Deck 13: Gene Expression

A) more than one ribosome can bind to an mRNA molecule.
B) some amino acids are coded for by more than one codon.
C) there is more than one stop codon in the genetic code.
D) a particular amino acid may be linked to more than one type of tRNA molecule.
E) certain tRNA anticodons can pair with more than one codon sequence.

A) tRNA
B) cDNA
C) rRNA
D) promoter sequences
E) DNA

A) contained all the enzymes needed for normal metabolism.
B) was missing all the enzymes for metabolism of amino acids.
C) was missing an enzyme for metabolism and could not synthesize arginine.
D) was missing an enzyme for metabolism and could not synthesize citrulline.
E) was missing an enzyme for metabolism and could not synthesize ornithine.

A) The ability to bond with adenine.
B) The ability to bond with guanine.
C) It is a purine.
D) The ability to bond with cytosine.
E) It contains two nitrogenous rings.

A) mRNA.
B) nontemplate strand of DNA.
C) template strand of DNA.
D) tRNA.
E) rRNA.

A) Because it is easier to grow haploid molds in the laboratory.
B) Because haploid molds have simpler nutritional requirements than do diploid molds.
C) Because a mutation that arises is not masked by a normal allele on a homologous chromosome.
D) Because haploid Neurospora will always mutate.
E) Because diploid Neurospora will always mutate.

A) elongation.
B) reverse transcription.
C) termination.
D) translation.
E) transcription.

A) metabolic defects were due to the lack of an enzyme.
B) metabolic defects were due to excess enzyme production.
C) metabolic defects were due to chromosomal changes.
D) mutations were inheritable.
E) metabolic defects did not occur in humans.

A) RNA is usually single-standed.
B) RNA lacks thymine.
C) RNA contains uracil.
D) RNA contains ribose.
E) RNA contains cytosine.

A) attach to the mRNA molecule and travel along its length.
B) attach to the DNA molecule and travel along its length to produce an mRNA molecule.
C) translate mRNA into tRNA.
D) transcribe mRNA to tRNA.
E) translate mRNA into DNA.

A) By growing the mold on a complete medium with extra vitamins and nutrients.
B) By growing the mold on minimal media supplemented with different combinations of amino acids, vitamins, etc.
C) By growing the mold in its diploid form to see which traits were masked.
D) By comparing Neurospora to other species of mold.
E) By observing the marked differences in morphology between the different strains.

A) Each mutant gene affected three enzymes.
B) Each mutant gene affected a pair of enzymes.
C) Each mutant gene affected only one enzyme.
D) Mutant genes had no effect on the enzymes produced by the cells.
E) Each mutant gene affected as many enzymes as were present in a particular metabolic pathway.

A) two attached bases.
B) one less oxygen.
C) an extra hydroxyl group.
D) an extra carbon in the ring.
E) one less carbon in the ring.

A) the structure of hemoglobin was altered by a mutation of a single gene.
B) mutations only caused defects in enzymes.
C) mutations alter the structure of RNA, but not proteins.
D) mutations were inherited.
E) the structure of hemoglobin was altered by mutations in any of a dozen genes.

A) Neurospora is easy to grow.
B) Neurospora grows as a haploid organism.
C) Neurospora manufactures all its necessary molecules when grown on a minimal medium.
D) A mutant Neurospora strain that cannot make a particular amino acid can still grow if that amino acid is added to the growth medium.
E) Neurospora contains homologous chromosomes that are easily viewed with a light microscope.

A) Neurospora that only grows in the wild.
B) a mutant strain that will only grow in the lab on complete medium.
C) a strain that will not grow in the lab.
D) a virulent strain of Neurospora.
E) a normal phenotype that will grow on minimal medium.

A) adenine; adenine
B) adenine; thymine
C) thymine; thymine
D) uracil; adenine
E) adenine; uracil

A) tRNA only
B) mRNA only
C) rRNA only
D) mRNA and tRNA only
E) mRNA, tRNA, and rRNA

A) towards the 3'end of the amino acid sequence.
B) towards the 5' end of the mRNA sequence.
C) towards the 3' end of the mRNA sequence.
D) towards the 5' end of the transcribed DNA strand.
E) towards the carboxyl end of the amino acid sequence.

A) no additional energy.
B) the input of two ATP molecules to supply the needed energy.
C) energy supplied by GTP.
D) activation of the A site.
E) phosphorylation of the tRNA molecule.

A) the initiation of translation.
B) the termination of transcription.
C) the termination of chain elongation.
D) the amino acid valine.
E) a termination tRNA molecule.

A) mRNA; A; P
B) ribosome; P; A
C) tRNA; P; A
D) ribosome; A; P
E) tRNA; A; P

A) in the middle of the loop
B) at the end of the 3' end of the molecule
C) in the first loop
D) along the longest stretch of base pairing in the molecule
E) on the 5 ' end of the molecule

A) degraded immediately.
B) translated into a repeating amino acid chain.
C) translated into a chain of random amino acids not resembling the protein in humans.
D) translated into the protein that is found in humans.
E) integrated into the genome of the yeast.

A) A.
B) D.
C) E.
D) G.
E) F

A) prevent enzymes from degrading the newly synthesized mRNA.
B) inhibit ribosome binding until the appropriate time.
C) initiate chain termination.
D) allow the ribosomes to be properly positioned to translate the message.
E) allow tRNA molecules to successfully bind to mRNA.

A) DNase.
B) DNA polymerase.
C) RNA primase.
D) RNA polymerase.
E) reverse transcriptase.

A) DNA synthesis.
B) translation.
C) transcription.
D) a frame shift mutation.
E) protein synthesis.

A) A.
B) B.
C) C.
D) D.
E) E.

A) The first nucleotide is always a uracil.
B) The first nucleotide is always a cytosine.
C) The first nucleotide retains its triphosphate group, while the others do not.
D) The first nucleotide does not retain its triphosphate group, while the others in the chain do.
E) The first nucleotide is always a modified cytosine.

A) a promoter sequence.
B) DNA polymerase.
C) an RNA primer.
D) a DNA primer.
E) Okazaki fragments.

A) A; P; rDNA
B) P; A; tRNA
C) A; P; mRNA
D) P; A; rRNA
E) P; A; sugar

A) ionically; mRNAs
B) loosely; mRNAs
C) terminally; codons
D) covalently; amino acids
E) enzymatically; codons

A) 1 $\rightarrow$ 2 $\rightarrow$ 3 $\rightarrow$ 4
B) 3 $\rightarrow$ 2 $\rightarrow$ 4 $\rightarrow$ 1
C) 2 $\rightarrow$ 1 $\rightarrow$ 4 $\rightarrow$ 3
D) 4 $\rightarrow$ 2 $\rightarrow$ 1 $\rightarrow$ 3
E) 3 $\rightarrow$ 4 $\rightarrow$ 2 $\rightarrow$ 1

A) They are recognized by ribosomes.
B) They have an anticodon.
C) They have an attachment site for an amino acid.
D) They are recognized by a specific aminoacyl-tRNA synthetase.
E) They are considerably larger than rRNA molecules.

A) releases the growing polypeptide chain.
B) picks up another amino acid to add to the chain.
C) moves to the P site of the ribosome.
D) forms a peptide bond with A site of the ribosome.
E) forms a covalent bond with the P site of the ribosome.

A) 1 $\rightarrow$ 2 $\rightarrow$ 3
B) 1 $\rightarrow$ 3 $\rightarrow$ 2
C) 2 $\rightarrow$ 1 $\rightarrow$ 3
D) 2 $\rightarrow$ 3 $\rightarrow$ 1
E) 3 $\rightarrow$ 2 $\rightarrow$ 1

A) Because mRNA is only required in small quantities.
B) Because transcribing both DNA strands would produce different amino acid sequences.
C) Because the other strand would produce the same amino acid sequence in reverse order.
D) Because all genes are located on the same DNA strand, while the other strand acts as protection.
E) Because the other strand is transcribed directly into amino acids.

A) N-formyl-methionine
B) N-acetyl-adenine
C) adenine triphosphate
D) the AUG codon
E) the UUU codon

A) a DNA sequence that carries information to produce a specific RNA or protein product.
B) a DNA nucleotide sequence that carries information to produce a specific polypeptide.
C) a DNA or RNA sequence that carries information to produce a single polypeptide.
D) a DNA nucleotide sequence that carries information to produce an enzyme.
E) a DNA or RNA sequence that carries information to produce a specific polypeptide.

A) remnants of older life forms.
B) sequences that code for protein domains that are shuffled to form new proteins.
C) the result of mutation of introns.
D) not present in prokaryotes.
E) sequences that interrupt the coding sequences of proteins.

A) no additional energy.
B) activation of the P site.
C) the input of two ATP molecules to supply the needed energy.
D) energy supplied by GTP.
E) phosphorylation of the mRNA molecule.

A) frameshift
B) recombinant
C) nonsense
D) missense
E) neutral

A) the substitution of one base pair for another.
B) the substitution of more than one base pair.
C) the insertion or deletion of one or two base pairs.
D) the substitution of a stop codon for an amino acid-specifying codon.
E) the substitution of a start codon for an amino acid codon.

A) exons; only prokaryotic
B) introns; only prokaryotic
C) exons; only eukaryotic
D) introns; only eukaryotic
E) exons; both prokaryotic and eukaryotic

A) code for specific protein domains.
B) undergo excision, whereby they are spliced out of the message.
C) be able to move within the mRNA, thereby giving rise to new exon combinations.
D) protect pre mRNA from enzyme degradation.
E) code for important amino acid sequences.

A) DNA polymerase
B) DNA-dependent RNA polymerase
C) RNA polymerase
D) primase
E) reverse transcriptase

A) prevents translation.
B) prevents the binding of ribosomes.
C) marks the mRNA for degradation.
D) is added to mRNA but not pre-mRNA.
E) protects mRNA from degradation.

A) removing the last phosphate group.
B) adding a "cap."
C) copying the last few bases so that it can form a duplex structure.
D) adding 100-250 adenine nucleotides.
E) phosphorylation of the mRNA molecule.

A) nonsense
B) frameshift
C) chromosomal
D) missense
E) silent

A) a complex of many ribosomes and an mRNA.
B) a complex of many ribosomes in eukaryotes.
C) an initiation complex in eukaryotes.
D) an elongation complex in eukaryotes.
E) a complex of a ribosome with its two subunits and several mRNAs.