1 / 69

Glycolysis

Glycolysis. Chapter 14. Definitions, Notes. Sequence of 10 rxns Converts glu  pyruvate Some ATP Divided – 5 “preparatory”, 5 “payoff” Glycolytic intermediates 6C – deriv’s of glu or fru 3C – deriv’s of dihydroxyacetone, glyceraldehye. All intermediates phosph’d as esters or anhydrides

tawana
Download Presentation

Glycolysis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Glycolysis Chapter 14

  2. Definitions, Notes • Sequence of 10 rxns • Converts glu  pyruvate • Some ATP • Divided – 5 “preparatory”, 5 “payoff” • Glycolytic intermediates • 6C – deriv’s of glu or fru • 3C – deriv’s of dihydroxyacetone, glyceraldehye

  3. All intermediates phosph’d as esters or anhydrides • Net neg charge • Raises free energy of reactants • Enz active sites specific for ADP/ATP/intermediate complexes w/ Mg+2

  4. 5 types of rxns • phosphoryl transfer • phosphoryl shift • isomerization • dehydration • aldol cleavage • In cell cytosol

  5. Overall • Glu + 2 NAD+ + 2 ADP + 2 Pi  2 Pyruvate + 2 NADH + 2 H+ + 2 ATP + 2 H2O • D G’o entire rxn = -85 kJ/mole • Pyruvate prod (if aerobic cond’s)  TCA  e- transport/ox’ve phosph’n  ATP gen’d • From glycolysis  ATP yields ~2800 kJ/mole • No O2 = anaerobic metab = diff pathway = diff energy

  6. Glycolysis Regulation • 3 Cell mech’s • 1. Reg’n enz catalytic activity • Allosteric control • Enz’s have sev subunits • Modulators bind @ binding site • Often regulatory subunit •  conform’l change @ regulatory subunit •  conform’l change @ catalytic subunit •  Stimulation or inhibition

  7. 1. Reg’n enz activity -- cont’d • (Reversible) covalent mod’n • Enz’s have other enz’s assoc’d • Assoc’d enz’s catalyze covalent binding (or removal) of funct’l grp to reg enz •  Stimulation or inhibition

  8. 2. Regulation of concent of enz’s in cell • Rates of enz synth, degrad’n impt • When incr’d substrate (chronic), •  Incr’d transcr’n genes coding •  Incr’d concent enz’s impt to pathway

  9. 3. Regulation of flux of substrates • Cell can allow more substrate into cell •  Incr’d activity of pathway •  Incr’d prod’n • Hormones impt

  10. Glu  Glu-6-PO4

  11. Hexokinase • Phosphoryl transfer from ATP • Type of transferase • Hydrol ATP  ADP + Pi • Other hexose substrates • Cofactor Mg+2 • Reversible? • Induced fit w/ glu binding (Chpt 6) • Isozymes in mammals

  12. Glu-6-PO4 Fru-6-PO4

  13. Phosphohexose Isomerase • Aldose  ketose • Mg+2 cofactor • Reversible • Mechanism through enediol intermediate

  14. His plays role in steps 1,4 B:=Glu

  15. Fru-6-PO4Fru-1,6-Bisphosphate

  16. Phosphofructokinase-1 (PFK-1) • Phosphoryl transfer w/ hydrol ATP • Mg+2 cofactor • Reversible? • Regulatory enz • Commits to glycolysis • Impt to regulation of pathway • Sev binding sites for modulators (Chpt 15)

  17. PFK-1 Modulators • 1. Adenine nucleotides •  PFK-1 activity (inhib’n) when  [ATP] or other fuels • ATP binds allosteric site •  affinity for fru-6-PO4 •  activity (stim’d) when  [ADP]/[AMP] OR  [ATP] • ADP/AMP bind allosterically •  Stm’n PFK-1 •  More ATP overall in cell

  18. Blue=ADP Yellow=fru-1,6-bisphosphate

  19. 1. Adenine nucleotides -- cont’d • Note: If  [ATP] in cell, ATP  feedback inhib to decr further synth • As  ATP synth, and ATP used,  [ADP], [AMP] • Signals cell to restart ATP syth, so ADP, AMP act as “feedback stimulators” to incr ATP synth again

  20. 1. Adenine nucleotides -- cont’d • Also impt to balancing glycolysis w/ gluconeogenesis (“making new glucose”) • Uses sev enz’s impt in glycolysis (reversed) • BUT other, diff enz’s allow separation of pathways, regulation of 2 (so no “futile cycles”) • Gluconeogenesis alternative to PFK-1 cat’d by fructose-1,6-bisphosphatase (FBPase-1) • AMP stim’s PFK-1 (when more ATP needed by cell, much glu avail), BUT inhib’s FBPase-1 (when cell needs more glu, not enough avail to make more ATP)

  21. Chpt 15

  22. 2. Citrate • Intermed formed in Kreb’s cycle •  PFK-1 activity when  [citrate] • Citrate binds allosteric site • Usually concurrent w/ ATP modulation • So feedback inhib’n

  23. 3. Fru-2,6-Bisphosphate • In liver •  PFK-1 activity when  [Fru-2,6-bisphosphate] • Binds allosteric site •  affinity of PFK-1 for fru-6-PO4 • Acts as allosteric stimulator of PFK-1 • When Fru-2,6-bis… present, glycolysis encouraged, gluconeogenesis discouraged

  24. 2 1

  25. Chpt 15

  26. 3. Fru-2,6-Bisphosphate -- cont’d • Helps balance glu used in cell w/ glu generated (gluconeogenesis) • Impt to maintaining [blood glu] • Works through hormone glucagon • If not enough blood glu •  stim’n ad cyclase/cAMP/prot kinase pathway if gluconeogenesis nec because not enough nutrient glu avail to maintain sufficient [blood glu]

  27. Fru-1,6-Bisphosphate  Dihydroxyacetone PO4 + Glyceraldehyde-3-PO4

  28. Aldolase • Reverse aldol condensation • Schiff base form’n; enamine intermediate • Reversible? • Proceeds readily as 2P’s immediately  subsequent rxns • Have committed to pathway • Where was commitment?

  29. Dihydroxyacetone PO4 Glyceraldehyde-3-PO4

  30. Triose Phosphate Isomerase • Reversible? • Enediol intermediate (sim to phosphohexose isomerase mech) • Glu 165 –COOH, His 95 –H participate • Lys –NH3 “holds” –PO4 • kcat/KM shows kinetically perfect enzyme activity

  31. Priming Phase Ends Here; Payoff Phase to Begin • 6C glu  2 3C phosph’d cmpds • More red’d  more ox’d • Consumed 2 ATP from cell • Cell energy “invested” • Will yield more energy for cell at end of pathway • REMEMBER: for each future step, cell has 2x the mol’s as began (each 1 glu  2 glyc-3-PO4)

  32. Glyceraldehyde-3-PO4 1,3-Bisphosphoglycerate

  33. Glyceraldehyde-3-PO4 Dehydrogenase • Where did you hear about dehydrogenases before? • HINT: 1st step leading to ATP prod'n through e- transport • Aldehyde now  carboxylic acid anhydride w/ PO4 • High D G of hydrolysis (-49.3 kJ/mole)

  34. Rxn Mechanism: Glyc-3-PO4 DeHase

  35. Cys in enz active site forms thiohemiacetal w/ glyc-3-PO4 aldehyde grp • So S cov'ly bound to E in active site

  36. 1 :H- reduces NAD+ • Cofactor of enz • Now NADH •  thioester @ active site • Energy-rich intermediate

  37. 2nd NAD+ enters, accepts :H- from orig NAD cofactor •  NADH avail to transport e- to mitoch for e- transport/ox'v phosph'n/ATP synth • Ox'd cofactor regen'd • Pi enters • Thioester good target for phosphate attack • Energy rel'd w/ attack, cleavage of thioester by phosphate

  38. Cleavage w/ phosph’n  prod released and active site regen’d

  39. 1,3-Bisphosphoglycerate + ADP  3-Phosphoglycerate + ATP

  40. Phosphoglycerate Kinase • Requires Mg+2 • Substrate-level phosphorylation • In cytosol • Ox've phosph'n in mitoch • Coupled w/ preceding rxn to allow overall neg D G • Book notes E inc'd into ATP "from" ox'n aldehyde (step 6)  carbox acid (step 7)

  41. 3-Phosphoglycerate 2-Phosphoglycerate

More Related