Deck 10: Protein Synthesis, Processing, and Regulation

A) 62; 40
B) 62; 20
C) 50; 20
D) 40; 20

A) redundancy.
B) wobble.
C) reading frameshift.
D) degeneracy.

A) Ribosomes
B) Endoplasmic reticulum
C) Nuclear envelope
D) Mitochondria

A) the same.
B) 30S and 50S, respectively.
C) 40S and 60S, respectively.
D) 70S and 80S, respectively.

A) Ribosomes are inactive after protease digestion.
B) Ribosomes are inactive after RNase digestion.
C) Structural analysis shows that proteins occupy the catalytic site where peptide bonds are formed.
D) Structural analysis shows that mRNA occupies the catalytic site where peptide bonds are formed.

A) Proteins of the small subunit
B) 16S rRNA
C) Proteins of the large subunit
D) 23S rRNA

A) A Shine-Dalgarno sequence
B) The 7-methylguanosine cap
C) A TATA sequence
D) A CCAAT sequence

A) initiation factors; initiation codon
B) initiation factors; small ribosomal subunit
C) the small ribosomal subunit; initiation codon
D) the initiator tRNA; initiation codon

A) any amino acid.
B) glutamine.
C) methionine.
D) N-formylmethionine.

A) 5ʹ to 3ʹ; carboxyl to the amino
B) 5ʹ to 3ʹ; amino to the carboxyl
C) 3ʹ to 5ʹ; carboxyl to the amino
D) 3ʹ to 5ʹ; amino to the carboxyl

A) ribosome.
B) transfer RNA.
C) small cytoplasmic RNA.
D) aminoacyl tRNA synthetase.

A) the 3ʹ end of the mRNA.
B) a site downstream of a 3ʹ untranslated region.
C) the 5ʹ end of the mRNA.
D) a site downstream of a 5ʹ untranslated region.

A) eIF1.
B) eRF1.
C) eIF2.
D) eE $\alpha$ .

A) tRNA binds to a termination codon via a complementary anticodon but lacks an amino acid.
B) a protein release factor binds to the termination codon.
C) a tRNA with a complementary anticodon binds to a termination codon, and a release factor bound to the CCA end releases the chain.
D) a small molecule shaped like puromycin binds to the termination codon.

A) regulates message degradation.
B) interferes with the 5ʹ cap binding to the ribosome.
C) blocks the translation start site.
D) inhibits the binding of eEF2.

A) translation of its mRNA only.
B) transcription of its gene and translation of its mRNA only.
C) translation of its mRNA and degradation of the protein only.
D) transcription of its gene, translation of its mRNA, and degradation of the protein.

A) no cap; adding a cap
B) long poly-A tails; shortening the tails
C) short poly-A tails; lengthening the tails
D) bound siRNA; removing the siRNA

A) an enzyme catalyzed reaction.
B) a tRNA catalyzed reaction.
C) a tRNA synthase catalyzed reaction.
D) an rRNA catalyzed reaction.

A) transcription, by binding to specific genes.
B) transcription, by formation of heterochromatin.
C) translation, by blocking ribosomal attachment.
D) translation, by binding to an mRNA.

A) allows them to be recycled back to the ribosome.
B) allows them to initiate translation.
C) blocks their exchange of bound GDP for GTP.
D) blocks the addition of a terminal phosphate to the bound GDP.

A) sequence of nucleotides of its gene.
B) primary sequence of its amino acids.
C) chaperones with which it interacts.
D) pathway by which it folds.

A) are expressed at higher levels after a heat shock than under normal growth conditions.
B) cause fever in mammals.
C) misfold during a heat shock.
D) denature at high temperatures.

A) protein only.
B) protein and RNA.
C) protein and DNA.
D) RNA surrounded by a lipid-protein coat.

A) cytosol.
B) lumen of the endoplasmic reticulum.
C) matrix of mitochondria.
D) lumen of lysosomes.

A) disrupts the normal interactions of CFTR with chaperones in the endoplasmic reticulum, leading to defective protein folding and reduced levels of functional CFTR in the plasma membranes of affected cells.
B) leads to misfolded proteins, which aggregate to form insoluble amyloid fibrils characterized by β-sheet structures.
C) precludes CFTR phosphorylation by a protein kinase, which is necessary for activation of this protein.
D) prevents ATP hydrolysis required for the active transport of Cl^- by CFTR.

A) a prenyl group.
B) myristic acid.
C) dolichol phosphate.
D) phosphatidylinositol.

A) free amino group at the amino terminal end of the polypeptide.
B) amino group of asparagine.
C) amino group of lysine.
D) carboxyl group of aspartic acid.

A) Myristate
B) Farnesyl
C) Palmitate
D) Glycolipid

A) GDP
B) GTP
C) ADP
D) ATP

A) lysine.
B) cysteine.
C) tyrosine.
D) serine and threonine.

A) protein phosphatases.
B) phosphoproteases.
C) protein phosphorylases.
D) protein kinases.

A) Serine
B) Threonine
C) Tryptophan
D) Tyrosine

A) cAMP
B) the plasma membrane
C) ATP
D) GTP

A) Growth hormone
B) Insulin
C) Steroid hormones
D) Epinephrine

A) Adenylyl cyclase
B) cAMP-dependent protein kinase
C) Protein kinase C
D) Phosphorylase kinase

A) glutathione
B) ubiquinone
C) ubiquitin
D) KDEL

A) vesicle containing proteolytic enzymes.
B) precursor to lysosomes.
C) complex of a proteolytic enzyme and the protein that is being degraded.
D) multisubunit protease complex that degrades proteins marked for destruction.

A) is degraded.
B) is released and recycled.
C) is phosphorylated.
D) has a GTP group added.

A) tubulin.
B) cyclin.
C) Ras.
D) cAMP-dependent protein kinase.

A) tRNAs are approximately 70-80 bases long and form a cloverleaf structure.
B) All tRNAs have a CCA sequence at their 3ʹ terminus.
C) tRNAs differ in sequence only at the anticodon.
D) There are several modified bases present in mature tRNAs.

A) covalently attach amino acids to their corresponding tRNA molecules.
B) synthesize tRNA molecules.
C) catalyze the formation of the aminoacyl ATP intermediate during amino acid attachment to tRNAs.
D) catalyze the formation of a peptide bond between amino acids.

A) The amino acid is first joined to AMP, forming an aminoacyl AMP intermediate.
B) Two molecules of ATP are required for the process, one at each step.
C) Aminoacyl tRNA synthetases catalyze the reaction.
D) The amino acid is transferred to the 3ʹ end of the tRNA.

A) the amino acid encoded by the first 5ʹ codon.
B) valine.
C) N-formylmethionine.
D) methionine.

A) the first codon located at the 5ʹ end of the mRNA.
B) recognized by scanning of the ribosome downstream of the 5ʹ 7-methylguanosine cap.
C) recognized via the Shine-Dalgarno sequence.
D) the first 5ʹ AUG of the mRNA.

A) In prokaryotes, ribosomes often bind the mRNA and can scan 5ʹ or 3ʹ until recognizing a Shine-Dalgarno sequence.
B) Viral mRNAs contain internal ribosome entry sites that allow ribosomes to bind to an internal site of the mRNA.
C) Initiation codons in prokaryotic cells are preceded by Shine-Dalgarno sequences.
D) 5ʹ 7-methylguanosine caps serve as the point of recognition and binding for ribosomes in eukaryotic cells.

A) Inhibiting translational initiation
B) Inducing premature polypeptide chain termination
C) Inhibiting aminoacyl tRNA binding
D) All of the above

A) serve as a scaffold for the ribosomal proteins.
B) assist in the proper positioning of tRNAs along the mRNA template.
C) catalyze peptide bond formation.
D) assist in the proper folding of ribosomal proteins.

A) stimulates a protein to bind the ferritin mRNA and inhibit its degradation.
B) stimulates the dissociation of a translational inhibitor from the ferritin mRNA.
C) binding stabilizes the ferritin protein.
D) stimulates the extension of poly-A tails of ferritin mRNAs.