Deck 12: Gene Mutation

A) mitosis.
B) meiosis.
C) fertilization.
D) puberty.
E) RNA replication.

A)different tissues have different variants of the gene.
B)lamin A proteins affect how chromatin touches the nuclear membrane.
C)many different results occur.
D)every tissue type has lamin A.
E)they are only active under certain conditions.

A) cystic fibrosis.
B) Duchenne muscular dystrophy.
C) hemophilia.
D) sickle cell disease.
E) diabetes mellitus.

A) occurs only in microbes.
B) affects a particular subset of cells.
C) affects all cells of an individual.
D) is expressed only in embryos.
E) affects sleep cycles.

A) it is extremely rare.
B) during meiosis, the chromosome that bears the mutation is more likely to enter a gamete than the chromosome that carries the wild type allele.
C) collagen has a very precise three-dimensional structure, so nearly any disruption alters the overall conformation.
D) people who use cosmetics with collagen silence collagen genes.
E) there are many collagen genes.

A) a DNA base is in a rare tautomeric form as the replication fork arrives, and a mismatched base is inserted.
B) a person smokes cigarettes or is exposed to a teratogen for many years.
C) the sugars and phosphates in the DNA double helix exchange places.
D) thymine temporarily becomes uracil.
E) a replication fork stalls.

A) Jewel inherited two wild type alleles from her carrier parents.
B) Jewel inherited a dominant form of the condition.
C) Jewel inherited two recessive mutant alleles in the beta globin gene that cause thalassemia.
D) Jewel also has sickle cell disease.
E) Malonie underwent a deletion in the beta globin gene.

A) 100.
B) 1,000.
C) 10,000.
D) 100,000.
E) 1,000,000.

A) One
B) Two
C) Three
D) Four
E) Ten

A) beta globin.
B) alpha globin.
C) a clotting factor.
D) myosin.
E) collagen.

A) too short.
B) missing.
C) too long.
D) too scarce.
E) too abundant.

A) a mutation in collagen that causes the skin to be extra stretchy.
B) the mutation that causes sickle cell disease.
C) a mutation in the CCR5 gene.
D) a mutation in a cytokine gene that causes an allergy.
E) a mutation that causes a person to be neither right nor left-handed.

A) 0 percent.
B) the same as for any other child in the population.
C) 25 percent.
D) 50 percent.
E) 50 percent for a boy and 25 percent for a girl.

A) it takes several generations for the phenotype to change.
B) they do not affect offspring.
C) the mutant phenotype is obvious.
D) they can be identified by DNA sequencing.
E) they are much more common than recessive disorders.

A) a change in a DNA sequence that affects at least 10 percent of individuals in a population.
B) a change in a DNA sequence present in less than 1 percent of individuals in a population.
C) a change in a DNA sequence that harms health.
D) a type of radiation that can alter the genetic code.
E) a substitution of amino acids for nucleotides in the genome.

A) they less severely affect the phenotype, so that individuals can reproduce and transmit them.
B) more people have them.
C) mutations are always lethal.
D) they more severely affect the phenotype, so that individuals cannot reproduce and transmit them.
E) mutations refer to a real situation, whereas a polymorphism is an idealized state that biologists hypothesized to explain genetic change.

A) occurs in the same gene that, when mutant in a different way, causes beta thalassemia.
B) deletes two contiguous DNA bases.
C) results in a single DNA base change that does not alter the encoded amino acid.
D) changes a valine to a glutamic acid in the beta globin gene.
E) changes a glutamic acid to a valine in the alpha globin gene.

A) a mutagen.
B) an RNA base.
C) an alternate structure of a molecule.
D) a poison.
E) the type of bond that holds DNA bases together.

A) a gain of function.
B) a loss of function.
C) a translocation of function.
D) a deletion.
E) a change in the genetic code.

A) A to T
B) G to A
C) C to T
D) T to C
E) A to U

A) spontaneous mutations occur too frequently to study.
B) using a mutagen yields results that are specific to a gene and not applicable everywhere in the genome.
C) mutation can happen at a specific site in the genome, compared to a mutagen that might cause mutations in several genes.
D) it works in humans but not in experimental organisms or cell culture.
E) it can treat genetic disease.

A)missense; first
B)missense; third
C)missense; second
D)nonsense; second
E)nonsense; third

A) T
B) GC
C) GCT
D) GGCT
E) AAAAA

A) plutonium and cesium isotopes.
B) alpha and beta globin.
C) uranium and radium.
D) carbon-14 and strontium-70.
E) kryptonite and dilithium crystals.

A) nonsense
B) missense
C) sense
D) presence
E) antisense

A) the number of beta globin genes.
B) the presence or absence of a sickle cell mutation.
C) the number of alpha globin chains.
D) the rate of replication of the alpha globin genes.
E) whether the person smokes or not.

A) a single base.
B) 3 bases.
C) a chromosome tip.
D) a centromere.
E) only a purine.

A) these bases are unstable.
B) bases in the strand can form base pairs, generating loops that interfere with replication and repair enzymes.
C) the repeats hold onto the replication enzymes, causing base mismatches.
D) the repeats attract and bind to mutagens, increasing the mutation rate.
E) repeated sequences do not have a sugar-phosphate backbone.

A) a person encounters a mutagen.
B) homologs misalign during meiosis such that the first copy of the gene on one chromosome lies opposite the second copy on the homolog.
C) introns are not removed promptly and their sequences are included in the gene product.
D) they bond within the same DNA strand, forming loops that disrupt replication enzymes.
E) they jump out of the chromosome and spontaneously invert.

A) disrupt the reading frame of the gene.
B) replace an AT base pair with a GC base pair.
C) reverse the polarity of the double helix.
D) kill cells.
E) change a deoxyribose to a ribose.

A) a missense mutation.
B) a nonsense mutation.
C) a deletion of 9 bases.
D) a duplication of the gene.
E) a replacement of all purines with pyrimidines.

A) deleting bases.
B) removing the nitrogen from the bases.
C) kinking the double helix.
D) breaking the sugar-phosphate backbone.
E) reversing replication forks.

A) acute radiation sickness in the exposed person.
B) short DNA repeats in a child's genome that didn't match the size in either exposed parent.
C) increased rates of asthma and allergies in the exposed people and their children.
D) a child that failed an Ames test.
E) loss of teeth in exposed individuals.

A) unwound and stretched.
B) repetitive or symmetrical.
C) highly coiled.
D) bound by RNA polymerase.
E) replaced with RNA in the genome.

A) profoundly change the protein's conformation.
B) result in a frameshift mutation.
C) shorten the protein.
D) have no effect on the protein.
E) also change the first two positions.

A) missense
B) nonsense
C) frameshift
D) truncation
E) viral

A) ACC to CCC
B) A to G
C) GG to AA
D) A to T
E) a deoxyribonucleotide to a ribonucleotide

A) deletion.
B) translocation.
C) expanding triplet repeat.
D) point mutation.
E) brittle nucleotides.

A) AAAATTTT
B) ATATGCGC
C) GATCCTAG
D) GATCGATC
E) UCGUGGCCUU

A) the encoded amino acid changes to a smaller one.
B) the encoded amino acid changes to a larger one.
C) the encoded amino acid does not change.
D) they are not nonsynonymous.
E) they cause dangerous mutations to be excised and repaired.

A) a second somatic point mutation.
B) an increasing number of repeated short DNA sequences.
C) a transposing tandem triplet repeat.
D) family members perceiving their symptoms as worse.
E) genetic anticipation.

A) DNA ligase
B) Photoreactivation
C) Ionizing radiation
D) DNA replication
E) Chromatin remodeling

A) alter a protein's shape and affect its function.
B) alter an intron splicing site so that an entire exon is deleted.
C) change a triplet codon that does not affect the reading frame.
D) invert a segment of a chromosome.
E) create a stop signal.

A) altering the protein's shape and affecting its function.
B) changing a triplet codon that does not affect the reading frame.
C) altering an intron splicing site so that an entire exon is deleted.
D) substituting beta globin chains with alpha globin chains.
E) deleting the gene for a key clotting factor.

A) mismatch repair.
B) base excision repair.
C) roto-rooter repair.
D) photoreactivation.
E) repair of the sugar-phosphate backbone.

A) transversion; nonsense
B) transversion; missense
C) transition; missense
D) transition; nonsense
E) transcondition; antisense

A) xeroderma pigmentosum
B) trichothiodystrophy
C) ataxia telangiectasis
D) Becker muscular dystrophy
E) hereditary nonpolyposis colon cancer

A) GTCCCA
B) GTCCTGATTATTCA
C) GTCCACTTATT
D) GTCCTTATATTCA
E) GTCCTTATTCAACTTATTCCTG

A) are found only in viruses.
B) cannot mutate.
C) move.
D) are rare.
E) are deleted in meiosis.

A) skewed distribution of parental versus newly replicated DNA.
B) a conscious effort on the part of the individual.
C) lack of DNA replication in stem cells.
D) skewed distribution of stem and progenitor cells.
E) repair enzymes in stem cells that are not in differentiated cells.

A) pseudogene.
B) expanded gene.
C) phenocopy.
D) transposon.
E) psychogene.

A) germinal.
B) somatic
C) de novo.
D) conditional.
E) deleterious

A) purine rings.
B) strand breaks.
C) pyrimidine dimers.
D) radioactivity.
E) night blindness.

A) sickle cell disease.
B) a normal phenotype.
C) a bluish complexion.
D) a black mouth.
E) black ear tips.

A)whether people are heterozygotes at particular part of the prion protein gene.
B)whether people have extra copies of the prion protein gene.
C)whether people eat food contaminated with toxin from E.coli.
D)whether people eat tainted beef.
E)whether people inherit a sickle cell allele.

A) are extremely are, occurring in only about a dozen sites in the genome.
B) are found only in even-numbered chromosomes.
C) account for about 25 percent of the genome and number in the hundreds to thousands.
D) account for less than 1 percent of the genome and are five or fewer bases long.
E) are very common in the genomes of fetuses and infants but are lost as we age.

A) ataxia telangiectasis
B) Cockayne syndrome
C) Werner syndrome
D) xeroderma pigmentosum
E) hereditary nonpolyposis colon cancer