Session 1

Question 1

What are amphipathic molecules?

Answer 1

Molecules with polar and non-polar regions.

Question 2

What is a zwitterion and when does it exist?

Answer 2

An ionised form of amino acid where both the carboxyl and amino group are ionised, found at the isoelectric point (pH) specific to that amino acid.

Question 3

Which stereoisomer is found in proteins?

Answer 3

L isomer, the D isomer is never found in proteins.

Question 4

What determines an amino acids behaviour?

Answer 4

R groups.

Question 5

How can amino acids be classified?

Answer 5

Based on R group:
Non-polar aliphatic/aromatic
Polar charged/uncharged

Question 6

What state will an amino acid be in if pH is:

1. Above pK
2. Below pK

Answer 6

1. Deprotonated

2. Protonated

Question 7

How are peptide bonds formed?

Answer 7

By linking 2 amino acids in a condensation reaction (creates a molecule of water).

Question 8

Why are peptide bonds planar?

Answer 8

Peptide bond C-N has partial double bond characteristics so the bond is rigid and planar.

Question 9

What is the difference between trans and cis peptide bonds?

Answer 9

There are steric clashes in a cis peptide bond; the R groups are on the same side of the molecule so they clash.
In a trans peptide bond the R groups are on opposite sides of the molecule so there are no steric clashes.

Question 10

Define the isoelectric point of a protein.

Answer 10

The pH at which there is no overall net charge on a protein.

Question 11

What is the isoelectric point likely to be for:

1. Positively charged amino acids
2. Negatively charged amino acids

Answer 11

1. Above 7, they are likely to be basic

2. Below 7, they are likely to be acidic

Question 12

Define primary structure of a protein.

Answer 12

Linear amino acid sequence of a polypeptide chain.

Question 13

Define secondary structure of a protein.

Answer 13

The local spatial arrangement of the polypeptide backbone.

Question 14

Define tertiary structure of a protein.

Answer 14

3-D arrangement of all atoms in a polypeptide.

Question 15

Define quaternary structure of a protein.

Answer 15

3-D arrangement of protein subunits.

Question 16

What determines the conformation of a protein?

Answer 16

The angles of the covalent bonds, they determine how the protein folds.

Question 17

What are the properties of an alpha-helix

Answer 17

3.6 amino acids per turn
0.54nm pitch
Right-handed helix
All R-groups are on the outside of the helix so don’t contribute to its secondary structure
Backbone of the -C=O in one residue is H-bonded to the -NH group of the residue 4 amino acids away

Question 18

Which amino acids are strong helix formers?

Answer 18

Alanine and leucine

Question 19

Which amino acids are strong helix breakers and why?

Answer 19

Glycine, it has a tiny R-group (-H) so it will readily support other formations.
Proline, rotation around its C-N bond is impossible due to the ring structure.

Question 20

What are the properties of a beta-strand?

Answer 20

Fully extended conformation
0.35nm between amino acids
R-groups alternate between opposite sides of the chain
Side-by-side arrangement of beta-strands forms a beta-sheet (in anti parallel, parallel or mixed arrangement)

Question 21

What are the roles of fibrous proteins?

Answer 21

Support, shape and protection.

Question 22

What are the roles of globular proteins?

Answer 22

Catalysis and regulation.

Question 23

What are the properties of collagen?

Answer 23

Triple helical arrangement of collagen chains
Contain glycine every third amino acid
Hydrogen bonds stabilise interactions between chains

Question 24

What is a protein motif?

Answer 24

A folding pattern containing 1 or more elements of secondary structure, e.g. Beta-barrel, beta-alpha-beta loop.

Question 25

What is a protein domain?

Answer 25

Part of a polypeptide chain that folds into a distinct shape, it often has a specific functional role.

Question 26

How do proteins fold with respect to water?

Answer 26

They fold such that hydrophobic side chains are buried and polar, charged side chains are on the surface.

Question 27

How are membrane proteins often folded?

Answer 27

They are often folded with an inside-out distribution of amino acids: hydrophobic exterior and a hydrophilic centre.

Question 28

What forces are involved at each level of protein structure?

Answer 28

PRIMARY: Peptide covalent bonds
SECONDARY: H- bonds
TERTIARY: Disulphide, ionic and H- bonds, Van dear Waals and hydrophobic forces
QUATERNARY: Disulphide, ionic and H- bonds, Van der Waals and hydrophobic forces

Question 29

How are Disulphide bonds formed/broken?

Answer 29

Formed between cysteine residues

Can be broken with reducing agents

Question 30

What can be used to denature proteins and why?

Answer 30

Heat: increases vibrational energy
pH: alters the ionisation stated of amino acids and changes ionic/H- bonds
Detergents/organic solvents: disrupt hydrophobic interactions

Question 31

What is amyloidosis?

Answer 31

The misfolding of a protein.

Question 32

What is the difference between polar and non-polar molecules?

Answer 32

Polar molecules can form H-bonds and dissolve, non-polar molecules cannot form H-bonds and are insoluble.