Complications of Diabetes

Question 1

Diabetic Ketoacidosis is generally associated with which type of Diabetes?

Answer 1

Type I

Question 2

Insulin resistance associated with which type of Diabetes?

Answer 2

Type II (they’ll have hyperinsulinemia)

Question 3

What are the three organs most commonly and dramaticaly affected by diabetes?

Answer 3

Eyes, Nerves, Kidneys

Question 4

What is the most likely cause of death for diabetic pts?

Answer 4

Atherosclerotic vascular disease

-Prior to age 40, the most common cause of death is renal failure. However, only 10% of diabetes pts die during this time period and after ago 40 atherosclerotic vascular disease becomes the greatest cause

Question 5

Metabolic Syndrome (T2D) requires a comboination of genetic and environmental factors. The major environmental factors are:

Answer 5

Obesity and lack of exercise

Question 6

The development of fat tissue where is a significant risk factor for metabolic syndrome?

Answer 6

Visceral fat tissue (in messentery and omentum)

Question 7

Why is visceral fat such a risk factor?

Answer 7

visceral fat secretes excessive amounts of free fatty acids, leptin, TNF, Angiotensin II, PI-1.

Also reduces the secretion of adiponectin

Question 8

What exactly is the mechanism by which the secretion of these substances by visceral fat leads to damage?

Answer 8

Various tissues take up the Free fatty acids where they are oxidized, stored as triglycerides, or converted to prostaglandins. The excessive oxidation of glucose and FFAs via the mitochondrial electron transport chain genereates the ROS “super oxide” which is a free radical that oxidizes cysteine amino acids. One of these is RAS which, when oxidized, will activate serine threonine kinases such as Protein kinase C. These free radicals can oxidize and damage many cell macromolecules

Question 9

What does RAS activate once it is oxidized?

Answer 9

Serine threonine kinases such as protein C

Question 10

What can free radicals do that is bad>

Answer 10

oxidize and damage many cellular macromolecules

Question 11

Superoxide can be generated via what enzyme?

Answer 11

coenzyme Q10

Question 12

How does a high glucose/ high FFA concentration cause this development of superoxide?

Answer 12

Excess FFA and glucose oxidation means that there is excess H+.
This excess H+ is pumped into the electron transport chain and inhibits the cytochromes from accepting an electron from CoQ10, which is what normally happens. This electron is then pushed to oxygen and SO is generated.

Question 13

What do the Super Oxides then do>

Answer 13

activate kinases which activate nuclear factors which ctivate genes that control inflammation. These cytokines, chemokine, etc…then produce the ischemia, cellular proliferation, matrix accumulation, and dysfunction, cellular necrosis, and apoptosis

Question 14

What does NO do?

Answer 14

vasodilator
inhibits NFKB (inflammation)
inhibits platelett aggregation

Question 15

What does super oxide do to NO

Answer 15

Destroys it

Question 16

excess glucose can generate additional super-oxide via

Answer 16

auto-oxidation…it is metabolized to sorbitol and advanced glycosylation end products

Question 17

excess glucose will induce a deficiency of what?

Answer 17

myo-inositol

Question 18

KNOW.. high free fatty acids also induce excessive VLDL secretion from the liver which will have adverse effects on other lipoproteins and forther accelerate microvascular disease

Answer 18

This is very detrimental to beta cells

Question 19

Ceramide is

Answer 19

a particularly bad fatty acid that induces NO to cause apoptosis. Apoptosis in the islets destroys beta cells.

Question 20

Arachidonate

Answer 20

substrate for the pro-inflammatory prostaglandins that contribute to islet destruction

Question 21

What is bad about a high NADPH to NADP ratio

Answer 21

1) inhibits further glucose and fatty acid oxidation- The partially degraded FAs remain bound to carnitine and inhibits the transfer of more fatty acids into the mitochondria. This allows toxic organic acids to accumulate in the cytoplasm
2) Increase in the production of Glyceraldehyde 3 Phosphate, a precursor for Diacylglycerol which activates protein kinase 3
3) More lactate made…acidosis

Question 22

What is super oxide a potent activator of?

Answer 22

Protein Kinase 3

Question 23

What is aldose reductase

Answer 23

an enzyme present in certain cells that converts glucose to sorbitol and then to fructose

Question 24

Conversion to fructose is inhibited by

Answer 24

high NADH concentrations

Question 25

Inhibition of conversion of sorbitol to fructose leads to?

Answer 25

Increased levels of sorbitol in the cytoplasm….osmotic swelling of cells.

Question 26

Where does this conversion to sorbitol and the osmotic swelling generally take place

Answer 26

In the lens, contributes to blurring of vision

Question 27

What is Myo-isositol?

Answer 27

It is a molecule involved in the Phosphatidylinositol (PI) pathway. PI is found on the outside of plasma membranes and has a rapid turnover. Must have intracellular myo-inositol for this pathway. Myo-inositol is generally concentrated inside the cell by an active transport system.

Question 28

What blocks myo-inosital active transport?

Answer 28

sorbitol

Question 29

What cells are particularly susceptible to sorbitol’s inhibitance of the PI pathway via its blocking of myo-inosital active transport?

Answer 29

Neurons

Question 30

It is apparent from several studies that in order for Na/K ATPase to be functional, both arms of the PI pathway must function correctly (DAG and IP3 arms).

Answer 30

Na/K ATPase is reduced in a number of diabetic issues, particularly nerves where it is vital for nerve conduction.

Question 31

What is the basic concept behind non-enzymatic glycosylation?

Answer 31

Whenever glucose comes in contact with protein or DNA molecules, it can become covalently linked via the aldehyder group on glucose and the terminal amino acid groups on arginine, lysine, and nucleic acids.

Question 32

The initial step in NEG is what?

Answer 32

formation of a schiff base…very labile, easily reversible, reaches equilibrium within hours

Question 33

What occurs after Schiff base formation

Answer 33

Amadori product formation (less labile)

Question 34

Reversal of the Amadori product takes about how long?

Answer 34

Four weeks….this is the product that is used to measure hemoglobin A1C which monitors pts glucose control over the previous 4-8 weeks

Question 35

What determines the extent of NEG

Answer 35

the concentration of glucose and the period of time that DNA or protein is exposed to it?

• If these glucose molecules happen to block an important binding or enzymatic site, they can disrupt normal function. Glycosylation can also create novel binding sites so that the protein binds to things that it normally would not.

Question 36

Glycosylated proteins can undergo a series of oxidation-dehydration reactions and rearrangements to form:

Answer 36

complex advanced glycosylation end products (AGE-products)

Question 37

What is the most important result of this reaction?

Answer 37

the formation of cross-links between proteins and/or strands of DNA via these AGE-products.

Question 38

Are AGE reactions reversible?

Answer 38

No…prevent normal degradation of these proteins

Question 39

Macrophages and endothelial cells have a receptor for AGE proteins. When these cells bind an AGE protein, they activate Protein Kinase C which leads to ischemia and inflammation

Answer 39

ok

Question 40

What proteins make up the extracellular matrix?

Answer 40

collagen, elastin, fibronectin

Question 41

What proteoglycans make up the extracellular matrix?

Answer 41

heparan sulfate

Question 42

Collagen and Elastin are mainly:

Answer 42

structural proteins (like the steel beams of a building)

Question 43

Fibronectin is:

Answer 43

adhesive protein

Question 44

Collagen synthesis is stimulated by

Answer 44

TGF-beta (elevated in diabetes by protein kinase C)

Question 45

What inhibits collagen synthesis?

Answer 45

Nitric Oxide

Question 46

Proteoglycans act as:

Answer 46

fillers (like mortar)

Question 47

Proteoglycan synthesis is inhibited by?

Answer 47

Protein Kinase C

Question 48

Heparan sulfate is the most important proteoglycan because it does what?

Answer 48

determines size and charge sieving property of basement membrane

Question 49

Heparan sulfate is held in place byu binding to:

Answer 49

collagen

Question 50

Heparan binding to collagen is disrupted by?

Answer 50

glycosylation

Question 51

Basement membranes in diabetic patients:

Answer 51

feature increased collagen (b/c TGF-beta stimulates collagen synthesis and TGF-beta is eloevated by protein kinase c) and a reduction in heparan sulfate (due to reduced production and reduced binding to collagen). see the ecm section oif handout

Question 52

Diabetes is a disease of the body’s filters, meaning

Answer 52

diabetes negatively impacts basement membranes

Question 53

Glomerular filtration is determined by three factors

Answer 53

1) perfusion pressure
2) glomerular capillary surface
3) Integrity of the basement membrane

Question 54

Within days of development of diabetes, what happens to perfusion pressure in the glomerulus?

Answer 54

It goes up because of dilation of the afferent and constrictin of the efferent arterioles

Question 55

Kidneys enlarge in diabetes?

Answer 55

yes

Question 56

GFR Is increased?

Answer 56

yes

Question 57

TIght regulation of blood glucose will arrest the progression of nephropathy at what stage?

Answer 57

micro-albuminuric….variable effect at later stages

Question 58

Read section on diabetic nephropathy

Answer 58

really only makes sense when you see it all connecting

Question 59

The fundamental pathophysiology of a neuropathic ulcer is:

Answer 59

pressure—> ischemia—> inflammation