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Carbohydrate metabolism

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Dentist(Umar Ali )
Dentist(Umar Ali )

Biochemistry

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Carbohydrate Metabolism Digestion of Carbohydrate
I. Introduction: A. More than 60% of our foods are carbohydrates. Starch, glycogen, sucrose, lactose and cellulose are the chief carbohydrates in our food. Before intestinal absorption, they are hydrolysed to hexose sugars (glucose, galactose and fructose). B. A family of a glycosidases that degrade carbohydrate into their monohexose components catalyzes hydrolysis of glycocidic bonds. These enzymes are usually specific to the type of bond to be broken.
Digestion of carbohydrate by salivary α -amylase (ptylin) in the mouth: A. This enzyme is produced by salivary glands. Its optimum pH is 6.7. B. It is activated by chloride ions (cl-). C. It acts on cooked starch and glycogen breaking α 1-4 bonds, converting them into maltose [a disaccharide containing two glucose molecules attached by α 1-4 linkage]. This bond is not attacked by -amylase. Because both starch and glycogen also contain 1-6 bonds, the resulting digest contains isomaltose [a disaccharide in which two glucose molecules are attached by 1-6 linkage]. E. Because food remains for a short time in the mouth, digestion of starch and glycogen may be incomplete and gives a partial digestion products called: starch dextrins (amylodextrin, erythrodextrin and achrodextrin). F. Therefore, digestion of starch and glycogen in the mouth gives maltose, isomaltose and starch dextrins.
III. ln the stomach: carbohydrate digestion stops temporarily due to the high acidity which inactivates the salivary - amylase. IV. Digestion of carbohydrate by the pancreatic - amylase small intestine in the small intestine. A. α-amylase enzyme is produced by pancreas and acts in small intestine. Its optimum pH is 7.1. B. It is also activated by chloride ions. C. It acts on cooked and uncooked starch, hydrolysing them into maltose and isomaltose. :Final carbohydrate digestion by intestinal enzymes A. The final digestive processes occur at the small intestine and include the action of several disaccharidases. These enzymes are secreted through and remain associated with the brush border of the intestinal mucosal cells.
B. The disaccharidases include: 1. Lactase (β-galactosidase) which hydrolyses lactose into two molecules of glucose and galactose: Lactase Lactose Glucose + Galactose 2. Maltase ( α-glucosidase), which hydrolyses maltose into two molecules of glucose: Maltase Maltose Glucose + Glucose 3. Sucrose (α-fructofuranosidase), which hydrolyses sucrose into two molecules of glucose and fructose: Sucrose Sucrose Glucose + Fructose 4. α - dextrinase (oligo-1,6 glucosidase) which hydrolyze (1 ,6) linkage of isomaltose. Dextrinase Isomaltose Glucose + Glucose
VI. Digestion of cellulose: A. Cellulose contains β(1-4) bonds between glucose molecules. B. In humans, there is no β (1-4) glucosidase that can digest such bonds. So cellulose passes as such in stool. C. Cellulose helps water retention during the passage of food along the intestine → producing larger and softer feces → preventing constipation.
Absorptions I. Introduction A.The end products of carbohydrate digestion are monosaccharides: glucose, galactose and fructose. They are absorbed from the jejunum to portal veins to the liver, where fructose and galactose are transformed into glucose. B.Two mechanisms are responsible for absorption of monosaccharides: active transport (against concentration gradient i.e. from low to high concentration) and passive transport (by facilitated diffusion). C. For active transport to take place, the structure of sugar should have: 1. Hexose ring. 2. OH group at position 2 at the right side. Both of which are present in glucose and galactose. Fructose, which does not contain -OH group to the right at position 2 is absorbed more slowly than glucose and galactose by passive diffusion (slow process). 3. A methyl or a substituted methyl group should be present at carbon 5.
II. Mechanisms of absorption: A. Active transport: 1. Mechanism of active transport: a) In the cell membrane of the intestinal cells, there is a mobile carrier protein called sodium dependant glucose transporter (SGL T-1) It transports glucose to inside the cell using energy. The energy is derived from sodium-potassium pump. The transporter has 2 separate sites, one for sodium and the other for glucose. It transports them from the intestinal lumen across cell membrane to the cytoplasm. Then both glucose and sodium are released into the cytoplasm allowing the carrier to return for more transport of glucose and sodium.
b) The sodium is transported from high to low concentration (with concentration gradient) and at the same time causes the carrier to transport glucose against its concentration gradient. The Na+ is expelled outside the cell by sodium pump. Which needs ATP as a source of energy. The reaction is catalyzed by an enzyme called "Adenosine triphosphatase (ATPase)". Active transport is much more faster than passive transport. c) Insulin increases the number of glucose transporters in tissues containing insulin receptors e.g. muscles and adipose tissue.
B. Transport Proteins Transport proteins = Integral membrane proteins that transport specific molecules or ions across biological membranes. Protein (Figure 8.9)
2. Inhibitors of active transport: a) Ouabin (cardiac glycoside): Inhibits adenosine triphosphatase (ATPase) necessary for hydrolysis of ATP that produces energy of sodium pump. b) Phlorhizin; Inhibits the binding of sodium in the carrier protein. B. Passive transport (facilitated diffusion): Sugars pass with concentration gradient i.e. from high to low concentration. It needs no energy. It occurs by means of a sodium independent facilitative transporter (GLUT -5). Fructose and pentoses are absorbed by this mechanism. Glucose and galactose can also use the same transporter if the concentration gradient is favorable. C. There is also sodium – independent transporter (GLUT-2), that is facilitates transport of sugars out of the cell i.e. to circulation.
Summary of types of functions of most important glucose transporters: Function Site SGLT- Absorption of glucose Intestine and renal 1 by active transport tubules. (energy is derived from Na+- K+ pump) GLUT - Fructose transport and Intestine and sperm 5 to a lesser extent glucose and galactose. GLUT - Transport glucose out -Intestine and renal 2 of intestinal and renal tubule cells → circulation -β cells of islets-liver
III. Defects of carbohydrate digestion and absorption: A. Lactase deficiency = lactose intolerance: 1. Definition: a) This is a deficiency of lactase enzyme which digest lactose into glucose and galactose b) It may be: (i) Congenital: which occurs very soon after birth (rare). (ii) Acquired: which occurs later on in life (common). 2. Effect: The presence of lactose in intestine causes: a) Increased osmotic pressure: So water will be drawn from the tissue (causing dehydration) into the large intestine (causing diarrhea). b) Increased fermentation of lactose by bacteria: Intestinal bacteria ferment lactose with subsequent production of CO2 gas. This causes distention and abdominal cramps. c) Treatment: Treatment of this disorder is simply by removing lactose (milk) from diet.
B. Sucrose deficiency: A rare condition, showing the signs and symptoms of lactase deficiency. It occurs early in childhood. C. Monosaccharide malabsorption: This is a congenital condition in which glucose and galactose are absorbed only slowly due to defect in the carrier mechanism. Because fructose is not absorbed by the carrier system, its absorption is normal. IV. Fate of absorbed sugars: Monosaccharides (glucose, galactose and fructose) resulting from carbohydrate digestion are absorbed and undergo the following: A. Uptake by tissues (liver): After absorption the liver takes up sugars, where galactose and fructose are converted into glucose. B. Glucose utilization by tissues: Glucose may undergo one of the following fate:
1. Oxidation: through a) Major pathways (glycolysis and Krebs' cycle) for production of energy. b) Hexose monophosphate pathway: for production of ribose, deoxyribose and NADPH + H+ c) Uronic acid pathway, for production of glucuronic acid, which is used in detoxication and enters in the formation of mucopolysaccharide. 2. Storage: in the form of: a) Glycogen: glycogenesis. b) Fat: lipogenesis. 3. Conversion: to substances of biological importance: a) Ribose, deoxyribose → RNA and DNA. b) Lactose → milk. c) Glucosamine, galactosamine → mucopolysaccharides. d) Glucoronic acid → mucopolysaccharides. e) Fructose → in semen.
Glucose Oxidation major Pathway
I. Glycolysis (Embden Meyerhof Pathway): A. Definition: 1. Glycolysis means oxidation of glucose to give pyruvate (in the presence of oxygen) or lactate (in the absence of oxygen). B. Site: cytoplasm of all tissue cells, but it is of physiological importance in: 1. Tissues with no mitochondria: mature RBCs, cornea and lens. 2. Tissues with few mitochondria: Testis, leucocytes, medulla of the kidney, retina, skin and gastrointestinal tract. 3. Tissues undergo frequent oxygen lack: skeletal muscles especially during exercise.
C. Steps: Stages of glycolysis 1. Stage one (the energy requiring stage): a) One molecule of glucose is converted into two molecules of glycerosldhyde-3-phosphate. b) These steps requires 2 molecules of ATP (energy loss) 2. Stage two (the energy producing stage(: a) The 2 molecules of glyceroaldehyde-3-phosphate are converted into pyruvate (aerobic glycolysis) or lactate (anaerobic glycolysis(. b) These steps produce ATP molecules (energy production). D. Energy (ATP) production of glycolysis: ATP production = ATP produced - ATP utilized
In the energy investment phase, ATP provides • .activation energy by phosphorylating glucose .This requires 2 ATP per glucose – In the energy payoff • phase, ATP is produced by substrate-level phosphorylation and NAD+ is .reduced to NADH ATP (net) and 2 • 2 NADH are produced .per glucose Fig. 9.8
Energy Investment Phase (steps 1- Fig. 9.9a )5
Fig. 9.9b Energy-Payoff Phase (Steps 6-
Energy production of glycolysis: ATP produced ATP utilized Net energy In absence of oxygen 4 ATP 2ATP 2 ATP (anaerobic glycolysis) (Substrate level From glucose to phosphorylation) glucose -6-p. 2ATP from 1,3 DPG. From fructose -6-p to 2ATP from fructose 1,6 p. phosphoenol pyruvate In presence of 4 ATP 2ATP 6 ATP oxygen (aerobic (substrate level -From glucose to Or glycolysis) phosphorylation) glucose -6-p. 8 ATP 2ATP from 1,3 BPG. From fructose -6-p to 2ATP from fructose 1,6 p. phosphoenol pyruvate. + 4ATP or 6ATP (from oxidation of 2 NADH + H in mitochondria).
E. oxidation of extramitochondrial NADH+H+: 1. cytoplasmic NADH+H+ cannot penetrate mitochondrial membrane, however, it can be used to produce energy (4 or 6 ATP) by respiratory chain phosphorylation in the mitochondria. 2. This can be done by using special carriers for hydrogen of NADH+H+ These carriers are either dihydroxyacetone phosphate (Glycerophosphate shuttle) or oxaloacetate (aspartate malate shuttle). a) Glycerophosphate shuttle: 1) It is important in certain muscle and nerve cells. 2) The final energy produced is 4 ATP. 3) Mechanism: - The coenzyme of cytoplasmic glycerol-3- phosphate dehydrogenase is NAD+. - The coenzyme of mitochodrial glycerol-3-phosphate dehydogenase is FAD. - Oxidation of FADH, in respiratory chain gives 2 ATP. As glycolysis gives 2 cytoplasmic NADH + H+ → 2 mitochondrial FADH, 2 x 2 ATP → = 4 ATP. b) Malate – aspartate shuttle: 1) It is important in other tissues patriculary liver and heart.
Differences between aerobic and anaerobic glycolysis: Aerobic Anaerobic 1. End product Pyruvate Lactate 2 .energy 6 or 8 ATP 2 ATP 3. Regeneration of Through respiration Through Lactate NAD+ chain in mitochondria formation 4. Availability to TCA Available and 2 Not available as lactate in mitochondria Pyruvate can oxidize to is cytoplasmic substrate give 30 ATP
Substrate level phosphorylation: This means phosphorylation of ADP to ATP at the reaction itself .in glycolysis there are 2 examples: - 1.3 Bisphosphoglycerate + ADP 3 Phosphoglycerate + ATP - Phospho-enol pyruvate + ADP Enolpyruvate + ATP I. Special features of glycolysis in RBCs: 1. Mature RBCs contain no mitochondria, thus: a) They depend only upon glycolysis for energy production (=2 ATP). b) Lactate is always the end product. 2. Glucose uptake by RBCs is independent on insulin hormone. 3. Reduction of met-hemoglobin: Glycolysis produces NADH+H+, which used for reduction of met-hemoglobin in red cells.
Biological importance (functions) of glycolysis: 1. Energy production: a) anaerobic glycolysis gives 2 ATP. b) aerobic glycolysis gives 8 ATP. 2. Oxygenation of tissues: Through formation of 2,3 bisphosphoglycerate, which decreases the affinity of Hemoglobin to O2. 3. Provides important intermediates: a) Dihydroxyacetone phosphate: can give glycerol-3phosphate, which is used for synthesis of triacylglycerols and phospholipids (lipogenesis). b) 3 Phosphoglycerate: which can be used for synthesis of amino acid serine. c) Pyruvate: which can be used in synthesis of amino acid alanine. 4. Aerobic glycolysis provides the mitochondria with pyruvate, which gives acetyl CoA Krebs' cycle.
Reversibility of glycolysis (Gluconeogenesis): 1. Reversible reaction means that the same enzyme can catalyzes the reaction in both directions. 2. all reactions of glycolysis -except 3- are reversible. 3. The 3 irreversible reactions (those catalyzed by kinase enzymes) can be reversed by using other enzymes. Glucose-6-p → Glucose F1, 6 Bisphosphate → Fructose-6-p Pyruvate → Phosphoenol pyruvate 4. During fasting, glycolysis is reversed for synthesis of glucose from non- carbohydrate sources e.g. lactate. This mechanism is called: gluconeogenesis.
Comparison between glucokinase and hexokinase enzymes: Glucokinaase Hexokinase 1. Site Liver only All tissue cells 2. Affinity to glucose Low affinity (high km) i.e. it High affinity (low km) i.e. it acts acts only in the presence of even in the presence of low blood high blood glucose glucose concentration. concentration. 3. Substrate Glucose only Glucose, galactose and fructose 4. Effect of insulin Induces synthesis of No effect glucokinase. 5. Effect of glucose-6-p No effect Allosterically inhibits hexokinase 6. Function Acts in liver after meals. It It phosphorylates glucose inside removes glucose coming in the body cells. This makes glucose portal circulation, converting concentration more in blood than it into glucose -6-phosphate. inside the cells. This leads to continuous supply of glucose for the tissues even in the presence of low blood glucose concentration.
Importance of lactate production in anerobic glycolysis: 1. In absence of oxygen, lactate is the end product of glycolysis: Glucose → Pyruvate → Lactate 2. In absence of oxygen, NADH + H+ is not oxidized by the respiratory chain. 3. The conversion of pyruvate to lactate is the mechanism for regeneration of NAD+. 4. This helps continuity of glycolysis, as the generated NAD+ will be used once more for oxidation of another glucose molecule.
As pyruvate enters the mitochondrion, a • multienzyme complex modifies pyruvate to acetyl CoA which enters the Krebs cycle in the .matrix .A carboxyl group is removed as CO2 – A pair of electrons is transferred from the – remaining two-carbon fragment to NAD+ to .form NADH The oxidized – fragment, acetate, combines with coenzyme A to .form acetyl CoA Fig. 9.10

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Carbohydrate metabolism

  • 2. I. Introduction: A. More than 60% of our foods are carbohydrates. Starch, glycogen, sucrose, lactose and cellulose are the chief carbohydrates in our food. Before intestinal absorption, they are hydrolysed to hexose sugars (glucose, galactose and fructose). B. A family of a glycosidases that degrade carbohydrate into their monohexose components catalyzes hydrolysis of glycocidic bonds. These enzymes are usually specific to the type of bond to be broken.
  • 3. Digestion of carbohydrate by salivary α -amylase (ptylin) in the mouth: A. This enzyme is produced by salivary glands. Its optimum pH is 6.7. B. It is activated by chloride ions (cl-). C. It acts on cooked starch and glycogen breaking α 1-4 bonds, converting them into maltose [a disaccharide containing two glucose molecules attached by α 1-4 linkage]. This bond is not attacked by -amylase. Because both starch and glycogen also contain 1-6 bonds, the resulting digest contains isomaltose [a disaccharide in which two glucose molecules are attached by 1-6 linkage]. E. Because food remains for a short time in the mouth, digestion of starch and glycogen may be incomplete and gives a partial digestion products called: starch dextrins (amylodextrin, erythrodextrin and achrodextrin). F. Therefore, digestion of starch and glycogen in the mouth gives maltose, isomaltose and starch dextrins.
  • 4. III. ln the stomach: carbohydrate digestion stops temporarily due to the high acidity which inactivates the salivary - amylase. IV. Digestion of carbohydrate by the pancreatic - amylase small intestine in the small intestine. A. α-amylase enzyme is produced by pancreas and acts in small intestine. Its optimum pH is 7.1. B. It is also activated by chloride ions. C. It acts on cooked and uncooked starch, hydrolysing them into maltose and isomaltose. :Final carbohydrate digestion by intestinal enzymes A. The final digestive processes occur at the small intestine and include the action of several disaccharidases. These enzymes are secreted through and remain associated with the brush border of the intestinal mucosal cells.
  • 5. B. The disaccharidases include: 1. Lactase (β-galactosidase) which hydrolyses lactose into two molecules of glucose and galactose: Lactase Lactose Glucose + Galactose 2. Maltase ( α-glucosidase), which hydrolyses maltose into two molecules of glucose: Maltase Maltose Glucose + Glucose 3. Sucrose (α-fructofuranosidase), which hydrolyses sucrose into two molecules of glucose and fructose: Sucrose Sucrose Glucose + Fructose 4. α - dextrinase (oligo-1,6 glucosidase) which hydrolyze (1 ,6) linkage of isomaltose. Dextrinase Isomaltose Glucose + Glucose
  • 6. VI. Digestion of cellulose: A. Cellulose contains β(1-4) bonds between glucose molecules. B. In humans, there is no β (1-4) glucosidase that can digest such bonds. So cellulose passes as such in stool. C. Cellulose helps water retention during the passage of food along the intestine → producing larger and softer feces → preventing constipation.
  • 7. Absorptions I. Introduction A.The end products of carbohydrate digestion are monosaccharides: glucose, galactose and fructose. They are absorbed from the jejunum to portal veins to the liver, where fructose and galactose are transformed into glucose. B.Two mechanisms are responsible for absorption of monosaccharides: active transport (against concentration gradient i.e. from low to high concentration) and passive transport (by facilitated diffusion). C. For active transport to take place, the structure of sugar should have: 1. Hexose ring. 2. OH group at position 2 at the right side. Both of which are present in glucose and galactose. Fructose, which does not contain -OH group to the right at position 2 is absorbed more slowly than glucose and galactose by passive diffusion (slow process). 3. A methyl or a substituted methyl group should be present at carbon 5.
  • 8. II. Mechanisms of absorption: A. Active transport: 1. Mechanism of active transport: a) In the cell membrane of the intestinal cells, there is a mobile carrier protein called sodium dependant glucose transporter (SGL T-1) It transports glucose to inside the cell using energy. The energy is derived from sodium-potassium pump. The transporter has 2 separate sites, one for sodium and the other for glucose. It transports them from the intestinal lumen across cell membrane to the cytoplasm. Then both glucose and sodium are released into the cytoplasm allowing the carrier to return for more transport of glucose and sodium.
  • 9. b) The sodium is transported from high to low concentration (with concentration gradient) and at the same time causes the carrier to transport glucose against its concentration gradient. The Na+ is expelled outside the cell by sodium pump. Which needs ATP as a source of energy. The reaction is catalyzed by an enzyme called "Adenosine triphosphatase (ATPase)". Active transport is much more faster than passive transport. c) Insulin increases the number of glucose transporters in tissues containing insulin receptors e.g. muscles and adipose tissue.
  • 10. B. Transport Proteins Transport proteins = Integral membrane proteins that transport specific molecules or ions across biological membranes. Protein (Figure 8.9)
  • 11. 2. Inhibitors of active transport: a) Ouabin (cardiac glycoside): Inhibits adenosine triphosphatase (ATPase) necessary for hydrolysis of ATP that produces energy of sodium pump. b) Phlorhizin; Inhibits the binding of sodium in the carrier protein. B. Passive transport (facilitated diffusion): Sugars pass with concentration gradient i.e. from high to low concentration. It needs no energy. It occurs by means of a sodium independent facilitative transporter (GLUT -5). Fructose and pentoses are absorbed by this mechanism. Glucose and galactose can also use the same transporter if the concentration gradient is favorable. C. There is also sodium – independent transporter (GLUT-2), that is facilitates transport of sugars out of the cell i.e. to circulation.
  • 12. Summary of types of functions of most important glucose transporters: Function Site SGLT- Absorption of glucose Intestine and renal 1 by active transport tubules. (energy is derived from Na+- K+ pump) GLUT - Fructose transport and Intestine and sperm 5 to a lesser extent glucose and galactose. GLUT - Transport glucose out -Intestine and renal 2 of intestinal and renal tubule cells → circulation -β cells of islets-liver
  • 13. III. Defects of carbohydrate digestion and absorption: A. Lactase deficiency = lactose intolerance: 1. Definition: a) This is a deficiency of lactase enzyme which digest lactose into glucose and galactose b) It may be: (i) Congenital: which occurs very soon after birth (rare). (ii) Acquired: which occurs later on in life (common). 2. Effect: The presence of lactose in intestine causes: a) Increased osmotic pressure: So water will be drawn from the tissue (causing dehydration) into the large intestine (causing diarrhea). b) Increased fermentation of lactose by bacteria: Intestinal bacteria ferment lactose with subsequent production of CO2 gas. This causes distention and abdominal cramps. c) Treatment: Treatment of this disorder is simply by removing lactose (milk) from diet.
  • 14. B. Sucrose deficiency: A rare condition, showing the signs and symptoms of lactase deficiency. It occurs early in childhood. C. Monosaccharide malabsorption: This is a congenital condition in which glucose and galactose are absorbed only slowly due to defect in the carrier mechanism. Because fructose is not absorbed by the carrier system, its absorption is normal. IV. Fate of absorbed sugars: Monosaccharides (glucose, galactose and fructose) resulting from carbohydrate digestion are absorbed and undergo the following: A. Uptake by tissues (liver): After absorption the liver takes up sugars, where galactose and fructose are converted into glucose. B. Glucose utilization by tissues: Glucose may undergo one of the following fate:
  • 15. 1. Oxidation: through a) Major pathways (glycolysis and Krebs' cycle) for production of energy. b) Hexose monophosphate pathway: for production of ribose, deoxyribose and NADPH + H+ c) Uronic acid pathway, for production of glucuronic acid, which is used in detoxication and enters in the formation of mucopolysaccharide. 2. Storage: in the form of: a) Glycogen: glycogenesis. b) Fat: lipogenesis. 3. Conversion: to substances of biological importance: a) Ribose, deoxyribose → RNA and DNA. b) Lactose → milk. c) Glucosamine, galactosamine → mucopolysaccharides. d) Glucoronic acid → mucopolysaccharides. e) Fructose → in semen.
  • 17. I. Glycolysis (Embden Meyerhof Pathway): A. Definition: 1. Glycolysis means oxidation of glucose to give pyruvate (in the presence of oxygen) or lactate (in the absence of oxygen). B. Site: cytoplasm of all tissue cells, but it is of physiological importance in: 1. Tissues with no mitochondria: mature RBCs, cornea and lens. 2. Tissues with few mitochondria: Testis, leucocytes, medulla of the kidney, retina, skin and gastrointestinal tract. 3. Tissues undergo frequent oxygen lack: skeletal muscles especially during exercise.
  • 18. C. Steps: Stages of glycolysis 1. Stage one (the energy requiring stage): a) One molecule of glucose is converted into two molecules of glycerosldhyde-3-phosphate. b) These steps requires 2 molecules of ATP (energy loss) 2. Stage two (the energy producing stage(: a) The 2 molecules of glyceroaldehyde-3-phosphate are converted into pyruvate (aerobic glycolysis) or lactate (anaerobic glycolysis(. b) These steps produce ATP molecules (energy production). D. Energy (ATP) production of glycolysis: ATP production = ATP produced - ATP utilized
  • 19. In the energy investment phase, ATP provides • .activation energy by phosphorylating glucose .This requires 2 ATP per glucose – In the energy payoff • phase, ATP is produced by substrate-level phosphorylation and NAD+ is .reduced to NADH ATP (net) and 2 • 2 NADH are produced .per glucose Fig. 9.8
  • 20. Energy Investment Phase (steps 1- Fig. 9.9a )5
  • 21. Fig. 9.9b Energy-Payoff Phase (Steps 6-
  • 22. Energy production of glycolysis: ATP produced ATP utilized Net energy In absence of oxygen 4 ATP 2ATP 2 ATP (anaerobic glycolysis) (Substrate level From glucose to phosphorylation) glucose -6-p. 2ATP from 1,3 DPG. From fructose -6-p to 2ATP from fructose 1,6 p. phosphoenol pyruvate In presence of 4 ATP 2ATP 6 ATP oxygen (aerobic (substrate level -From glucose to Or glycolysis) phosphorylation) glucose -6-p. 8 ATP 2ATP from 1,3 BPG. From fructose -6-p to 2ATP from fructose 1,6 p. phosphoenol pyruvate. + 4ATP or 6ATP (from oxidation of 2 NADH + H in mitochondria).
  • 23. E. oxidation of extramitochondrial NADH+H+: 1. cytoplasmic NADH+H+ cannot penetrate mitochondrial membrane, however, it can be used to produce energy (4 or 6 ATP) by respiratory chain phosphorylation in the mitochondria. 2. This can be done by using special carriers for hydrogen of NADH+H+ These carriers are either dihydroxyacetone phosphate (Glycerophosphate shuttle) or oxaloacetate (aspartate malate shuttle). a) Glycerophosphate shuttle: 1) It is important in certain muscle and nerve cells. 2) The final energy produced is 4 ATP. 3) Mechanism: - The coenzyme of cytoplasmic glycerol-3- phosphate dehydrogenase is NAD+. - The coenzyme of mitochodrial glycerol-3-phosphate dehydogenase is FAD. - Oxidation of FADH, in respiratory chain gives 2 ATP. As glycolysis gives 2 cytoplasmic NADH + H+ → 2 mitochondrial FADH, 2 x 2 ATP → = 4 ATP. b) Malate – aspartate shuttle: 1) It is important in other tissues patriculary liver and heart.
  • 24. Differences between aerobic and anaerobic glycolysis: Aerobic Anaerobic 1. End product Pyruvate Lactate 2 .energy 6 or 8 ATP 2 ATP 3. Regeneration of Through respiration Through Lactate NAD+ chain in mitochondria formation 4. Availability to TCA Available and 2 Not available as lactate in mitochondria Pyruvate can oxidize to is cytoplasmic substrate give 30 ATP
  • 25. Substrate level phosphorylation: This means phosphorylation of ADP to ATP at the reaction itself .in glycolysis there are 2 examples: - 1.3 Bisphosphoglycerate + ADP 3 Phosphoglycerate + ATP - Phospho-enol pyruvate + ADP Enolpyruvate + ATP I. Special features of glycolysis in RBCs: 1. Mature RBCs contain no mitochondria, thus: a) They depend only upon glycolysis for energy production (=2 ATP). b) Lactate is always the end product. 2. Glucose uptake by RBCs is independent on insulin hormone. 3. Reduction of met-hemoglobin: Glycolysis produces NADH+H+, which used for reduction of met-hemoglobin in red cells.
  • 26. Biological importance (functions) of glycolysis: 1. Energy production: a) anaerobic glycolysis gives 2 ATP. b) aerobic glycolysis gives 8 ATP. 2. Oxygenation of tissues: Through formation of 2,3 bisphosphoglycerate, which decreases the affinity of Hemoglobin to O2. 3. Provides important intermediates: a) Dihydroxyacetone phosphate: can give glycerol-3phosphate, which is used for synthesis of triacylglycerols and phospholipids (lipogenesis). b) 3 Phosphoglycerate: which can be used for synthesis of amino acid serine. c) Pyruvate: which can be used in synthesis of amino acid alanine. 4. Aerobic glycolysis provides the mitochondria with pyruvate, which gives acetyl CoA Krebs' cycle.
  • 27. Reversibility of glycolysis (Gluconeogenesis): 1. Reversible reaction means that the same enzyme can catalyzes the reaction in both directions. 2. all reactions of glycolysis -except 3- are reversible. 3. The 3 irreversible reactions (those catalyzed by kinase enzymes) can be reversed by using other enzymes. Glucose-6-p → Glucose F1, 6 Bisphosphate → Fructose-6-p Pyruvate → Phosphoenol pyruvate 4. During fasting, glycolysis is reversed for synthesis of glucose from non- carbohydrate sources e.g. lactate. This mechanism is called: gluconeogenesis.
  • 28. Comparison between glucokinase and hexokinase enzymes: Glucokinaase Hexokinase 1. Site Liver only All tissue cells 2. Affinity to glucose Low affinity (high km) i.e. it High affinity (low km) i.e. it acts acts only in the presence of even in the presence of low blood high blood glucose glucose concentration. concentration. 3. Substrate Glucose only Glucose, galactose and fructose 4. Effect of insulin Induces synthesis of No effect glucokinase. 5. Effect of glucose-6-p No effect Allosterically inhibits hexokinase 6. Function Acts in liver after meals. It It phosphorylates glucose inside removes glucose coming in the body cells. This makes glucose portal circulation, converting concentration more in blood than it into glucose -6-phosphate. inside the cells. This leads to continuous supply of glucose for the tissues even in the presence of low blood glucose concentration.
  • 29. Importance of lactate production in anerobic glycolysis: 1. In absence of oxygen, lactate is the end product of glycolysis: Glucose → Pyruvate → Lactate 2. In absence of oxygen, NADH + H+ is not oxidized by the respiratory chain. 3. The conversion of pyruvate to lactate is the mechanism for regeneration of NAD+. 4. This helps continuity of glycolysis, as the generated NAD+ will be used once more for oxidation of another glucose molecule.
  • 30. As pyruvate enters the mitochondrion, a • multienzyme complex modifies pyruvate to acetyl CoA which enters the Krebs cycle in the .matrix .A carboxyl group is removed as CO2 – A pair of electrons is transferred from the – remaining two-carbon fragment to NAD+ to .form NADH The oxidized – fragment, acetate, combines with coenzyme A to .form acetyl CoA Fig. 9.10