Pathogenesis of Diabetes: Glucose Homeostasis, Insulin Resistance

Question 1

What 2 hormones regulate glucose?

Answer 1

Insulin and glucagon
While glucagon keeps blood glucose from dropping too low, insulin is produced to keep blood glucose from rising too high. The two hormones counterbalance each other to stabilize blood glucose.

Question 2

How do pancreatic hormones in the pre- and post-pandrial states change?

Answer 2

• Glucagon signals are high during lack of glucose to ensure adequate supply of energy to the brain energy, once you eat and glucose is readily available, glucagon is inhibited with release of insulin
• With rapid rise in glucose in circulation, beta cells release insulin to activate uptake into cells

Question 3

Energy homeostasis in the fasting state

Answer 3

Glucagon high (released from alpha cells) activates the transition to utilizing alternative fuels for energy as a means of maintaining glucose homeostasis.
* liver → glycogenolysis, gluconeogenesis, proteolysis, FFA oxidation
* muscle → proteolysis & FFA oxidation (precursers for gluconeogenesis)
* fat → lipolysis

Need to look at 301 notes

Question 4

What is the primary goal of glucose homeostasis?

Answer 4

Supplying the brain with glucose to maintain normal function

Question 5

What occurs in the prolonged fasting state?

Answer 5

FFAs are used to generate ketone bodies as a fuel source for the brain
* Usually just extreme situations

Question 6

glucose from proteolysis

Answer 6

Protein can be broken down to AA and these can be used as precursers for gluconeogenesis

Question 7

glucose from lipolysis

Answer 7

triacylglycerols (TAGs) break down via hydrolysis into their constituent molecules: glycerol and free fatty acids (FFAs) and the glycerol can be a precurser for gluconeogenesis

Question 8

Where does glucagon act on in gluconeogenesis?

Answer 8

• PEPCK
• fructose 1,6-bisphosphates
• glycogen phosphorylase
• glucose 6 phosphatase

Question 9

Glucagon on PEPCK

Answer 9

Phosphoenolpyruvate carboxykinase (PEPCK) is a rate-controlling enzyme in hepatic gluconeogenesis, and it therefore plays a central role in glucose homeostasis. The rate of transcription of the PEPCK gene is increased by glucagon (via cAMP) and glucocorticoids and is inhibited by insulin

Question 10

glucagon effect on fructose 1,6 bisphosphatase

Answer 10

enhances flux through fructose 1,6-bisphosphates

Question 11

Glucagon effect on glycogen phosphorylase

Answer 11

increased glycogenolysis and the production of glucose-6-phosphate.

Question 12

Glucagon effect on glucose 6-phosphatase

Answer 12

G-6-Pase promotes gluconeogenesis by converting G-6-P to glucose, the last step of the pathway, glucagon has been shown to increase G-6-Pase expression and activity

Question 13

Draw supply of energy in pre-pandrial state

Answer 13

Question 14

How do AAs enter gluconeogenesis?

Answer 14

Through conversion to lactate or gluconeogenic AA intermediates can enter the CAC at different steps, then gluconeogenesis removes oxaloacetate from CAC
* Leu and Lys are NOT glucogenic

Question 15

Cori Cycle

Draw it out

Answer 15

If fasting but exercising muscles will use up glucose and produce lactate which can be transported to the liver to make more glucose to be used for energy

Question 16

Energy homeostasis in the postprandial state

Draw it out

Answer 16

Pancreatic beta cells sense lots of glucose and secret insulin stimulared glucose uptake and regenerating energy stores for all macronutrients
* Brain: glucose uptake and once gets enough glucose, stimulates satiety and extra glucose is put towards storage
* liver: glucose uptake, glycogenesis, protein synthesis
* Lipocytes: glucose uptake, TG uptake (CMs, VLDL) lipid synthesis, FFA storage (esterification)
* muscle: glucose uptake glycogenesis, protein synthesis

Question 17

What does insulin stimulate/ inhibit?

Answer 17

Stimulates glucose uptake and usage in peripheral tissues
* Glycolysis to generate ATP
* Glycogenesis in liver and muscles
* Lipogenesis in adipose tissue
* Glucose usage for protein synthesis

Inhibits:
* Ketogenesis (b-oxidation)
* Gluconeogenesis
* Glycogenolysis

Question 18

Where does insulin act in glycolysis?

Answer 18

• stimulates hexokinase
• stimulate phosphofructokinase 1
• stimulate pyruvate dehydrogenase
• stimulate glycogen synthase

Question 19

Draw supply of energy in post prandrial state

Answer 19

Question 20

What 2 biological functions does insulin signalling serve?

Answer 20

• apoptosis (survival)
• growth

Question 21

Insulin effect on GLUT4

Draw it out

Answer 21

Stimulates PI3 Kinase cascase which causes translocation of GLUT4 to the membrane

Question 22

Detailed description of the PI3K cascade

Answer 22

Question 23

Insulin resistance definition

Answer 23

Inability of insulin to produce its usual biological actions at circulating concentrations that are effective in normal subjects.
* Insulin does not fully exert its action

Question 24

What increases insulin resistance?

Answer 24

• Fat mass (linked to BMI)
• pregnancy
• gender (males)
• diet (fat, vitamins)
• alcohol
• hormones
• drugs/medications
• sedentary lifestyle.

Question 25

Energy homeostasis in insulin resistance

Answer 25

Hyperinsulinemia → Glucose goes up and beta cells senses it so secretes insulin but does not do very good in activating uptake so beta cells secrete more because it still sense it and will do so until it can exert normal action and then glucose will be taken up and beta cells can turn off. So just keeps secreting insulin until desired result.
* a lot of people who have this don’t even know it and probably 70% will go on without developing diabetes or experiencing hyperglycaemia.

Question 26

What are potential problems with insulin resistance?

Answer 26

• Episodes of hyperlipidemia? →Because insulin does not do its job there is more time for glucose to remain higher so does that contribute to more fat gain?
• Hyperglycemic excursions? → Does glucose go higher and/ or remain elevated for longer and can this damage the body?

Question 27

Energy homeostasis in diabetes

Answer 27

Lots of glucose → hyperglycemia, hyperlipidemia, ketoacidosis.

Pancreatic beta cells do not secrete enough insulin and cannot evaluate glucose concentration properly so it remains elevated and glucagon continues to be released and the systems are tricked into thinking there is a lack of glucose.
* hepatic glucose output → Glycogenolysis, gluconeogenesis, proteolysis, FFA oxidation
* lipocytes → lipolysis, ketogenesis
* muscle → proteolysis, FFA oxidation

Question 28

What are some biological outcomes of hyperglycemia?

Answer 28

• neuronal dysfunction → certain threshold of glucose is toxic
• decreased incretins → gut hormones that signal plentiness are not released as well
• glucose reabsorption from kidneys
• decreased insulin → glucose stays elevated
• Increased HGP → keeps making glucose
• increased FFAs → mobilizes fat stores
• inefficient glucose uptake
• increased glucagon