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Reducing equivalent

Electron Transport Between Photosystem I and Photosystem II Inhibitors. The interaction between PSI and PSII reaction centers (Fig. 1) depends on the thermodynamically favored transfer of electrons from low redox potential carriers to carriers of higher redox potential. This process serves to communicate reducing equivalents between the two photosystem complexes. Photosynthetic and respiratory membranes of both eukaryotes and prokaryotes contain stmctures that serve to oxidize low potential quinols while reducing high potential metaHoproteins (40). In plant thylakoid membranes, this complex is usually referred to as the cytochrome b /f complex, or plastoquinolplastocyanin oxidoreductase, which oxidizes plastoquinol reduced in PSII and reduces plastocyanin oxidized in PSI (25,41). Some diphenyl ethers, eg, 2,4-dinitrophenyl 2 -iodo-3 -methyl-4 -nitro-6 -isopropylphenyl ether [69311-70-2] (DNP-INT), and the quinone analogues,... [Pg.40]

The substrates of catabolism—proteins, carbohydrates, and lipids—are good sources of chemical energy because the carbon atoms in these molecules are in a relatively reduced state (Figure 18.9). In the oxidative reactions of catabolism, reducing equivalents are released from these substrates, often in the form of hydride ions (a proton coupled with two electrons, H ). These hydride ions are transferred in enzymatic dehydrogenase reactions from the substrates... [Pg.577]

FIGURE 18.11 Transfer of reducing equivalents from catabolism to anabolism via the NADPH cycle. [Pg.579]

In green plants, water serves as the ultimate electron donor for the photosynthetic generation of reducing equivalents. The reaction sequence... [Pg.712]

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]

NADPH can be produced in the pentose phosphate pathway as well as by malic enzyme (Figure 25.1). Reducing equivalents (electrons) derived from glycolysis in the form of NADH can be transformed into NADPH by the combined action of malate dehydrogenase and malic enzyme ... [Pg.805]

To summarize, squalene epoxidase is a flavoprotein capable of catalyzing the insertion of oxygen into the 2,3-double bond of squalene to give 2,3-oxidosqualene, with the second oxygen atom from 02 being reduced to water. The reducing equivalents necessary for this transformation are relayed from NADPH through NADPH-cytochrome c reductase to the flavin cofactor of the epoxidase. [Pg.373]

Metabolites whose biosynthesis leads to the net production of ATP and/or reducing equivalents, for example organic adds and certain secondary metabolites. In these cases, the P/O quotient influences the extent to which energy can be dissipated. [Pg.51]

The lower than expected yields can be explained by the nature of methane oxidation to methanol in these bacteria. This reaction, catalysed by methane mono-oxygenase, is a net consumer of reducing equivalents (NADH), which would otherwise be directed to ATP generation and biosynthesis. In simple terms the oxidation of methane to methanol consumes energy, lowering the yield. [Pg.89]

If the glycolytic flux is slow much of the pyruvate formed enters the mitochondria and is oxidized by the citrate cycle and reducing equivalents (2H) from NADH are oxidized indirectly (see below). When the flux is fast there is net production of... [Pg.111]

Davis, E.J., Bremer, J., Akerman, K.E. (1980). Thermodynamic aspects of translocation of reducing equivalents by mitochondria. J. Biol. Chem. 225, 2277-2283. [Pg.152]

THE RESPIRATORY CHAIN COLLECTS OXIDIZES REDUCING EQUIVALENTS... [Pg.92]

Most of the energy liberated during the oxidation of carbohydrate, fatty acids, and amino acids is made available within mitochondria as reducing equivalents (—H or electrons) (Figure 12-2). Mitochondria contain the respiratory chain, which collects and transports reducing equivalents directing them to their final reaction with oxygen to form water, the machinery for... [Pg.92]

Ubiquinone or Q (coenjyme Q) (Figure 12-5) finks the flavoproteins to cytochrome h, the member of the cytochrome chain of lowest redox potential. Q exists in the oxidized quinone or reduced quinol form under aerobic or anaerobic conditions, respectively. The structure of Q is very similar to that of vitamin K and vitamin E (Chapter 45) and of plastoquinone, found in chloroplasts. Q acts as a mobile component of the respiratory chain that collects reducing equivalents from the more fixed flavoprotein complexes and passes them on to the cytochromes. [Pg.92]

Figure 12-2. Role of the respiratory chain of mitochondria in the conversion of food energy to ATP. Oxidation of the major foodstuffs leads to the generation of reducing equivalents (2H) that are collected by the respiratory chain for oxidation and coupled generation of ATP. Figure 12-2. Role of the respiratory chain of mitochondria in the conversion of food energy to ATP. Oxidation of the major foodstuffs leads to the generation of reducing equivalents (2H) that are collected by the respiratory chain for oxidation and coupled generation of ATP.
Figure 12-3. Transport of reducing equivalents through the respiratory chain. Figure 12-3. Transport of reducing equivalents through the respiratory chain.
Figure 12-4. Components of the respiratory chain in mitochondria, showing the collecting points for reducing equivalents from important substrates. FeS occurs in the sequences on the O2 side of Fp or Cyt b. Figure 12-4. Components of the respiratory chain in mitochondria, showing the collecting points for reducing equivalents from important substrates. FeS occurs in the sequences on the O2 side of Fp or Cyt b.
Figure 12-12. Glycerophosphate shuttle for transfer of reducing equivalents from the cytosol into the... Figure 12-12. Glycerophosphate shuttle for transfer of reducing equivalents from the cytosol into the...
REACTIONS OF THE CITRIC ACID CYCLE LIBERATE REDUCING EQUIVALENTS CO2 (Figure 16-3) ... [Pg.130]

Figure 16-2. The citric acid cycle the major catabolic pathway for acetyl-CoA in aerobic organisms. Acetyl-CoA, the product of carbohydrate, protein, and lipid catabolism, is taken into the cycle, together with HjO, and oxidized to CO2 with the release of reducing equivalents (2H). Subsequent oxidation of 2H in the respiratory chain leads to coupled phosphorylation of ADP to ATP. For one turn of the cycle, 11 are generated via oxidative phosphorylation and one arises at substrate level from the conversion of succinyl-CoA to succinate. Figure 16-2. The citric acid cycle the major catabolic pathway for acetyl-CoA in aerobic organisms. Acetyl-CoA, the product of carbohydrate, protein, and lipid catabolism, is taken into the cycle, together with HjO, and oxidized to CO2 with the release of reducing equivalents (2H). Subsequent oxidation of 2H in the respiratory chain leads to coupled phosphorylation of ADP to ATP. For one turn of the cycle, 11 are generated via oxidative phosphorylation and one arises at substrate level from the conversion of succinyl-CoA to succinate.
As a result of oxidations catalyzed by the dehydrogenases of the citric acid cycle, three molecules of NADH and one of FADHj are produced for each molecule of acetyl-CoA catabohzed in one mrn of the cycle. These reducing equivalents are transferred to the respiratory chain (Figure 16-2), where reoxidation of each NADH results in formation of 3 ATP and reoxidation of FADHj in formation of 2 ATP. In addition, 1 ATP (or GTP) is formed by substrate-level phosphorylation catalyzed by succinate thiokinase. [Pg.133]

Reducing Equivalents Are Generated in Those Tissues Specializing in Reductive Syntheses... [Pg.166]

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Electrons reducing equivalent

Hydrogen reducing equivalents

NADPH reducing equivalents

Other Reducing-Equivalent Transport and Oxygen-Consuming Systems

Reduced thickness equivalent

Reducing agent, equivalent mass

Reducing equivalents from citric acid cycl

Reducing-equivalent transport and

Reducing-equivalent transport and oxygen-consuming systems

Representations, completely reduced equivalent

Sources of Carbon and Reducing Equivalents for Fatty Acid Synthesis

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