Deck 16: The Molecular Basis of Inheritance

A)Mutant mice were resistant to bacterial infections.
B)Mixing a heat-killed pathogenic strain of bacteria with a living nonpathogenic strain can convert some of the living cells into the pathogenic form.
C)Mixing a heat-killed nonpathogenic strain of bacteria with a living pathogenic strain makes the pathogenic strain nonpathogenic.
D)Infecting mice with nonpathogenic strains of bacteria makes them resistant to pathogenic strains.
E)Mice infected with a pathogenic strain of bacteria can spread the infection to other mice.

A)DNA contains sulfur, whereas protein does not.
B)DNA contains phosphorus, but protein does not.
C)DNA contains nitrogen, whereas protein does not.
D)DNA contains purines, whereas protein includes pyrimidines.
E)RNA includes ribose, while DNA includes deoxyribose sugars.

A)Frederick Griffith
B)Alfred Hershey and Martha Chase
C)Oswald Avery, Maclyn McCarty, and Colin MacLeod
D)Erwin Chargaff
E)Matthew Meselson and Franklin Stahl

A)the diameter of the helix
B)the rate of replication
C)the sequence of nucleotides
D)the bond angles of the subunits
E)the frequency of A vs. T nucleotides

A)Frederick Griffith
B)Alfred Hershey and Martha Chase
C)Oswald Avery, Maclyn McCarty, and Colin MacLeod
D)Erwin Chargaff
E)Matthew Meselson and Franklin Stahl

A)The prokaryotic chromosome has histones, whereas eukaryotic chromosomes do not.
B)Prokaryotic chromosomes have a single origin of replication, whereas eukaryotic chromosomes have many.
C)The rate of elongation during DNA replication is slower in prokaryotes than in eukaryotes.
D)Prokaryotes produce Okazaki fragments during DNA replication, but eukaryotes do not.
E)Prokaryotes have telomeres, and eukaryotes do not.

A)Frederick Griffith
B)Alfred Hershey and Martha Chase
C)Oswald Avery, Maclyn McCarty, and Colin MacLeod
D)Erwin Chargaff
E)Matthew Meselson and Franklin Stahl

A)hydrogen
B)ionic
C)covalent
D)sulfhydryl
E)phosphate

A)sequence of bases
B)phosphate-sugar backbones
C)complementary pairing of bases
D)side groups of nitrogenous bases
E)different five-carbon sugars

A)A = C
B)A = G and C = T
C)A + C = G + T
D)G + C = T + A

A)the relative proportion of each of the four bases differs within individuals of a species.
B)the human genome is more complex than that of other species.
C)the amount of A is always equivalent to T, and C to G.
D)the amount of ribose is always equivalent to deoxyribose.
E)transformation causes protein to be brought into the cell.

A)the creation of a strand of DNA from an RNA molecule
B)the creation of a strand of RNA from a DNA molecule
C)the infection of cells by a phage DNA molecule
D)the type of semiconservative replication shown by DNA
E)assimilation of external DNA into a cell

A)There is no radioactive isotope of nitrogen.
B)Radioactive nitrogen has a half-life of 100,000 years, and the material would be too dangerous for too long.
C)Avery et al. have already concluded that this experiment showed inconclusive results.
D)Although there are more nitrogens in a nucleotide, labeled phosphates actually have 16 extra neutrons; therefore, they are more radioactive.
E)Amino acids (and thus proteins)also have nitrogen atoms; thus, the radioactivity would not distinguish between DNA and proteins.

A)V, IV, II, I, III
B)II, I, III, V, IV
C)I, II, III, V, IV
D)I, II, V, IV, III
E)II, III, IV, V, I

A)The viral DNA will be radioactive.
B)The viral proteins will be radioactive.
C)The bacterial DNA will be radioactive.
D)both A and B
E)both A and C

A)the particulate nature of the hereditary material
B)dominance vs. recessiveness
C)sex-linkage
D)genetic distance and mapping
E)the usefulness of peas and Drosophila

A)Purines pair with pyrimidines.
B)C nucleotides pair with A nucleotides.
C)Deoxyribose sugars bind with ribose sugars.
D)Nucleotides bind with nucleosides.
E)Nucleotides bind with nucleoside triphosphates.

A)DNA passed from the heat-killed strain to the living strain.
B)Protein passed from the heat-killed strain to the living strain.
C)The phosphorescence in the living strain is especially bright.
D)Descendants of the living cells are also phosphorescent.
E)Both DNA and protein passed from the heat-killed strain to the living strain.

A)Proteins have a greater variety of three-dimensional forms than does DNA.
B)Proteins have two different levels of structural organization; DNA has four.
C)Proteins are made of 40 amino acids and DNA is made of four nucleotides.
D)Some viruses only transmit proteins.
E)A and B are correct.

A)leading strands and Okazaki fragments.
B)lagging strands and Okazaki fragments.
C)Okazaki fragments and RNA primers.
D)leading strands and RNA primers.
E)RNA primers and mitochondrial DNA.

A)The evolution of telomerase enzyme
B)DNA polymerase that cannot replicate the leading strand template to its 5' end
C)Gaps left at the 5' end of the lagging strand because of the need for a 3' onto which nucleotides can attach
D)Gaps left at the 3' end of the lagging strand because of the need for a primer
E)The "no ends" of a circular chromosome

A)primase, polymerase, ligase
B)3' RNA nucleotides, DNA nucleotides 5'
C)5' RNA nucleotides, DNA nucleotides 3'
D)DNA polymerase I, DNA polymerase III
E)5' DNA to 3'

A)the inactivity of this DNA
B)the low frequency of mutations occurring in this DNA
C)that new evolution of telomeres continues
D)that mutations in telomeres are relatively advantageous
E)that the critical function of telomeres must be maintained

A)the particular DNA polymerase catalyzing the reaction
B)the relative amounts of the four nucleoside triphosphates in the cell
C)the nucleotide sequence of the template strand
D)the primase used in the reaction
E)the arrangement of histones in the sugar phosphate backbone

A)helicase
B)DNA polymerase III
C)ligase
D)DNA polymerase I
E)primase

A)The twisting nature of DNA creates nonparallel strands.
B)The 5' to 3' direction of one strand runs counter to the 5' to 3' direction of the other strand.
C)Base pairings create unequal spacing between the two DNA strands.
D)One strand is positively charged and the other is negatively charged.
E)One strand contains only purines and the other contains only pyrimidines.

A)5' G C C T A G G 3'
B)3' G C C T A G G 5'
C)5' A C G T T A G G 3'
D)5' A C G U U A G G 3'
E)5' G C C U A G G 3'

A)replication followed by mitosis
B)replication without separation
C)meiosis followed by mitosis
D)fertilization by multiple sperm
E)special association with histone proteins

A)Replication is semi-conservative.
B)Replication is not dispersive.
C)Replication is not semi-conservative.
D)Replication is not conservative.
E)Replication is neither dispersive nor conservative.

A)There are two replication forks going in opposite directions.
B)Thymidine is only being added where the DNA strands are furthest apart.
C)Thymidine is only added at the very beginning of replication.
D)Replication proceeds in one direction only.

A)helicase
B)DNA polymerase III
C)ligase
D)DNA polymerase I
E)primase

A)adding a single 5' cap structure that resists degradation by nucleases
B)causing specific double strand DNA breaks that result in blunt ends on both strands
C)causing linear ends of the newly replicated DNA to circularize
D)adding numerous short DNA sequences such as TTAGGG, which form a hairpin turn
E)adding numerous GC pairs which resist hydrolysis and maintain chromosome integrity

A)to unwind the DNA helix during replication
B)to seal together the broken ends of DNA strands
C)to add nucleotides to the end of a growing DNA strand
D)to degrade damaged DNA molecules
E)to rejoin the two DNA strands (one new and one old)after replication

A)exonuclease, DNA polymerase III, RNA primase
B)helicase, DNA polymerase I, DNA ligase
C)DNA ligase, nuclease, helicase
D)DNA polymerase I, DNA polymerase III, DNA ligase
E)endonuclease, DNA polymerase I, DNA ligase

A)No proofreading will occur.
B)No replication fork will be formed.
C)The DNA will supercoil.
D)Replication will occur via RNA polymerase alone.
E)Replication will require a DNA template from another source.

A)One of the daughter cells, but not the other, would have radioactive DNA.
B)Neither of the two daughter cells would be radioactive.
C)All four bases of the DNA would be radioactive.
D)Radioactive thymine would pair with nonradioactive guanine.
E)DNA in both daughter cells would be radioactive.

A)primase
B)DNA ligase
C)DNA polymerase III
D)topoisomerase
E)helicase

A)A nucleoside triphosphate is added to the 5' end of the DNA, releasing a molecule of pyrophosphate.
B)A nucleoside triphosphate is added to the 3' end of the DNA, releasing a molecule of pyrophosphate.
C)A nucleoside diphosphate is added to the 5' end of the DNA, releasing a molecule of phosphate.
D)A nucleoside diphosphate is added to the 3' end of the DNA, releasing a molecule of phosphate.
E)A nucleoside monophosphate is added to the 5' end of the DNA.

A)primase
B)ligase
C)DNA polymerase
D)single-strand binding proteins
E)exonuclease

A)These oocytes have no histones.
B)Any mutation during oogenesis results in sterility.
C)Phosphorylation of all proteins in the cell must result.
D)Histone tail phosphorylation prohibits chromosome condensation.
E)Histone tails must be removed from the rest of the histones.

A)a high probability of becoming cancerous
B)production of Okazaki fragments
C)inability to repair thymine dimers
D)a reduction in chromosome length
E)high sensitivity to sunlight

A)DNA can wind itself around either of the two kinds of tetramers.
B)The two types of tetramers associate to form an octamer.
C)DNA has to associate with individual histones before they form tetramers.
D)Only H2A can form associations with DNA molecules.
E)The structure of H3 and H4 molecules is not basic like that of the other histones.

A)relieving strain in the DNA ahead of the replication fork
B)elongation of new DNA at a replication fork by addition of nucleotides to the existing chain
C)the addition of methyl groups to bases of DNA
D)unwinding of the double helix
E)stabilizing single-stranded DNA at the replication fork

A)double-stranded DNA, 4 kinds of dNTPs, primers, origins
B)topoisomerases, telomerase, polymerases
C)G-C rich regions, polymerases, chromosome nicks
D)nucleosome loosening, 4 dNTPs, 4 rNTPs
E)ligase, primers, nucleases

A)helicase
B)DNA polymerase III
C)ligase
D)DNA polymerase I
E)primase

A)the nucleoside triphosphates have the sugar deoxyribose; ATP has the sugar ribose.
B)the nucleoside triphosphates have two phosphate groups; ATP has three phosphate groups.
C)ATP contains three high-energy bonds; the nucleoside triphosphates have two.
D)ATP is found only in human cells; the nucleoside triphosphates are found in all animal and plant cells.
E)triphosphate monomers are active in the nucleoside triphosphates, but not in ATP.

A)DNA supercoiling at or around H1
B)methylation and phosphorylation of histone tails
C)hydrolysis of DNA molecules where they are wrapped around the nucleosome core
D)accessibility of heterochromatin to phosphorylating enzymes
E)nucleotide excision and reconstruction

A)10 X
B)100 X
C)1000 X
D)10,000 X
E)100,000 X

A)4)6 million
B)4)4 thousand
C)45 thousand
D)about 400

A)They cannot replicate DNA.
B)They cannot undergo mitosis.
C)They cannot exchange DNA with other cells.
D)They cannot repair thymine dimers.
E)They do not recombine homologous chromosomes during meiosis.

A)DNA without attached histones
B)DNA with H1 only
C)the 10 nm chromatin fiber
D)the 30 nm chromatin fiber
E)the metaphase chromosome

A)helicase
B)DNA polymerase III
C)ligase
D)DNA polymerase I
E)primase

A)the leading strand is synthesized in the same direction as the movement of the replication fork, and the lagging strand is synthesized in the opposite direction.
B)the leading strand is synthesized by adding nucleotides to the 3' end of the growing strand, and the lagging strand is synthesized by adding nucleotides to the 5' end.
C)the lagging strand is synthesized continuously, whereas the leading strand is synthesized in short fragments that are ultimately stitched together.
D)the leading strand is synthesized at twice the rate of the lagging strand.

A)There would be an increase in the amount of "satellite" DNA produced during centrifugation.
B)The cell's DNA couldn't be packed into its nucleus.
C)Spindle fibers would not form during prophase.
D)Amplification of other genes would compensate for the lack of histones.
E)Pseudogenes would be transcribed to compensate for the decreased protein in the cell.

A)DNA polymerase begins adding nucleotides at the 5' end of the template.
B)Okazaki fragments prevent elongation in the 3' to 5' direction.
C)the polarity of the DNA molecule prevents addition of nucleotides at the 3' end.
D)replication must progress toward the replication fork.
E)DNA polymerase can only add nucleotides to the free 3' end.

A)synthesize RNA nucleotides to make a primer
B)catalyze the lengthening of telomeres
C)join Okazaki fragments together
D)unwind the parental double helix
E)stabilize the unwound parental DNA

A)It is composed of DNA alone.
B)The nucleosome is its most basic functional subunit.
C)The number of genes on each chromosome is different in different cell types of an organism.
D)It consists of a single linear molecule of double-stranded DNA.
E)Active transcription occurs on heterochromatin.

A)nuclease, DNA polymerase, DNA ligase
B)telomerase, primase, DNA polymerase
C)telomerase, helicase, single-strand binding protein
D)DNA ligase, replication fork proteins, adenylyl cyclase
E)nuclease, telomerase, primase

A)A = G
B)A + G = C + T
C)A + T = G + T
D)A = C
E)G = T

A)the protein coat from pathogenic cells was able to transform nonpathogenic cells.
B)heat-killed pathogenic cells caused pneumonia.
C)some substance from pathogenic cells was transferred to nonpathogenic cells, making them pathogenic.
D)the polysaccharide coat of bacteria caused pneumonia.
E)bacteriophages injected DNA into bacteria.

A)DNA polymerase
B)DNA ligase
C)nucleotides
D)Okazaki fragments
E)primase

A)Each nucleosome consists of two molecules of histone H1.
B)Histone H1 is not present in the nucleosome bead; instead it is involved in the formation of higher-level chromatin structures.
C)The carboxyl end of each histone extends outward from the nucleosome and is called a "histone tail."
D)Histones are found in mammals, but not in other animals or in plants.
E)The mass of histone in chromatin is approximately nine times the mass of DNA.

A)nucleosome, 30-nm chromatin fiber, looped domain
B)looped domain, 30-nm chromatin fiber, nucleosome
C)looped domain, nucleosome, 30-nm chromatin fiber
D)nucleosome, looped domain, 30-nm chromatin fiber
E)30-nm chromatin fiber, nucleosome, looped domain

A)Histones are positively charged, and DNA is negatively charged.
B)Histones are negatively charged, and DNA is positively charged.
C)Both histones and DNA are strongly hydrophobic.
D)Histones are covalently linked to the DNA.
E)Histones are highly hydrophobic, and DNA is hydrophilic.

A)one high-density and one low-density band
B)one intermediate-density band
C)one high-density and one intermediate-density band
D)one low-density and one intermediate-density band
E)one low-density band

A)The origins of replication occur only at the 5' end.
B)Helicases and single-strand binding proteins work at the 5' end.
C)DNA polymerase can join new nucleotides only to the 3' end of a growing strand.
D)DNA ligase works only in the 3' → 5' direction.
E)Polymerase can work on only one strand at a time.

A)Heterochromatin is composed of DNA, whereas euchromatin is made of DNA and RNA.
B)Both heterochromatin and euchromatin are found in the cytoplasm.
C)Heterochromatin is highly condensed, whereas euchromatin is less compact.
D)Euchromatin is not transcribed, whereas heterochromatin is transcribed.
E)Only euchromatin is visible under the light microscope.

A)polymerase molecules.
B)ribosomes.
C)histones.
D)a thymine dimer.
E)satellite DNA.

A)progresses away from the replication fork.
B)occurs in the 3' → 5' direction.
C)produces Okazaki fragments.
D)depends on the action of DNA polymerase.
E)does not require a template strand.