in any way the expression of a gene in humans.
D) Environmental factors determine the way in which 90 percent of our genes are expressed.

A) gg
B) GG
C) Dg
D) Gg

A) people carrying dominant genetic disorders always die before birth
B) recessive genetic disorders are limited to persons of the same ethnicity
C) carriers are not eliminated by the disease before passing the defective alleles on to their offspring
D) dominant genetic disorders are never expressed in males

A) polymorphism
B) polygene inheritance
C) incomplete dominance
D) polyploidy

A) 1:1:1:1
B) 1:2:1
C) 1:3
D) 4:0

A) A, B, AB, or O
B) AB only
C) A or B only
D) AB or O only

A) 1:1:1:1
B) 1:2:1
C) 1:3
D) 4:0

A) CVS
B) A DNA probe
C) Blood chemistry
D) Amniocentesis

A) dominance
B) incomplete dominance
C) recessive inheritance
D) sex-linked inheritance

A) XX
B) XY
C) YY
D) any of these, depending on the father

A) hair that seems to have several shades of a color
B) the appearance of birthmarks on the skin
C) the appearance of freckles on the skin
D) the ABO blood group

A) deletion
B) translocation
C) crossing-over
D) inversion

A) hypersecretion of growth hormone
B) the presence of an extra chromosome
C) hyposecretion of thyroxine
D) degeneration of the basal nuclei of the brain