Deck 3: Protein I: Composition and Structure

A) hydrogen bonds.
B) charged dipoles.
C) hydrophobic interactions.
D) disulfide bridges.
E) hydration by water.

A) contains an amino group.
B) can form an ester with an alcohol.
C) contains a sulfhydryl group.
D) is that of histidine.
E) is that of glutamate.

A) proline.
B) lysine.
C) arginine.
D) asparagine.
E) histidine.

A) they are a complex of protein, phospholipids and neutral lipids.
B) they are found in the plasma and cellular membrane.
C) they are covalent complexes of lipids and proteins.
D) the lipids and proteins are separable from one another by treatment with detergent.
E) most or all of the lipid can be removed from the protein by extraction with chloroform-methanol mixtures.

A) size of the polypeptide chain
B) net charge of the native protein
C) net charge of the denatured protein
D) all of the above
E) none of the above

A) planarity.
B) freedom to rotate.
C) polarity.
D) greater stability in TRANS configuration.
E) partial double bond character.

A) no ionized groups.
B) no positively charged groups.
C) no negatively charged groups.
D) equal numbers of positively and negatively charged groups.
E) an increased affinity for substrate.

A) a pH values above Pi.
B) a pH values below Pi.
C) a pH value = Pi.
D) low salt concentrations.
E) none of the above

A) Hydrogen bonds between groups involved in peptide bonding.
B) Hydrogen bonds between amino acid side chains.
C) Electrostatic interactions.
D) Hydrophobic bonding.
E) They are all involved.

A) aggregation.
B) denaturation.
C) alteration of electrostatic interactions.
D) rupture of covalent bonds.
E) rupture of hydrophobic bonds.

A) Covalent
B) Electrostatic
C) Hydrogen
D) Hydrophobic
E) Van der Waals

A) Precipitation with ethanol
B) Gel filtration
C) Ultracentrifugation
D) Electrophoresis

A) serine
B) threonine
C) lysine
D) hydroxylysine
E) asparagines

A) Glutamate
B) Serine
C) Valine
D) Glutamine
E) Arginine

A) Diethylaminoethyl (DEAE) chromatography
B) Two dimensional gel electrophoresis
C) Isoelectric focusing
D) Gel filtration chromatography

A) salt bridges
B) hydrogen bonds
C) van der Waals forces
D) hydrophobic interactions
E) disulfide crosslinks

A) The alpha-helix conformation is stabilized by hydrophobic interactions.
B) The beta-sheet conformation is rarely found in globular proteins.
C) The folding of a polypeptide into a globular structure results in an interior enriched with hydrophobic amino acids.
D) The primary structure does not influence the native tertiary structure.
E) The subunits of proteins with quaternary structure associate through covalent bonds.

A) Tryptophan
B) Proline
C) Tyrosine
D) Histidine
E) Isoleucine

A) the same amino acid composition.
B) the same sedimentation coefficient.
C) the same diffusion coefficient.
D) the same conformation.
E) none of the above

A) cystine is two cysteine molecules covalently attached by a disulfide bridge
B) cystine is formed by the reduction of two cysteines
C) cystine is a dipeptide
D) cystine is a tripeptide
E) cystine forms disulfide bridges with methionine

A) contain amino acids.
B) include all the nitrogen compounds of tissues.
C) are salts of amino acids linked with one another.
D) are polymers formed by hydrogen bonding between the amino acids.
E) are polymers formed by amide linkages between the carboxyl and alpha-amino groups of alpha-amino acids.

A) Replacement of glutamate with lysine.
B) Replacement of valine with alanine.
C) Replacement of aspartic acid with glutamic acid.
D) Replacement of lysine with arginine.

A) a metabolic pathway for catabolism of proteins.
B) a chemical method for determination of the N-terminal amino acid sequence of proteins and polypeptides.
C) an enzymatic method for determination of the C-terminal sequence of proteins and polypeptides.
D) a chemical method for determination of the C-terminal sequence of proteins and polypeptides.
E) None of the above statements correctly refer to the Edman degradation.

A) the alpha-helix is right-handed.
B) there are 3.6 amino acids per turn of the alpha-helix.
C) the R groups of the amino acids are externally directed.
D) the alpha-helix is stabilized primarily by hydrophobic interactions.
E) the structure of the alpha-helix was predicted before it was observed in a protein

A) isoleucine
B) threonine
C) arginine
D) valine
E) lysine

A) It is primarily dependent upon hydrogen bonding.
B) It is primarily dependent upon disulfide linkages.
C) It is found in all proteins.
D) It refers to interactions between adjacent chains in fibrous proteins.

A) a decrease in free carboxyl groups.
B) an increase in free amino groups.
C) a large decrease in pH.
D) formation of peptide bonds.
E) a decrease in free amino groups.

A) Beta-pleated sheet
B) collagen triple helix
C) Alpha-helix
D) Beta-bend
E) disulfide bridge

A) Precipitation with ethanol
B) Gel filtration
C) Ultracentrifugation
D) Electrophoresis

A) creates partial double-bond character among three atoms.
B) permits unrestricted rotations about each chemical bond.
C) places the alpha-carbons in the "centers" of two different planes.
D) retains the chemical properties of the typical ester bond.

A) Evolutionary development
B) Ratio of a-helices to b-pleated sheets
C) Similar function
D) Similar primary structure
E) Thermodynamic stability

A) 1
B) 3
C) 5
D) 7
E) 11

A) Disulfide interactions are required for the stability of globular structures.
B) Hydrophobic sidechains commonly occur clustered in interior areas of globular proteins.
C) The alpha-helix is maintained chiefly by hydrophobic interactions.
D) Covalent linkages between the protomeric chains are a common feature of globular oligomeric proteins such as hemoglobin and lactate dehydrogenase (LDH).
E) Pleated-sheet structures are found only in fibrous proteins.

A) Isoleucine, valine and tryptophan tend to be in the interior of protein molecules.
B) Catalytically functional groups include aspartate, histidine and cysteine.
C) Tyrosine, phenylalanine and threonine participate in hydrogen bond formation.
D) Lysine, arginine and glutamate form ionic bonds with substrates and other protein components.
E) Lysine, cysteine and tyrosine have pKa's higher than 7.0.

A) proteins are least soluble.
B) the net ionic charge is zero.
C) repulsive forces between proteins are at a minimum.
D) the pH of the solution may vary widely from protein to protein.
E) all of the above

A) Disulfide bridges.
B) Hydrophobic bonds.
C) Amide linkages between amino acid sidechains.
D) Ester linkages between sidechains of acidic and alcoholic amino acids.
E) Hydrogen bonds to water molecules.

A) Serine : polar, uncharged.
B) Glutamic : polar, acidic.
C) Arginine : polar, basic.
D) Histidine : nonpolar, uncharged.
E) Phenylalanine : nonpolar, uncharged.

A) a net negative charge.
B) a net positive charge.
C) a positive charge equal to the negative charge.
D) no ionic charge.
E) an unknown charge, since its concentration is not specified.

A) quaternary structure
B) tertiary structure
C) secondary structure
D) primary structure
E) none of the above

A) helical content
B) subunit content
C) disulfide interactions
D) ligand binding specificity
E) isoionic point

A) after the incorporation of a prosthetic group during polypeptide folding.
B) by non-covalent interactions among the amino acid side chains.
C) following the hydrolysis of ATP.
D) in the presence of one or more chaperones.
E) near the ends of these structural conformations.

A) asp-his-lys
B) arg-pro-gly
C) asn-glu-val
D) gln-his-arg

A) 2.6
B) 3.2
C) 3.6
D) 4.2
E) none of the above

A) circular dichroism
B) sedimentation velocity ultracentrifugation
C) SDS polyacrylamide gel electrophoresis
D) gel chromatography in dilute buffer
E) cellulose acetate electrophoresis

A) hydroxylysine.
B) proline.
C) lysine.
D) glycine.
E) desmosine.

A) the absolute configuration of the asymmetric C-atom as compared to L-glyceraldehyde.
B) the levorotation of plane polarized light by solutions of these compounds.
C) the fact that the amino group is attached to C-atom #1.
D) the designation is of historical origin and bears no relationship to structure.
E) none of the above

A)+3
B)+2
C)+1
D)-1
E)-2

A) phospholipid.
B) cholesterol ester.
C) triglyceride.
D) ganglioside.

A) alpha-lipoprotein
B) beta-lipoprotein
C) pre-beta-lipoprotein
D) chylomicrons
E) pre-albumin

A) alpha-helix.
B) Beta-sheet conformation.
C) Reverse-turn (beta bend).
D) Random coil.
E) Collagen triple helix.

A) Other than peptide bonds, hydrogen bonding is the most important interaction in pleated sheet and alpha-helical structures.
B) The peptide bond is one kind of amide linkage.
C) The native state of a protein is the least stable form under cell conditions and accordingly is easily denatured.
D) In the alpha helix, the amino acid side chains project out from the coiled backbone of the polypeptide chain.
E) Globular proteins often contain a pocket or groove into which a prosthetic group or substrate can fit.

A) leucine.
B) isoleucine.
C) alanine.
D) tyrosine.
E) phenylalanine.

A) a repeating tripeptide sequence, Gly-Xaa-Pro or Gly-Xaa-HyPro
B) a long triple helix
C) the unusual amino acid hydroxyproline
D) glycine at every third residue of the helix
E) beta-pleated sheet secondary structure

A) acylation.
B) peptide bond formation.
C) reduction.
D) oxidation.
E) esterification.

A) the disruption of covalent bonds.
B) the disruption of non-covalent bonds.
C) the binding of toxic compounds.
D) changes in primary structure.
E) changes in the state of aggregation.

A) Arginine
B) Aspartate
C) Methionine
D) Leucine
E) Serine

A) a triple helix.
B) a double alpha-helix.
C) antiparallel beta-sheet regions.
D) mostly random coil regions.
E) the lack of any stable conformation.

A) 1.96
B) 5.07
C) 8.18
D) 9.23
E) 10.28

A) contains a sulfhydryl group
B) contains an alcoholic group
C) contains an branched chain hydrocarbon
D) doesn't have a side chain
E) contains an acidic group

A) complementary DNA analysis.
B) ion-exchange chromatography.
C) polyacrylamide gel electrophoresis.
D) ultraviolet spectroscopy.
E) x-ray crystallography.

A) no ionized groups.
B) no positively charged groups.
C) no negatively charged groups.
D) equal numbers of positively and negatively charged groups.
E) none of the above

A)6 5
B)7 5
C)7 4
D)6 4
E)5 7

A) no basic amino acids
B) no acidic amino acids
C) no neutral amino acids
D) more basic than acidic amino acids
E) more acidic than basic amino acids

A) ser-gly-lys-phe-lys
B) gly-lys-ser-lys-phe
C) ser-gly-lys-lys-phe
D) phe-lys-gly-ser-lys
E) ser-lys-gly-lys-phe

A) hydrogen bonding.
B) hydrophobic interactions.
C) ionic interactions.
D) disulfide bonding.
E) van der Waals forces.

A) Glycine.
B) Isoleucine.
C) Lysine.
D) Serine.
E) Aspartate.

A) Isoelectric point.
B) pH of maximum buffering.
C) Intrinsic viscosity.
D) amino acid composition.
E) Ultraviolet absorption.

A) contains a branched chain hydrocarbon
B) contains a sulfhydryl group
C) contains an aromatic ring
D) contains a methyl group
E) contains an amide

A) disulfide bonds.
B) hydrogen bonds perpendicular to the axis.
C) salt links.
D) hydrogen bonds randomly placed.
E) hydrogen bonds parallel to the axis.

A) Proteins contain only L amino acids.
B) Hydrogen bonding.
C) Steric hindrance.
D) The peptide bond is trans rather than cis.
E) The partial double bond character of the carbon-nitrogen bond.

A) difference spectroscopy.
B) reversible denaturation.
C) atomic adsorption.
D) hydrodynamic analysis.
E) sequence analysis.

A) ability to form intrachain hydrogen bonds.
B) amino acid sequence.
C) folding induced by disulfide linkages.
D) ability to form subunit structures.
E) ability to form interchain hydrogen bonds.

A) lysine
B) threonine
C) isoleucine
D) arginine
E) aspartic acid

A) Collagen is the most abundant protein in the human.
B) Collagen has an amino acid composition typical of that found in most soluble proteins.
C) Collagen is a very inelastic protein in the native state.
D) Collagen is a very insoluble protein in the native state.
E) Collagen is made up of subunits termed tropocollagen.

A) Alanine.
B) Proline.
C) Isoleucine.
D) Threonine.
E) Phenylalanine.

A) amino acid residues on the surface of the protein are polar.
B) amino acid residues in the interior are hydrophobic.
C) Charged amino acids on the protein interact with ions in the environment.
D) The alpha-helix or the pleated sheet is present in most proteins.
E) Hydrogen bonds in the peptide backbone play a minor role in the structure of the protein.

A) leu-val-phe
B) cys-his-ala
C) ile-ser-trp
D) val-arg-pro
E) asp-lys-ser

A) contributes atoms to hydrophobic interactions.
B) exhibits unrestricted rotation around the C-N bond.
C) is formed between the side chains of Glu and Lys residues.
D) is planar and partially ionic.

A) hydrogen
B) carbon
C) nitrogen
D) oxygen
E) sulfur