biology chapter 15
*Messenger RNA molecules contain information that is used to
synthesize ___________.
A. nucleotides
B. amino acids
C. polypeptides(proteins)
D. fatty acids
polypeptides
*To begin transcription, RNA polymerase must bind to a segment of DNA
called the ____.
A. initiation site
B. primer
C.
inducer
D. promoter
E. transcription bubble
promoter
*The sequence of nucleotides in a DNA molecule is called the ________
code.
A. protein
B. ribosomal
C. translation
D. genetic
E. amino acid
genetic
*Most eukaryotic genes contain noncoding sequences called ________
that are interspersed with the coding sequences.
A. introns
B. exons
C. codons
D. spacers
E. spliceosomes
introns
*The polypeptide-making organelles, which consist of protein combined
with RNA, are called
A. ribosomes.
B. Golgi bodies.
C. lysosomes.
D. centrosomes.
E. mitochondria.
ribosomes
*During translation, amino acids are carried to the ribosome by
A. mRNA.
B. tRNA.
C. snRNA.
D. rRNA.
E. miRNA.
tRNA
*A codon is composed of how many bases?
A. one
B. two
C. three
D. four
E. 64
three
*The A, P, and E sites are progressively occupied by amino acids
being assembled into a polypeptide. These sites are part of
A.
DNA.
B. the large ribosomal subunit.
C. mRNA.
D.
tRNA.
E. the spliceosome.
B. the large ribosomal subuni
*
Eukaryotes have ____ type(s) of RNA polymerase.
A. two
B. three
C. four
D. one
E. 64
three
1. DNA affects the traits of an organism by providing the
instructions for synthesizing _______.
A. proteins
B.
nucleotides
C. codons
D. amino acids
A. proteins
2. Gene expression involves two phases, ___________ and
translation.
A. replication
B. transcription
C.
initiation
D. condensation
B. transcription
4. To begin transcription, RNA polymerase must bind to a segment of
DNA called the ____.
A. initiation site
B. primer
C.
inducer
D. promoter
E. transcription bubble
D. promoter
5. The strand of DNA that is not transcribed is called the ______
strand.
A. coding
B. non-coding
C. template
D. complementary
A. coding
6. During ________, a ribosome assembles a polypeptide whose amino
acid sequence is specified by the nucleotide sequence in a molecule of
mRNA.
A. transcription
B. translation
C.
replication
D. posttranscriptional modification
B. translation
7. The sequence of nucleotides in a DNA molecule is called the
________ code.
A. protein
B. ribosomal
C.
translation
D. genetic
E. amino acid
D. genetic
8. Crick and his colleagues proposed that the genetic code consists
of a series of blocks of information, called ______, each
corresponding to one amino acid in an encoded protein.
A.
alleles
B. codons
C. genes
D. polypeptides
B. codons
9. Gene ________ refers to the combined processes of transcription
and translation.
A. expression
B. replication
C.
modification
D. regulation
expression
10. During transcription of mRNA in eukaryotes, some sequences are
cut out of the primary transcript and the remaining sequences are
joined together. This processing of mRNA is called _________.
A.
termination
B. translation
C. splicing
D.
capping
E. elongation
splicing
11. Most eukaryotic genes contain noncoding sequences called ________
that are interspersed with the coding sequences.
A.
introns
B. exons
C. codons
D. spacers
E. spliceosomes
introns
12. To remove noncoding sequences in the pre-mRNA of eukaryotes,
multiple snRNPs combine with proteins to form a larger complex called
the ___________ .
A. 5' cap
B. introsome
C.
ribosome
D. spliceosome
E. 3' poly-A tail
spliceosome
13. The connection that exists between genes and hereditary traits is
based on using the information encoded in genes to synthesize
A.
codons.
B. nucleotides.
C. proteins.
D.
histones.
E. complementary bases.
proteins
14. Both DNA and RNA are made up of building blocks known as
A.
nucleotides.
B. nucleic acids.
C. amino acids.
D.
genes.
E. codons.
nucleotides
15. The "one-gene/one-enzyme" hypothesis was proposed
by
A. Watson and Crick.
B. Griffith.
C. Garrod.
D.
Franklin.
E. Beadle and Tatum.
beadle and tatum
16. The polypeptide-making organelles, which consist of protein
combined with RNA, are called
A. ribosomes.
B. Golgi
bodies.
C. lysosomes.
D. centrosomes.
E. mitochondria.
ribosomes
17. During translation, amino acids are carried to the ribosome
by
A. mRNA.
B. tRNA.
C. snRNA.
D. rRNA.
E. miRNA.
tRNA
18. During _______, RNA polymerase synthesizes a molecule of RNA
using DNA as a template.
A. mRNA splicing
B.
translation
C. transcription
D. gene sequencing
E. termination
transcription
19. Which base in an anticodon will pair with the base adenine in a
codon?
A. thymine
B. cytosine
C. guanine
D. uracil
uracil
20. A codon is composed of how many bases?
A. one
B.
two
C. three
D. four
E. 64
three
21. In eukaryotes, translation takes place
A. on the plasma
membrane.
B. inside the nucleus.
C. on ribosomes.
D. on
the nuclear membrane.
E. on spliceosomes.
on ribosomes
22. Ribosomes are complex aggregates of
A. RNA and DNA.
B.
RNA and proteins.
C. RNA and sugars.
D. DNA and
proteins.
E. nucleosomes and RNA.
RNA and proteins
23. The A, P, and E sites are progressively occupied by amino acids
being assembled into a polypeptide. These sites are part of
A.
DNA.
B. the large ribosomal subunit.
C. mRNA.
D.
tRNA.
E. the spliceosome.
the large ribosomal subunit
24. In eukaryotic cells, transcription occurs
A. on the surface
of the nuclear membrane.
B. on ribosomes.
C. on
spliceosomes.
D. inside the nucleus.
E. on the surface of
the plasma membrane.
inside the nucleus
25. In prokaryotes, the form of RNA polymerase that can accurately
initiate synthesis of RNA is called
A. the holoenzyme.
B.
the core polymerase.
C. RNA polymerase II.
D. RNA polymerase
III.
E. the sigma subunit.
the holoenzyme
26. During _________, nucleotide sequence information is changed into
amino acid sequence information.
A. replication
B.
sequencing
C. transcription
D. translocation
E. translation
translation
27. The genetic code uses _________ nucleotide(s) to specify one
amino acid.
A. one
B. two
C. three
D. four
E. 64
three
28. Which statement about the genetic code is false?
A. There is
no punctuation or spacing between codons.
B. Nucleotides are
always read in groups of three.
C. Every codon codes for one
amino acid.
D. Some amino acids are specified by more than one
codon.
E. The genetic code is almost universal, but not quite.
C. Every codon codes for one amino acid.
29. How many unique mRNA codons can be constructed from the four
different RNA nucleotides?
A. four
B. 12
C. 16
D.
61
E. 64
64
30. During translation, the nucleotides that make up the mRNA are
read in groups of three. These groups are called
A.
codons.
B. anticodons.
C. exons.
D. introns.
E. templates.
codons
31. The tRNA nucleotide sequence that pairs with bases on the mRNA is
called a(n)
A. intron.
B. exon.
C. codon.
D.
initiation factor.
E. anticodon.
anticodon
32. Ribosome movement along the mRNA is called
A.
transcription.
B. initiation.
C. replication.
D.
translocation.
E. activation.
transolcation
33. Specific amino acids are attached to tRNA molecules by
A.
aminoacyl-tRNA synthetases.
B. hydrogen bonds.
C.
anticodons.
D. deactivating enzymes.
E. initiation factors.
A. aminoacyl-tRNA synthetases.
34. Codons that serve as "stop" signals for translation are
recognized by
A. tRNA.
B. release factors.
C.
anticodons.
D. translation terminators.
E. aminoacyl-tRNA synthetases
release factors
35. When a polypeptide is being assembled, the bond that forms
between a newly added amino acid and the previous amino acid in the
chain is a _________ bond.
A. hydrogen
B.
hydrophobic
C. terminal
D. phosphodiester
E. peptide
peptide
36. During translation in prokaryotes, formation of the initiation
complex requires all of the following except
A. a small ribosomal
subunit.
B. mRNA.
C. tRNA charged with
N-formylmethionine.
D. RNA polymerase.
E. initiation factors.
RNA polymerase
37. Eukaryotic mRNA molecules may contain non-coding sequences that
must be removed before translation. These are called
A.
anticodons.
B. introns.
C. exons.
D.
nucleosomes.
E. noncodons.
introns
38. The location of translation in prokaryotic cells is
A. in
the nucleoid.
B. on ribosomes.
C. on the plasma
membrane.
D. on mesosomes.
E. on chromosomes
on ribosomes
39. In eukaryotes, pre-mRNA processing may involve all of the
following except
A. removal of exons from the pre-mRNA.
B.
addition of a 5' cap.
C. addition of a 3' poly-A tail
D.
pre-mRNA splicing by the spliceosome.
A. removal of exons from the pre-mRNA.
40. During translation, uncharged tRNA molecules leave the ribosome
from the _________ site.
A. E
B. P
C. A
D.
termination
E. release
release
41. The Central Dogma of biology can be stated as
A. proteins
RNA DNA.
B. RNA DNA proteins.
C. DNA proteins RNA.
D.
DNA RNA proteins.
DNA RNA proteins
42. If the sequence of bases in the template strand of a DNA molecule
is 3' ATCGCTCC 5', what is the sequence of bases in the RNA that is
transcribed from this molecule?
A. 3' UAGCGAGG 5'
B. 3'
TAGCGAGG 5'
C. 5' UAGCGAGG 3'
D. 5' TAGCGAGG 3'
E. 5'
AUCGCUCC 3'
C. 5' UAGCGAGG 3'
43. The template strand of a DNA segment that codes for mRNA has the
sequence: ATGCGT. Which tRNA anticodons would pair with the mRNA that
is coded for by this sequence?
A. AUG CGU.
B. ATG
CGT.
C. UAC GCA.
D. UAG CGU.
A. AUG CGU.
44. Although 61 different codons code for amino acids, cells contain
fewer than 61 different tRNAs. Why?
A. Because the 5' base on the
tRNA anticodon has some flexibility (wobble); thus, some tRNA
anticodons can pair with more than one mRNA codon.
B. Although 61
different codons code for amino acids, any given cell contains fewer
than 61.
C. Because the 5' base on the mRNA codon has some
flexibility (wobble); thus, some mRNA codons can pair with more than
one tRNA anticodon.
D. Because each amino acid is coded for by
just one codon.
A. Because the 5' base on the tRNA anticodon has some flexibility (wobble); thus, some tRNA anticodons can pair with more than one mRNA codon.
45. Eukaryotic and prokaryotic organisms differ in how they process
genetic information. Which statements best explain one of these
differences?
A. In prokaryotes, translation of the mRNA begins
before transcription is complete. In eukaryotes, transcription and
modification of the mRNA is completed before translation
begins.
B. In prokaryotes, genes are transcribed directly into
polypeptides. In eukaryotes, genes are transcribed into RNA which is
used to assemble polypeptides.
C. In prokaryotes, translation
occurs before genes are transcribed into mRNA. In eukaryotes, genes
are transcribed into mRNA which is then translated into
polypeptides.
D. In prokaryotes, introns are removed before genes
are transcribed into mRNA. In eukaryotes, introns are removed after
genes are transcribed into mRNA.
A. In prokaryotes, translation of the mRNA begins before transcription is complete. In eukaryotes, transcription and modification of the mRNA is completed before translation begins.
46. What is the first step during transcription initiation in
prokaryotes?
A. the transcription bubble is formed
B. RNA
polymerase binds to the promoter
C. the DNA double helix is
unwound
D. RNA polymerase synthesizes a short primer
E.
transcription factors bind to the TATA box sequence
B. RNA polymerase binds to the promoter
47. Initiation of transcription differs from initiation of DNA
replication in several ways. One difference is that initiation of
transcription does not require
A. a promoter.
B.
enzymes.
C. a primer.
D. a DNA template strand.
a primer
48. Transcription in prokaryotes is carried out by ______, which
unwind(s) and transcribe(s) the gene.
A. RNA synthetase
B.
RNA polymerase II
C. RNA polymerase III
D. transcription
factors
E. RNA polymerase
RNA polymerase
49. Eukaryotes have ____ type(s) of RNA polymerase.
A.
two
B. three
C. four
D. one
E. 64
three
50. In eukaryotes, each type of RNA polymerase recognizes a
different
A. start codon
B. stop codon
C.
promoter
D. release factor
E. transcription factor
promoter
51. Eukaryotic pre-mRNA molecules are modified
A. in the
cytoplasm.
B. at the ribosome.
C. inside the
nucleus.
D. as they pass through the nuclear membrane.
E. at
the transcription bubble.
inside the nucleus
52. In eukaryotes, the 3' poly-A tail is attached to
A. poly-A
polymerase.
B. mRNA.
C. tRNA.
D. the ribosome.
E.
the template strand of DNA.
mRNA
53. Why are there fewer tRNA anticodons than the 61 needed to match
each mRNA codon that codes for an amino acid?
A. There is some
flexibility in pairing between the 5' base of the codon and the 3'
base of the anticodon.
B. There is some flexibility in pairing
between the middle base of the codon and the middle base of the
anticodon.
C. There is some flexibility in pairing between the 3'
base of the codon and the 5' base of the anticodon.
D. There is
some flexibility in pairing between all 3 bases of the codon and all 3
bases of the anticodon.
C. There is some flexibility in pairing between the 3' base of the codon and the 5' base of the anticodon.
54. During translation, translocation refers to
A. releasing a
tRNA molecule from the ribosome.
B. joining an amino acid to a
tRNA molecule.
C. joining an amino acid to the next amino acid in
the chain.
D. joining a tRNA molecule to the ribosome.
E.
moving the ribosome along the mRNA molecule.
E. moving the ribosome along the mRNA molecule.
55. During protein synthesis in eukaryotes, what happens during RNA
splicing?
A. The product of translation, called the primary
transcript, is cut and some pieces are joined back together to form
the mature mRNA.
B. The product of transcription, called the
primary transcript, is cut and some pieces are joined back together to
form the mature tRNA.
C. The product of transcription, called the
secondary transcript, is cut and some pieces are joined back together
to form the mature mRNA.
D. The product of transcription, called
the primary transcript, is cut and some pieces are joined back
together to form the mature mRNA.
E. The product of
transcription, called the primary transcript, is cut and all pieces
are joined back together to form the mature mRNA.
D. The product of transcription, called the primary transcript, is cut and some pieces are joined back together to form the mature mRNA.
56. During protein synthesis in eukaryotes, which molecule passes
from the nucleus to the cytoplasm and specifies the sequence of amino
acids in the new polypeptide?
A. DNA
B. RNA
polymerase
C. mRNA
D. rRNA
E. tRNA
mRNA
57. Which molecule combines with proteins to form both the large and
small ribosomal subunits?
A. DNA
B. RNA polymerase
C.
miRNA
D. rRNA
E. tRNA
rRNA
58. You are conducting a genetic screen to isolate nutritional
mutants in yeast. Specifically, you want to isolate a double mutant
that cannot synthesize histidine or leucine, two nutrients essential
for growth. You start with a wild type yeast strain and mutagenize it
with a UV light. Which of the following outlines the remaining steps
for isolating such a mutant?
A. Grow mutagenized yeast on rich
media. Then grow them on minimal media, as well as on minimal media
containing histidine, minimal media containing leucine, and minimal
media containing both histidine and leucine. Select for yeast that do
not grow on minimal media, do not grow on media supplemented with only
histidine or leucine, but do grow on minimal media supplemented with
both histidine and leucine.
B. Grow mutagenized yeast on minimal
media. Then grow them on rich media, as well as on minimal media
containing histidine, minimal media containing leucine, and minimal
media containing both histidine and leucine. Select for yeast that do
not grow on rich media, do not grow on media supplemented with only
histidine or leucine, but do grow on minimal media supplemented with
both histidine and leucine.
C. Grow mutagenized yeast on rich
media. Then grow them on minimal media, as well as on minimal media
containing histidine, minimal media containing leucine, and minimal
media containing both histidine and leucine. Select for yeast that
grow on minimal media, grow on media supplemented with only histidine
or leucine, but do not grow on minimal media supplemented with both
histidine and leucine.
D. Grow mutagenized yeast on minimal
media. Then grow them on rich media, as well as on minimal media
containing histidine, minimal media containing leucine, and minimal
media containing both histidine and leucine. Select for yeast that
grow on rich media, grow on media supplemented with only histidine or
leucine, but do not grow on minimal media supplemented with both
histidine and leucine.
A. Grow mutagenized yeast on rich media. Then grow them on minimal media, as well as on minimal media containing histidine, minimal media containing leucine, and minimal media containing both histidine and leucine. Select for yeast that do not grow on minimal media, do not grow on media supplemented with only histidine or leucine, but do grow on minimal media supplemented with both histidine and leucine.
59. Given the sentence "THE FAT CAT ATE THE RED RAT," which
of the following would represent a frameshift mutation?
A. THE
FAT RAT ATE THE RED CAT
B. THE CAT ATE THE RED RAT
C. THE
FAC ATA TET HER EDR AT
D. THE THE FAT CAT ATE THE RED RAT
. THE FAC ATA TET HER EDR AT
60. What would happen if snRNAs did not recognize the branch point
within an intron?
A. A lariat would not form.
B. snRNAs
would not base-pair with the 5' end of the intron.
C. A 3' poly A
tail would not be added to the transcript.
D. A 5' cap would not
be added to the transcript.
a lariat would not form
61. During the splicing reaction, the intron-exon junctions are
recognized by
A. snRNPs.
B. miRNAs.
C. SRP
RNAs.
D. the lariat.
E. the branch point.
snRNPs
61. During the splicing reaction, the intron-exon junctions are
recognized by
A. snRNPs.
B. miRNAs.
C. SRP
RNAs.
D. the lariat.
E. the branch point.
a
62. In prokaryotes, the RNA polymerase holoenzyme consists of
A.
the core polymerase plus two alpha subunits.
B. the core
polymerase plus two beta subunits.
C. the core polymerase plus
two alpha subunits, two beta subunits, and a sigma subunit.
D.
the core polymerase plus a sigma subunit.
E. two alpha subunits,
two beta subunits, and two sigma subunits.
D. the core polymerase plus a sigma subunit.
63. Two 6-base sequences are present in bacterial promoters: TATAAT
(located 10 nt upstream from the start site) and TTGACA (located 35 nt
upstream from the start site). What is the significance of the fact
that these two base sequences are different?
A. Binding sites for
both the holoenzyme and ATP are provided.
B. Both the location of
the start site and the direction of transcription can be
established.
C. Binding sites for both the core polymerase and
holoenzyme are provided.
D. The transcription bubble can be
properly formed.
E. It allows RNA polymerase to distinguish
between the template strand and the coding strand of the DNA molecule.
B. Both the location of the start site and the direction of transcription can be established.
64. Within the transcription bubble, the 9 most recently added
nucleotides in the newly synthesized RNA strand temporarily form a
helix with the template DNA strand. How might transcription be
affected if helix formation did not occur?
A. Rewinding the DNA
molecule would be inhibited.
B. Unwinding the DNA molecule would
be inhibited.
C. The position of the 5' end of the RNA would be
unstable, inhibiting elongation.
D. The position of the 3' end of
the RNA would be unstable, inhibiting elongation.
E. The position
of the 5' end of the RNA would be unstable, stimulating elongation.
D. The position of the 3' end of the RNA would be unstable, inhibiting elongation.
65. Cells conserve energy and resources by making active proteins
only when they are needed. If a protein is not needed, which of the
following methods of control would be the most
energy-efficient?
A. block transcription
B. degrade the mRNA
after it is made
C. prevent translation of the mRNA
D.
degrade the protein after it is made
A. block transcription
66. What is required for formation of the transcription initiation
complex in eukaryotes?
A. binding of a transcription factor to
the TATA box, followed by recruitment of additional transcription
factors and recruitment of RNA polymerase II
B. binding of a
transcription factor to the transcription bubble, followed by
recruitment of additional transcription factors and recruitment of RNA
polymerase III
C. binding of the sigma subunit to the start site
followed by recruitment of RNA polymerase II
D. binding of RNA
polymerase II to the TATA box, followed by recruitment of
transcription factors
E. binding of the sigma subunit to promoter
elements at -35 and -10, followed by recruitment of the core polymerase
A. binding of a transcription factor to the TATA box, followed by recruitment of additional transcription factors and recruitment of RNA polymerase II
67. What is the likely consequence of a mutation that alters the
branch point within an intron?
A. no effect, since introns are
not expressed
B. failure to form a lariat
C. failure of
snRNPs to recognize the 5' end of intron
D. no exon
shuffling
E. failure of snRNPs to combine with protein and form
the spliceosome
B. failure to form a lariat
68. You are working to characterize a novel protein in mice. Analysis
shows that high levels of the primary transcript that codes for this
protein are found in tissue from the brain, muscle, liver, and
pancreas. However, an antibody that recognizes the C-terminal portion
of the protein indicates that the protein is present in brain, muscle,
and liver, but not in the pancreas. What is the most likely
explanation for this result?
A. The gene that codes for this
protein is not transcribed in the pancreas.
B. There is no
modification of the primary transcript in the pancreas.
C. There
is no modification of the primary transcript in the brain, muscle, and
liver.
D. Alternative splicing in the pancreas yields a protein
that is missing the portion that the antibody recognizes.
E.
Alternative splicing in the brain, muscle, and liver increases the
level of translation.
D. Alternative splicing in the pancreas yields a protein that is missing the portion that the antibody recognizes.
69. The mutation responsible for Huntington's disease is a
A.
missense mutation.
B. nonsense mutation.
C. frameshift
mutation.
D. triplet repeat expansion mutation.
D. triplet repeat expansion mutation.
70. How would a large chromosomal inversion affect the expression of
a gene if the gene is located between the two break points but no
breaks occur within the gene?
A. The inversion would probably
have no effect on gene expression.
B. The gene would not be
transcribed because it would be oriented in the wrong
direction.
C. The gene would be transcribed in the 3' to 5'
direction.
D. The gene would be transcribed normally but the mRNA
would be translated in the 3' to 5' direction.
A. The inversion would probably have no effect on gene expression.
71. How does DNA polymerase differ from RNA polymerase?
A. Only
RNA polymerase adds new nucleotides to the 3' end of a growing
chain.
B. Only RNA polymerase requires a primer.
C. Only DNA
polymerase uses a template DNA strand to direct synthesis of a new
nucleotide strand.
D. Only DNA polymerase has a proofreading ability.
D. Only DNA polymerase has a proofreading ability.
72. A scientist makes three artificial mRNA strands:
(x) 5'
AAAUUUAAAUUUAAAUUUAAAUUUAAA 3'
(y) 5' UUUCCCUUUCCCUUUCCCUUUCCCUUU
3'
(z) 5' AUAUAUAUAUAUAUAUAUAUAUAUAU 3'
When he analyzes the polypeptides produced, he finds that:
x
produces a polypeptide that is 50% phenylalanine and 50%lysine.
y
produces a polypeptide that is 50% phenylalanine and 50%
proline.
z produces a polypeptide that is 50% isoleucine and 50% tyrosine.
Based on these results only, the best conclusion to make is that
A. AUA codes for isoleucine
B. AAA codes for
phenylalanine
C. AAA codes for lysine
D. AAA codes for
lysine and AUA codes for isoleucine
E. AAA codes for
phenylalanine and AUA codes for isoleucine
C. AAA codes for lysine
73. A bacterial cell has a nonsense mutation that prevents it from
producing a functional sigma subunit for RNA polymerase. Inability to
synthesize a functional sigma subunit would have the most direct
effect on
A. transcription initiation.
B. transcription
elongation.
C. transcription termination.
D. translation
initiation.
E. translation termination.
A. transcription initiation.
74. What is the best way to describe our current understanding of the
one-gene/one-polypeptide hypothesis?
A. It applies to both
prokaryotes and eukaryotes.
B. It applies to prokaryotes but not
to eukaryotes.
C. It applies to eukaryotes but not to
prokaryotes.
D. It has been replaced by the one-gene/one-enzyme hypothesis.
B. It applies to prokaryotes but not to eukaryotes.
76. You are studying an individual with very low levels of insulin in
her blood. Further analysis indicates that cells of her pancreas are
producing normal levels of this protein, but most of it is
accumulating in the cytoplasm rather than being secreted from the
cells. Which hypothesis to explain this observation makes the most
sense?
A. A small deletion has removed the nucleotides that code
for the signal sequence at the amino terminus of the protein.
B.
A missense mutation has caused premature termination during
translation of this protein.
C. A chromosomal segment that
includes the gene for insulin has been inverted.
D. A two-base
deletion near the middle of the gene has altered the reading frame
during translation of the protein.
E. A missense mutation has
altered the ribosome-binding sequence at the 5' end of the mRNA.
A. A small deletion has removed the nucleotides that code for the signal sequence at the amino terminus of the protein.
75. You are attempting to synthesize rRNA in a test tube using DNA
isolated from mouse cells. In addition to the template DNA,
ribonucleotides, and the necessary transcription factors, you should
also add _________ to the test tube.
A. poly-A polymerase
B.
RNA polymerase III
C. RNA polymerase II
D. RNA polymerase I
D. RNA polymerase I
77. A gene that codes for a protein was removed from a eukaryotic
cell and inserted into a prokaryotic cell. Although the gene was
successfully transcribed and translated, it produced a different
protein than it produced in the eukaryotic cell. What is the most
likely explanation?
A. There are slight differences in the
genetic code for prokaryotes and eukaryotes.
B. Unlike
eukaryotes, which have three different RNA polymerases, prokaryotes
have a single RNA polymerase.
C. Eukaryotic genes often contain
introns while prokaryotic genes do not.
D. Eukaryotic transcripts
have a 5' cap while prokaryotic transcripts do not.
C. Eukaryotic genes often contain introns while prokaryotic genes do not.
78. What is the base sequence, in the DNA template strand, of the
intron that is closest to the 3' end of this strand?
Shown below
is a hypothetical DNA sequence from a virus. Also shown is the
sequence of the RNA that is synthesized from this DNA.
DNA sequence:
5'-AGCACCTGCCGAATGGGCCAAATCCTGCCGAATAAA-3'
3'-TCGTGGACGGCTTACCCGGTTTAGGACGGCTTATTT -5'
RNA sequence (G* = G cap):
5'-G*AGCACCUGCCGCCUGCCGAAUAAAAAAA....-3'
78. What is the base sequence, in the DNA template strand, of the
intron that is closest to the 3' end of this strand?
A.
TCGTGGACGGC
B. TTACCCGGTTTA
C. GGACGGCTTATTT
D. GCTTACCCGGTT
A. TCGTGGACGGC
B. TTACCCGGTTTA
C. GGACGGCTTATTT
D. GCTTACCCGGTT
B. TTACCCGGTTTA
79. The RNA was most likely transcribed by
A. RNA polymerase
holoenzyme.
B. RNA polymerase I.
C. RNA polymerase
II.
D. RNA polymerase III.
B. RNA polymerase I.