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Vías centrales del metabolismo de los carbohidratos

Vías centrales del metabolismo de los carbohidratos. El estudio de los carbohidratos debe considerar. Central pathways of carbohydrate metabolism Conversion of compounds to intermediates usable in central pathways Mechanisms of energy (ATP) production Substrate-level phosphorylation

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Vías centrales del metabolismo de los carbohidratos

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  1. Vías centrales del metabolismo de los carbohidratos

  2. El estudio de los carbohidratos debe considerar • Central pathways of carbohydrate metabolism • Conversion of compounds to intermediates usable in central pathways • Mechanisms of energy (ATP) production • Substrate-level phosphorylation • Oxidative phosphorylation • Other mechanisms of energy transfer

  3. El estudio de los carbohidratos debe considerar • Metabolic steps involved in the generation and use of reducing activity • Reduction of pyruvate or other substrates to fermentation end products • Biosynthetic reactions requiring reducing action

  4. El estudio de los carbohidratos debe considerar • Oxygen involvement in energy-generating reactions • Aerobic metabolism • Anaerobic metabolism • Facultative metabolism • Metabolic intermediates serving as biosynthetic precursors

  5. El estudio de los carbohidratos debe considerar • Reactions that replenish biosynthetic intermediates (anapleurotic reactions) • Metabolic and genetic regulatory system

  6. Los carbohidratos no son los únicos compuestos utilizados como fuente de energía por los microorganismos • Fatty acids, lipids, amino acids, purines, pyrimidines, and a wide variety of other compounds can also serve as carbon and energy sources.

  7. Los carbohidratos no son los únicos compuestos utilizados como fuente de energía por los microorganismos • Generally, utilization of an alternate substrate involves its conversion to an intermediate intrinsic to one of the central pathways of carbohydrate metabolism.

  8. Vias principales del metabolismo de carbohidratos • Glucolisis o via de Embden-Meyerhof-Parnas, o via de la Fructosa bisfosfato – aldolasa • Entner-Doudoroff o Cetogluconato • Ciclo oxidativo de la Pentosa fosfato • Gluconeogénesis y síntesis de glicógeno.

  9. FRUCTOSE BISPHOSPHATE - ALDOLASE OR EMBDEN-MEYERHOF-PARNAS (EMP)PATHWAY OF GLYCOLYSIS.

  10. Fructose Bisphosphate Aldolase Pathway

  11. Reacciones más importantes de de la ruta de EMP • Phosphorylation of glucose and fructose-6-phosphate by ATP • Cleavage of fructose-1,6-bisphosphate to trioses by a specific aldolase • Structural rearrangements • Oxidation–reduction and Pi (inorganic phosphate) assimilation

  12. Fructose Bisphosphate Aldolase Pathway

  13. Fructose Bisphosphate Aldolase Pathway

  14. The enzyme fructose bisphosphate (FPB) aldolase is one of the most critical steps in the pathway. In the absence of this enzyme, glucose or other hexose sugars must be metabolized via one of several alternative pathways,

  15. Regulación metabólica de las enzimas de la glucólisis y del ciclo de los ácidos tricarboxílicos

  16. Alternate Pathways of Glucose Utilization • Warburg and Christian • described the oxidation of glucose-6-phosphate to 6phosphogluconate (6-P-G) via G-6-P dehydrogenase). They also described the decarboxylation of 6-P-G to form a pentose sugar. • Entner-Doudoroff or Ketogluconate Pathway • differs from the EMP pathway primarily in the form of the 6-carbon intermediate that undergoes C3-C3 cleavage (aldol cleavage) to form three-carbon intermediates.

  17. Inicio de la vía del 6 fosfo gluconato

  18. Phosphoketolase Pathway

  19. Oxidative Pentose Phosphate Cycle

  20. After one turn of the cycle, the net reaction is Encircled P, phosphate group; G-6-P, glucose-6-phosphate; 6-PG, 6-phosphogluconate; F-6-P, fructose-6-phosphate; F-1,6-BP, fructose-1,6-bisphosphate; DOHAP, dihydroxyacetone phosphate; GA-P, glyceraldehyde-3-phosphate.

  21. Tarea ¿Cuál es el destino de los carbonos 3 y 4 marcados con radiactividad de una glucosa que entra a la vía • EMP • Entner-Doudoroff • Pentosa fosfato • Fosfogluconato • Ciclo oxidativo de pentosa fosfato ?

  22. Diferencias entre la glucólisis y la via de la pentosa fosfato • Glycolysis generates NADH, which can be reoxidized by linkage to the electron transport system, or under anaerobic conditions it can be used to reduce an oxidized substrate, such as pyruvate, to lactate.

  23. Diferencias entre la glucólisis y la via de la pentosa fosfato • The pentose phosphate pathway generates NADPH, which is used primarily for reducing power in biosynthetic reaction (e.g., the conversion of α-ketoglutarate to glutamate or the incorporation of acetate into fatty acids) and is not linked to the terminal respiratory system.

  24. Operation of the TCA cycle under anaerobic conditions.

  25. GLUCONEOGENESIS • Growth of microorganisms on poor carbon sources, • (L-malate, succinate, acetate, or glycerol), • requires the ability to synthesize hexoses for the production of other compounds • (cell wall mucopeptides, storage glycogen, and other compounds derived from hexose, such as pentoses, for nucleic acid biosynthesis).

  26. Pyruvate kinase is not reversible 12. Pyruvate kinase (pykA; pykF). Generates ATP from ADP 14. Pyruvate carboxylase. Converts pyruvate to oxaloacetic acid (OAA) via carbon dioxide (CO2) fixation using ATP. 15. PEP carboxykinase. Forms phosphoenolpyruvate from OAA using GTP..

  27. A second irreversible enzyme is phosphofructokinase 5. Phosphofructokinase (pfkA). Phosphorylation of F-6-P to FBP using ATP. 16. Fructose-1,6-bisphosphatase. Removes Pi from F-1,6-bisP to form F-6-P.

  28. The third bypass reaction required for gluconeogenesis involves dephosphorylationof G-6-P the formation of glucose from pyruvate requires a considerable expenditure of energy

  29. Gluconeogenesis Regulation • A major regulatory step is PEP carboxykinase, encoded by pckA in E. coli. • By catabolite repression, a process in which gluconeogenesis is inhibited when glucose or other carbohydrate carbon sources are available.

  30. Gluconeogenesis Regulation • Maximum levels of PEP carboxykinase are induced at • the onset of the stationary phase of growth, • to ensure the synthesis of adequate carbohydrate storage reserves or • to provide metabolites from the upper part of the EMP pathway as the organism converts proteins to gluconeogenic amino acids.

  31. Gluconeogenesis Regulation • The stationary phase induction of PEP carboxykinase requires • Cyclic AMP and • a regulatory signal, (not been fully elucidated)

  32. Glycogen Synthesis

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