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Overview of Carbohydrate Digestion and Metabolism

Overview of Carbohydrate Digestion and Metabolism. Carbohydrates. Carbohydrates are called carbohydrates because they are essentially hydrates of carbon (i.e. they are composed of carbon and water and have a composition of (CH 2 O) n.

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Overview of Carbohydrate Digestion and Metabolism

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  1. Overview of Carbohydrate Digestion and Metabolism

  2. Carbohydrates • Carbohydrates are called carbohydrates because they are essentially hydrates of carbon (i.e. they are composed of carbon and water and have a composition of (CH2O)n. • The major nutritional role of carbohydrates is to provide energy and digestible carbohydrates provide 4 kilocalories per gram. No single carbohydrate is essential, but carbohydrates do participate in many required functions in the body.

  3. Photosynthesis: Sun’s energy becomes part of glucose molecule energy Carbon dioxide Water Chlorophyll GLUCOSE 6 CO2 + 6 H20 + energy (sun) C6H12O6 + 6 O2

  4. 120 grams of glucose / day = 480 calories

  5. Simple Sugars -

  6. Disaccharides

  7. Complex carbohydrates • Oligosaccharides • Polysaccharides • Starch • Glycogen • Dietary fiber (Dr. Firkins)

  8. Starch • Major storage carbohydrate in higher plants • Amylose – long straight glucose chains (a1-4) • Amylopectin – branched every 24-30 glc residues (a 1-6) • Provides 80% of dietary calories in humans worldwide

  9. G G G G G G G G G G G G G G G G G G G Glycogen • Major storage carbohydrate in animals • Long straight glucose chains (a1-4) • Branched every 4-8 glc residues (a 1-6) • More branched than starch • Less osmotic pressure • Easily mobilized α 1-6 link α 1-4 link

  10. G G G G G G G G G G G G G G G G G G G G G G G G G G G G G G G G G G Digestion • Pre-stomach – Salivary amylase : α 1-4 endoglycosidase α Limit dextrins amylase α 1-6 link maltotriose α 1-4 link maltose isomaltose

  11. Stomach • Not much carbohydrate digestion • Acid and pepsin to unfold proteins • Ruminants have forestomachs with extensive microbial populations to breakdown and anaerobically ferment feed

  12. G G G G G G G G G G G G G G G G G G G G G G G G G G G Small Intestine • Pancreatic enzymes α-amylase maltotriose maltose + α amylase amylose amylopectin α Limit dextrins

  13. G G G G G G G G G G G G G G G G G G G G G G G G G Oligosaccharide digestion..cont α Limit dextrins sucrase maltase Glucoamylase (maltase) or α-dextrinase α-dextrinase

  14. Small intestine Portal for transport of virtually all nutrients Water and electrolyte balance • Enzymes associated with • intestinal surface membranes • Sucrase • α dextrinase • Glucoamylase (maltase) • Lactase • peptidases

  15. Carbohydrate absorption Hexose transporter apical basolateral

  16. Glucose and galactose absorption • Read Chapter 5 and answer the questions on page 102 of Stipanuk. Be prepared to discuss them on Friday

  17. Carbohydrate malabsorption • Lactose intolerance (hypolactasia), page 100. • Decline lactase with age • Lactose fermented in LI – • Gas and volatile FA • Water retention – diarrhea/bloating • Not all populations • Northern European – low incidence • Asian/African Americans – High β 1-4 linkage

  18. Metabolism – the chemical changes that take place in a cell that produce energy and basic materials needed for important life processes • millions of cells • Multiple organs (liver, adipose, heart, brain) • Thousands of enzymes • Various conditions (fed, fasted, exercise, stress)

  19. Carbohydrates Glucose • Serve as primary source of energy in the cell • Central to all metabolic processes Cytosol - anaerobic Hexokinase Pentose Phosphate Shunt Glc-1- phosphate Glucose-6-P glycolysis glycogen Pyruvate

  20. cytosol Pyruvate mitochondria (aerobic) Aceytl CoA FATTY ACIDS Krebs cycle Reducing equivalents AMINO ACIDS Oxidative Phosphorylation (ATP)

  21. Glucose Glucose Glucose No mitochondria Glucose Glycogen Lactate The Full Monty

  22. Fasted State Glucose Need 13.8 kJ/mol ATP = -30 kJ/mol -16.7 kJ/mol G-6-Pase Hexokinase Pentose Phosphate Shunt Glc-1- phosphate Glucose-6-P glycolysis GNG glycogen Pyruvate

  23. Controlling Metabolic Flux 1. Control enzyme levels 2. Control of enzyme activity (activation or inhibition)

  24. Control of enzyme activity Rate limiting step

  25. insulin IR P Protein Kinase B (active) Protein Kinase B (inactive) OH P Glycogen synthase kinase (active) OH P Glycogen synthase kinase (inactive) P OH Glycogen synthase (inactive) Glycogen synthase (active) Glycogen formation

  26. Controlling Metabolic Flux 1. Control enzyme levels 2. Control of enzyme activity (activation or inhibition) 3. Compartamentalization Fatty acid oxidation occurs in mitochondrial matrix Fatty acid synthesis occurs in endoplasmic reticulum membrane exposed to the cytoplasm of the cell. 4. Hormonal control

  27. Glucose utilization

  28. Stage 1 – postparandial All tissues utilize glucose Stage 2 – postabsorptive KEY – Maintain blood glucose Glycogenolysis Glucogneogenesis Lactate Pyruvate Glycerol AA Propionate Spare glucose by metabolizing fat Stage 3- Early starvation Gluconeogenesis Stave 4 – Intermediate starvation gluconeogenesis Ketone bodies Stage 5 – Starvation

  29. Carbohydrate Metabolism/ Utilization- Tissue Specificity • Muscle – cardiac and skeletal • Oxidize glucose/produce and store glycogen (fed) • Breakdown glycogen (fasted state) • Shift to other fuels in fasting state (fatty acids) • Adipose and liver • Glucose à acetyl CoA • Glucose to glycerol for triglyceride synthesis • Liver releases glucose for other tissues • Nervous system • Always use glucose except during extreme fasts • Reproductive tract/mammary • Glucose required by fetus • Lactose à major milk carbohydrate • Red blood cells • No mitochondria • Oxidize glucose to lactate • Lactate returned to liver for Gluconeogenesis

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