Deck 4: The Three-Dimensional Structure of Proteins

A) always side by side.
B) generally near each other in sequence.
C) invariably restricted to about 7 of the 20 standard amino acids.
D) often on different polypeptide strands.
E) usually near the polypeptide chain's amino terminus or carboxyl terminus.

A) a negatively charged Arg residue.
B) a nonpolar residue near the carboxyl terminus.
C) a positively charged Lys residue.
D) a Pro residue.
E) two Ala residues side by side.

A) alternate between the outside and the inside of the helix.
B) are found on the outside of the helix spiral.
C) cause only right-handed helices to form.
D) generate the hydrogen bonds that form the helix.
E) stack within the interior of the helix.

A) at pH 7, many different peptide bond conformations are equally probable.
B) peptide bonds are essentially planar, with no rotation about the C-N axis.
C) peptide bonds in proteins are unusual, and unlike those in small model compounds.
D) peptide bond structure is extraordinarily complex.
E) primary structure of all proteins is similar, although the secondary and tertiary structure may differ greatly.

A) are roughly parallel to the axis of the helix.
B) are roughly perpendicular to the axis of the helix.
C) occur mainly between electronegative atoms of the R groups.
D) occur only between some of the amino acids of the helix.
E) occur only near the amino and carboxyl termini of the helix.

A) C _$\alpha$ -C and N-C _$\alpha$
B) C=O and N-C
C) C=O and N-C _$\alpha$
D) N-C and C _$\alpha$ -C
E) N-C _$\alpha$ and N-C

A) C _$\alpha$ -N-C _$\alpha$ -C-C _$\alpha$ -N-C _$\alpha$ -C
B) C _$\alpha$ -N-C-C-N-C _$\alpha$
C) C-N-C _$\alpha$ -C _$\alpha$ -C-N
D) C _$\alpha$ -C-N-C _$\alpha$ -C-N
E) C _$\alpha$ -C _$\alpha$ -C-N-C _$\alpha$ -C _$\alpha$ -C

A) an electric dipole spanning several peptide bonds throughout the $\alpha$ helix.
B) interactions between neighboring Asp and Arg residues.
C) interactions between two adjacent hydrophobic Val residues.
D) the presence of an Arg residue near the carboxyl terminus of the $\alpha$ helix.
E) the presence of two Lys residues near the amino terminus of the $\alpha$ helix.

A) 1
B) 2.8
C) 3.6
D) 4.2
E) 10

A) formation of the maximum number of hydrophilic interactions.
B) maximization of ionic interactions.
C) minimization of entropy by the formation of a water solvent shell around the protein.
D) placement of hydrophobic amino acid residues within the interior of the protein.
E) placement of polar amino acid residues around the exterior of the protein.

A) are in a slightly less extended configuration than antiparallel strands.
B) do not have as many disulfide crosslinks between adjacent strands.
C) do not stack in sheets as well as antiparallel strands.
D) have fewer lateral hydrogen bonds than antiparallel strands.
E) have weaker hydrogen bonds laterally between adjacent strands.

A) They involve dipole-dipole interactions.
B) Their strength depends on the distance between the two interacting atoms.
C) They are highly specific.
D) An individual van der Waals interaction does not contribute significantly to the stability of a protein.
E) They can involve hydrophobic amino acids.

A) hydrogen bonds
B) hydrophobic interactions
C) ionic bonds
D) peptide bonds
E) van der Waals forces

A) an amino acids like Thr is highly hydrophobic.
B) covalent interactions may occur between the Thr side chains.
C) electrostatic repulsion occurs between the Thr side chains.
D) steric hindrance occurs between the bulky Thr side chains.
E) the R group of Thr can form a hydrogen bond.

A) entropy increase from the decrease in ordered water molecules forming a solvent shell around it.
B) maximum entropy increase from ionic interactions between the ionized amino acids in a protein.
C) sum of free energies of formation of many weak interactions among the hundreds of amino acids in a protein.
D) sum of free energies of formation of many weak interactions between its polar amino acids and surrounding water.
E) stabilizing effect of hydrogen bonding between the carbonyl group of one peptide bond and the amino group of another.

A) Ala and Gly.
B) hydrophobic.
C) Pro and Gly.
D) those with ionized R-groups.
E) two Cys.

A) antiparallel $\beta$ sheet.
B) parallel $\beta$ sheet.
C) $\alpha$ helix.
D) $\alpha$ sheet.
E) $\beta$ turn.

A) They contain small hydrophobic cores.
B) They represent misfolded conformations of cellular proteins.
C) They have no stable three-dimensional structure and therefore have no cellular function.
D) They are responsible for proteostasis.
E) They can interact with multiple protein-binding partners and are central to protein interaction networks.

A) absence of rotation around the C-N bond because of its partial double-bond character.
B) plane of rotation around the C _$\alpha$ -N bond.
C) region of steric hindrance determined by the large C=O group.
D) region of the peptide bond that contributes to a Ramachandran plot.
E) theoretical space between -180 and +180 degrees that can be occupied by the $\phi$ and $\Psi$ angles in the peptide bond.

A) Y, K, W
B) E, C, F
C) V, I, L
D) R, K, A
E) H, F, W

A) domains.
B) oligomers.
C) peptides.
D) sites.
E) subunits.

A) domain.
B) motif.
C) oligomer.
D) protomer.
E) subunit.

A) amino-acid sequence.
B) evolutionary relationships.
C) function.
D) secondary structure content and arrangement.
E) subunit content and arrangement.

A) folding of denatured RNase into the native, active conformation, requires the input of energy in the form of heat.
B) native ribonuclease does not have a unique secondary and tertiary structure.
C) the completely unfolded enzyme, with all -S-S- bonds broken, is still enzymatically active.
D) the enzyme, dissolved in water, is thermodynamically stable relative to the mixture of amino acids whose residues are contained in RNase.
E) the primary sequence of RNase is sufficient to determine its specific secondary and tertiary structure.

A) They are a form of secondary structure.
B) They are examples of structural motifs.
C) They consist of separate polypeptide chains (subunits).
D) They have been found only in prokaryotic proteins.
E) They may retain their correct shape even when separated from the rest of the protein.

A) inside; oxidizing
B) inside; reducing
C) outside; oxidizing
D) outside; reducing
E) inside; hydrophobic

A) in the interior of a protein of a bacterium that lives in humans.
B) on the exterior of a protein of a bacterium that lives in humans.
C) in the interior of a protein of a thermophilic archaeal organism.
D) on the exterior of a protein of a thermophilic archaeal organism.
E) A salt bridge would be equally likely to be found in any of these cases.

A) proteasome
B) molecular chaperone
C) protein precursor
D) structural motif
E) supersecondary structural unit

A) Collagen is a protein in which the polypeptides are mainly in the $\alpha$ -helix conformation.
B) Disulfide linkages are important for keratin structure.
C) Gly residues are particularly abundant in collagen.
D) Silk fibroin is a protein in which the polypeptide is almost entirely in the $\beta$ conformation.
E) $\alpha$ -keratin is a protein in which the polypeptides are mainly in the $\alpha$ -helix conformation.

A) altering net charge by changing pH
B) changing the salt concentration
C) disruption of weak interactions by boiling
D) exposure to detergents
E) mixing with organic solvents such as acetone

A) a detergent such as sodium dodecyl sulfate.
B) heating to 90°C.
C) iodoacetic acid.
D) pH 10.
E) urea.

A) chaperonins
B) disulfide interchange
C) heat shock proteins
D) peptide bond condensation
E) peptide bond isomerization

A) N, Y, and K
B) I, M, and V
C) V, T, and R
D) M, S, and Y
E) F, Y, and W

A) proteins are synthesized.
B) proteins are folded.
C) proteins are modified.
D) proteins are degraded.
E) protein levels are maintained.

A) A subunit may be similar to other proteins.
B) All subunits must be identical.
C) Many have regulatory roles.
D) Some oligomeric proteins can further associate into large fibers.
E) Some subunits may have nonprotein prosthetic groups.

A) native
B) unique
C) intrinsic
D) inherent
E) natural

A) It may be an essentially random process.
B) It may be defective in some human diseases.
C) It may involve a gradually decreasing range of conformational species.
D) It may involve initial formation of a highly compact state.
E) It may involve initial formation of local secondary structure.

A) evolutionary origin.
B) physico-chemical properties.
C) structure and/or function.
D) subcellular location.
E) subunit structure.

A) "corners" between $\alpha$ -helical regions invariably lacked proline residue.
B) highly polar or charged amino-acid residues tended to be located interiorally.
C) myoglobin was completely different from hemoglobin, as expected.
D) the structure was very compact, with virtually no internal space available for water.
E) the $\alpha$ helix predicted by Pauling and Corey was not found in myoglobin.

A) x-ray crystallography
B) electron microscopy
C) circular dichroism
D) mass spectrometry
E) liquid chromatography

A) parallel $\beta$ sheet.
B) antiparallel $\beta$ sheet.
C) right-handed $\alpha$ helix.
D) left-handed $\alpha$ helix.
E) $\beta$ turn.

A) An $\alpha$ helix from a fibrous protein is left-handed, not right-handed.
B) An $\alpha$ helix from a fibrous protein contains mainly hydrophobic residues, elongating the helix.
C) An $\alpha$ helix from a fibrous protein contains mainly polar residues, elongating the helix.
D) An $\alpha$ helix from a fibrous protein forms a coiled-coil, distorting the helix.
E) An $\alpha$ helix from a fibrous protein contains mainly Gly residues for more efficient packing.

A) Collagen fibrils change their degree of supercoiling over time.
B) Many older adults have vitamin C deficiencies that result in collagen oxidation.
C) As cells age, a variant of collagen is expressed.
D) Crosslinks between collagen fibrils accumulate over time.
E) UV damage to collagen accumulates over time.

A) steric hindrance between the side chain and the peptide backbone.
B) polarity differences between adjacent side chains.
C) hydrophobic interactions between adjacent side chains.
D) steric hindrance between adjacent side chains.
E) too few van der Waals contacts for proper folding.

A) primary
B) secondary
C) tertiary
D) quaternary
E) globular

A) increasing the number of coiled-coils in the supercomplex
B) increasing the number of Pro residues in the polypeptide
C) increasing the number of Cys residues in the polypeptide
D) placing the protein in an oxidizing environment
E) All of these methods could increase the strength of a fibrous protein.

A) primary
B) secondary
C) tertiary
D) quaternary
E) global

A) macromolecular
B) fibrous
C) globular
D) helical
E) membrane

A) parallel $\beta$ sheet.
B) antiparallel $\beta$ sheet.
C) right-handed $\alpha$ helix.
D) left-handed $\alpha$ helix.
E) $\beta$ turn.

A) Both silk and wool fibers have roughly equal distributions of $\alpha$ helices and $\beta$ sheets, but they are arranged in different conformations.
B) Silk is mainly $\beta$ sheets; wool is mainly $\alpha$ helices.
C) Silk is mainly $\alpha$ helices; wool is mainly $\beta$ sheets.
D) Silk contains mainly $\beta$ barrels; wool contains mainly coiled-coil $\alpha$ helices.
E) Silk contains coiled-coil $\alpha$ helices; wool contains mainly $\beta$ barrels.

A) $\beta$ turn; hydrogen bonds with solvent molecules
B) $\beta$ sheet; R-group contacts
C) $\beta$ sheet; internal hydrogen bonds
D) $\alpha$ helix; R-group contacts
E) $\alpha$ helix; internal hydrogen helical bonds

A) Met
B) Cys
C) Ala
D) Gly
E) His

A) NMR
B) x-ray crystallography
C) mass spectrometry
D) circular dichroism
E) electron microscopy

A) right-handed $\alpha$ helix
B) left-handed $\alpha$ helix
C) $\beta$ sheet
D) twisted $\beta$ sheets
E) Amino acids will not adopt this conformation.

A) $\alpha$ helices; decreased ability to serve as hydrogen-bond donors
B) $\alpha$ helices; large positive charge that disrupts the repeating structure
C) $\beta$ sheets; decreased ability to serve as hydrogen-bond donors
D) $\beta$ sheets; large positive charge that disrupts the repeating structure
E) $\beta$ turns; decreased flexibility as an amino acid

A) All of them
B) II, III, and IV
C) I, II, and IV
D) I, II, and III
E) I and IV

A) right-handed $\alpha$ helix
B) left-handed $\alpha$ helix
C) $\beta$ sheet
D) twisted $\beta$ sheets
E) Amino acids will not adopt this conformation

A) NMR
B) x-ray crystallography
C) mass spectrometry
D) circular dichroism
E) electron microscopy

A) N_term-RIFHKVAE-C_term
B) N_term-RIHFKMEA-C_term
C) N_term-RHKEMVAI-C_term
D) N_term-ALIWSQDK-C_term
E) None of the answers is correct.

A) Alzheimer disease
B) diabetes
C) Parkinson disease
D) scurvy
E) All of these diseases are linked to unfolded protein aggregates.

A) Lys $\rightarrow$ Arg
B) Gln $\rightarrow$ Glu
C) Lys $\rightarrow$ Phe
D) Tyr $\rightarrow$ His
E) Trp $\rightarrow$ Ile

A) The conformational changes in GroEL/GroES do not require external energy input.
B) An unfolded protein binds to the hydrophobic surface of the GroEL chamber.
C) Constraining a protein inside the GroEL chamber restricts the conformational space a protein can explore while folding.
D) Constraining a protein inside the GroEL chamber prevents protein aggregation.
E) All of these function in the process of the GroEL/GroES chaperonin.

A) all $\beta$
B) $\alpha$ + $\beta$
C) $\alpha$ / $\beta$ 0
D) $\beta$ / $\alpha$ / $\beta$
E) $\alpha$ / $\beta$ / $\alpha$

A) wrap around their targets.
B) have multiple interaction partners.
C) function as molecular "scavengers."
D) lack a hydrophobic core.
E) All of the answers are correct.

A) The addition of GdnHCl has little effect on protein secondary structure.
B) Increasing temperature causes the protein to become unfolded.
C) Unfolding of this protein is a cooperative process.
D) Ribonuclease A is a heat-stable protein.
E) The peptide bonds of the protein are broken around 3.4 M GdnHCl.

A) Burial of hydrophobic residues requires at least two layers of secondary structure.
B) Generally, $\alpha$ helices and $\beta$ sheets are found in different layers of a protein structure.
C) Residues close together in primary structure are often close together in tertiary structure.
D) The $\beta$ conformation is most stable in a right-handed twist.
E) The backbone of a $\beta$ sheet cannot readily hydrogen bond to an adjacent $\alpha$ helix.

A) The protein may form an inactive aggregate that leads to disease.
B) The protein may be remodeled by a chaperone.
C) The protein may be degraded by the proteasome.
D) The protein may be refolded.
E) All of these consequences are possible.

A) I
B) II
C) III
D) IV
E) None of the answers is correct.

A) I
B) III
C) IV
D) I and III
E) II and IV