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Transcript
Copyright COMMONWEALTH OF AUSTRALIA Copyright Regulation WARNING This material has been reproduced and communicated to you by or on behalf of the University of Sydney pursuant to Part VB of the Copyright Act 1968 (the Act). The material in this communication may be subject to copyright under the Act. Any further reproduction or communication of this material by you may be the subject of copyright protection under the Act. Do not remove this notice Fatty acid oxidation • Also called beta-oxidation – Because the action occurs on the beta-carbon atom Fatty acid oxidation • Requires tissues to have mitochondria • Reciprocally regulated with glucose oxidation – Fatty acid oxidation inhibits glucose oxidation • Consumes a lot of FAD, NAD, CoA – Availability of cofactors is important Transport of FA Fatty acid binding protein Albumin Transport of FA • FA needs to be transported from blood into tissues • FA is carried in blood on albumin – Several binding sites for FA • There are specific transporters for FA – CD36 moves to the cell surface whenever there is a need to take up FA at a rapid rate • FA is carried on FABP (fatty acid binding protein) in cytoplasm Trapping of FA • FA is trapped by attaching it to CoA • This also ‘activates’ the fatty acid (‘tags’ the FA) • Requires quite a lot of energy, – ATP is not converted into ADP, but AMP Transport of FA: Mitochondria FA-CoA is oxidized Example: 16C FA-CoA • 7 NADH & 7 FADH2 are produced…. NAD & FAD needed • 8 acetyl CoA produced…. CoA needed Cofactor Availability • NAD, FAD and CoA – All needed to keep FA oxidation going • How are these carriers regenerated? – CoA • By entry of acetyl CoA into Krebs Cycle – NAD/FAD • By giving cargo to electron transport chain Rate Limiting Enzymes • The slowest enzyme in the metabolic pathway determines the overall speed – Rate-limiting step (RLS) – Flux generating step • Key points of regulation Enzyme kinetics • Vmax • Rate ½ Vmax Km S1 [substrate] S2 At high [substrate], minor changes in [substrate] will not affect the rate of reaction Doubling or halving the [S] isn’t even going to affect the rate Redfern Station Analogy • Imagine the station at peak hour with just one barrier operating – This gate will soon become ‘saturated’ with people – Increasing the number of people doesn’t increase the rate – It is the ‘rate limiting’ step – The point which determines the overall rate at which people get to Uni Changing the Flux • There are 3 major ways to regulate this (and metabolic!) pathways – Change the intrinsic activity of the step • Make ticket-reading & gate-opening happen faster – Make more gates open • • • Switch them from being ‘off’ to ‘on’ Or change the direction from ‘in’ to out Or bring in a set of gates when you need them – Make and destroy gates according to need • Seems crazy! Properties of RLS • Irreversible – Need alternative enzymes to ‘go back’ – Not ‘equilibrium’ under physiological conditions – “Committed steps” • Saturated with substrate – Low Km or [S] >> Km – Working at Vmax RLS in FA ox? • • • • Availability of fatty acids? Cell membrane transport & Trapping? Mitochondrial transport? Carnitine Oxidation? – Activity of enzymes • Co-factor availability? • Does it depend on the circumstances? Glycolysis • • • • • • Uses carbohydrate (glucose) Wholly cytosolic All cells of the body No requirement for oxygen Very, very fast Very inefficient Glucose Glucose Uptake P hexokinase glucose blood glucose Using ATP glucose 6-phosphate cytoplasm Uptake facilitated by Glucose transporters (GLUTs) •GLUT-1 present in all cells all the time •GLUT-4 muscle and adipose tissue (the insulin sensitive tissues) •GLUT-2 liver and pancreas (blood glucose regulating tissues) Early Glycolysis Investment of energy giving a biphosphorylated symmetrical sugar P P Phosphofructokinase glucose 6-phosphate PFK fructose 6-phosphate P P Using ATP fructose 1,6-bisphosphate Splitting to give two 3-carbon molecules P P Two molecules of 3-carbon sugar phosphates Return Phase Remember two 3-carbon molecules go down the pathway P Bring in phosphate Oxidize with NAD P P Super energy molecule! Recoup some ATP P Recoup some ATP pyruvate Overview • Total yield is 2 ATP per glucose – And two pyruvate – And two NADH • Need to regenerate NAD • Fate of the pyruvate – Aerobic – Anaerobic Completing Glycolysis • More ATP from oxidation of pyruvate – Need to transport into mitochondria – Oxidize with pyruvate dehydrogenase • Need to reoxidise NADH – To maintain the supply of NAD – Shuttle systems available • To send NADH electrons/hydrogens into matrix – Lactate production – In yeast, alcohol production – Latter two keep everything cytosolic Regulation • Most points reversible • Focus on three steps – Hexokinase (G G6P) • Mainly feedback inhibition from G6P – Phosphofructokinase (F6P F6BP) • Strongly affected by ATP/ADP levels • But mainly via AMP levels – Pyruvate kinase (last step) • ATP/ADP important Energy Charge • Large changes in ATP not desirable – Keep ATP at 5 mM • Adenylate kinase – Translates small change in ATP to large relative change in AMP – 2ADP ATP + AMP • Ratio of adenine nucleotide concentrations often called ‘energy charge’ • Strong stimulation of PFK Energy Charge Integration of Catabolism FA BETA-OXIDATION “CARNITINE” FA-CoA CD36 ac-CoA ac-CoA ac-CoA FA-CoA ac-CoA ac-CoA PDH pyruvate GLUT-4 glucose citrate GLYCOLYSIS G6P OAA pyruvate KREBS CYCLE PHOSPHORYLASE CO2 glycogen CO2 IC ICDH 2OG OGDH Krebs Cycle • TCA cycle, Citric Acid cycle • Substrate is acetyl CoA – Fatty acid oxidation and/or glucose oxidation • Overall strategy – – – – Completely oxidize acetate carbons to CO2 Produce lots of NADH, FADH2, even an ATP Perform the reaction on a carrier molecule Regenerate the carrier Regulation • Krebs cycle activity is controlled early on – At isocitrate dehydrogenase (ICDH) – alpha-ketoglutarate dehydrogenase (OGDH) • ICDH and OGDH are stimulated by rise in Ca2+ – Such as is found during exercise • ICDH & OGDH are also sensitive to NAD levels – Activity is dependent on availability of NAD Important Features • During the cycle – 2 carbon atoms come in, 2 carbon atoms released • Generates – 3 NADH, 1 reduced FAD plus a GTP – Each NADH gives 2.5 ATP in oxidative phosphorylation – Each FADH2 gives 1.5… – So with the GTP, that’s about 10 ATP per acetate • Oxaloacetate is not ‘net’ consumed in the cycle – acts as carrier
