Proteins 2 - folding 09/05 Traish

Question 1

what is protein primary structure

Answer 1

order of aa’s

Question 2

by convention, an aa polypeptide sequence is written from __-terminus to __-terminus

Answer 2

N-terminus to C-terminus

Question 3

secondary structure consists of…

Answer 3

locally folded structures (a-helices, b-sheets, turns, random coils [loops]) dependent on H-bonding between a-N and a-C groups

Question 4

T/F secondary structure depends upon H-bonding between R groups

Answer 4

False

depends upon H-bonding between primary amino and carbonyl

Question 5

by convention, the __-terminus is left and the __-terminus is right in an aa polypeptide sequence

Answer 5

N-terminus left

C-terminus right

Question 6

tertiary structure consists of…

Answer 6

3-D structure from interactions between domains in a single pp sequence

Question 7

tertiary structure is dependent upon what kinds of intermolecular interactions

Answer 7

H-bonds, hydrophobic interactions, electrostatic interactions, van der Waal’s forces, disulfide bonds

Question 8

quaternary structure is dependent upon what kinds of intermolecular interactions

Answer 8

H-bonds, hydrophobic interactions, electrostatic interactions, van der Waal’s forces, disulfide bonds (same as tertiary) BUT globular protein monomers are RARELY held together by disulfide bonds and never by other covalent linkages

Question 9

do the same intermolecular interactions stabilize tertiary and quaternary structure?

Answer 9

yes they can

Question 10

is hemoglobin a homo-oligomer or hetero-oligomer?

Answer 10

hetero-oligomer – 2 alpha subunits, 2 beta subunits

Question 11

what is a homo-oligomer?

Answer 11

an oligomer composed of identical subunit monomers

Question 12

what is a hetero-oligomer?

Answer 12

an oligomer composed of non-identical subunit monomers

Question 13

a tetramer is__

Answer 13

an oligomer with 4 monomeric subunits

Question 14

the bond between a-amino and a-carboxyl aa groups is called

Answer 14

a peptide bond

Question 15

can a peptide bond twist/rotate? why?

Answer 15

very little – partial double bond character (delocalization of pi electrons)

Question 16

quaternary structure consists of

Answer 16

the oligomerization of multiple monomeric subunits from separate pp sequences

Question 17

how are the C=O and N-H bonds of a peptide bond oriented to one another?

Answer 17

parallel – usually antiparallel

Question 18

T/F the O, C, N, and H of a peptide bond are nearly coplanar

Answer 18

true

Question 19

what does it mean that a peptide bond is “metastable?”

Answer 19

proteins hydrolyze in an aqueous environment when a catalyst is present

Question 20

T/F a peptide bond can rotate

Answer 20

false (double bond character)

Question 21

T/F the N-C alpha and C-C alpha bonds can rotate?

Answer 21

true

Question 22

the aa N-C alpha bond is called __

Answer 22

phi (O with |

Question 23

the aa C-C alpha bond is called __

Answer 23

psi (pitchfork)

Question 24

common secondary structures include

Answer 24

a helices, b sheets, turns, loops / coils (as yet unclassified)

Question 25

what is a crystallographic repeat?

Answer 25

a periodically repeating pattern of atoms in 3D

Question 26

what does a crystallographic repeat measurement (c) refer to?

Answer 26

distance parallel to the axis of a-helix over which the structure exactly repeats itself

Question 27

a-helix pitch (p) refers to…

Answer 27

distance parallel to a-helix axis in one turn

Question 28

a-helix rise (h) refers to

Answer 28

distance parallel to a-helix axis from one residue to next

Question 29

a-helix (n) refers to

Answer 29

the number of residues… per turn, or repeat, or what have you

Question 30

do R groups exist on exterior or interior of an a-helix?

Answer 30

exterior

Question 31

2 aa’s that are likely to disrupt an a-helix include:

Answer 31

G, P

Question 32

a “dihedral” angle is…

Answer 32

the angle between two planes

Question 33

T/F the dihedral angle pairs, phi and psi, can differ from one residue from the next in an a-helix

Answer 33

false – dihedral angle pairs are the same for each residue

Question 34

T/F a-helices are classified as “repetitive secondary structure”

Answer 34

true – their backbone phi and psi angles repeat

Question 35

what are the phi and psi angles in an ideal, right-handed a-helix?

Answer 35

phi = -57.8
psi = -47.0
(- signifies counter clockwise)

Question 36

what do + and - rotation angles in phi and psi refer to?

Answer 36

\+ = clockwise rotation
- = ccw rotation

Question 37

T/F a-helices are the most abundant helical conformation found in globular proteins

Answer 37

true

Question 38

a-helices account for __ to __ percent of all globular protein residues

Answer 38

32-38%

Question 39

average n in an a-helix is…

Answer 39

10 residues

Question 40

H-bonds in an a-helix are between…

Answer 40

each backbone C=O and the backbone N-H 4 residues ahead (i+4)

Question 41

T/F H-bonds in an a-helix are between each backbone N-H and the backbone C=O 4 residues ahead

Answer 41

false. between each backbone C=O and the backbone N-H 4 residues ahead (i+4)

Question 42

X-ray data suggest that an a-helix repeats itself after __ residues

Answer 42

18

Question 43

how many turns are there in an alpha helix repeat?

Answer 43

5

Question 44

how many residues per a-helix turn?

Answer 44

3.6

Question 45

a-helix pitch (p) is __ nm

Answer 45

.54 nm per turn

Question 46

a-helix rise (h) is __ nm, or __ angstroms

Answer 46

.15 nm per residue

• or-
  1. 5 A per residue

Question 47

how many angstroms in a nanometer?

Answer 47

10

Question 48

how many meters in an angstrom?

Answer 48

10^-10

Question 49

how many angstroms in a meter?

Answer 49

10^10

Question 50

a stretched a-helix will have a (higher or lower) rise and a (higher or lower) n per turn

Answer 50

a stretched a-helix will have a higher rise and a lower number of residues per turn

Question 51

prolyl residues, adjacent bulky residues, adjacent branched residues ,and adjacent charged residues can all do what to an a-helix?

Answer 51

interrupt it

Question 52

how many polypeptide stretches are involved in an a-helix vs a b-sheet?

Answer 52

a-helix – single stretch

b-sheet – multiple stretch

Question 53

beta stretches consist of at least __ to __ aa’s

Answer 53

5-10

Question 54

a key difference between the H-bonds in a-helices vs b-sheets is…

Answer 54

b-sheets H-bond between different pp stretches

a-helices H-bond along the same strand

Question 55

why are b-sheets “pleated” ?

Answer 55

the alpha carbons alternate above and below the plane of the sheet

Question 56

T/F b-sheets can be parallel, antiparallel, or mixed

Answer 56

true

Question 57

what is a parallel b-sheet

Answer 57

adjacent stretches’ N-termini and C-termini run in same directions

Question 58

what is an anti-parallel b-sheet

Answer 58

adjacent stretches’ N-termini and C-termini run in opposite directions

Question 59

golubular proteins cointain __ to __ percent b-sheets

Answer 59

20-28%

Question 60

what is the basic unit of a b-sheet

Answer 60

b-strand (n=2 residues/turn)

Question 61

a b-strand can be thought of one turn of a helix with n = __ residues per turn

Answer 61

n=2 residues per turn

Question 62

the backbone dihedral angels, phi and psi, in a b-strand, are:

Answer 62

phi = -120
psi = +120

Question 63

translational “rise” (h) in a beta sheet is __ for antiparallel strands

Answer 63

3.2 nm per residue

Question 64

translational “rise” (h) in a beta sheet is __ for parallel strands

Answer 64

3.4 nm per residue

Question 65

is translational “rise” (h) in a beta sheet greater for parallel strands or antiparallel strands?

Answer 65

h is greater in parallel strands (3.4 nm vs 3.2 nm)

Question 66

are there any intrasegment H-bonds or van der Waal’s forces in a b-sheet?

Answer 66

no – only intersegment forces – due to the extended nature of the chain

Question 67

what is the average length of a b-pleated sheet?

Answer 67

6 residues

Question 68

most b-pleated sheets contain fewer than __ strands

Answer 68

fewer than 6 strands

Question 69

do side chains from adjacent residues in a b-sheet interact with each other?

Answer 69

no – because they exist on alternating sides of the sheet

Question 70

can b-sheets exhibit amphiphilicity with one face polar and one face nonpolar? can a-helices?

Answer 70

yes in both cases

Question 71

can a-helices be formed from strands from distant portions of the pp chain? can b-sheets?

Answer 71

a-helices - no

b-sheets - yes

Question 72

which is thought to be more intrinsically stable, antiparallel b-sheets or parallel b-sheets? why?

Answer 72

antiparallel

• more optimal orientation of hydrogen bonds
• peptide dipoles cancel

Question 73

are side chains closer / interacting more strongly in parallel or antiparallel b-sheets?

Answer 73

same in both. side chains can match up above and below the plane of the sheet either way

Question 74

the most stretched “helix”, with n=2 residues per turn, is also known as…

Answer 74

a beta sheet

Question 75

what kind of secondary structure is pervasive in silk versus wool?

Answer 75

silk = b-sheets (strong & inextensible because already maximally stretched, flexible because only H-bonding)
wool = a-helices (stretchy because coiled and H-bonds along axis of fiber, not perpendicular)

Question 76

what is the typical secondary structure of an immunoglobulin fold (hypervariable domain / antigen binding site) ?

Answer 76

two antiparallel b-sheets in a barrel structure

Question 77

what is the primary function of a “turn” in protein secondary structure?

Answer 77

reverse the direction of the polypeptide chain

Question 78

where are turns primarily located?

Answer 78

on the protein surface

Question 79

are residues on a turn mostly hydrophobic or hydrophilic?

Answer 79

polar and charged because they exist usually at surface where protein must be turned back in

Question 80

T/F antibody recognition, phosphorylation, glycosylation, and hydroxilation sites are frequently found at or adjacent to “turns”

Answer 80

True – turns mostly located at surface with polar and charged residues as it turns the pp sequence back toward protein

Question 81

approximately what proportion of globular protein residues are “turns” ?

Answer 81

~1/3

Question 82

approximately __ to __ percent of residues in globular proteins can be calssified as participating in a-helices, b-sheets, or reverse turns

Answer 82

80-90%

Question 83

this secondary structure is compact and globular in structure

Answer 83

loop

Question 84

loops contain between __ and __ residues

Answer 84

6 and 16

Question 85

T/F like turns, loops generally contain polar residues and are predominantly found at the protein surface

Answer 85

true

Question 86

between a-helices, b-sheets, turns, and loops, this is the order of frequence in globular proteins

Answer 86

a-helices & turns (most common)

loops & b-sheets (less common)

Question 87

T/F in globular proteins, a-helices and turns are more common than loops and b-sheets

Answer 87

true

Question 88

describe the hydrophobic effect in protein folding

Answer 88

non polar side chains tend to be buried in the center of proteins with polar chains on outside

Question 89

T/F hemoglobin exists as a single polypeptide chain

Answer 89

false – it is a tetramer

Question 90

T/F myoglobin exists as a single polypeptide chain

Answer 90

true – it is a monomer

Question 91

what is the name of the “O2 warehouse” protein that stores oxygen in muscle tissue?

Answer 91

myoglobin

Question 92

T/F fibrous proteins are elongated molecules with well-defined secondary structures that play structural roles in cells (skin, connective tissue, hair, silk)

Answer 92

true

Question 93

T/F alpha-keratin, fibroin, and collagen are examples of globular proteins

Answer 93

false – they are fibrous proteins

Question 94

T/F a “domain” is a compact, locally folded region of tertiary structure

Answer 94

true

Question 95

T/F a protein domain can be classified as predominantly a-helix, predominantly b-sheet, or mixed

Answer 95

true

Question 96

T/F beta sheets can be twisted

Answer 96

true – they are usually twisted or wrapped into barrel structures

Question 97

T/F “random coil” secondary structures are sometimes referred to as “turns”

Answer 97

false – they are sometimes referred to as “loops”

Question 98

is the conformational entropy change of protein folding + or -, favorable or unfavorable?

Answer 98

-, unfavorable

Question 99

is the enthalpy change arising from protein folding + or -, favorable or unfavorable?

Answer 99

-, favorable

Question 100

is the entropy change of burying hydrophobic groups in protein folding + or -, favorable or unfavorable?

Answer 100

+, favorable

Question 101

how does the hydrophobic effect in protein folding increase entropy?

Answer 101

it eliminates the orderly formation of “hydration shells” along hydrophobic surfaces. adjacent to hydrophilic surfaces, H2O is not restricted in orientation or mobility

Question 102

what two thermodynamic factors does Gibbs free energy combine?

Answer 102

enthalpy and entropy

Question 103

what is the equation for Gibbs free energy of a system

Answer 103

dG = dH - TdS
"G = HoTS"

Question 104

T/F when calculating Gibbs free energy of protein folding, you must remember to account for dH, dS, and T of both protein and solvent

Answer 104

true.
dH = dHp + dHs
dS = dSp + dSs

Question 105

is protein folding spontaneous when dG is + or - ?

Answer 105

negative dG is spontaneous

Question 106

what scientist performed the experiment to demonstrate that protein folding depended on primary structure?

Answer 106

Nobel laureate Christian Anfinsen

Question 107

what protein did C. Anfinsen denature in his experiment with protein folding?

Answer 107

ribonuclease

Question 108

what is the normal function of ribonuclease?

Answer 108

hydrolyze RNA into single nucleotides

Question 109

what organic solvent did C. Anfinsen use to denature ribonuclease in his experiment with protein folding?

Answer 109

urea

(disrupts hydrogen bonds in protein by replacing them with hydrogen bonds with itself

Question 110

what substance did C. Anfinsen use to reduce the disulfide bonds in ribonuclease in his experiment with protein folding?

Answer 110

beta-mercaptoethanol

Question 111

why were small amounts of beta-mercaptoethanol needed to ensure appropriate renaturation of ribonuclease in c. Anfinsen’s experiments with protein folding?

Answer 111

2ME (b-mercaptoethanol) was needed to allow inappropriate disulfide bonds to break and find the most stable conformation

Question 112

how many disulfide bonds are involved in the tertiary structure of ribonuclease?

Answer 112

4

Question 113

how many cysteine residues are involved in the tertiary structure of ribonuclease?

Answer 113

8

Question 114

what are the odds of approprate renaturation of ribonuclease if determined randomly (not by primary pp sequence?)

Answer 114

1/71/51/3*1/1 = 1/105 = <1%

Question 115

what was the rate of ribonuclease function restoration (appropriate renaturation) achieved by C. Anfinsen in his experiments with protein folding?

Answer 115

97%

Question 116

how does beta-mercaptoethanol disrupt disulfide bonds?

Answer 116

it is a thiol agent that reduces disulfide bonds as it is oxidized into dimers joined by disulfide bonds itself

Question 117

T/F a molecule containing -S-S- bridges has a larger number of conformations available in the unfolded form than does a comparable protein without the bridges

Answer 117

False

-S-S- bridges reduce the number of conformations available to an unfolded protein

Question 118

what degree of protein structure is involved in allosteric regulation?

Answer 118

quaternary structure
(requires interactions with other proteins / molecules -- e.g. hemoglobin)

Question 119

this amino acid, found in milk, eggs, and lime but not in corn or dry cereal, is a pre-courser of vitamin B3 and a lack may cause dermatitis

Answer 119

W

e.g. southern corn diet vs mexican lime+corn diet

Question 120

T/F the Linus Pauling postulates re polypeptide conformations include:

• bond length and angles should be distorted as little as possible
• no two atoms should violate each other’s van der Waal’s radii
• amide group remains planar and trans config (phi & psi rotation only)
• non-covalent usually H-bonds between N and C groups stabilize folding

Answer 120

true