Alcohol dehydrogenase association

Alcohol dehydrogenases found in certain microorganisms utilize a pyrroloquino-line quinone (PQQ) or flavin cofactor to pass electrons released upon oxidation of alcohols to the heme electron-acceptor protein, cytochrome c. These membrane-associated alcohol dehydrogenases form part of a respiratory chain, and the energy from fuel oxidation therefore contributes to generation of a proton gradient across... 

Figure 5 Model of phosphorus (P) deficiency-induced physiological changes associated with the release of P-mobilizing root exudates in cluster roots of white lupin. Solid lines indicate stimulation and dotted lines inhibition of biochemical reaction sequences or mclaholic pathways in response to P deliciency. For a detailed description see Sec. 4.1. Abbreviations SS = sucrose synthase FK = fructokinase PGM = phosphoglueomutase PEP = phosphoenol pyruvate PE PC = PEP-carboxylase MDH = malate dehydrogenase ME = malic enzyme CS = citrate synthase PDC = pyruvate decarboxylase ALDH — alcohol dehydrogenase E-4-P = erythrosc-4-phosphate DAMP = dihydraxyaceConephos-phate APase = acid phosphatase.

Borras E, Coutelle C, Rosell A et al. Genetic polymorphism of alcohol dehydrogenase in Europeans The ADH2 2 allele decreases the risk of alcoholism and is associated with ADH3 1. Hepatology 2000 31 984-989. 

The primary pathway for alcohol metabolism involves alcohol dehydrogenase (ADH), a cytosolic enzyme that catalyzes the conversion of alcohol to acetaldehyde (Figure 23-1, left). This enzyme is located mainly in the liver, but small amounts are found in other organs such as the brain and stomach. In some Asian populations with polymorphisms in ADH that affect enzyme activity, a form of ADH with reduced activity is associated with an increased risk of alcoholism. 

Tobias, C. M, and Chow, E. K., 2005, Structure of the cinnamyl-alcohol dehydrogenase gene family in rice and promoter activity of a member associated with lignification, Planta 220 678-688. 

Alcohol-related liver diseases are complex, and ethanol has been shown to interact with a large number of molecular targets. Ethanol can interfere with hepatic lipid metabolism in a number of ways and is known to induce both inflammation and necrosis in the liver. Ethanol increases the formation of superoxide by Kupffer cells thus implicating oxidative stress in ethanol-induced liver disease. Similarly prooxidants (reactive oxygen species) are produced in the hepatocytes by partial reactions in the action of CYP2E1, an ethanol-induced CYP isoform. The formation of protein adducts in the microtubules by acetaldehyde, the metabolic product formed from ethanol by alcohol dehydrogenase, plays a role in the impairment of VLDL secretion associated with ethanol. 

N-1 ormy [piperidine (4.15) is an uncompetitive inhibitor of liver alcohol dehydrogenase (Figure 4.18).14 Liver alcohol dehydrogenase is often associated with the oxidation of ethanol in the bloodstream, but it also oxidizes methanol to formaldehyde, which is a toxic metabolite. Safe, effective inhibitors of liver alcohol dehydrogenase represent a potential treatment for individuals who have ingested methanol. 

Tapia and Eklund (1986) carried out a Monte Carlo simulation of the substrate channel of liver alcohol dehydrogenase, based on the X-ray diffraction structure for this enzyme. The addition of substrate and the associated conformation change induce an order—disorder transition for the solvent in the channel. A solvent network, connecting the active-site zinc ion and the protein surface, may provide the basis for a proton relay system. A molecular dynamics simulation of carbonic anhydrase showed two proton relay networks connecting the active-site zinc atom to the surrounding solvent (Vedani et ai, 1989). They remain intact when the substrate, HCOf, is bound. 

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