Alcohol Metabolism & Oxidative Stress

Question 1

Describe how alcohol is metabolised

Answer 1

90% met in liver:

1) alcohol is oxidised by alcohol dehydrogenase to acetaldehyde (NAD+ –> NADH)
2) then to acetate by aldehyde dehydrogenase (NAD+ –> NADH),
3) acetate is then converted to acetyl-CoA,
4) used in the TCA cycle or for fatty acid synthesis

Question 2

What is the recommended alcohol limit for men and women?

Answer 2

14 units over 3 days

Question 3

What part of alcohol met is toxic and causes hangovers?

Answer 3

Acetaldehyde – accumulation causes hangovers

Question 4

Explain how alcohol can cause liver damage

Answer 4

Acetaldehyde toxicity normally kept to a minimum by aldehyde dehydrogenase

prolonged excessive alcohol consumption can = acetaldehyde accumulation = liver damage.

Increase in Acetyl-CoA = increased synthesis of fatty acids = fatty liver

Question 5

Explain the metabolic response to chronic alcohol consumption

Answer 5

Increase in Acetyl-CoA = increased synthesis of fatty acids = fatty liver.

Decrease in NAD+/NADH ratio = low NAD+ for conversion of lactate to pyruvate = lactic acidosis, lactate effects kidneys ability to excrete uric acid = gout.

Low NAD+ = low gluconeogenesis = hypoglycaemia

Question 6

Explain the mechanism of action of Disulfiram

Answer 6

Inhibits aldehyde dehydrogenase = accum of acetaldehyde = severe hangover = deterrent

Question 7

What is oxidative stress?

Answer 7

Unbalance between cell damage by ROS/RNS and cell defences = antioxidants, glutathions, superoxide dismutase

Question 8

What is a free radical?

Answer 8

Atom/molecules that contain unpaired electrons = extremely reactive = want to grab electron from somewhere else = propagating reaction

Question 9

How are superoxide radicals produced

Answer 9

In ETC e- can accidently escape chain and react with dissolved O2 = superoxide

Question 10

What is a reactive oxygen species (ROS)

Answer 10

Group of oxygen related compounds that have free radicals = superoxide, hydroxyl radical

Question 11

What is a reactive nitrogen species (RNS)

Answer 11

Group of nitrogen related compounds that have free radicals = nitric oxide

Question 12

What is the most damaging free radical?

Answer 12

Hydroxyl radical = reacts with anything

Question 13

What are the 2 main types of DNA damage by ROS?

Answer 13

Reacting with base = mispairing/mutation.

Reacting with sugar = strand break

Question 14

How do ROS damage proteins?

Answer 14

Backbone damage = fragmentation = degradation.

Sidechain damage = structure change = function change = loss/gain.

Inappropriate disulphide bond formation if ROS take e- from cysteines

Question 15

How do ROS damage lipids?

Answer 15

Damage the cell membrane = propagated chain reaction = membrane integrity fails

Question 16

What are the sources of biological oxidants?

Answer 16

Endogenous = ETC, nitic oxide synthesis, NADPH oxidases.

Exogenous = radiation, drugs, toxins

Question 17

What is the respiratory burst?

Answer 17

Phagocytic cells prod superoxide = rapid release = destroy invading bacteria

Question 18

What happens when the respiratory burst is dysfunctional?

Answer 18

Chronic granulomatous disease = defect in NADPH oxidase = can’t form ROS to kill bacteria = more prone to infections

Question 19

Outline defences against reactive oxygen species

Answer 19

Superoxide dismutase (SOD) = converts superoxide to H2O2 + O2 THEN catalase converts H2O2 to water + oxygen.

Free radical scavengers = vit E = donate H atom to free radicals, nonenzymatic, Vit C regenerates vit E

Glutathione

Question 20

How does glutathione protect the cell against oxidative damage?

Answer 20

Glutathione = donates e- to free radical (requires glutathione peroxidase),

regeneration of glutathione requires glutathione reductase (needs NADPH from the pentose phosphate pathway)

Question 21

Explain the role of oxidative stress in galactosaemia

Answer 21

Galactosaemia = def in any of the 3 key enzymes

pathway converts = galactose (via NADPH –> NADP+) to galactitol

= using up NADPH which is required to regenerate glutathione which protects cells from free radicals

= prone to ROS damage = crystalline denatured = cataract

Question 22

Explain the role of oxidative stress in the formation of Heinz bodies

Answer 22

G6PDH def = low NADPH regeneration = low glutathione regenerated = low protection from free radicals = protein damage = aggregates of cross-lined Hb = Heinz bodies

Question 23

How does a paracetamol overdose cause toxicity to the liver?

Answer 23

Overdose = prod of NAPQI toxic metabolite = oxidative damage to liver.

Liver try to combat by reacting NAPQI with glutathione = depletes stores = damage elsewhere

Question 24

What drug should be given after a paracetamol overdose and why?

Answer 24

Acetylcysteine = replenishes glutathione levels

Question 25

With a def of galactokinase what substance would build up?

Answer 25

Galactitol = build up in osmotic pressure = cataract

Question 26

Does aldehyde dehydrogenase have a low or high Km for acetaldehyde?

Answer 26

Low Km

Question 27

Disulphide bone in a protein can form between 2 residues of which AA?

Answer 27

Cysteine

Question 28

Which enzyme converts superoxide to H2O2 and oxygen?

Answer 28

Superoxide dismutase (SOD)

Question 29

Which enzyme converts H2O2 to water and oxygen?

Answer 29

Catalase

Question 30

Which fat soluble vit acts as a free radical scavenger?

Answer 30

E

Question 31

What toxic metabolite accumulates in the liver a during paracetamol overdose?

Answer 31

NAPQI

Question 32

What is the role of G6PDH?

Answer 32

To convert NADP back to NADPH

Question 33

What is the role of NADPH?

Answer 33

Reduction of oxidised glutathione = to protect cells

Question 34

What happens in G6PDH def?

Answer 34

= limits amount of NADPH prod = reduced amount of glutathione regenerated by NADPH = less protection from oxidative stress

Question 35

What is the clinical sign of G6PDH?

Answer 35

Heinz bodies

Question 36

How does NAPQI cause liver damage?

Answer 36

Damage to protein/DNA

Oxidative degradation of lipids