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Pancreas

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Exocrine (acinar) cells secrete enzyme-rich juice that is ducted to duodenum ... increase hepatic gluconeogenesis. Catabolic action on muscle, fat ... – PowerPoint PPT presentation

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Title: Pancreas


1
Pancreas
  • Located partially behind stomach in abdomen
  • Composed of both endocrine and exocrine tissue
  • Exocrine (acinar) cells secrete enzyme-rich juice
    that is ducted to duodenum
  • Clusters of endocrine cells are scattered among
    exocrine cells

2
Endocrine pancreas
  • Islets of Langerhans
  • Two major populations of cells
  • Alpha cells (glucagon)
  • Beta cells (insulin)
  • Others
  • D cells (somatostatin)
  • F cells (pancreatic polypeptide)
  • Hormones signal in classic endocrine and
    paracrine manner

3
Insulin
  • Polypeptide
  • Alpha chain (21 a.a.)
  • Beta chain (30 a.a.)
  • Normally degraded within liver and kidneys by
    hepatic glutathione insulin dehydrogenase
  • Half-life is 5 minutes

4
Insulin
  • Released in response to elevated glucose levels
  • Most important target tissues
  • Hepatic cells
  • Muscle cells
  • Adipose tissue cells
  • Enhances glucose uptake into cells (glucose
    transporter)
  • Cells metabolize glucose and
  • Store as glycogen
  • Used as energy substrate to synthesize proteins,
    fats

5
Insulin Effects on liver
  • Enhances glucokinase activity
  • Phosphorylates glucose gt glucose-6-PO4
  • Maintains diffusion gradient for glucose entry
  • Activates glycogen synthetase
  • Promotes formation of glycogen

6
Insulin Glycogen Synthetase
  • GS is inactivate when phosphorylated
  • 2 protein kinases can phosphorylate GS
  • cAMP-dependent
  • cAMP-independent
  • cAMP-dependent kinase relies on glucagon for
    activation
  • Insulin inhibits cAMP-independent kinase
  • Result no phosphorylation gt GS is active

7
Insulin Effects on fat cells
  • Enhances glucose uptake and ultimately
    triglyceride production
  • Glucose catabolized to glycerol
  • Glycerol combined with free fatty acids to form
    triglycerides gt stored
  • Free fatty acids obtained from chylomicrons
  • Insulin causes endothelial cell release of
    lipoprotein lipases
  • FFAs released from chylomicrons, taken up by fat
    cells

8
Insulin Other effects
  • Enhances presence of facilitated glucose
    transport (GLUT) proteins
  • In liver, fat, and muscle cells
  • GLUT proteins form pores allow polar sugars to
    cross lipid bilayer, move down gradient
  • GLUT1 is constitutively expressed
  • housekeeping glucose transporter
  • Primary transporter exped in liver
  • Insulin enhances GLUT 1 gene expression

9
Insulin effects, contd.
  • GLUT 4 primarily expressed in muscle, adipose
    tissue
  • GLUT4 initially resides in intracellular vesicles
  • Insulin causes insertion into cell membrane
  • Interesting side note exercise also induces
    GLUT4 membrane insertion in muscle cells

10
Insulin receptors
  • Figure 2.6
  • Receptor is complex of two subunits
  • alpha (extracellular bind insulin)
  • beta (transmembrane protein covalently linked to
    alpha)
  • Insulin binds to receptor dimer
  • Activation gt autophosphorylation of beta subunit
    tail
  • Acts as tyrosine kinase

11
Insulin receptor
  • Target of receptor insulin receptor substrate 1
    (IRS-1)
  • IRS-1 generates secondary signals
  • P13 kinase enhances glucose transport
  • Activates growth receptor-binding protein 2,
    which enhances glycogen synthesis

12
Glucagon
  • Peptide (29 aa) produced by alpha cells
  • Opposes insulin actions (hyperglycemic factor)
  • A catabolic factor
  • Figure 8.3
  • actions involve transmembrane receptor, cAMP
    pathway

13
Glucagon actions
  • Stimulates hepatic glucose synthesis and release
  • Glycogenolytic actions
  • Role of phosphorylase a (Fig. 8.6)
  • Inhibits glycogen formation (Fig. 8.7)
  • Promotes conversion of amino acids and glycerol
    to glucose
  • Lipolytic actions on fat cells
  • Release of FFAs and glycerol
  • Can only occur when insulin is low

14
Glucagon Lipolytic actions
  • Mobilization of triglycerides depends on lipase
    activity
  • Lipase activated by glucagon (also
    catecholamines)
  • cAMP-dependent kinase activates lipase gt free
    fatty acid release
  • Insulin can reverse (mechanisms unclear)

15
Glucagon Lipolytic actions, contd.
  • Glucagon inhibits lipogenesis (Fig. 8.8)
  • Important enzyme for lipogenesis acetyl CoA
    carboxylase
  • Acetyl CoA carboxylase inhibited via
    phosphorylation
  • Two enzymes regulate its activity (cAMP-dep.,
    -indep. Kinases)
  • Glucagon gt cAMP gtgt phos. of carboxylase gt
    inhibition of lipogenesis

16
Somatostatin
  • 14 aa in length
  • Produced by D cells of islets
  • Juxtaposed to alpha, beta cells
  • Local, paracrine actions (inhibits glucagon,
    insulin, pancreatic polypeptide release)
  • Receptor inhibits cAMP levels in target cells
  • Release stimulated by ingestion of protein meal
  • Regulates movement of triglycerides from gut to
    internal environment
  • Lowers postprandial triglyceride levels

17
Pancreatic polypeptide
  • Produced by F cells
  • Inhibits secretion of enzymes from acinar cells
  • Secreted in response to ingestion of meal
  • Conservation of digestive enzymes?
  • Suppresses secretion of SST from D cells

18
Control of islet function
  • Glucose is major metabolic substrate for brain
  • Cant make, store, increase uptake of glucose
  • Prevention / correction of hypoglycemia is
    critical to survival
  • Most important / immediate regulator of islet
    function glucose
  • Low glucose gt glucagon release increases
  • Increase in glucose gt insulin release increases
  • Extreme hypoglycemia gt release of epinephrine
    from adrenal medulla

19
Autonomic control of islet function
  • Catecholamines of neural (ANS) and endocrine
    (adrenal) origin control islets
  • Alpha and beta cells possess catecholamine
    receptors
  • High E, NE gt beta adrenergic receptors gt
    inhibition of insulin secretion

20
Autonomic control ofislet function, contd.
  • Epinephrine inhibits insulin secretion
  • Prevents glucose from being converted to
    glycogen, fat
  • Readily available to active tissues (brain,
    muscles)
  • Epinephrine and norepinephrine stimulate glucagon
    secretion
  • Activates hepatic glucose production, release

21
Insulin glucagon feedback
  • Intra-islet feedback loop?
  • Elevated glucose gt increased insulin secretion
  • Insulin then inhibits glucagon production
  • Only beta cells appear to possess liver-type
    glucose transporter
  • Beta cells may then convey info to alpha cells
  • Other supporting evidence juvenile diabetes
  • No beta cells
  • Glucagon elevated even in presence of
    hyperglycemia
  • Elevated hepatic production of glucose

22
Other factors that influence glucose homeostasis
  • Growth hormone is diabetogenic
  • reduces sensitivity of peripheral tissues
  • Side effect gt elevated insulin gt further
    downregulation of receptors
  • Acromegalics gt insulin resistance
  • Glucocorticoids
  • increase hepatic gluconeogenesis
  • Catabolic action on muscle, fat
  • Cushings syndrome leads to diabetes

23
Diabetes mellitus
  • Hyperglycemia induced by
  • Lack of insulin production
  • Insensitivity of target tissues to insulin
  • Two types
  • Type I (IDDM)
  • Type II (NIDDM) or maturity onset diabetes

24
Type I Diabetes Mellitus
  • Juvenile-onset diabetes
  • Insulin deficiency
  • Causes
  • Viral-induced beta cell destruction
  • Cytotoxic autoantibodies to beta cells
  • Abrupt onset of symptoms
  • Almost always requires insulin therapy

25
Type II Diabetes Mellitus
  • Accounts for 80 of cases of DM
  • Onset is during adulthood
  • Above-normal levels of insulin
  • Insensitivity of target tissues
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