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Transcript
Chapter 3 Carbohydrates 2009 Cengage-Wadsworth Structural Features • Simple carbohydrates – Monosaccharides – Disaccharides • Complex carbohydrates – Oligosaccharides – Polysaccharides 2009 Cengage-Wadsworth Simple Carbohydrates • Monosaccharides – Steroisomerism • Chiral carbon - have 4 different atoms or groups attached to them • Stereoisomers - have 2 or more chiral carbon atoms with same 4 groups attached but are not mirror images of each other 2009 Cengage-Wadsworth Simple Carbohydrates – Ring structures - molecules cyclize & form another chiral carbon – Haworth models – Pentoses – Reducing sugars 2009 Cengage-Wadsworth Simple Carbohydrates • Disaccharides – Maltose – Lactose – Sucrose 2009 Cengage-Wadsworth Complex Carbohydrates • Oligosaccharides – Raffinose – Stachyoses – Verbascose • Polysaccharides – Starch – Glycogen – Cellulose 2009 Cengage-Wadsworth Digestion • Polysaccharides – Salivary -amylase - mouth – Pacreatic -amylase - small intestine – Resistant starches • Digestion of disaccharides – Disaccharidases - active in microvilli of enterocytes 2009 Cengage-Wadsworth Absorption, Transport, & Distribution • Absorption of glucose & galactose – Into cell: active transport - SGLT1 – Into blood: diffusion, GLUT2 • Absorption of fructose – Into cell: facilitated transport - GLUT5 – Into blood: GLUT2 – Limited in 60% of adults 2009 Cengage-Wadsworth Absorption, Transport, & Distribution • Monosaccharide transport & cellular uptake • Glucose transporters – GLUT isoforms • Integral proteins • Each has specific combining site • Undergoes a conformational change upon binding the molecule • Can reverse this change when unbound 2009 Cengage-Wadsworth Absorption, Transport, & Distribution – Specificity of GLUTs • GLUT1 - basic supply of glucose to cells • GLUT2 - low infinity transporter; glucose from enterocyte to blood • GLUT3 - high-affinity for brain & other glucose-dependent tissues • GLUT4 - insulin sensitive, in muscle & adipose tissues • GLUT5 - for fructose 2009 Cengage-Wadsworth Absorption, Transport, & Distribution • Insulin – Role in cellular glucose absorption • Binds to membrane receptor • Stimulates GLUT4 to move to membrane • Maintenance of blood glucose levels 2009 Cengage-Wadsworth Glycemic Response to Carbohydrates • Glycemic index – Increase in blood glucose during 2hour period after consumption of a certain amount of CHO compared with equal CHO from reference food • Glycemic load – GI x g of CHO in 1 serving of food 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • Glycogenesis – Conversion of glucose to glycogen • Glycogenolysis – Breakdown of glycogen to glucose – Phosphorolysis process – Regulation of phosphorylase • Covalent - glucagon, epinephrine • Allosteric - AMP 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • Glycolysis - degradation of glucose to pyruvate – Hexokinase/glucokinase reaction – Glucose phosphate isomerase – Phosphofructokinase reaction – Aldolase reaction – Glyceraldehyde 3-phosphate & dihydroxyacetone phosphate 2009 Cengage-Wadsworth Integrated Metabolism in Tissues – Oxidation of glyceraldehyde 3-phosphate to carboxylic acid, incorporation of inorganic phosphate into high-energy anhydride bond – Substrate-level phosphorylation of ADP – Phosphoglyceromutase – Dehydration of 2-phosphoglycerate – Phophoenolpyruvate (PEP) donates phosphate group to ADP – Lacate dehydrogenase reaction 2009 Cengage-Wadsworth Integrated Metabolism in Tissues – Fructose enters pathway – Galactose is phophorylated – Galactose 1-phosphate converted to glucose 1-phosphate – Glucose 6-phosphate enters hexosemonophophate shunt – Glucose 1-phosphate enteres glycogenesis – Glucose can enter glycolysis 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • Substrate-level phosphorylation • The tricarboxylic acid cycle – TCA pathway • Formation of citrate from oxaloacetate & acetyl CoA • Isomerization of citrate to isocitrate • Dehydrogenation catalyzed by isocitrate dehydrogenase • Decarboxylation & dehydrogenation of ketoglutarate 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • Hydrolysis of thioester bond of acetyl CoA drives phosphorylation of guanosine diphosphate (GDP) • Succinate dehydrogenase reaction • Fumerase incorporates H2O across double bond of fumarate to form malate • Malate converted to oxaloacetate – ATPs produced by complete glucose oxidation • C6H12O6 + 6O2 6CO2 + 6H2O + energy • Yields 12 ATPs + 2 mol acetyl CoA per 1 mol glucose = 24 ATPs 2009 Cengage-Wadsworth Integrated Metabolism in Tissues – Acetyl CoA oxidation and tricarboxylic acid cycle intermediates – NADH in anaerobic & aerobic glycolysis: the shuttle systems • Glycerol 3-phosphate shuttle system • Malate-aspartate shuttle system 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • Formation of ATP – Biological oxidation & the electron transport chain • Electron transport chain = sequential reduction-oxidation • Oxidative phosphorylation = oxidation of a metabolite by O2 through electron transport + phosphorylation of ADP 2009 Cengage-Wadsworth Integrated Metabolism in Tissues – Anatomical site for oxidative phosphorylation – Components of the oxidative phosphorylation chain • Complex I NADH-coenzyme Q oxidoreductase • Complex II • Complex III coenzyme Q-cytochrome c oxidoreductase • Complex IV 2009 Cengage-Wadsworth Integrated Metabolism in Tissues – Phosphorylation of ADP to form ATP – Translocation of H+ – ATP synthase 2009 Cengage-Wadsworth Integrated Metabolism in Tissues • The hexosemonophosphate shunt (pentose phosphate pathway) – Pentose phosphates – Reduced cosubstrate NADPH • Gluconeogenesis – – – – Synthesis of glucose from non-CHO Reversal of glycolytic pathway Lactate utilization Efficient glycogenesis 2009 Cengage-Wadsworth Regulation of Metabolism • 4 mechanisms: – Negative or positive modulation of allosteric enzymes – Hormonal activation by covalent modification/induction – Directional shifts in reactions – Translocation of enzymes within cells 2009 Cengage-Wadsworth Regulation of Metabolism • Allosteric enzyme modulation – AMP, ADP, & ATP as allosteric modulators – AMP’s positive modulation • Causes shift from inactive to active form of phosphorylase b • Stimulates phosphofructokinase 2009 Cengage-Wadsworth Regulation of Metabolism • Regulatory effect of NADH:NAD+ ratio • Hormonal regulation – Glycolytic enzymes – Bifunctional enzymes – Gluconeogenic enzymes • Directional shifts in reversible reactions 2009 Cengage-Wadsworth Perspective 3 Hypoglycemia: Fact or Fall Guy? 2009 Cengage-Wadsworth Hypoglycemia • Preprandial vs. postprandial serum glucose levels • Types: – Fasting hypoglycemia • Usually caused by insulin, sulfonylureas – Fed (reactive) hypoglycemia • Impaired glucose tolerance, idiopathic postprandial syndrome 2009 Cengage-Wadsworth
