Deck 3: Protein Structure and Function

A)zinc ion
B)proline residue
C)cysteine residue
D)histidine residue

A)Motifs are found in secondary structures,while domains are found in tertiary structures.
B)Helices are observed in motifs and domains.
C)Structural domains appear in different proteins with similar functions,while structural motifs have been less conserved over evolution.
D)A domain may be repeated in the same protein,but multiple copies of the same motif are rare.

A)primary structure.
B)secondary structure.
C)tertiary structure.
D)quaternary structure.

A)the enzyme became denatured.
B)bacteria can grow on cooked eggs.
C)the cell membranes were liquefied.
D)cooking sped up chemical reactions.

A)ability of side chains to form hydrogen and ionic bonds
B)backbone sequence of the polypeptide
C)rotations of the planes around the peptide bonds
D)size of side chains

A)secondary structure
B)primary structure
C)tertiary structure
D)quaternary structure

A)threonine
B)phenylalanine
C)glutamine
D)lysine

A)archaea.
B)bacteria.
C)fungi.
D)plants.

A)not likely to form quarternary structures.
B)likely to be an integral membrane protein.
C)not likely to form alpha helices.
D)likely to be found in beta turns.

A)the primary amino acid sequence
B)structural domains such as a DNA-binding domain
C)folded structures such as an α helix
D)structural features such as a turn

A)Amino acids cluster in the primary sequence so that all the hydrophobic amino acids are near each other to facilitate folding into the hydrophobic core of the tertiary structure.
B)All known proteins have well-ordered conformations.
C)Amino acids with hydrophobic,nonpolar side chains stabilize the tertiary structure through hydrogen bonding with water molecules surrounding the proteins.
D)Elements from the secondary structure are maintained in the tertiary structure.

A)A protein's structure determines its function.
B)Other molecules could be needed to allow proteins to fold into their active (ordered)conformation.
C)Quaternary structures are usually very transient (occur for short periods of time).
D)Proteins are crucial for many cell functions.

A)they play a role in the proper folding of proteins.
B)they are located in every cellular compartment.
C)they are found only in mammals.
D)they bind a wide range of proteins.

A)I,II,III,IV
B)III,II,I,IV
C)III,I,II,IV
D)II,III,I,IV

A)double the Vmₐₓ.
B)halve the Vmₐₓ.
C)double the Km.
D)halve the Km.

A)unfolding using energy released by ATPases.
B)entry into the proteasome through the narrow channel in the beta channel.
C)death by a thousand cuts in the alpha subunit rings.
D)complete cleavage into its amino acid monomers.

A)tryptophan residues.
B)serine residues.
C)cysteine residues.
D)tryptophan and cysteine residues.

A)ATP.
B)calcium.
C)cAMP.
D)ATP and cAMP.

A)carboxypeptidases.
B)aminopeptidases.
C)zymogens.
D)none of the above

A)an allosteric inhibitor.
B)a competitive inhibitor.
C)a noncompetitive inhibitor.
D)RNAi.

A)phosphorylation
B)ubiquitinylation
C)acetylation
D)glycosylation

A)is autocatalytic.
B)occurs in all eukaryotes.
C)is an ATP-dependent process.
D)is autocatalytic and occurs in all eukaryotes.

A)The catalytic site is responsible for substrate specificity.
B)Reactions catalyzed by enzymes give the products more free energy than reactions that occur spontaneously.
C)The rate of an enzymatic reaction is always proportional to the concentration of the substrate .
D)Enzymes increase reaction rates by lowering the activation energy needed to reach the transition state.

A)proteolytic activation.
B)positive cooperativity.
C)allostery.
D)ligand-induced activation.

A)recognition of intracellular viruses.
B)regulation of the cell cycle.
C)mRNA stability.
D)nuclear import.

A)centrifugation
B)ion exchange chromatography
C)SDS polyacrylamide gel electrophoresis
D)centrifugation and SDS polyacrylamide gel electrophoresis

A)they function in an aqueous environment.
B)they lower the activation energy of a reaction.
C)they increase the rate of a reaction.
D)a single enzyme typically reacts with many different substrates.

A)determines the shape of the kinetics curve.
B)determines the Vmₐₓ for the reaction.
C)is a measure of the affinity of the substrate for the enzyme.
D)is a measure of the rate of the reaction.

A)proteolytic processing
B)phosphorylation/dephosphorylation
C)ligand binding
D)all of the above

A)specificity.
B)affinity.
C)epitope.
D)specificity and affinity.

A)They hydrolyze GTP into GDP and Pᵢ.
B)They decrease the GTPase activity of the G-protein.
C)They catalyze the dissociation of GDP on the G-protein to therefore promote the replacement of GTP.
D)none of the above

A)RNAi
B)ubiquitin
C)proteasome
D)b and c

A)IEF;SDS-PAGE
B)SDS-PAGE;affinity chromatography
C)SDS-PAGE;ion exchange
D)IEF;gel filtration

A)14.3 days
B)28.6 days
C)42.9 days
D)57.2 days

A)charge.
B)mass.
C)affinity for a ligand.
D)mass and charge.

A)Depending on the speed of the centrifugation,the proteasome is more likely to be in the supernatant than a chaperone.
B)Proteins of similar density will be found in the same fraction (either pellet or supernatant).
C)The pellet contains the least dense material.
D)The pellet will contain a purified protein for further analysis.

A)examine where a protein is located within the cytosol of a cell.
B)compare thousands of samples from different people in the same experiment.
C)examine which proteins differ in abundance between a normal sample and a disease sample.
D)use antibodies to label specific proteins on an SDS-PAGE gel.

A)identification of thousands of proteins' amino acid sequences within a single cell.
B)characterization of proteolytically digested pieces of proteins from the sample.
C)identification of all the protein complexes present in certain yeast species.
D)identification of proteins within each organelle in liver tissue.

A)DNA.
B)RNA.
C)protein.
D)carbohydrate.