Deck 4: Proteins: Three-Dimensional Structure and Function

A) molecular weight
B) isoelectric point
C) tertiary structure
D) pK_a

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

A) cis peptide bonds are weaker.
B) trans peptide bonds are stronger.
C) cis peptide bonds prevent R groups from interacting.
D) trans peptide bonds minimize steric hindrance of R groups.

A) C and N are shorter than typical C-N bonds.
B) C and N are longer than typical C-N bonds.
C) C and O are longer than typical C=O bonds.
D) C and O are shorter than typical C=O bonds.
E) Both A and C

A) fibrous
B) enzyme
C) globular
D) β-strand

A) the peptide bond only
B) N-C_α only
C) N-C_α, C_α-C and C-N bonds
D) N-C_α and C_α-C bonds only

A) X-ray crystallography
B) SDS-PAGE
C) Affinity chromatography
D) NMR

A) Max Perutz
B) Linus Pauling
C) Rosalind Franklin
D) Dorothy Crowfoot

A) The peptide bond has partial double-bond character.
B) The peptide bond is longer than the typical carbon-nitrogen bond.
C) Rotation is restricted about the peptide bond.
D) The carbonyl oxygen and the amide hydrogen are most often in a trans configuration with respect to one another.

A) isoelectric focusing
B) the Edman degradation
C) SDS-PAGE
D) X-ray crystallography

A) In vivo it establishes an equilibrium between two or more active conformations.
B) It has more than fifty amino acids.
C) The active protein involves the association of two or more polypeptide chains.
D) The protein has multiple α-helices.

A) The rotation is free about all bonds in the backbone, except for the bond between the nitrogen and the alpha carbon in proline residues.
B) The bond between the carbonyl carbon and nitrogen is restricted. Other bonds are free to rotate depending only on steric hindrance or the presence of proline residues.
C) All bonds in the backbone have restricted rotation and partial double-bond character.
D) The rotation is free only about the peptide bond. The other bonds are restricted by steric hindrance and the presence of proline residues.

A) determining the specific sequence of amino acids.
B) finding repeating subunit patterns.
C) calculating atomic positions from X-ray diffraction patterns.
D) collimating X-ray beams.

A) Their similarity to structures determined by NMR.
B) The protein crystals are soluble in water.
C) The proteins must align in a regular pattern to form a crystal.
D) Only one conformation is ever possible for a protein so it is irrelevant whether the protein is in a crystal or in solution.

A) minimal configuration
B) native conformation
C) primary structure
D) most stable enantiomer

A) R₁R₂R₃R₄R₅
B) repeating units of N-C
C) repeating units of N-C_α-C
D) repeating units of C_α-C

A) allowed angles of phi and psi for a polypeptide backbone
B) preferred amino acids in an α-helix
C) the hydropathy of amino acids
D) the variation of pH versus volume of base added during titration to determine the pK_a

A) cis-1,2-dichloroethene and trans-1,2-dichloroethene
B) L-glycine and D-glycine
C) eclipsed ethane and staggered ethane
D) pentane and 2-methylbutane

A) rotation about bonds only
B) breaking and reforming of covalent bonds
C) inversion about a center of symmetry
D) Any of the above

A) axial distance
B) rise
C) screw length
D) pitch

A) It is usually right-handed.
B) It is a type of secondary structure.
C) It frequently contains proline residues.
D) It is stabilized by hydrogen bonding.

A) They extend above or below the pleats.
B) They extend radially outward from the helix axis.
C) They point toward the center of the helix.
D) They hydrogen bond extensively with each other.

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

A) has a small, uncharged side chain.
B) has a very bulky side chain.
C) lacks a hydrogen atom on its amide nitrogen.
D) interacts with adjacent amino acids.

A) 2
B) 3
C) 4
D) 5
E) not given

A) four different subunits.
B) four identical subunits.
C) three subunits and one prosthetic group.
D) A or B only
E) A, B or C

A) covalent bonds.
B) hydrophobic interactions exclusively.
C) both strong and weak interactions.
D) hydrophobic and other weak interactions.
E) All of the above

A) 1
B) 4
C) 8
D) 59

A) Oligomers are usually more stable than the free monomers.
B) Active sites can be formed when the protein chains associate.
C) The subunits always are able to maintain the same three-dimensional structure whether they are associated into an oligomer or not.
D) Increased efficiency by the sharing of the same subunit with the same function among different proteins.

A) domains
B) folds
C) homologous regions
D) motifs

A) 200 nm
B) 4.50 nm
C) 16.20 nm
D) 55.5 nm

A) Determined the α-helix structure in keratin.
B) Discovered β-strands and described their assembly into sheets.
C) Determined the three-dimensional structure of hemoglobin and myoglobin.
D) Determined the structure of penicillin.

A) peptide bonds
B) hydrophobic interactions
C) covalent bonds
D) disulfide bonds

A) cytochrome c
B) potassium channel protein
C) MS2 capsid protein
D) hemoglogin
E) bacterial photosynthetic reaction center

A) the pitch of a helix structure.
B) the amphipathic nature of a helix.
C) DNA binding.
D) pleated sheets.

A) two hydrophobic sides of b-sheets interact.
B) two hydrophilic sides of b-sheets interact.
C) an a-helix separates two b-sheets.
D) two amphipathic a-helices interact.

A) The side-chains of all amino acids point to the same side of the sheet.
B) The polypeptide chains in the sheet are nearly fully extended.
C) The range of allowed phi and psi angles is broader than for those in the α-helix.
D) In antiparallel sheets the hydrogen bonds between adjacent strands are nearly perpendicular to the backbones of the strands.

A) Helix formation would be favored at low pH.
B) Helix formation would be favored at high pH.
C) Helix formation would be favored at neutral pH.
D) Helix formation would never occur regardless of pH.

A) 4
B) 3
C) 2
D) 1
E) Cannot determine from the information given

A) renaturation.
B) stabilization.
C) hydrophobic interaction.
D) disulfide bridge formation.
E) cooperativity.

A) carbon dioxide.
B) 2,3 BPG.
C) protons.
D) All of the above
E) A and B above

A) has a single equilibrium constant for oxygen binding.
B) binds more oxygen after the initial proteins first bind oxygen.
C) shows cooperativity.
D) binds up to four molecules of oxygen.
E) All of the above

A) renature and denatured proteins.
B) help cells repair damage due to heat shock.
C) assist protein self assembly.
D) use ATP to fold proteins.
E) All of the above

A) a tetramer of 4 myoglobin proteins.
B) a tetramer of four globin chains and one heme prosthetic group.
C) a dimer of subunits each with two distinct protein chains alpha and beta).
D) a dimer of subunits each with two myoglobin proteins.
E) an erythrocyte.

A) light chains.
B) heavy chains.
C) hypervariable regions.
D) glycoprotein regions.
E) All of the above

A) room temperature 21 °C).
B) 50 ° to 60 °C.
C) temperatures below 50 °C.
D) temperatures above 60 °C.
E) All of the above

A) hydrophobicity.
B) different binding affinities for oxygen.
C) movement of the protein shapes.
D) cooperativity.
E) All of the above

A) they can be made radioactive.
B) they can be readily purified.
C) they are found in very small quantities.
D) they bind very specifically to antigens.
E) they are found everywhere.

A) energy stabilizers.
B) weak chemical interactions.
C) other proteins.
D) low entropy pickets.
E) All of the above

A) viscosity.
B) electrophoretic mobility and gel filtration.
C) UV absorption and light rotation.
D) A, B, and C above
E) A and C above

A) When oxygen binds to heme, the iron ion is oxidized from Fe²⁺ to Fe³⁺.
B) If exposed to air, a free heme group not associated with hemoglobin) is readily oxidized converting Fe²⁺ to Fe³⁺ and can no longer bind oxygen.
C) The heme group is tightly, but non-covalently, held in myoglobin molecule.
D) The chemical structure of the heme groups in myoglobin and hemoglobin are identical.

A) Disulfide bonds have no influence on protein folding since they only form after the protein adopts its native conformation.
B) Proteins occasionally adopt nonnative conformations and form improper disulfide bonds that can be reversed by the enzyme protein disulfide isomerase.
C) The folding of the native conformation is influenced more strongly by the formation of disulfide bonds than by the primary structure of a protein.
D) If a protein forms an improper disulfide bond it is irreversibly inactivated and must be targeted by the cell for degradation.

A) Melting point; SDS-gel electrophoresis
B) SDS-gel electrophoresis; gel-filtration chromatography
C) Acrylamide gel electrophoresis; isoelectric focusing
D) Gel-filtration chromatography; SDS-gel electrophoresis
E) SDS-gel electrophoresis; NMR

A) an active site is shared by different subunits.
B) they are more stable and flexible in movement.
C) different combinations can perform different functions.
D) All of the above
E) A and C above

A) is completely denatured.
B) liquifies.
C) is half denatured.
D) resists denaturation.

A) is induced by hemoglobin.
B) is a result of different affinities for oxygen by each subunit protein.
C) is induced by oxygenation.
D) is a result of interaction with myoglobin.

A) How the disulfide bonds hold it in the correct shape.
B) Proteins can refold even when the amino acid sequence is changed.
C) Proteins refold when the amino acid sequence is the same as in the native conformation.
D) Chaotropic agents cannot denature the native conformation.
E) All of the above

A) covalent bonding to the heme prosthetic group.
B) the folding of the polypeptide chain.
C) the irreversible binding of oxygen.
D) A and B above