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Citric acid synthesis from

Figure 16-5. Participation of the citric acid cycle in fatty acid synthesis from glucose. See also Figure 21-5. Figure 16-5. Participation of the citric acid cycle in fatty acid synthesis from glucose. See also Figure 21-5.
One final issue concerned with ATP synthesis from glucose remains. Recall that two molecules of ATP are produced in the citric acid cycle (from GTP). The price for their transport into the cytoplasm, where they will be used, is the uptake of 2 protons into the matrix. Therefore the total amount of ATP produced from a molecule of glucose is reduced by about 0.5 molecule of ATP. [Pg.321]

Studies of the enzymic mechanism of the citric acid synthesis by Stern and Ochoa have directly shown that citric acid, and not aconitic acid, is the primary product. It had earlier been thought that the mechanism of citric acid synthesis might be similar to that of the reaction leading in vitro to the formation of citric acid from oxalacetic and pyruvic acid in the presence of hydrogen peroxide, where oxalocitramalic acid is an intermediate. Martins, however, found this substance to be metabolically inert in animal tissue. Stern and Ochoa found that aqueous extracts of acetone-dried pigeon liver formed citrate when acetate, oxalacetate, ATP, coenzyme A, and Mg or Mn ions were present. Thus the condensation reaction is preceded by the decarboxylation of pyruvic acid and the formation of an active form of acetate. This active acetate, as discussed below, is acetyl coenzyme A. [Pg.124]

Zhang G, Yang G, Ma JS (2006) Versatile framework solids constructed from divalent transition metals and citric acid synthesis, crystal structures and thermal behaviors. Cryst Growth Des 6 375-381... [Pg.211]

The action of chlorosulfonic acid on citric acid differs from that of fuming sulfuric acid which yields acetonedicarboxylic acid. The procedure outlined by Equation 47 may be extended to the synthesis of other ketoacids. [Pg.169]

Figure 29.1 An overview of catabolic pathways for the degradation of food and the production of biochemical energy. The ultimate products of food catabolism are C02 and H2O, with the energy released in the citric acid cycle used to drive the endergonic synthesis of adenosine triphosphate (ATP) from adenosine diphosphate (ADP) plus phosphate ion, HOPO32-. Figure 29.1 An overview of catabolic pathways for the degradation of food and the production of biochemical energy. The ultimate products of food catabolism are C02 and H2O, with the energy released in the citric acid cycle used to drive the endergonic synthesis of adenosine triphosphate (ATP) from adenosine diphosphate (ADP) plus phosphate ion, HOPO32-.
The primary fate of acetyl CoA under normal metabolic conditions is degradation in the citric acid cycle to yield C02. When the body is stressed by prolonged starvation, however, acetyl CoA is converted into compounds called ketone bodies, which can be used by the brain as a temporary fuel. Fill in the missing information indicated by the four question marks in the following biochemical pathway for the synthesis of ketone bodies from acetyl CoA ... [Pg.1174]

The amino acids are required for protein synthesis. Some must be supplied in the diet (the essential amino acids) since they cannot be synthesized in the body. The remainder are nonessential amino acids that are supplied in the diet but can be formed from metabolic intermediates by transamination, using the amino nitrogen from other amino acids. After deamination, amino nitrogen is excreted as urea, and the carbon skeletons that remain after transamination (1) are oxidized to CO2 via the citric acid cycle, (2) form glucose (gluconeogenesis), or (3) form ketone bodies. [Pg.124]

Citrate is isomerized to isocitrate by the enzyme aconitase (aconitate hydratase) the reaction occurs in two steps dehydration to r-aconitate, some of which remains bound to the enzyme and rehydration to isocitrate. Although citrate is a symmetric molecule, aconitase reacts with citrate asymmetrically, so that the two carbon atoms that are lost in subsequent reactions of the cycle are not those that were added from acetyl-CoA. This asymmetric behavior is due to channeling— transfer of the product of citrate synthase directly onto the active site of aconitase without entering free solution. This provides integration of citric acid cycle activity and the provision of citrate in the cytosol as a source of acetyl-CoA for fatty acid synthesis. The poison fluo-roacetate is toxic because fluoroacetyl-CoA condenses with oxaloacetate to form fluorocitrate, which inhibits aconitase, causing citrate to accumulate. [Pg.130]

The citric acid cycle is not only a pathway for oxidation of two-carbon units—it is also a major pathway for interconversion of metabolites arising from transamination and deamination of amino acids. It also provides the substtates for amino acid synthesis by transamination, as well as for gluconeogenesis and fatty acid synthesis. Because it fimctions in both oxidative and synthetic processes, it is amphibolic (Figure 16—4). [Pg.133]

Aminotransferase (transaminase) reactions form pymvate from alanine, oxaloacetate from aspartate, and a-ketoglutarate from glutamate. Because these reactions are reversible, the cycle also serves as a source of carbon skeletons for the synthesis of these amino acids. Other amino acids contribute to gluconeogenesis because their carbon skeletons give rise to citric acid cycle... [Pg.133]

The key to unraveling the toxicity of fluoracetate came from observations of Buffa and Peters (1949) that in animals treated with FAc, considerable quantities of citrate accumulated in some tissues. Oxygen uptake was also diminished. The citric acid cycle was thus implicated as the site of inhibition. Fluorcitrate was then isolated from the affected tissues. It was found to be a powerful competitive inhibitor of aconitase, thus blocking citrate oxidation. The suggestion was therefore made that fluoracetate was toxic not in itself, but because it was metabolized in cells via fluoracetyl CoA to give a toxic derivative, an example of lethal synthesis —the capacity of organisms to metabolize nontoxic compounds and convert them to potentially lethal products. [Pg.80]

The citrate shuttle transports acetyl CoA groups from the mitochondria to the cytoplasm for fatty acid synthesis. Acetyl CoA combines with oxaloacetate in the mitochondria to form citrate, but rather than continuing in the citric add cycle, citrate is transported into the cytoplasm. Factors that indirectly promote this process indude insuKn and high-energy status. [Pg.208]

Vinblastine suppresses cell growth during metaphase, affects amino acid metabolism, in particular at the level of including glutamine acid into the citric acid cycle and preventing it from transformation into urea, and it also inhibits protein and nucleic acid synthesis. [Pg.405]

The steam-volatility of isomeric thienothiophenes allows separation from the resinous products formed during their synthesis from citric acid or acetylene. Selenophenoselenophenes are also steam-volatile. It is, however, very difficult to separate the isomeric thienothiophenes from each other and from benzo[b]thiophene with which they are also... [Pg.178]

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See also in sourсe #XX -- [ Pg.6 , Pg.49 ]



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Citric acid synthesis

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