ERS41 Pathophysiology Of Diabetes

Question 1

Type 1 / 2 DM complications

Answer 1

Type 1 / 2 DM
—> Hyperglycaemia
—> Extracellular + Intracellular effects
—> Vascular diseases (Retinopathy, Nephropathy, Atherosclerosis)

Question 2

3 pathways of pathophysiology of Hyperglycaemia

Answer 2

1. Non-enzymatic glycation
   —> Reactive Carbonyl Species (RCS)
   —> Advanced Glycation Endproducts (AGE)
2. Polyol pathway
   —> DAG synthesis (PKC activation) + Sorbitol + Consumption of NADPH
3. Hexosamine pathway

Question 3

Non-enzymatic glycation

Answer 3

Glycation: Reaction between Glucose (and its metabolites) with macromolecules (***Proteins, Lipids, Nucleic acids)

• addition of Glucose on Macromolecules —> products do damages
• no need enzyme
• elevated by Hyperglycaemia
• can occur within / outside cell
• involves multiple reactions, producing multiple products

Question 4

Reaction between Glucose / Proteins

Answer 4

Reversible phase (Short duration):
NH2 groups (from side chains, mostly by Lysine residues) in proteins
—> ***Schiff base adducts (Reversible but difficult, hours) (simple addition of glucose onto NH2 group)

Irreversible phase (Long duration):
—> **Amadori products (Irreversible, days) (highly chemically undefined)
—> Rearrangement, Elimination, Condensation, Oxidation etc.
—> **Reactive carbonyl products (Irreversible, weeks) (Extremely reactive intermediates, responsible for damages)
—> Structural and functional modifications of proteins
—> Crosslinking of proteins via covalent bond
—> ***Advanced Glycation Endproducts (AGE)
—> Functions nullified

N.B.: Above reaction can also occur in Normoglycaemia, but Rate of Production &laquo_space;Degradation

Question 5

Glucose within cells (in which glucose uptake is independent of insulin)

Answer 5

Side reactions within cells to produce Reactive carbonyl products (RCS)

1. Amadori pathway (reaction with proteins)
   —> ***3-Deoxyglucosone
2. Auto-oxidation of Glucose
   —> ***Glyoxal
3. Glycolysis (Alternative Breakdown of glyceraldehyde-3-phosphate if not cleared from cell quickly via subsequent glycolysis / glycolysis blocked)
   —> ***Methylglyoxal

3-Deoxyglucosone, Glyoxal, Methylglyoxal
—> ALL are RCS
—> react with proteins within / outside cell

Outside cells:
Only Amadori pathway —> 3-Deoxyglucosone

Question 6

Metabolism of Advanced Glycation Endproducts (AGE)

Answer 6

Under normal situation (Normoglycaemia):
1. RCS can be rendered inactive by **Reductases
—> Methylglyoxal + Glyoxal catabolised by **Glyoxalase system
2. AGE can be ***degraded by cells
3. Degradation products excreted by kidney

Hyperglycaemia condition:
- Production of AGE&raquo_space; Rate of Degradation

Question 7

Reaction of RCS / Direct glycation on Modification of ***Protein function

Answer 7

Example: Lipoprotein
—> Both lipids + protein components are modified by RCS

LDL (lipoproteins with high cholesterol content, come from VLDL)
1. Impairs binding and degradation of LDL by Fibroblast
2. Abolishes recognition by LDL-R
—> **LDL remain in circulation
3. Generation of **Anti-glycated LDL-Ab
4. ***Foam cell formation (modified LDL taken up) —> Atherogenic

HDL
1. ***Compromised reverse-transport of cholesterol (Glycation / Modification by RCS on HDL)

Question 8

Reaction of RCS / Direct glycation on Modification of ***Extracellular matrix

Answer 8

1. Inhibits lateral association of ***Type 4 collagen molecules
2. Alters packing of ***Type 1 collagen and laminin
3. Disrupts binding of **Heparan sulphate / other **Proteoglycan molecules to basement membrane
   —> ***dysfunction of Basement membrane (e.g. Kidney, Blood vessels)
   —> e.g. filtration property of kidney, affect response of blood vessel to NO
4. Abolish ***cell-matrix interaction
   —> cell receiving wrong signal from ECM
   —> cell cannot function properly
5. ***Dampens action of NO
   —> dysregulation of vascular tone

Question 9

AGE and AGE-R: Stimulation of cellular activities

Answer 9

AGE-R / Scavenger receptors / RAGE:
AGE bind to RAGE on cell surface
—> Intracellular signals
—> ***Change in cell activities

Cells with RAGE:

1. Macrophages
2. Monocytes
3. Mesangial cells
4. Endothelial cells

Macrophage / Monocytes:
- Secrete IL-1, IGF-1, TNF-α
- Proliferation
- Cytokine secretion
—> ***Overall ↑ Pro-inflammatory reactions

Endothelial cells:
- ↓ Thrombomodulin (anticoagulant) production
- ↑ Tissue factor (extrinsic pathway) production
—> ***Overall ↑ Pro-coagulant activity (↑ clotting tendency)

簡單而言: AGE —> ↑ Pro-inflammatory + ↑ Pro-coagulant activity

Question 10

Polyol pathway activation: Consequence of Hyperglycaemia

Answer 10

Hyperglycaemia
—> Influx of Glucose into cell
—> Glucose 6-phosphate (by Hexokinase: inhibited by high G6P formation)
—> Inhibition of conversion from Glucose to G6P
—> Accumulation of Glucose
—> Channel into Polyol pathway
—> Glucose —> Sorbitol (deplete NADPH —> NADP) (NADPH: reducing agent, important for suppressing ROS)
—> Sorbitol —> Fructose (deplete NAD —> NADH) (**NAD required for Glycolysis —> **suppression of Glycolysis)

(G6P —> Glycolysis / Pentose phosphate pathway)

Question 11

Effect of Polyol pathway on Glycolysis

Answer 11

1. NAD depleted by Sorbitol pathway
   —> Glycolysis suppressed
   —> **Glyceraldehyde 3-phosphate accumulate (cannot undergo Glycolysis to form Pyruvate)
   —> **Methylglyoxal formation (RCS)
2. Enhance conversion of Glyceraldehyde 3-phosphate to **Dihydroxyacetone phosphate
   —> conversion to **Glycerol 3-phosphate (enhanced due to ↑ NADH supply by Polyol pathway)
   —> Glycerol 3-phosphate accumulate
   —> react with Fatty acids from Lipolysis
   —> **DAG formation
   —> **PKC activation

簡單而言: Polyol pathway: Methylglyoxal formation (RCS) + PKC activation

Question 12

***Summary: Consequences of Polyol pathway activity

Answer 12

1. Competes with Glycolysis for NAD
   —> NAD depletion
   —> suppression of Glycolysis
   —> Glycerol 3-phosphate accumulation + Methylglyoxal (RCS) formation from Glyceraldehyde 3-phosphate accumulation
   —> **PKC activation + **AGE formation + further weakens cell ability to utilise glucose
2. Consumes NADPH (from Pentose phosphate pathway)
   —> **slows down re-generation of Glutathione (GSH: intracellular Antioxidant)
   —> cell more prone to **oxidative damage
3. **Sorbitol accumulation
   —> changes **Intracellular osmotic pressure in Lens cells
   —> change in **crystalline structure of lens proteins (also by AGE formation)
   —> **Cataract

Question 13

***Consequence of PKC activation

Answer 13

1. Vascular occlusion (∵ Pro-coagulant activity)
2. Capillary occlusion (∵ ECM synthesis)
3. Changes in vascular permeability
4. Blood flow abnormality
5. Inhibits NO formation (∵ ↓ expression of NO synthase) —> Vasoconstriction

Question 14

(Pentose phosphate pathway producing NADPH)

Answer 14

(NADPH:
—> **Oxidised GSH (GSSG) —> **Reduced GSH
—> Reduced GSH helps converts intracellular ROS —> inactivated oxidative compounds)

Question 15

Hexosamine pathway

Answer 15

Modify activities of transcription factors

Glucose (intracellular)
—> Fructose 6P
—> Glucosamine 6P (amino group added to F6P, from Glutamine —> Glutamate, by GFAT)
—> **UDP-GlcNAc (UDP-N-Acetyl-Glucosamine)
—> Nuclear transcription factors —(O-linked glycosylation)—> GlcNAc-linked Nuclear transcription factors
—> Activation of gene transcription (e.g. TGFβ, PAI (Inhibitors of Plasminogen activator))
—> **TGFβ: Inflammatory reaction + ***PAI: Inhibition of fibrinolysis

Question 16

***Overall summary of Hyperglycaemia

Answer 16

1. RCS —> Modify Protein + ECM function
2. ***AGE-formation —> ↑ Pro-inflammatory + ↑ Pro-coagulant activity
3. ***DAG synthesis —> PKC activation —> Vascular occlusion, Capillary occlusion, Changes in vascular permeability, Blood flow abnormality, Inhibits NO formation
4. ***Consumption of NADPH —> Disrupted metabolism of ROS
5. Sorbitol accumulation —> Cataract
6. ***Hexosamine pathway —> TGFβ: Inflammatory reaction + PAI: Inhibition of fibrinolysis

Results:

1. ↑ Cellular proliferation
2. Impaired breakdown of ECM (Thickening of vessel wall)
3. Disruption of basement membrane structure (Permeability changes)
4. Impaired lipid transport (Atherogenesis)
5. Protein deposition (∵ Crosslinking —> Blockade of vessels esp. capillaries)
6. Blood flow abnomalities (∵ ↓ NO)

Question 17

***Ultimate cause of damage by Hyperglycaemia

Answer 17

Hyperglycaemia
—> **↑ Glycolysis + ↑ TCA activity + ↑ NADH, FADH
—> ↑ Mitochondrial respiration / Electron transport
—> **↑ Superoxide production
—> **Nuclear DNA damage
—> **induce PARP (Polyadenine ribose polymerase) (DNA repair)
—> too much activation
—> **Polyribosylation / Inactivation of **GAPDH (Glyceraldehyde 3-phosphate dehydrogenase)
—> Glycolysis interrupted
—> ↑ AGE, DAG synthesis, Polyol pathway, Hexosamine pathway
—> Microvascular diseases

PARP:
1. Cleavage of Nicotinic acid from NAD
—> ADP-ribose

2. Polyribosylation
   —> adding multiple ADP-ribose (Poly-ADP-ribose tail) to GAPDH
   —> inactivate GAPDH
   —> Glycolysis interrupted

Question 18

Additional effects of DM: Fatty acids

Answer 18

Fatty acids (∵ uncontrolled Lipolysis)
—> ***β oxidation
—> Acetyl CoA oxidised in mitochondria
—> Mitochondrial superoxide production
—> DNA damage
—> PARP activation
—> GAPDH inactivation
—> Glycolysis interrupted
—> ↑ AGE, DAG synthesis, Polyol pathway, Hexosamine pathway
—> Microvascular diseases

Question 19

Cells affected by Hyperglycaemia

Answer 19

Cells that cannot control Glucose influx
—> prone to affected by Hyperglycaemia

E.g. Endothelial cells

Some other cells:
Glucose influx depends on insulin
—> Insulin resistance
—> impair Glucose influx
—> less affected by Hyperglycaemia

Question 20

***Common biochemical / haematological investigation results of patients with renal diseases

Answer 20

Chronic renal failure:

• Generalised oedema (salt and water retention)
• Metabolic acidosis (cannot excrete acidic products)
• Azotaemia / uraemia (cannot excrete metabolic end products of proteins)
• High concentration of other substances (phenols, phosphates, potassium)

***Kidney failure
Increase:
- Non-protein nitrogenous waste product
- K (calcium gluconate, beta agonist, insulin)
- H
- water
- Phosphate, sulphate (phosphate binder)
- phenols

Decrease:

• Na (dilution effect due to water retention)
• HCO3 (cannot synthesize)
• RBC (blood transfusion may worsen fluid overload)
• albumin
• Ca (arrhythmia, neuromuscular disease)

Water retention:

• reduced kidney function to excrete water and salt
• decrease in albumin
• increased secretion of renin and angiotensin
• decrease in Na concentration (dilution effect)

Increased potassium and phosphate:
- due to decreased GFR

Acidosis:

• acid accumulate in body fluid
• buffering power is used up —> Low bicarbonate level

Azotaemia:

• Increased urea, uric acid, creatinine
• concentration rise in proportion to degree of reduction —> assess CKD severity

Decreased albumin:

• loss in urine
• protein energy wasting

Anaemia:

• reduced erythropoietin production
• chronic problem because hormonal changes take time