Section 6: Carbohydrate Metabolism 3. Anaerobic & aerobic glycolysis 10/21/2005
Complete oxidation of glucose stoichiometry: glc + 6 O 2 6 CO H 2 O G' º = – 686 kcal/mol ATP yield theoretical: >90theoretical: >90 actual: 30-32actual: first stage: glycolysis (10-11 steps) location: cytosol of all cells (including microorganisms)location: cytosol of all cells (including microorganisms) 2 parts2 parts glc 2 glyceraldehyde 3-P (GAP)(steps 1-5) 2 GAP 2 pyruvate/lactate(steps 6 -10/11) (686/7.3) 1
Glycolysis 3.phosphoryl transfer phosphofructokinase irreversible committed step 2.isomerization phosphoglucose isomerase 1. glc 1. ( see L2sl9 “Phosphorylation of glc”) ATP ( see L2sl9 “Phosphorylation of glc”) ADP 2
4. aldol cleavage aldolase H 3
5. isomerization triose phosphate isomerase 6. oxidation-driven phosphorylation GAP DHase 7. phosphoryl transfer phosphoglycerate kinase 4
8. phosphoryl shift phosphoglycerate mutase 9. dehydration enolase 10. phosphoryl transfer irreversible pyruvate kinase 5
Regeneration of NAD + : 1. electron shuttles stoichiometry of steps 1-10: glc + 2 NAD + → 2 pyruvate + 2 NADH + 4 H + NAD present in cells in only catalytic amounts, so regeneration of NAD + is necessary cytosolic NADH cannot enter mitochondria solution: e – pair carried to mitochondrial e – transport chain via a shuttle (short linking pathway) net reaction: NADH cyt + oxid e – carrier mito → NAD + cyt + red. e – carrier mito 2 e – cyt → 2 e – mito malate-aspartate shuttle main shuttle in heart & liver cellsmain shuttle in heart & liver cells e – pair eventually transferred to mitochondrial matrix NAD +, so ATP yield is 2.5/ e – paire – pair eventually transferred to mitochondrial matrix NAD +, so ATP yield is 2.5/ e – pair 6
GOP-DHAP shuttle main shuttle in brain & skeletal muscle net reaction NADH cyt + H + + E-FAD ↓ NAD + cyt + E-FADH 2 yields 1.5 ATP per e – pair Fig ‚ 7 e – s from complex II, others
Regeneration of NAD + : 2. reduction of pyruvate conditions limiting electron shuttles: mitochondria scarce (“fast” muscle) or absent (RBC)mitochondria scarce (“fast” muscle) or absent (RBC) limited O 2 supply (ischemia)limited O 2 supply (ischemia) high demand for ATP causes glycolysis rate > shuttle ratehigh demand for ATP causes glycolysis rate > shuttle rate e – pair is transferred to pyruvate: as a result, glycolysis can occur without net oxidation: anaerobically fermentation: any anaerobic process 11. oxidation- reduction 8
Glycolysis stoichiometries Aerobic glycolysis: ATP yield steps 1-10 glc + 2 NAD + → 2 pyruvate + 2 NADH + 4H + 2 Regen. of NAD + : GOP shuttle + ox phos 2 H NADH + O 2 → 2 NAD H 2 O 3* glc + O 2 → 2 pyruvate + 2 H H 2 O 5 Anaerobic glycolysis: steps 1-10 glc + 2 NAD + → 2 pyruvate + 2 NADH + 4 H + 2 step 11 2 pyruvate +2 NADH + 2H + → 2 lactate +2 NAD + (steps 1-11) glc → 2 lactate + 2 H + 2 * 5 if malate-aspartate shuttle used 9
Effect of glycolysis products (pyruvate/lactate): acidification stoichiometry of both aerobic & anaerobic glycolysis shows production of 2 H + / glc unlike phosphate-containing metabolites, lactate & pyruvate permeant to most cell membranes (as protonated forms: lactic acid & pyruvic acid) microorganisms:microorganisms: their environment becomes acidic e.g., plaque bacteria on enamel surface ferment carbs low pH increases solubility of Ca phosphate minerals repeated acid attacks produce carious lesion skeletal muscle during exercise: [lactate], [pyruvate] & [H + ] riseskeletal muscle during exercise: [lactate], [pyruvate] & [H + ] rise 10
Fate of pyruvate/lactate pyruvate has a number of alternative fates e.g., oxidized further in mitochondria (next lecture)e.g., oxidized further in mitochondria (next lecture) diffusion out of cell (efflux)diffusion out of cell (efflux) lactate has only 1 metabolic fate: oxidation back to pyruvate if oxidation limited, efflux occursif oxidation limited, efflux occurs blood distributes these liver converts them back to glc by gluconeogenesis (next lecture) combination of muscle glycolysis & liver gluconeogenesis: Cori cycle 11 LIVERMUSCLE glucose glucose 6 ATP 2 ATP out pyruvate blood pyruvate lactate lactate gluconeogenesisglycolysis Net effect is transfer of energy from liver to muscle The Cori cycle
stepenzymeinhibitoractivator stepenzymeinhibitoractivator 1 hexokinaseglc 6-P 1 hexokinaseglc 6-P 3phosphofructokinase ATP, AMP, citrate* ADP 3phosphofructokinase ATP, AMP, citrate* ADP mechanism of control: mechanism of control: both kinases have allosteric sites to which activators/inhibitors bind Control of glycolysis * provides coordination with Krebs (citric acid) cycle hexokinase has allosteric site for glc 6P See Lehninger et al. p
Next time: 4. Gluconeogenesis Pyruvate oxidation