1. 18. Pancreatic function and metabolism
V BS 122
2012
Luis A. Bate

2. Objectives
To understand the role of the pancreas in the regulation of carbohydrate metabolism
To learn in depth about insulin and glucagon actions
To identify tha main pathophysiologies associated with these systems (Diabetes)

3. Reading
Chapter 78
Guyton

4. Pancreatic structures
ISLETS OF
LANGERHANS
DUCTULES
DUCTS
PANCREATIC
ACINI
F18-1

5. Pancreatic islets
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6. Pancreatic secretions
In addition to the digestive enzymes the pancreas serves an important endocrine role
Produces
Insulin
Glucagon
Pancreatic polypeptide
Somatostatin
Amylin
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7. Pancreatic islets α cells (Glucagon) β cells (Insulin, Amylin) D cells
(Somatostatin)
F cells
(Pancreatic
Polypeptide)
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8. INSULIN Traditionally associated with carbohydrate metabolism
It also affects fat and protein metabolism, specially under disease conditions
Circulates in an unbound form
Half-life of 6 minutes
Circulating for 10 minutes after release
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9. PROINSULIN
INSULIN
α chain
β chain
C peptide

10. Insulin secretion
β cell
Ca++
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11. Enzyme phosphorylation Growth and gene expression Glucose transport α α β β TK TK
Enzyme phosphorylation
Growth and gene expression
Glucose transport
Fat synthesis
Glucose synthesis
Protein synthesis
EFFECT
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12. GLYCOGEN
PHOSPHORYLASE
GLUCOSE-6
PHOSPHATASE
GLYCOGEN SYNTHASE
GLUCOSE
GLUCOSE-6-PHOSPHATE
GLUCOKINASE
6-PHOSPHOFRUCTOKINASE
FRUCTOSE-1-,6-BIPHOSPHATE
ALDOLASE
TRIOSE PHOSPHATE
PHOSPHOENOLPYRUVATE
PYRUVATE KINASE
PYRUVATE DEHYDROGENASE
PYRUVATE
ACETYL-CoA
ACETYL-CoA CARBOXYLASE
MALONYL-CoA
FATTY ACID SYNTHASE
F18-8
FFA

13. Use of glucose Brain tissue can only use glucose as a fuel
Brain can uptake glucose from circulation independently of insulin
Only few types of cells permit free transport of glucose onto themselves
Brain
Liver
Erythrocytes
F18-9

14. Metabolic pathways of glucose in muscle
Once inside a cell, glucose is phosphorilated by the enzyme glucokinase
Once phosphorilated glucose cannot cross the cell membrane (leave the cell)
Unlike the liver, muscle tissues lacks glucose-6-phosphatase
Cannot release glucose into circulation
Can only use it for its own metabolism
Storage
Energy
F18-10

15. GLYCOGEN
GLUCOSE-6-PHOSPHATE
GLYCOGEN
GLUCOSE
GLUCOSE-6-PHOSPHATE
TCA
GLUCOSE
GLUCOSE
GLUCOSE
FFA
GLUCOSE
TCA (ENERGY)
FFA
F18-11

16. Sequence of events following insulin elevation
After seconds of attachment
Increased glucose uptake by cells
Muscle and adipose cells not on neurons
Glucose is phosphorylated
Enters metabolic pathway
Permeability to aa increases
After minutes
Increases internal enzymes
After hours or days
Increases translation of mRNA
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17. Role of insulin
Lowers the circulatory concentrations of glucose, fatty acids and amino acids
Enhances storage of these in large molecules
Glycogen
Triglycerides
Proteins
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18. Effect of insulin on carbohydrates
Muscle absorption of glucose
Conversion of glucose to glycogen for storage
Liver uptake of glucose
Conversion of glucose to glycogen for short storage
Inhibition of gluconeogenesis in the liver
F18-14

19. Effect of insulin on fat metabolism
After the deposit of glycogen is full (6% liver weight) it promotes the synthesis of fat in the liver
Exported to circulation as VLDL
Uptake by adipose tissue
Stored as fat
Inhibit hormone-sensitive lipase (no FFA release from adipocytes)
Promotes glucose uptake in adipocytes
Synthesis of glycerol and FFA
F18-15

20. Effect of insulin on protein metabolism
Promotes protein synthesis and storage
Increases uptake of amino acids
Increases translation of mRNA
Turns on ribosomal assembly
Inhibits catabolism
In liver reduces gluconeogenesis (amino acid sparing)
F18-16

21. Effect of the lack of insulin on protein metabolism
Protein storage stops
Increases plasma amino acids concentration
Used for gluconeogenesis
Convertion to urea and excreted
Overall protein wastage
Causes weakness
Organ malfunction
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22. Insulin catabolism Takes place in the liver and kidney
Enzyme insulinase
Disulfide bonds are reduced
Peptide enzymes chop chains into small peptides and amino acids
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23. Glucagon 29 amino acid protein Produced by alpha cells
Released when circulatory glucose is low
Contributes to elevation of circulatory glucose
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24. Effect of glucagon on glucose metabolism
Promotes glycogenolysis
Through a complex enzymatic cascade
Increases gluconeogenesis in the liver
Promotes amino acid uptake
Convert them to glucose
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25. Regulation of circulatory glucose
HYPERGLYCEMIA
HYPOGLYCEMIA α β α β
INSULIN
GLUCAGON
NORMOGLYCEMIA
F18-21

26. Regulation of glucagon secretion
High circulatory glucose inhibits secretion
Low concentration enhances secretion
Increased circulating amino acids increase secretion
Permits conversion to glucose
Exercise increases glucagon secretion
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27. Other effects of glucagon
Activates adipose cell lipase
Makes available fatty acids for energy
Inhibits storage of triglycerides in the liver
Enhances heart strength
Increases irrigation of kidney
Enhances bile secretion
Inhibits gastric secretion
F18-23

28. Somatostatin inhibits both glucagon and insulin
Acts locally in islets
SS decreases stomach, duodenum and gallbladder motility
SS inhibits secretion and absorption by the GIT
Amylin is a protein produced by the pancreas which selectively inhibits insulin stimulated glucose utilization and glycogen deposition in muscle
Amylin does not affect adipocyte glucose metabolism
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29. Pancreatic cell interactionβ
INSULIN α D
GLUCAGON
SOMATOSTATIN
F18-25

30. Pathophysiology Diabetes Mellitus Type I diabetes (Insulin-dependent)
Due to lack of insulin production
Juvenile diabetes mellitus
Type II diabetes (non insulin-dependent)
Due to decrease sensitivity of tissue to insulin (insulin resistance)
Adult-onset diabetes
F18-26

31. Type I diabetes Damage of B cells High glucose concentration
Viral infection, autoimmune disorder, genetic predisposition
Appears at a young age
Very rapidly
High glucose concentration
Loss of glucose in urine
Osmotic diuresis (dehydration)
Polyurea
F18-27

32. Cont . . . Structural changes in tissue Switch to use of fats
Malfunction of blood vessels
Risk of heart attack, stroke, kidney disease, retinopathy and blindness, ischemia and gangrene of limbs
Also neurological problems
Switch to use of fats
Causes metabolic acidosis
Diabetic coma... Death
F18-27

33. Type II diabetes Accounts for 80-90% of cases
Manifest at mature age (adult onset diabetes)
Increased plasma insulin
Many metabolic abnormalities
Except ketosis
Patients usually obese
Can be managed through diet
F18-28

34. Summary
Reviewed the role of the pancreas in the regulation of carbohydrate metabolism
Identified the functions of insulin and glucagon
Pointed out the most common pathophysiologies associated with these systems (Diabetes)