1. Distribution of aldehyde dehydrogenase activity in rat liver was studied by measuring the rate of disappearance of acetaldehyde in the presence of each of the subcellular fractions. These were obtained by rough separation of particulate fractions from the soluble portion of the cell, by differential centrifugation, and by isopycnic gradient centrifugation. 2. The maximal rate of acetaldehyde oxidation was 3.7 mumol/min per g, with an apparent K(m) value below 10(-5)m. The highest rate of activity was observed in phosphate buffers of high P(i) concentration (above 60mm). 3. The activity measured was completely dependent on NAD(+). 4. The microsomal fraction and the nuclei were inactive in the assay. Of the total activity 80% was found in the mitochondrial fraction and the remaining 20% in the cytoplasm. 5. The distribution pattern is important from the point of view of acetaldehyde oxidation during ethanol metabolism. The apparent discrepancy of the results obtained by different workers and the localization of acetaldehyde oxidation in vivo is discussed.
Abstract A cytochrome b complex and cytochrome oxidase have been purified 14- and 20-fold respectively from yeast submitochondrial particles by a simple procedure involving their spontaneous precipitation from a deoxycholate extract. The recovery of both proteins was almost quantitative. The specific heme contents were 11 and 8 nmoles/mg protein for the cytochrome b complex and cytochrome oxidase respectively and both were spectrally pure. Sodium dodecyl sulfate gel electrophoresis resolved the cytochrome b complex into seven distinct subunits with molecular weights 42, 000, 33, 000, 27, 500, 23, 000, 15, 500, 13, 000 and 10, 500. Cytochrome oxidase contained five bands with molecular weights 42, 000, 26, 500, 21, 000, 14, 000 and 10, 500. Much of the cytochrome b complex (and all of the cytochrome oxidase) could be resolubilized in aqueous buffer following precipitation from the deoxycholate extract. The fraction of the cytochrome b preparation which remained insoluble appeared identical to the soluble protein in terms of polypeptide composition but contained less phospholipid and bound detergent, suggesting that insolubility may result from interaction between hydrophobic regions otherwise occupied by amphiphiles. The soluble cytochrome b complex migrated as a single species upon analytical ultracentrifugation and column chromatography, and during electrophoresis on polyacrylamide gels. Triton X-100, urea, or bile salts, failed to dissociate the complex. These findings suggest that the subunits are tightly associated in situ.
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