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Tricarboxylic transporter

Figure21-4. The provision of acetyl-CoA and NADPH for lipogenesis. (PPP, pentose phosphate pathway T, tricarboxylate transporter K, a-ketoglutarate transporter P, pyruvate transporter.)... Figure21-4. The provision of acetyl-CoA and NADPH for lipogenesis. (PPP, pentose phosphate pathway T, tricarboxylate transporter K, a-ketoglutarate transporter P, pyruvate transporter.)...
Acetyl-CoA carboxylase is an allosteric enzyme and is activated by citrate, which increases in concentration in the well-fed state and is an indicator of a plentiful supply of acetyl-CoA. Citrate converts the enzyme from an inactive dimer to an active polymeric form, having a molecular mass of several milhon. Inactivation is promoted by phosphorylation of the enzyme and by long-chain acyl-CoA molecules, an example of negative feedback inhibition by a product of a reaction. Thus, if acyl-CoA accumulates because it is not esterified quickly enough or because of increased lipolysis or an influx of free fatty acids into the tissue, it will automatically reduce the synthesis of new fatty acid. Acyl-CoA may also inhibit the mitochondrial tricarboxylate transporter, thus preventing activation of the enzyme by egress of citrate from the mitochondria into the cytosol. [Pg.178]

Figure 2.4. The provision of acetyl-CoA and NADPH for lipogenesis. PPP, pentose phosphate pathway T, tricarboxylate transporter K, a-ketoglutarate transporter. In ruminants, pyruvate dehydrogenase, ATP-citrate lyase and malic enzyme activities are low and perhaps non-functional. (From Murray et al., 1988. Harper s Biochemistry, 21st edn, p. 207, Appleton and Lange, Norwalk, CT reproduced with permission of The McGraw-Hill Companies). Figure 2.4. The provision of acetyl-CoA and NADPH for lipogenesis. PPP, pentose phosphate pathway T, tricarboxylate transporter K, a-ketoglutarate transporter. In ruminants, pyruvate dehydrogenase, ATP-citrate lyase and malic enzyme activities are low and perhaps non-functional. (From Murray et al., 1988. Harper s Biochemistry, 21st edn, p. 207, Appleton and Lange, Norwalk, CT reproduced with permission of The McGraw-Hill Companies).
Transfer of citrate through the inner membrane of MCh is provided by a tricarboxylate transporter (m.w. 32.5 kD), which also catalyzes transport of treo-Ds-isocitrate, cis-aconitate and other tricarboxylates (LaNoue and School-werth, 1979 Kaplan et al, 1990). This is electroneutral exchange for either another tricarboxylate or dicarboxylate (e.g. malate or succinate), or for phosphoenolpyruvate. Formation of glutathione-citryl thioester is irreversibly inhibited by (-)erythrofluorocitrate (IC50 = 25 pmol FC/mg protein), which makes a stable adduct with the synthase (Kun et al, 1977). However, the block of citrate transport... [Pg.182]

Kaplan, R.S., Mayor, J.A., Johnston, N., Oliveira, D.L. (1990). Jhirification and characterization of the reconstitutively active tricarboxylate transporter from rat liver mitochondria. J. Biol. Chem. 265 13379-85. [Pg.195]

FIGURE 20.1 Pyruvate produced hi glycolysis is oxidized in the tricarboxylic acid (TCA) cycle. Electrons liberated in this oxidation flow through the electron transport chain and drive the synthesis of ATP in oxidative phosphorylation. In eukaryotic cells, this overall process occurs in mitochondria. [Pg.640]

This complex consists of four subunits, all of which are encoded on nuclear DNA, synthesized on cytosolic ribosomes, and transported into mitochondria. The succinate dehydrogenase (SDH) component of the complex oxidizes succinate to fumarate with transfer of electrons via its prosthetic group, FAD, to ubiquinone. It is unique in that it participates both in the respiratory chain and in the tricarboxylic acid (TC A) cycle. Defects of complex II are rare and only about 10 cases have been reported to date. Clinical syndromes include myopathy, but the major presenting features are often encephalopathy, with seizures and psychomotor retardation. Succinate oxidation is severely impaired (Figure 11). [Pg.309]

F. Wu, F. Yang, KC Vinnakota, and DA Beard, Computer modeling of mitochondrial tricarboxylic acid cycle, oxidative phosphorylation, metabolite transport, and electrophysio logy. J. Biol. Chem. 282(34), 24525 24537 (2007). [Pg.240]

By the mid-1950s, therefore, it had become clear that oxidation in the tricarboxylic acid cycle yielded ATP. The steps had also been identified in the electron transport chain where this apparently took place. Most biochemists expected oxidative phosphorylation would occur analogously to substrate level phosphorylation, a view that was tenaciously and acrimoniously defended. Most hypotheses entailed the formation of some high-energy intermediate X Y which, in the presence of ADP and P( would release X and Y and yield ATP. A formulation of the chemical coupling hypothesis was introduced by Slater in 1953,... [Pg.94]

The citric acid cycle, also called the Krebs cycle or the tricarboxylic add (TCA) cyde, is in the mitochondria. Although oxygen is not directly required in the cyde, the pathway will not occur anaerobically because NADH and FADH will accumulate if oxygen is not available for the electron transport chain. [Pg.179]

The metabolic machinery responsible for the heterotrophic respiration reactions is contained in specialized organelles called mitochondria. These reactions occur in three stages (1) glycolysis, (2) the Krebs or tricarboxylic acid cycle, and (3) the process of oxidative phosphorylation also known as the electron transport chain. As illustrated in... [Pg.197]

Marine organisms concentrate metals in their tissues and skeletal materials. Many of these trace metals are classified as micronutrients because they are required, albeit in small amounts, for essential metabolic functions. Some are listed in Table 11.4, illustrating the role of metals in the enzyme systems involved in glycolysis, the tricarboxylic acid cycle, the electron-transport chain, photosynthesis, and protein metabolism. These micronutrients are also referred to as essential metals and, as discussed later, have the potential to be biolimiting. [Pg.273]

Under aerobic conditions, the pyravate is oxidized to CO and H O via the tricarboxylic acid or Krebs cycle and the electron transport system. The net yield for glycolysis followed by complete oxidation is 38 moles ATP per mole glucose, although there is evidence that the yield for bacteria is 16 moles ATP per mole glucose (Aiba et al., 1973). Thus, 673 kcal are liberated per mole glucose, much of which is stored as ATP. [Pg.76]

The most important process in the degradation of fatty acids is p-oxidation—a metabolic pathway in the mitochondrial matrix (see p. 164). initially, the fatty acids in the cytoplasm are activated by binding to coenzyme A into acyl CoA [3]. Then, with the help of a transport system (the carnitine shuttle [4] see p. 164), the activated fatty acids enter the mitochondrial matrix, where they are broken down into acetyl CoA. The resulting acetyl residues can be oxidized to CO2 in the tricarboxylic acid cycle, producing reduced... [Pg.162]

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The tricarboxylic acid cycle, and electron transport

Transporters tricarboxylate

Tricarboxylate transporter, mitochondrial

Tricarboxylates

Tricarboxylic Anion Transporters

Tricarboxylic acid transport

Tricarboxylic acid transport in mitochondria

Tricarboxylic transporter of mitochondria

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