Lecture 12- Type 2 diabetes

Question 1

type 2 diabetes definition

Answer 1

• metabolic disorder characterised by chronic hyperglycemia
• relative lack of insulin action/response (insulin resistance), insulin production or both
• leads to impaired glucose metabolism

Question 2

3 ways to diagnose diabetes

Answer 2

1. glycated haemoglobin test (HbA1c test)
2. oral glucose tolerance test (oral GTT)
3. impaired fasting blood glucose levels

Question 3

HbA1c test

Answer 3

glycated haemoglobin test

• measures how much glucose is bound to Hb in RBCs
• diabetes >6.5%

Question 4

oral glucose tolerance test (oral GTT)

Answer 4

consumption of 75g of anhydrous glucose, test plasma glucose 2 hrs later
-11.1mmol/L- diabetes

Question 5

impaired fasting blood glucose levels

Answer 5

plasma glucose>7.0mmol/L following 8 hr fast

Question 6

type 1 diabetes

Answer 6

autoimmune disease, immune mediated Beta cell destruction

- insulin deficiency, 5-10%

Question 7

type 2 diabetes

Answer 7

insulin resistance and insulin deficiency, 90-95%

Question 8

gestational diabetes

Answer 8

insulin resistance and relative insulin deficiency in pregnancy
- 3-5% of all pregnancies

Question 9

genetic defects affecting Beta cell function

Answer 9

1-2% of cases

Question 10

glucose homeostasis

Answer 10

balance of glucose intake/production and uptake/storage/usage

Question 11

when high blood glucose

Answer 11

gets stored in liver and muscle (as glycogen) and fat/WAT

Question 12

when low blood glucose

Answer 12

glucose released from stores- liver, muscle, WAT

Question 13

where is insulin produced?

Answer 13

produced and secreted by Beta cells of pancreatic islets

Question 14

beta cells of pancreatic islets

Answer 14

75-80% of the islet cells

produce and secrete insulin

Question 15

glucagon

Answer 15

alpha cells in pancreatic islets

- raises blood glucose level (acts opposite to insulin)

Question 16

somatostatin

Answer 16

gamma cells

Question 17

insulin synthesis pathway

Answer 17

1. genes encoding for insulin transcribed to mRNA in nucleus
2. Pre-proinsulin synthesised (in beta cell), excision of signal peptide, formation of disulphide bonds in ER (b/w A and B chain)
3. Transport of proinsulin to Golgi apparatus, cleaved by pro-hormone convertase
4. Formation of separate C-peptide and mature biologically active insulin (A and B chain)
5. Insulin stored in storage granules , secretion of insulin granules by exocytosis when calcium influx

Question 18

Insulin secretion pathway

Answer 18

1. glucose enters beta cells (via GLUT2 transporter)
2. glycolysis (breakdown of glucose) increases ATP:ADP ratio, increase energy supply to beta cells
3. Closes ATP-sensitive K channels (K cant go outside of beta cell now)
4. increase K in cells, makes cell more positively charged, depolarisation of cells
5. Opens voltage dependent Ca channels, influx of calcium, promotes exocytosis of insulin granules form storage granules

Question 19

glycogen synthesis

Answer 19

convert glucose into glycogen

Question 20

glycogenolysis

Answer 20

break down of glycogen

Question 21

gluconeogenesis

Answer 21

production of glucose from fat

Question 22

lipogenesis

Answer 22

convert/synthesise glucose into fat

Question 23

Normal glucose levels- liver

Answer 23

• increased glycogen synthesis
• decreased glycogenolysis
• decreased gluconeogenesis

Question 24

normal glucose levels- muscle

Answer 24

• increased glucose uptake

- increased glycogen synthesis

Question 25

normal glucose levels- WAT/fat

Answer 25

• increased glucose uptake

- increased lipogenesis

Question 26

vagus nerve

Answer 26

parasympathetic control of digestive tract e.g. liver

Question 27

high glucose levels- pancreas

Answer 27

decrease beta cell function

Question 28

normal glucose levels- brain

Answer 28

decrease appetite

Question 29

high glucose levels- liver

Answer 29

• decreased glycogen synthesis

- increased gluconeogenesis

Question 30

high glucose levels- muscle

Answer 30

• decreased glucose uptake

- decrease glycogen storage

Question 31

high glucose levels- WAT/fat

Answer 31

• decrease fat/TG storage
• increased lipolysis
• increase FFA in blood

Question 32

lipolysis

Answer 32

breakdown of fats and other lipids by hydrolysis to release FAs

Question 33

high glucose levels- insulin

Answer 33

• lots produced but not used by liver, muscle, WAT or brain

Question 34

high glucose levels- brain

Answer 34

increased appetite

Question 35

GLUT4 vesicle

Answer 35

used in glucose uptake by fat, muscle

Question 36

Akt

Answer 36

responsible for increasing glycogen synthesis

- Akt activates FOXO and GLUT4 vesicle

Question 37

FOXO

Answer 37

decreases gluconeogenesis in liver

Question 38

PI3K

Answer 38

activates Akt–>FOXO and GLUT4 vesicle

Question 39

how does insulin lead to changes in glucose production in organs and tissues?

Answer 39

insulin receptor (IR) binds to IRS (insulin receptor substrate)–>PI3K–>Akt–>

1. GLUT4 vesicle- increase glucose uptake
2. increased glycogen synthesis
3. FOXO- decrease gluconeogenesis

Question 40

chronic inflammation

Answer 40

triggers recruitment of immune cells–>increase pro inflammatory cytokine levels (IL-1, IL-18, TNF) in affected tissues (muscle, liver, islets, adipose tissue)
- islets (resident macrophages become activated, increased immune T and B cells)

Question 41

anti- inflammatory drugs

Answer 41

TNF, IL-1 blockers- beneficial for T2D- clinical trial

Question 42

ER stress

Answer 42

chronic overnutrition and increased FA (due to adiposity)–>accumulation of unfolded/misfolded proteins in ER lumen –>ER stress

Question 43

ER

Answer 43

central organelle in which trans-membrane and secretory proteins are synthesised and folded

Question 44

unfolded protein response- UPR

Answer 44

mitigate ER stress

• reduces protein synthesis through (PERK/ATF4)
• increase ER molecular chaperones through (ATF6)
• Activation of ER-associated degradation proteins through (IRE1/XBP1)
• CHOP- apoptosis

Question 45

PERK/ATF4

Answer 45

reduces translation, protein synthesis to reduce ER stress

Question 46

ATF6

Answer 46

increases ER molecular chaperones

Question 47

IRE1/XBP1

Answer 47

activates ER-associated degradation proteins (ERAD)

Question 48

CHOP

Answer 48

apoptosis of unfolded/misfolded proteins in ER

Question 49

BiP/GRP78

Answer 49

ER chaperones

Question 50

therapeutic potential for ER stress

Answer 50

chemical chaperones to reduce ER stress- clinical trial

Question 51

risk factors for T2D

Answer 51

lifestyle, age, genetics, history of gestational diabetes

Question 52

hallmarks of T2D

Answer 52

insulin resistance
hyperinsulinemia
hyperglycemia

Question 53

acute complications of T2D

Answer 53

hyperglycemic hyperosomlar state (HHS)

- high blood glucose levels–>high osmolarity–>extreme dehydration (dry skin, drowsy)

Question 54

chronic complications of T2D

Answer 54

micro- diabetic retinopathy/nephropathy/neuropathy

macro- stroke, heart disase, peripheral vascular disease

Question 55

key principle in treatment of T2D

Answer 55

control blood glucose levels

Question 56

3 key components of T2D treatment

Answer 56

1. lifestyle modification
2. oral glucose-lowering therapy
3. insulin therapy

Question 57

lifestyle modification

Answer 57

diet- healthy eating

exercise- reduce weight to improve insulin sensitivity and glucose uptake

Question 58

oral glucose lowering therapy

Answer 58

metformin

• safe, cheap, first line oral treatment (mono/combo therapy)
• activates AMP-activated kinase (AMPK)

Question 59

metformin

Answer 59

activates AMP-activated kinase (AMPK)

• liver- suppresses gluconeogenesis and lipogenesis
• skeletal muscle- increases insulin sensitivity and glucose uptake
• side effects- liver disease and GIT issues (diarrhoea)

Question 60

lipogenesis

Answer 60

formation of fat

Question 61

metformin- liver

Answer 61

suppresses gluconeogensis and lipogenesis

Question 62

metformin- skeletal muscle

Answer 62

increases insulin sensitivity and glucose uptake

Question 63

metformin side effects

Answer 63

liver disease and GIT issues

Question 64

incretin hormones

Answer 64

stimulate insulin production and trigger insulin release in response to meals

Question 65

GLP-1

Answer 65

gut derived glucagon peptide 1

- rapidly degraded by DPP-4

Question 66

function of GLP-1

Answer 66

activates GLP-1R–>decrease blood glucose levels and improve glycemic control

Question 67

DPP-4

Answer 67

degrades GLP-1 within minutes

Question 68

GLP-1R action on brain

Answer 68

decrease appetite

Question 69

GLP-1R action on stomach

Answer 69

decrease gastric emptying

Question 70

GLP-1R action on pancreas

Answer 70

• increase insulin secretion/synthesis
• decrease glucagon secretion
• increase beta cell proliferation
• decrease beta cell apoptosis

Question 71

GLP-1R agonists/ DPP-4 inhibitors

Answer 71

act on GLP-1R and DPP

Question 72

GLP-1R agonist

Answer 72

Exenatide

• inject subcutaneously
• side effects- hypoglycemia (act directly on beta cells)

Question 73

DPP-4 inhibitor

Answer 73

Gliptin

• Tablets, reduce GLP-1 degradation
• side effects- sinusitis, nausea, allergic issues

Question 74

sulfonylureas

Answer 74

safe, cheap, second generation

e.g. glimepiride, glipizide, glyburide

Question 75

function of sulfonylureas

Answer 75

• inhibit opening of ATP-sensitive K channels (no K goes out)
• increase Ca influx–>depolarisation
• increase insulin release from beta cells in pancreas

side effects– hypoglycemia, weight gain

Question 76

acarbose

Answer 76

alpha glucosidase inhibitor

- cheap, effective

Question 77

function of acarbose

Answer 77

lowers blood glucose, prevent T2D

• reduces rate of digestion of carbs in intestine–>less glucose is absorbed
• side effects- flatulence, diarrhoea

Question 78

alpha glucosidase

Answer 78

intestinal enzyme that breaks down carbs into glucose

Question 79

future therapies

Answer 79

prevention- public health policies, lifestyle modification

basic science- further understanding for causes of diabetes