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Catabolism pyruvate

The tricarboxylic acid (TCA) cycle catabolizes pyruvate to C02 and H20 in an oxygen-requiring process. [Pg.282]

Citric acid cycle electron transport and OKI dative phosphorylation fatty acid oxidation amino acid catabolism pyruvate oxidation... [Pg.762]

The catabolism of amino acids provides pyruvate, acetyl-CoA, oxaloacetate, fumarate, a-ketoglutarate, and succinate, ail of which may be oxidized by the TCA cycle. In this way, proteins may serve as excellent sources of nutrient energy, as seen in Chapter 26. [Pg.665]

FIGURE 25.1 The citrate-malate-pyruvate shuttle provides cytosolic acetate units and reducing equivalents (electrons) for fatty acid synthesis. The shuttle collects carbon substrates, primarily from glycolysis but also from fatty acid oxidation and amino acid catabolism. Most of the reducing equivalents are glycolytic in origin. Pathways that provide carbon for fatty acid synthesis are shown in blue pathways that supply electrons for fatty acid synthesis are shown in red. [Pg.804]

The next steps of glucose catabolism are called the citric acid cycle. The pyruvic acid formed in glycolysis is transported into the mitochondria, which arc subcellular organelles with double (inner and outer) membranes. They are referred to as the powerhous-... [Pg.170]

Active Figure 29.7 MECHANISM The 10-step glycolysis pathway for catabolizing glucose to two molecules of pyruvate. Individual steps are described in the text. Sign in at www.thomsonedu.com to see a simulation based on this figure and to take a short quiz. [Pg.1144]

Pyruvate, produced by catabolism of glucose (and by degradation of several amino acids), can undergo several further transformations depending on the conditions and on the organism. In the absence of oxygen, pyruvate can be either reduced by NADH to yield lactate [CHjCHfOHjCO - or, in yeast,... [Pg.1150]

The conversion occurs through a multistep sequence of reactions catalyzed by a complex of enzymes and cofactors called the pyruvate dehydrogenase complex. The process occurs in three stages, each catalyzed by one of the enzymes in the complex, as outlined in Figure 29.11 on page 1152. Acetyl CoA, the ultimate product, then acts as fuel for the final stage of catabolism, the citric acid cycle. All the steps have laboratory analogies. [Pg.1151]

Biomolecules are synthesized as well as degraded, but the pathways for anabolism and catabolism are not the exact reverse of one another. Fatty acids are biosynthesized from acetate by an 8-step pathway, and carbohydrates are made from pyruvate by the 11-step gluconeogenesis pathway. [Pg.1171]

Lactate, a product of glucose catabolism in oxygen-starved muscles, can be converted into pyruvate by oxidation. What coenzyme do you think is needed Write the equation in the normal biochemical format using a curved arrow. [Pg.1173]

Reactions involve several enzymes, which have to follow in sequence for lactic acid and alcohol fermentation. This is known as the glucose catabolism pathway, with emphasis on energetic and energy carrier molecules such as ATP, ADP, NAD+ and NADH. In this pathway the six-carbon substrate yields two three-carbon intermediates, each of which passes through a sequence of reactions to the stable end product of pyruvic acid. [Pg.244]

Pyruvate-dependent lyases serve catabolic functions in vivo in the degradation of sialic acids and KDO (2-keto-3-deoxy-manno-octosonate), and in that of 2-keto-3-deoxy aldonic acid intermediates from hexose or pentose catabolism. [Pg.278]

The KDO aldolase (KdoA, EC 4.1.2.23) is involved in the catabolism of the eight-carbon sugar d-KDO, which is reversibly degraded to D-arabinose (15) and pyruvate (Figure 10.10). The enzyme has been partially purified from bacterial sources and studied for synthetic applications [71,74]. It seems that the KdoA, similar to... [Pg.281]

Figure 30-2. Catabolism of i-as-paragine (top) and of i-glutamine (bottom) to amphibolic intermediates. (PYR, pyruvate ALA, i-alanine.) In this and subsequent figures, color highlights portions of the molecules undergoing chemical change. Figure 30-2. Catabolism of i-as-paragine (top) and of i-glutamine (bottom) to amphibolic intermediates. (PYR, pyruvate ALA, i-alanine.) In this and subsequent figures, color highlights portions of the molecules undergoing chemical change.
Alanine. Transamination of alanine forms pyruvate. Perhaps for the reason advanced under glutamate and aspartate catabolism, there is no known metabolic defect of alanine catabolism. Cysteine. Cystine is first reduced to cysteine by cystine reductase (Figure 30-7). Two different pathways then convert cysteine to pyruvate (Figure 30-8). [Pg.250]

The majority of microbial hydrogen production is driven by the anaerobic metabolism of pyruvate, formed during the catabolism of various substrates. The breakdown of pyruvate is catalyzed by one of two enzyme systems ... [Pg.98]

Examples of such intra cellular membrane transport mechanisms include the transfer of pyruvate, the symport (exchange) mechanism of ADP and ATP and the malate-oxaloacetate shuttle, all of which operate across the mitochondrial membranes. Compartmentalization also allows the physical separation of metabolically opposed pathways. For example, in eukaryotes, the synthesis of fatty acids (anabolic) occurs in the cytosol whilst [3 oxidation (catabolic) occurs within the mitochondria. [Pg.57]

Muscle protein catabolism generates amino acids some of which may be oxidized within the muscle. Alanine released from muscle protein or which has been synthesized from pyruvate via transamination, passes into the blood stream and is delivered to the liver. Transamination in the liver converts alanine back into pyruvate which is in turn used to synthesise glucose the glucose is exported to tissues via the blood. This is the glucose-alanine cycle (Figure 7.11). In effect, muscle protein is sacrificed in order to maintain blood adequate glucose concentrations to sustain metabolism of red cells and the central nervous system. [Pg.243]

The calorific capacity of amino acids is comparable to that of carbohydrates so despite their prime importance in maintaining structural integrity of cells as proteins, amino acids may be used as fuels especially during times when carbohydrate metabolism is compromised, for example, starvation or prolonged vigorous exercise. Muscle and liver are particularly important in the metabolism of amino acids as both have transaminase enzymes (see Figures 6.2 and 6.3 and Section 6.4.2) which convert the carbon skeletons of several different amino acids into intermediates of glycolysis (e.g. pyruvate) or the TCA cycle (e.g. oxaloacetate). Not all amino acids are catabolized to the same extent... [Pg.254]

See other pages where Catabolism pyruvate is mentioned: [Pg.180]    [Pg.42]    [Pg.180]    [Pg.42]    [Pg.574]    [Pg.576]    [Pg.171]    [Pg.1143]    [Pg.1161]    [Pg.1170]    [Pg.1281]    [Pg.1299]    [Pg.1310]    [Pg.255]    [Pg.259]    [Pg.53]    [Pg.202]    [Pg.58]    [Pg.323]    [Pg.85]    [Pg.312]    [Pg.86]    [Pg.88]    [Pg.92]    [Pg.93]    [Pg.97]    [Pg.86]    [Pg.370]    [Pg.47]    [Pg.58]    [Pg.75]   
See also in sourсe #XX -- [ Pg.1150 , Pg.1151 , Pg.1152 , Pg.1153 ]

See also in sourсe #XX -- [ Pg.1150 , Pg.1151 , Pg.1152 , Pg.1153 ]

See also in sourсe #XX -- [ Pg.911 , Pg.912 , Pg.913 , Pg.914 ]

See also in sourсe #XX -- [ Pg.1181 , Pg.1182 , Pg.1183 , Pg.1184 ]



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