Quiz 3

Question 1

Which amino acids orient toward the hydrophobic interior?

Answer 1

V, L, I, M, F (non-polar no G, A, P “weird ones”)

Question 2

Which amino acids tend to H-bond with the protein interior?

Answer 2

Y, W, (non-polar)
S, T, N, Q (polar no C)

Question 3

Which amino acids tend to display on the protein surface/ active site?

Answer 3

H, K, R, D, E (acids + bases)

Question 4

Linus Pauling’s secondary structure rules

Answer 4

1. bond length and angles should conform to predetermined
2. Steric restrictions (bond rotation around peptide backbone via VDW of atom radii)
3. backbone, 6 carbons remain coplanar
4. H-bonds are key to secondary structure stabilization

Question 5

How many atoms define each?
- torsion
- bond angle
- bond length

Answer 5

• 4
• 3
• 2

Question 6

What is the name and symbol for the N-terminal angle? Draw the structure in line and Newman projection.

Answer 6

Phi (O/) - between N and alpha carbon
= Look for ss

Question 7

What is the name and symbol for the C-terminal angle? Draw the structure in line and Newman projection.

Answer 7

Psi (Y/) - between alpha carbon and C
= Look for ss

Question 8

What is the plot name that combines the phi and psi angles to determine the most favourable orientations? Roughly draw it out.

Answer 8

Ramachandra plot
find ss

Question 9

When describing helices
- n =
- p =
- direction =

Answer 9

n = number of residues per turn
p = distance between turns
direction = right hand / left hand

Question 10

Details for alpha helix
- phi angle
- psi angle
- n
- p

Answer 10

phi = -57º
psi = -47º
n = 3.6 residues/turn
p = 5.4 Å/turn

Question 11

Details of other helices (3^10 and pi)
- n
- p
- h-bond angle

Answer 11

3^10
n = 3.0
p = 6.0 Å
angle = 120º (i+3)

pi
n = 4.4
p = 5.2 Å
angle = not coplanar (i+5)

Question 12

How to draw a helical wheel?

Answer 12

1. build 4 square coordinates
2. place the first amino acid at 0º
3. add next amino acid ___º away (360/n)
4. keep adding from the previous amino acid
5. connect with line

Question 13

Details for peptide II helix
- n
- p

Answer 13

Does not satisfy Pauling (no H-bonds)
- made of glycine and proline
n = 3
p = 9.4Å

Question 14

Difference in h-bonds in helix and sheet

Answer 14

helix - between 1 strand of polypeptide
sheet - between 2 strands of polypeptide

Question 15

Beta sheets
- classification
- bond angle
- h-bond strength
- abundance
- phi-psi angles

Answer 15

• antiparallel vs parallel
• 180º vs ≠ 180º
• strong vs weak
• 80% vs 20%
• (-139º,135º) vs (-119º, 113º)

Question 16

Two types of beta turns, draw them. What is the difference between beta and gamma turns?

Answer 16

type 1 - cis-pro at position 2 (4 residues)
type 2 - gly at position 3(4 residues)

gamma - cis pro (3 residues)

Question 17

3 characteristics that make loops good protein identifiers

Answer 17

1. irregular and unique to amino acid sequence
2. at the surface, accessible to other proteins
3. charged or polar

Question 18

3 types of loops, draw them

Answer 18

• simple turn
• left-handed crossover
• right-handed crossover

Question 19

4 types of supersecondary motifs

Answer 19

= aa
= BB
= BBBB motif - greek key
= BaB (parallel B sheet, right-handed)

Question 20

3 types of alpha-alpha structures

Answer 20

• hairpin (<4 residues) - gamma turn
• helix-turn-helix (~4 residues) - 1/2 turn
• helix-loop-helix (~12 residues) - loop

Question 21

Another name for helix-loop-helix

Answer 21

the loop is also known as the leucine-zipper
= cationic Lys or Arg create salt bridges with anionic phosphate backbone of DNA

Question 22

Rossman fold Motif

Answer 22

• bind cofactors like NAD+ or FAD
• BaB - a - BaB
  = two helix-loop-helix motifs bonded by alpha helix

Question 23

Disulfide bond

Answer 23

intrachain covalent linkage
- oxidation of two Cystein-thiols
- very stable

Question 24

Draw out a melting curve

Answer 24

heat applied to a given protein, the % denatured (native state vs unfolded) and is compared to a protein property that changes with unfolding (light)

Tm (melting temp) = temperature at which 50% denatured

Question 25

Levinthal's paradox

Answer 25

total number of protein residues is the number of preferred states to the power of the number of amino acids 3^n - this is a false assumption of random sampling of conformations

Question 26

Protein folding kinetics

Answer 26

unfolded - hydrophobic collapse molten globule (condense but still a lot of disorder) - side chains ordered (max interactions) native state

Question 27

Folding pathways = two-state = multi-state

Answer 27

two-state = highly cooperative folding - start -> end multi-state (globule) = driven by hydrophobic effect - start -> intermediate -> end multi-state (multi-domain) = driven by side-chain interactions - start -> intermediate -> end

Question 28

Example of how to read hydropathic index to assume folding pathway

Answer 28

- hydrophobic (+) - hydrophilic (-) - if the graph has many hydrophobic regions = molten globules will form - if the graph has few/no hydrophobic regions = side-chain, domain formation

Question 29

Cooperativity

Answer 29

nucleation - first binding increases the likelihood of the next binding (same for denaturing) = bring closer = limit mobility of backbone

Question 30

Cooperativity directly opposes what theory?

Answer 30

Levinthal's Paradox

Question 31

Chaperones -definition -draw process

Answer 31

- a protein that binds to unfolded protein and helps other proteins fold to a natural state in an isolated environment

Question 32

What protein favours correct disulfide protein formation?

Answer 32

protein disulfide isomerase

Question 33

Quarternary structures typically are formed in rational symmetry. What does that mean?

Answer 33

- can rotate around without changing L to D or breaking bonds cyclic symmetry = C2, C3, C4 dihedral symmetry = vert + horz axis

Question 34

Chargaff's rules

Answer 34

1. base composition of DNA is different between species 2. base composition of DNA is the same between tissues of the same species 3. base composition doesn't change with age, environment, nutrition in same species 4. #(A-T) = #(G-C) and #(A+G)=#(T+C)

Question 35

Features of a B-DNA vs A-DNA vs Z-DNA - P - n - screw sense - glycosidic bond

Answer 35

B p = 3.4Å n = 10.4 bases/turn - right-handed - anti A p = 2.3Å n = 11 - right-handed - anti Z p = 3.8Å n = 12 - left-handed - alternating

Question 36

Triple helices or H-DNA

Answer 36

need 1. palindromic homopurine sequence 2. Hoogsteen base pairing

Question 37

Go over the Hoogsteen base pairing

Answer 37

find ss

Question 38

Go over the interacting edges of DNA

Answer 38

find ss

Question 39

Quadruple helices

Answer 39

4 hoogsteen guanine bonds + 1 monovalent cation in the middle

Question 40

Intrastrand self-complementary pairing

Answer 40

1 strand = hairpin 2 strand = cruciform

Question 41

T or F Cruciforms and hairpins leave bases unpaired in the loop regions and are less stable than double helical DNA

Answer 41

T

Question 42

T or F Supercoiling is a form of nucleic acid tertiary structure

Answer 42

T

Question 43

How is supercoiling induced? How would it affect normal coiling and underwinding?

Answer 43

strain is induced by a deviation of 10.5 bases/turn normal = supercoil underwinding = normal

Question 44

Concerning supercoiling what is the linking number and what is the equation

Answer 44

L = T + W L = linking number T = twist = # helical turns W = writhe = # turns in duplex axis + = right - = left

Question 45

Concerning supercoiling what is the superhelix density and what is the equation

Answer 45

- # turns removed relative to the # of turns of relaxed DNA - independent to DNA length σ = ∆L/Lº ∆L = L-T Lº=lenth of bp/ bp per turn (10.5) σ<0 Underwound σ>0 Overwound

Question 46

What is the enzyme responsible for changes in linking number of tertiary DNA structures?

Answer 46

topoisomerase 1 = ∆L=1 topoisomerase 2 = ∆L=2

Question 47

When strand separation occurs over long stretches it is called what?

Answer 47

over 10 bps = denaturation