Chapter 13
In his transformation experiments, what did Griffith observe?
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.
Mixing a heat-killed pathogenic strain of bacteria with a living
nonpathogenic strain can
convert some of the living cells into
the pathogenic form.
How do we describe transformation in bacteria?
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
assimilation of external DNA into a cell
After mixing a heat-killed, phosphorescent (light-emitting) strain of
bacteria with a living,
nonphosphorescent strain, you discover
that some of the living cells are now phosphorescent.
Which
observation(s) would provide the best evidence that the ability to
phosphoresce is a
heritable trait?
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.
Descendants of the living cells are also phosphorescent.
In trying to determine whether DNA or protein is the genetic
material, Hershey and Chase
made use of which of the following
facts?
A) DNA contains sulfur, whereas protein does not.
B)
DNA contains phosphorus, whereas protein does not.
C) DNA
contains nitrogen, whereas protein does not.
D) DNA contains
purines, whereas protein includes pyrimidines.
E) RNA includes
ribose, whereas DNA includes deoxyribose sugars.
DNA contains phosphorus, whereas protein does not.
Which of the following investigators was (were) responsible for the
following discovery?
In DNA from any species, the amount of
adenine equals the amount of thymine, and the amount
of guanine
equals the amount of cytosine.
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
Erwin Chargaff
Cytosine makes up 42% of the nucleotides in a sample of DNA from an
organism.
Approximately what percentage of the nucleotides in
this sample will be thymine?
A) 8%
B) 16%
C)
31%
D) 42%
E) It cannot be determined from the information provided.
8%
Which of the following can be determined directly from X-ray
diffraction photographs of
crystallized DNA?
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
the diameter of the helix
It became apparent to Watson and Crick after completion of their
model that the DNA
molecule could carry a vast amount of
hereditary information in which of the following?
A) sequence of
bases
B) phosphate-sugar backbones
C) complementary pairing
of bases
D) side groups of nitrogenous bases
E) different
five-carbon sugars
sequence of bases
In an analysis of the nucleotide composition of DNA, which of the
following will be found?
A) A = C
B) A = G and C = T
C)
A + C = G + T
D) G + C = T + A
A + C = G + T
What is meant by the description "antiparallel"
regarding the strands that make up DNA?
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.
The 5' to 3' direction of one strand runs counter to the 5' to 3' direction of the other strand.
Replication in prokaryotes differs from replication in eukaryotes for
which of the following
reasons?
A) Prokaryotic chromosomes
have 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.
Prokaryotic chromosomes have a single origin of replication, whereas
eukaryotic
chromosomes have many.
Suppose you are provided with an actively dividing culture of E. coli
bacteria to which
radioactive thymine has been added. What would
happen if a cell replicates once in the presence
of this
radioactive base?
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.
DNA in both daughter cells would be radioactive.
An Okazaki fragment has which of the following arrangements?
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'
5' RNA nucleotides, DNA nucleotides 3'
In E. coli, there is a mutation in a gene called dnaB that alters the
helicase that normally acts
at the origin. Which of the following
would you expect as a result of this mutation?
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.
No replication fork will be formed.
Which enzyme catalyzes the elongation of a DNA strand in the 5' → 3'
direction?
A) primase
B) DNA ligase
C) DNA polymerase
III
D) topoisomerase
E) helicase
DNA polymerase III
At a specific area of a chromosome, the following sequence of
nucleotides is present where
the chain opens to form a
replication fork:
3' C C T A G G C T G C A A T C C 5'
An RNA
primer is formed starting at the underlined T (T) of the template.
Which of the
following represents the primer sequence?
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'
5' A C G U U A G G 3'
Polytene chromosomes of Drosophila salivary glands each consist of
multiple identical DNA
strands that are aligned in parallel
arrays. How could these arise?
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
replication without separation
To repair a thymine dimer by nucleotide excision repair, in which
order do the necessary
enzymes act?
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
endonuclease, DNA polymerase I, DNA ligase
What is the function of DNA polymerase III?
A) to unwind the DNA
helix during replication
B) to seal together the broken ends of
DNA strands
C) to add nucleotides to the 3' 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
to add nucleotides to the 3' end of a growing DNA strand
The difference between ATP and the nucleoside triphosphates used
during DNA synthesis is
that
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.
the nucleoside triphosphates have the sugar deoxyribose; ATP has the sugar ribose.
The leading and the lagging strands differ in that
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.
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.
A new DNA strand elongates only in the 5' to 3' direction
because
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.
DNA polymerase can only add nucleotides to the free 3' end.
What is the function of topoisomerase?
A) relieving strain in
the DNA ahead of the replication fork
B) elongating new DNA at a
replication fork by adding nucleotides to the existing chain
C)
adding methyl groups to bases of DNA
D) unwinding of the double
helix
E) stabilizing single-stranded DNA at the replication fork
relieving strain in the DNA ahead of the replication fork
What is the role of DNA ligase in the elongation of the lagging
strand during DNA
replication?
A) It synthesizes RNA
nucleotides to make a primer.
B) It catalyzes the lengthening of
telomeres.
C) It joins Okazaki fragments together.
D) It
unwinds the parental double helix.
E) It stabilizes the unwound
parental DNA.
It joins Okazaki fragments together.
Which of the following help(s) to hold the DNA strands apart while
they are being
replicated?
A) primase
B) ligase
C)
DNA polymerase
D) single-strand binding proteins
E) exonuclease
single-strand binding proteins
Individuals with the disorder xeroderma pigmentosum are
hypersensitive to sunlight. This
occurs because their cells are
impaired in what way?
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.
They cannot repair thymine dimers.
Which of the enzymes removes the RNA nucleotides from the primer and
adds equivalent
DNA nucleotides to the 3' end of Okazaki fragments?
I. helicase
II. DNA polymerase III
III.
ligase
IV. DNA polymerase I
V. primase
DNA polymerase I
Which of the enzymes separates the DNA strands during replication?
I. helicase
II. DNA polymerase III
III.
ligase
IV. DNA polymerase I
V. primase
helicase
Which of the enzymes covalently connects segments of DNA?
I. helicase
II. DNA polymerase III
III.
ligase
IV. DNA polymerase I
V. primase
ligase
Which of the enzymes synthesizes short segments of RNA?
I. helicase
II. DNA polymerase III
III.
ligase
IV. DNA polymerase I
V. primase
primase
Given the damage caused by UV radiation, the kind of gene affected in
those with XP is one
whose product is involved with
A) mending of double-strand breaks in the DNA backbone.
B)
breakage of cross-strand covalent bonds.
C) the ability to excise
single-strand damage and replace it.
D) the removal of
double-strand damaged areas.
E) causing affected skin cells to
undergo apoptosis.
the ability to excise single-strand damage and replace it.
Which of the following sets of materials is required by both
eukaryotes and prokaryotes for
replication?
A)
double-stranded DNA, four kinds of dNTPs, primers, origins of
replication
B) topoisomerases, telomerases, polymerases
C)
G-C rich regions, polymerases, chromosome nicks
D) nucleosome
loosening, four dNTPs, four rNTPs
E) ligase, primers, nucleases
double-stranded DNA, four kinds of dNTPs, primers, origins of replication
Studies of nucleosomes have shown that histones (except H1) exist in
each nucleosome as
two kinds of tetramers: one of 2 H2A molecules
and 2 H2B molecules, and the other as 2 H3 and
2 H4 molecules.
Which of the following is supported by this data?
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.
The two types of tetramers associate to form an octamer.
In a linear eukaryotic chromatin sample, which of the following
strands is looped into
domains by scaffolding?
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
the 30-nm chromatin fiber
Which of the following statements describes the eukaryotic
chromosome?
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 plus proteins.
E) Active transcription occurs
on heterochromatin but not euchromatin.
It consists of a single linear molecule of double-stranded DNA plus proteins.
If a cell were unable to produce histone proteins, which of the
following would be a likely
effect?
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.
The cell's DNA couldn't be packed into its nucleus.
Which of the following statements is true of histones?
A) Each
nucleosome consists of two molecules of histone H1.
B) Histone H1
is not present in the nucleosome bead; instead, it draws the
nucleosomes together.
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 or fungi.
E) The mass of histone in
chromatin is approximately nine times the mass of DNA.
Histone H1 is not present in the nucleosome bead; instead, it draws the nucleosomes together.
Which of the following statements describes chromatin?
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.
Heterochromatin is highly condensed, whereas euchromatin is less compact.
Why do histones bind tightly to DNA?
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.
Histones are positively charged, and DNA is negatively charged.
Which of the following represents the order of increasingly higher
levels of organization of
chromatin?
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
nucleosome, 30-nm chromatin fiber, looped domain
Which of the following modifications is least likely to alter the
rate at which a DNA
fragment moves through a gel during
electrophoresis?
A) altering the nucleotide sequence of the DNA
fragment without adding or removing
nucleotides
B)
acetylating the cytosine bases within the DNA fragment
C)
increasing the length of the DNA fragment
D) decreasing the
length of the DNA fragment
E) neutralizing the negative charges
within the DNA fragment
altering the nucleotide sequence of the DNA fragment without adding
or removing
nucleotides
Assume that you are trying to insert a gene into a plasmid. Someone
gives you a preparation
of genomic DNA that has been cut with
restriction enzyme X. The gene you wish to insert has
sites on
both ends for cutting by restriction enzyme Y. You have a plasmid with
a single site for
Y, but not for X. Your strategy should be
to
A) insert the fragments cut with restriction enzyme X directly
into the plasmid without cutting
the plasmid.
B) cut the
plasmid with restriction enzyme X and insert the fragments cut with
restriction
enzyme Y into the plasmid.
C) cut the DNA again
with restriction enzyme Y and insert these fragments into the plasmid
cut
with the same enzyme.
D) cut the plasmid twice with
restriction enzyme Y and ligate the two fragments onto the ends
of
the DNA fragments cut with restriction enzyme X.
E) cut
the plasmid with restriction enzyme X and then insert the gene into
the plasmid.
cut the DNA again with restriction enzyme Y and insert these
fragments into the plasmid cut
with the same enzyme.
How does a bacterial cell protect its own DNA from restriction
enzymes?
A) by adding methyl groups to adenines and
cytosines
B) by using DNA ligase to seal the bacterial DNA into a
closed circle
C) by adding histones to protect the
double-stranded DNA
D) by forming "sticky ends"
of bacterial DNA to prevent the enzyme from attaching
E) by
reinforcing the bacterial DNA structure with covalent phosphodiester bonds
by adding methyl groups to adenines and cytosines
What is the most logical sequence of steps for splicing foreign DNA
into a plasmid and
inserting the plasmid into a
bacterium?
I. Transform bacteria with a recombinant DNA
molecule.
II. Cut the plasmid DNA using restriction
enzymes.
III. Extract plasmid DNA from bacterial cells.
IV.
Hydrogen-bond the plasmid DNA to nonplasmid DNA fragments.
V. Use
ligase to seal plasmid DNA to nonplasmid DNA.
A) I, II, IV, III,
V
B) II, III, V, IV, I
C) III, II, IV, V, I
D) III, IV,
V, I, II
E) IV, V, I, II, III
III, II, IV, V, I
Why is it so important to be able to amplify DNA fragments when
studying genes?
A) DNA fragments are too small to use
individually.
B) A gene may represent only a millionth of the
cell's DNA.
C) Restriction enzymes cut DNA into fragments that
are too small.
D) A clone requires multiple copies of each gene
per clone.
E) It is important to have multiple copies of DNA in
the case of laboratory error.A gene may represent only a millionth of
the cell's DNA.
A gene may represent only a millionth of the cell's DNA.
The reason for using Taq polymerase for PCR is that
A) it is
heat stable and can withstand the heating step of PCR.
B) only
minute amounts are needed for each cycle of PCR.
C) it binds more
readily than other polymerases to the primers.
D) it has regions
that are complementary to the primers.
E) it is heat stable, and
it binds more readily than other polymerases to the primers.
it is heat stable and can withstand the heating step of PCR.
For a science fair project, two students decided to repeat the
Hershey and Chase experiment,
with modifications. They decided to
label the nitrogen of the DNA, rather than the phosphate.
They
reasoned that each nucleotide has only one phosphate and two to five
nitrogens. Thus,
labeling the nitrogens would provide a stronger
signal than labeling the phosphates. Why won't
this
experiment work?
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.
Amino acids (and thus proteins) also have nitrogen atoms; thus, the
radioactivity would not
distinguish between DNA and proteins.
You briefly expose bacteria undergoing DNA replication to
radioactively labeled nucleotides.
When you centrifuge the DNA
isolated from the bacteria, the DNA separates into two
classes.
One class of labeled DNA includes very large molecules
(thousands or even millions of
nucleotides long), and the other
includes short stretches of DNA (several hundred to a
few
thousand nucleotides in length). These two classes of DNA
probably represent
leading strands and Okazaki fragments
A eukaryotic gene has "sticky ends" produced by the
restriction endonuclease EcoRI. The gene is
added to a mixture
containing EcoRI and a bacterial plasmid that carries two genes
conferring
resistance to ampicillin and tetracycline. The plasmid
has one recognition site for EcoRI located
in the tetracycline
resistance gene. This mixture is incubated for several hours, exposed
to DNA
ligase, and then added to bacteria growing in nutrient
broth. The bacteria are allowed to grow
overnight and are
streaked on a plate using a technique that produces isolated colonies
that are
clones of the original. Samples of these colonies are
then grown in four different media: nutrient
broth plus
ampicillin, nutrient broth plus tetracycline, nutrient broth plus
ampicillin and
tetracycline, and nutrient broth without antibiotics.
Bacteria that contain the plasmid, but not the eukaryotic gene,
would grow
A) in the nutrient broth plus ampicillin, but not in
the broth containing tetracycline.
B) only in the broth
containing both antibiotics.
C) in the broth containing
tetracycline, but not in the broth containing ampicillin.
D) in
all four types of broth.
E) in the nutrient broth without
antibiotics only.
in all four types of broth.
Bacteria containing a plasmid into which the eukaryotic gene has
integrated would grow
A) in the nutrient broth only.
B) in
the nutrient broth and the tetracycline broth only.
C) in the
nutrient broth, the ampicillin broth, and the tetracycline
broth.
D) in all four types of broth.
E) in the ampicillin
broth and the nutrient broth.
in the ampicillin broth and the nutrient broth.
Bacteria that do not take up any plasmids would grow on which
media?
A) the nutrient broth only
B) the nutrient broth and
the tetracycline broth
C) the nutrient broth and the ampicillin
broth
D) the tetracycline broth and the ampicillin broth
E)
all three broths
the nutrient broth only
A group of six students has taken samples of their own cheek cells,
purified the DNA, and used a
restriction enzyme known to cut at
zero, one, or two sites in a particular gene of interest.
6) Why
might they be conducting such an experiment?
A) to find the
location of this gene in the human genome
B) to prepare to
isolate the chromosome on which the gene of interest is found
C)
to find which of the students has which alleles
D) to collect
population data that can be used to assess natural selection
E)
to collect population data that can be used to study genetic drift
to find which of the students has which alleles
Analysis of the data obtained shows that two students each have two
fragments, two students
each have three fragments, and two
students each have one only. What does this demonstrate?
A) Each
pair of students has a different gene for this function.
B) The
two students who have two fragments have one restriction site in this
region.
C) The two students who have two fragments have two
restriction sites within this gene.
D) The students with three
fragments are said to have "fragile sites."
E)
Each of these students is heterozygous for this gene.
The two students who have two fragments have one restriction site in this region.
In his work with pneumonia-causing bacteria and mice, Griffith found
that
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
some substance from pathogenic cells was transferred to nonpathogenic
cells, making them
pathogenic.
What is the basis for the difference in how the leading and lagging
strands of DNA molecules
are synthesized?
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.
DNA polymerase can join new nucleotides only to the 3' end of a growing strand.
In analyzing the number of different bases in a DNA sample, which
result would be consistent
with the base-pairing rules?
A) A
= G
B) A + G = C + T
C) A + T = G + T
D) A = C
E)
G = T
A + G = C + T
The elongation of the leading strand during DNA synthesis
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.
depends on the action of DNA polymerase.
In a nucleosome, the DNA is wrapped around
A) polymerase
molecules.
B) ribosomes.
C) histones.
D) a thymine
dimer.
E) satellite DNA.
histones.
E. coli cells grown on 15N medium are transferred to 14N medium and
allowed to grow for
two more generations (two rounds of DNA
replication). DNA extracted from these cells is
centrifuged. What
density distribution of DNA would you expect in this
experiment?
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
one low-density and one intermediate-density band
A biochemist isolates, purifies, and combines in a test tube a
variety of molecules needed for
DNA replication. When she adds
some DNA to the mixture, replication occurs, but each
DNA
molecule consists of a normal strand paired with numerous
segments of DNA a few hundred
nucleotides long. What has she
probably left out of the mixture?
A) DNA polymerase
B) DNA
ligase
C) nucleotides
D) Okazaki fragments
E) primase
DNA ligase
The spontaneous loss of amino groups from adenine in DNA results in
hypoxanthine, an
uncommon base, opposite thymine. What
combination of proteins could repair such damage?
A) nuclease,
DNA polymerase, DNA ligase
B) topoisomerase, primase, DNA
polymerase
C) topoisomerase, helicase, single-strand binding
protein
D) DNA ligase, replication fork proteins, adenylyl
cyclase
E) nuclease, topoisomerase, primase
nuclease, DNA polymerase, DNA ligase