Deck 22: Gene Expression: II Protein Synthesis and Sorting

A)tuberculosis
B)scrapie
C)mad cow disease
D)Creutzfeldt- Jacob disease

A)have a signal peptidase error.
B)are synthesizing cytoplasmic proteins.
C)do not make the appropriate anchor protein.
D)have a defect in ribosomal proteins that allow attachment to the surface.
E)all of the above

A)the DNA and plasmids for the incorporation of a second complete copy of the malate dehydrogenase gene.
B)the DNA sequence to see if a suppresor mutation has occurred.
C)other proteins to see if other stop codons are ignored, indicating the presence of a suppresor tRNA.
D)the DNA sequence to see if a reversion has occurred.
E)all of the above

A)prokaryotic translation.
B)prokaryotic transcription.
C)eukaryotic translation.
D)both A and C
E)both B and C

A)prokaryotes.
B)algae.
C)mosses.
D)eukaryotes.
E)fungi.

A)16S
B)18S
C)30S
D)both A and B
E)all of the above

A)eukaryotic translation.
B)prokaryotic translation.
C)prokaryotic modification.
D)both prokaryotic and eukaryotic translation.
E)neither prokaryotic nor eukaryotic translation.

A)There may be a mutation in the Shine Delgarno sequence of the DNA, resulting in a RNA that poorly binds the ribosome.
B)These bacteria may not manufacture enough translation factors for effective translation.
C)This mutant may have altered tRNA molecules, such that the codon- anticodon interaction during translation is affected.
D)There may be a mutation in the ribosomal rRNA recognizing the Shine Delgarno sequence of the message.
E)In this mutant, the ribosomal subunits may not associate well enough for effective translation.

A)duplication.
B)nonstop.
C)inversion.
D)translocation.
E)nonsense.

A)suppressor tRNAs encode an amino acid for a stop signal
B)suppressor tRNAs encode a four- nucleotide anticodon
C)suppressor tRNAs encode a two- nucleotide anticodon
D)both B and C
E)all of the above

A)The different messages have sequences with more or less homology to the Shine Delgarno sequence; fewer ribosomes binding results in less product.
B)There is no termination sequence at the end of each gene, so one long protein is made, resulting in equal amounts of products.
C)Feedback regulation of ribosomes tells the cell that enough product is made, and ribosomes from such mRNAs dissociate.
D)Because transcription and translation in prokaryotes are essentially coupled, there is no gradation in the amount of individual proteins made from a polycistronic message.
E)all of the above

A)archaea.
B)prokaryotes.
C)eukaryotes.
D)all of the above
E)none of the above

A)more than one protein.
B)exclusively archaeal proteins.
C)one product that it alternatively spliced.
D)a single message.
E)none of the above

A)glycosylation
B)addition of lipid groups
C)specific cleavage of polypeptides
D)polyadenylation
E)chaperonin activity

A)prokaryotes.
B)eukaryotes.
C)cyanobacteria.
D)yeast only.
E)both A and B

A)formation of the initiation complex
B)translocation of the ribosome
C)release of polypeptide
D)binding of the aminoacyl tRNA to codon at the A site
E)aminoacylation of tRNA

A)proteosome function.
B)translocase.
C)the enzyme foldase.
D)insertion of proper amino acids during translation.
E)chaperone activity.

A)nonsense- mediated decay.
B)directed RNase activity.
C)error- mediated repair.
D)nonstop decay.
E)none of the above

A)DNA replication
B)eukaryotic translation
C)E.coli translation
D)eukaryotic transcription
E)chaperonin activity

A)It is associated with the large subunit of ribosomes.
B)It requires no outside source of additional energy, such as ATP.
C)It is a ribozyme having catalytic activity.
D)It moves the ribosome, so translation continues.
E)It catalyzes peptide bond formation.

A)AAA
B)UAG
C)AUG
D)UUU
E)AGG

A)amyloid plaques.
B)apoplipoprotein E.
C)tau protein.
D)prions.
E)E- cadherin.

A)IF- 3 interaction with an aminoacyl tRNA
B)EF- Tu interaction with an aminoacyl tRNA
C)EF- Tu placement of N- formyl met onto the ribosome
D)EF- Ts translocation of tRNAs from the A site to the P site
E)all of the above

A)posttranslational import
B)transportin mechanisms
C)the activity of ribosomes
D)the importin protein
E)cotranslational import

A)degenerate.
B)inverse.
C)complementary.
D)redundant.
E)ambiguous.

A)inteins.
B)exons.
C)cleaved.
D)introns.
E)exteins.

A)incorporate radioactive amino acids into the protein.
B)incorporate appropriate DNA sequence to create signal sequences into mature peptide.
C)do nothing; all proteins go through the ER.
D)incorporate appropriateDNA sequence to create signal sequences into the mature peptide.
E)incorporate appropriate mannose- 6- phosphate groups.

A)proteosome.
B)protease.
C)inteins.
D)all of the above
E)none of the above

A)catalysis by RNA polymerase
B)attachment of f- Met aminoacyl tRNA
C)binding of mRNA to a ribosome
D)aminoacylation of the tRNA molecule
E)joining of 30S and 50S ribosomal subunits into 70S ribsomes

A)inversion.
B)nonsense.
C)translocation.
D)duplication.
E)point mutation.

A)error- mediate repair.
B)directed Rnase activity.
C)nonsense- mediated decay.
D)nonstop decay.
E)none of the above