Enzymes

Question 1

What does a co-factor do?

Answer 1

Binds to the enzyme to contribute to the catalytic mechanism in some way

Question 2

What does an enzyme do?

Answer 2

Catalyses the rate at which a chemical reaction reaches equilibrium, without changing the position of equilibrium

Question 3

What is Kcat?

Answer 3

The number of substrate molecules a single molecule of enzyme can bind and convert every second (when substrate is unlimited)

Question 4

What three things can be measured in an enzyme assay to measure enzyme activity?

Answer 4

Rate of production of product
Rate of loss of substrate
Rate of production or loss of cofactor

Question 5

Why is it important to meaasure the initial rate?

Answer 5

Rate can decrease due to less substrate being available as the reaction goes on

Question 6

How does gel filtration work?

Answer 6

There is a column of beads with small cavities/pores. Smaller molecules can move through/get stuck in these pores and so take a long time to fall through the column. Larger molecules fall straight through. This layers the molecules by size

Question 7

What is specific activity?

Answer 7

The number of enzyme units per mg of protein

Question 8

What two things do we want to maximise in the purification of an enzyme?

Answer 8

Recovery of enzyme

Purity of enzyme

Question 9

How do you calculate specific activity?

Answer 9

crude (or purified) rate in um per min / protein per ml in the sample

Question 10

How do you find % recovery of an enzyme?

Answer 10

units in pure sample / units in crude sample x 100

Question 11

How do you find the degree of purification of an enzyme?

Answer 11

specific activity of pure sample / specific activity of crude sample

Question 12

What are the properties of an irreversible enzyme inhibitor? 3

Answer 12

Covalent or tight binding
Can be toxins that kill enzymes
Can be therapeutic (eg aspirin inactivating COX)

Question 13

What are the properties of a reversible enzyme inhibitor? 4

Answer 13

Competitive
Can be overcome at high [S]
Vmax unaffected
Km increased

Question 14

What are the properties of a non-competitive inhibitor? 5

Answer 14

Binds to a site other than the active site (allosteric)
Substrate and inhibitor can bind at the same time
Active site shape can be altered
Enzyme activity reduced
Vmax decreased, Km unaffected

Question 15

What is the equation for a Lineweaver-Burk plot?

Answer 15

1/V = KM/Vmax x 1/[S] + 1/Vmax
y    = m              x    X   +     c

Question 16

What do the lines on a linear plot look like in competitive enzyme inhibition?

Answer 16

The line with the inhibitor has a higher Km than the line without. Both lines have the same intercept (Vmax)

Question 17

What do the lines on a linear plot look like in non-competitive enzyme inhibition?

Answer 17

Both lines have the same Km (starting point). The inhibited line has a lower Vmax (higher intercept).

Question 18

What happens during the transition state of a reaction? 3 What do catalysts do to this state? 1

Answer 18

Higher free energy than substrate or product
Unstable
Slows down the reaction
A catalyst can lower the transition state energy and stabilise it

Question 19

How can RNA be hydrolysed by acids or bases?

Answer 19

Contains O and OH
Both cleave phosphate ester bonds
Acid O -> OH
Base OH -> O-

Question 20

How do RNA histidine side chains allow for cleavage by both base and acid at the same time? When is each more likely to happen?

Answer 20

Histidine can be protonated or unprotonated around its pKa.
Hydrophobic environment = unprotonated
Negative environment = protonated

Question 21

What is electrostatic steering?

Answer 21

Some enzymes can attract the substrate towards the active site. E.g using positively charged groups

Question 22

What does chymotrypsin do?

Answer 22

Cleaves peptide bonds on the C terminal side of bulky hydrophobic + aromatic amino acids

Question 23

What does trypsin do?

Answer 23

Cleaves peptide bonds on the C terminal side of K or R amino acids

Question 24

What does elastase do?

Answer 24

Cleaves peptide bonds on the c terminal side of small amino acids

Question 25

Name 4 uses of serine proteases

Answer 25

Control of blood clotting
Immune response
Penetration of ovum
Protein turnover regulation

Question 26

What are the basic principles underlying burst kinetics?

Answer 26

Enzyme reactions can produce an ES complex as well as multiple products. If two (or more) products are produced, the one that does not form the ESC will be released quickly causing a ‘burst’. It will then take more time for the second product to dissociate from the ESC in the steady state phase.

Question 26

What is the importance of a specificity pocket?

Answer 26

A space near the active site that enables the enzyme to be substrate specific?

Question 27

What are three examples of specificity pockets?

Answer 27

Chymotrypsin pocket (large and hydrophobic)
Trypsin (Asp 189- only allows positively charged K + R)
Elastase (bulky Val molecules only allow small amino acids)

Question 28

How does the body stop serine proteases from breaking important peptide bonds?

Answer 28

Inactive serine protease precursors called zymogens are packaged into vesicles and released when required. These can be activated by the cleavage of a specific peptide bond.

Question 29

Which enzyme cleaves the peptide bond required to activate serine protease precursors?

Answer 29

Trypsin

Question 30

What activated inactive trypsin (trypsinogen)?

Answer 30

Enteropeptidease secreted by the cells lining the duodenum.

Question 31

What is the importance of having one anzyme control the activation of all serine proteases?

Answer 31

Means that the whole process can be switched on and off.

On by enteropeptidase and off by pancreatic trypsin inhibitor.

Question 32

How have serine proteases come about by divergent evolution?

Answer 32

An ancient single gene containing the catalytic triad, over time, duplicated and evolved to form different mutations and features.

Question 33

What is K?

Answer 33

The rate constant

Question 34

What does K[A] find?

Answer 34

Rate

Question 35

What is K1 and K2?

Answer 35

The rate of the forwards vs reverse reaction

Question 36

What is V?

Answer 36

Velocity

Question 37

At equilibrium V=?

Answer 37

0

Question 38

At equilibrium K1[A]=?

Answer 38

K2[B]

Question 39

At equilibrium [B]/[A] = ?

Answer 39

K1/K2 OR Keq

Question 40

What is V=Vmas[S] / [S] + Km?

Answer 40

The Michaelis-Menten equation

Question 41

How does HIV protease inhibit enzymes?

Answer 41

Converts viral proteins into acitve forms by cleaving specific peptide bonds.
Important in the life cycle of HIV

Question 42

What does Crixivan do to HIV?

Answer 42

• similar structure to the peptide substrates
• binds to HIV protease reversibly
• inhibits HIV protease

Question 43

What are the properties of irreversible inhibitors?

Answer 43

• covalent or tight bindig

Question 44

In a Lineweaver–Burk plot, the presence of a competitive inhibitor will alter: (3)

Answer 44

The slope of the curve

the intercept on 1/s

Question 45

What can reduce the effect of a competitive inhibitor of an enzyme?

Answer 45

Increased substrate concentration