Deck 31: Completing the Protein Life Cycle: Folding, Processing, and Degradation

A) primary structure
B) amino acid content
C) content of hydrophobic amino acids
D) content of basic amino acids
E) none are true

A) translocator; N
B) leader; C
C) translocational; N
D) stop-transfer; C
E) translocon; N

A) translocon; endoplasmic reticulum
B) signal sequence; plasma
C) EF-G; endoplasmic reticulum
D) chaperonin; plasma
E) all are true

A) positively; folded; Hsp40
B) positively; unfolded; Hsp70
C) negatively; folded; Hsp70
D) neutral; unfolded; Hsp40
E) negatively; prefolded; Hsp90

A) hydrogen bonding; dehydration
B) hydrogen bonding; non-specific bonding
C) hydrophobic interactions; aggregation
D) hydrophilic interactions; non-specific binding
E) none are true

A) carbohydrate addition.
B) lipid addition.
C) phosphorylation.
D) adding signal sequences.
E) proteolytic cleavage.

A) inactivation of regulatory enzymes.
B) elimination of the N-terminal Met residue.
C) activation of zymogens.
D) elimination of signal sequences after the protein has reached its proper location.
E) digestion of dietary proteins.

A) polyglutamine aggregates
B) neurofibrillary tangles of polymeric microtubule-binding protein tau
C) extracellular deposits of amyloid-β and intracellular neurofibrillary tangles of microtubule-binding protein tau
D) mutation in the huntingtin gene
E) none of the above

A) proteins to be translocated are made as pre-proteins containing contiguous blocks of amino acid sequences that act as sorting signals.
B) membranes involved in translocation have specific protein receptors exposed on their cytosolic faces.
C) translocons catalyze movement of the proteins across the membrane and metabolic energy in the form of ATP, GTP, or membrane potential is essential.
D) pre-proteins are maintained in a loosely folded, translocation-competent conformation through interaction with molecular chaperones.
E) all are characteristics.

A) chaperonin; trigger factor; H-binding
B) trigger factor; DnaK; hydrophobic
C) DnaK; Hsp70; ionic
D) Hsp70; chaperonin; hydrophilic
E) all are true

A) 1-2% of total cytosolic proteins in eukaryotes.
B) action depends on cyclic binding and hydrolysis of ATP.
C) major purpose is conformational regulation of signal transduction molecules.
D) directs proteins toward degradation pathways.
E) all are true.

A) A, B, C, D, E
B) B, A, C, D, E
C) C, D, A, E, B
D) C, A, D, E, B
E) D, C, E, A, B

A) sec61 complex at the core.
B) transmembrane protein-conducting channel.
C) BiP carries out ATP-dependent protein folding.
D) composed of a single transmembrane spanning (TMS) protein.
E) all are true.

A) GroEL serves as a cap for GroES
B) GroES is a large, cylindrical protein complex
C) DnaK works with DnaJ to sequester hydrophobic regions of peptides
D) while the GroEL-GroES complex requires ATP to aid in protein folding, the DnaK-DnaJ system does not
E) all are true.

A) Hsp40; un-; Hsp70
B) Hsp90; un-; chaperonin
C) Hsp70; partially; chaperonin
D) Hsp40; partially; Hsp70
E) Hsp60; partially; Hsp40

A) the Hsp70 proteins bind to hydrophilic regions of the protein, thus preventing aggregation
B) the Hsp60 proteins are also known as chaperonins
C) the GroEL protein provides an environment free from possibility of aggregation
D) the GroES protein serves as the cap for GroEL
E) all are correct

A) Signal recognition particles; signal receptors; translocons
B) Signal receptors; translocons; signal recognition particles
C) Translocons; signal recognition particles; signal receptors
D) Signal receptors; signal recognition particles; translocons
E) Translocons; signal receptors; signal recognition particles

A) A, C, E, B, D
B) C, D, A, B, E
C) C, A, D, B, E
D) A, C, B, D, E
E) C, B, D, E, A

A) cleave large inactive pro-proteins.
B) remove leader peptides after translocation.
C) transfer a Met to the C-terminal end for translocation.
D) remove invariable Met and introduce N-terminal diversity.
E) all are true.

A) proteins with Met as the N-terminal amino acid
B) proteins with short sequences rich in Pro, Glu, Ser and Thr
C) proteins with short sequences rich in Trp, Thr, and Phe
D) proteins having a C-terminal Cys for the formation of a thioester bond with ubiquitin
E) none of the above

A) ricin
B) met-aminopeptidase
C) ubiquitin
D) degradase
E) peptidyl transferase

A) TOM; TIM22
B) TOM; TIM23
C) SAM; TOM; TIM22
D) TOM; SAM; TIM22
E) SAM; TOM; TIM23

A) The modified protein is degraded by an ATP-dependent protease complex.
B) The ubiquitin binding to the protein to be degraded leads to a novel branched protein.
C) The ubiquitin is covalently attached to a cysteine residue in the protein to be degraded.
D) Three additional proteins (E₁, E₂, and E₃) are involved in the ligation of ubiquitin to the protein.
E) Ubiquitin is a highly conserved protein.

A) helical stabilizing protein
B) hydrophobic sequestering protein
C) heat shock protein
D) high-histidine subunit protein
E) none of the above

A) ribosomes; endoplasmic reticulum
B) ribosomes; Golgi
C) proteosomes; mitochondria
D) proteasomes; lysosomes
E) lysosomes; endoplasmic reticulum

A) Ser; ester
B) Lys; amide
C) α-amine group of the N-terminal amino acid if the particular residue is Arg, Lys, His, Phe, Tyr, Trp, Leu, Asn, Gln, Asp or Glu; amide
D) Glu; acid anhydride
E) Cys; thioester

A) addition of SUMO targets a protein for destruction by a slightly different pathway than attachment of ubiquitin
B) addition of SUMO often changes the conformation of a protein so that it interacts with other proteins in a different manner
C) addition of SUMO targets a protein for transport into the mitochondria
D) the addition of SUMO occurs during the translation process and is meant to stall translation of certain proteins
E) none of the above

A) hydrolysis; unfolded; disposal
B) regulatory; unfolded; disposal
C) hydrolysis; ubiquitinylated; degradation
D) regulatory; ubiquitinylated; degradation
E) all are true

A) ATP-dependent.
B) chaperones at low temperatures.
C) proteases at high temperatures.
D) bind misfolded or unfolded proteins.
E) all are true.

A) A, C, B, D, E
B) E, D, A, B, C
C) D, E, C, A, B
D) C, E, D, B, A
E) E, D, C, B, A