L40 - Biochemical basis of Diabetes Mellitus II

Question 1

Describe how overnutrition can lead to diabetes?

Answer 1

Overnutrition 
> obesity 
> Insulin resistance + impaired glucose tolerance >> increase stress on beta cells
> Beta cell dysfunction 
> Hyperglycaemia 
> diabetes

Question 2

Explain the relationship between Abdominal fat and lipolytic rate?

Answer 2

Higher abdominal fat:

• Increase pro-lipolytic b-adrenergic receptors
• Increase Insulin resistance
• Increase 11β-HSD1 = Increase Cortisol

> > > fatter = higher lipolytic rate

Question 3

Describe the intracellular effects of PRO-Lipolytic β-adrenergic receptors on lipolytic rate at adipose tissue?

Answer 3

Increase expression of pro-lipotypic B- receptors:

• Increase cAMP formation: activate PKA:
  1) PKA phosphorylate Hormone sensitive lipase (HSL): break DAG into FA
  2) Disintegrate protective protein coat of Perilipin on surface of lipid droplet&raquo_space; more HSL action

> > increase lipolysis

Question 4

Describe the intracellular effects of ANTI-Lipolytic adrenergic receptors receptors on lipolytic rate at adipose tissue?

Answer 4

1. Catecholamines activate α-Adrenergic receptor > Gαi inhibit cAMP production**
2. Insulin receptor:
   a) Activate IRS > P13K/PKB pathway to degrade cAMP

b) Inhibit desnutrin (HSL) > less DAG converted to FA
c) IRS > PP1 pathway to preserve perilipin protein coat on lipid droplet

Question 5

Summarize all the altered adipocyte metabolism pathways caused by obesity?

Answer 5

1) Increase expression of pro-lipolytic B-adrenergic receptors&raquo_space; Increase basal rate of lipolysis
2) Increase leptin-stimulated lipolysis
3) Decrease expression of IRS-1 = decrease insulin sensitivity (less anti-lipolysis)
4) expression of 11β-hydroxysteroid dehydrogenase type 1 (11β-HSD1)&raquo_space; more cortisol
5) Activate Denustrin (HSL)

Question 6

Describe the normal function of IRS-1 in insulin receptors in adipocyte (Careful: not asking about skeletal muscle)

Answer 6

1) Activate IRS > P13K/PKB pathway to degrade cAMP
2) IRS > PP1 pathway to preserve perilipin protein coat on lipid droplet

> > decrease lipolysis rate/ Anti-lipolysis

Question 7

Describe how obeisity/ overnutrition/ lack of exercise can lead to increased TAG in liver and skeletal muscles?

Answer 7

Dysregulation of lipolysis

> > Fatty acid transported into liver and muscles

> > Fatty acyl CoA not transported into mitochondria for B-oxidation to make ATP (no exercise)

> > Fatty acyl CoA converted to DAG and TAG:

• VLDL-TAG in liver
• Intramyocellular TAG in skeletal muscle

Question 8

Compare the functions of IRS-1 in Insulin receptors based on which part is phosphorylated?

Answer 8

1) Phos. at tyrosine residues&raquo_space; normal downstream signalling
2) Phos. at serine, threonine residues&raquo_space; no signalling&raquo_space; IRS incapacitated

Question 9

Describe how increased abundance of DAG (due to dysregulation) in adipocyte can directly*** cause insulin inhibition?

Answer 9

DAG
> Activation of Novel Protein Kincase C***

> Phosphorylate serine/threonine residue of IRS

> Disable IRS, no downstream signalling

> Selective inhibition of insulin receptor: Increase pro-lipolytic receptors, no inhibition on HSL, more cortisol…etc

Question 10

Describe how increased abundance of Fatty acid can INDIRECTLY cause insulin resistance? not asking about DAG and PKC

Answer 10

Increase FA

> > Activate PPARα/δ (peroxisome proliferator activated receptor)

> > Increase B-oxidation pathway activity

> > Increase NADH, FADH, Acetyl-CoA

> > Saturation of respiratory electron transport chain in mitochondria

> > Produce ROS to activate protein kinases

> > IRS phosphorylation = insulin resistance

Question 11

Describe the effects of IRS on glycogenolysis, glycogenesis and glucose transport?

Answer 11

IRS&raquo_space; P13K/PDK pathway:

(Recruit P13K (lipid kinase)&raquo_space; Make Ptdlns 3,4,5-triphosphate&raquo_space; Recruit PDK to plasma membrane)

a) Activate GLUT4 translocation = more glucose transport
b) Activate AKT kinase:
i) Inhibit glycogenolysis
ii) Activate glycogenesis

Question 12

Explain how Fatty acid can increase VLDL secretion?

Answer 12

Fatty acid cause insulin resistance (direct pathway via novel PKC + indirect pathway via PPARα/δ and ROS)

> > Remove insulin inhibition on conversion from TAG to VLDL-TAG (VLDL1)/ VLDL packaging

> > Untimely export of VLDL from liver

Question 13

Summarize the effects of insulin resistance on liver glucose control?

Answer 13

1) PI3K/PDK/AKT kinase pathway affected&raquo_space; Persistent gluconeogenesis and glycogenolysis + impaired glycogenesis
2) Increase De novo lipid synthesis and untimely VLDL packaging&raquo_space; Increases VLDL1 secretion

Question 14

Summarize the effects of elevated VLDL in serum on other lipoproteins?

Answer 14

1) More VLDL transfer Triglycerides to HDL&raquo_space; Increase HDL degradation, impair reverse cholesterol transport
2) More VLDL converted to LDL to Dense LDL&raquo_space; Harmful, highly Atherogenic

Question 15

Explain how physical exercise can lead to increase FA utilization (instead of converted to TAG in liver and muscles)?

Answer 15

• Increase exercise = more ATP used = more AMP
• AMP activates AMP-activated kinase&raquo_space; Inactivation of Acetyl CoA carboxylase
• Less A-coA made into Malonyl CoA&raquo_space; less inhibition of transporting Fatty acyl CoA into mitochondria for B-oxidation

Question 16

What is the normal function of malonyl CoA in lipid metabolism?

Answer 16

Inhibit the translocation of Fatty acyl CoA into mitochondria for B-oxidation

Question 17

Explain how physical exercise can improve glucose metabolism in muscles?

Answer 17

Exercise: more ATP used, converted to AMP, activate AMP-Kinase (AMPK)
1) AMPK-independent: GLUT 4 translocation to plasma membrane&raquo_space; increase glucose transport into skeletal muscle

2) AMPK- dependent: increase FA utilization&raquo_space; reduce inhibitory phosphorylation of insulin receptor&raquo_space; restore insulin sensitivity

Question 18

Describe the triple action of Thiazolidinediones (TZD, e.g. rosiglitazone, pioglitazone)?

Answer 18

bind to activate PPARγ (= transcription factor for β-oxidation enzymes) in adipose tissue and muscle:

1) Increase FA uptake in adipocyte
2) Suppress Anti-inflammatory reaction (NF-kB) that cause insulin resistance by PPARγ complex
3) Differentiation of pre-adipocyte: more insulin-sensitive

Question 19

MoA of Biguanides?

Answer 19

insulin sensitizers, e.g. metformin

act on liver to activate AMP-protein kinase:
Inactivation of Acetyl CoA carboxylase = less malonyl CoA = more Fatty acyl CoA transport into mitochondria
» better FA utilization

Question 20

MoA of DDP-4 inhibitors?

Answer 20

inhibit breakdown of incretins&raquo_space; increase stimulation on pancreas for insulin secretion