Sulphate uptake and metabolism in the chrysomonad, monochrysis lutheri.

The intracellular concentration of inorganic 35SO4 in Monochrysis lutheri cells exposed to 0.513 mM Na235SO4 for up to 6-hr remained constant at about 0.038 mM. The exchange rate of this 35SO4 with the external unlabelled sulphate was negligible compared to the rate of influx across the plasmalemma (0.032 mu moles/g cells/hr). The flux of free 35SO4 to organic 35S was 0.029 mu moles/g cells/hr. Assuming an internal electrical potential in the cells of -70 mV, this intracellular concentration of inorganic 35SO4 was well in excess of that obtainable by passive diffusion as calculated from the Nernst equation. These results indicate that sulphate is accumulated by an active mechanism rather than by facilitated diffusion. Sulphate uptake appears to occur via a carrier-mediated membrane transport system which conforms to Michaelis-Menten type saturation kinetics with a Km of 3.2 X 10(-5) M and Vmax of 7.9 X 10(-5) mu moles sulphate/hr/10(5) cells. Uptake was dependent on a source of energy since the metabolic inhibitor CCCP almost completely inhibited uptake under both light and dark conditions and DCMU caused a 50% decrease in uptake under light conditions. Under dark conditions, uptake remained at about 80% of that observed under light conditions and was little affected by DCMU, indicating that the energy for uptake could be supplied by either photosynthesis or respiration. A charge and size recognition site in the cell is implied by the finding that sulphate uptake was inhibited by chromate and selenate but not by tungstate, molybdate, nitrate or phosphate. Chromate did not inhibit photosynthesis. Cysteine and methionine added to the culture medium were apparently capable of exerting inhibition of sulphate uptake in both unstarved and sulphate-starved cells. Cycloheximide slightly inhibited sulphate uptake over an 8-hr period indicating, either a slow rate of entry of the inhibitor into the cells or a slow turnover of the protein(s) associated with sulphate transport.     

Lipid metabolism by the gall-bladder. I. The in situ uptake and metabolism of lysophosphatidylcholine

Accumulation of lysophosphatidylcholine in gall-bladder bile is involved in the pathogenesis of acute cholecystitis. [1-14C]oleoyl- or [1-14C]palmitoyl-lysophosphatidylcholine was thus instilled in the in situ guinea pig gall-bladder and the absorption and metabolism of the lipid were determined. We found that, after 6 h instillation, 53% of the oleoyl derivative was adsorbed by the gall-bladder, whereasee only 37% of the palmitoyl derivative was absorbed. Although some differences in the metabolism of these two lipids were observed, a major portion of the absorbed radioactivity was found in the gall-bladder wall as phosphatidylcholine. To determine the mechanism of phosphatidylcholine formation from lysophosphatidylcholine by the gall-bladder mucosa, we used lysophosphatidylcholine which was labelled in the fatty acid moiety with 14C and in the choline moiety with 3H. Our data suggest that the mechanism of phosphatidylcholine formation from lysophosphatidylcholine involved acylation with an acyl donor other than a second molecule of lysophosphatidylcholine. We hypothesize that this mechanism as well as others described serve to prevent accumulation of lysophosphatidylcholine within the gall-bladder lumen and thus prevent damage to the gall-bladder mucosa.     

Oxalate, formate, formamide, and methanol metabolism in Thiobacillus novellus.

Thiobacillus novellus was able to grow with oxalate, formate, formamide, and methanol as sole sources of carbon and energy. Extensive growth on methanol required yeast extract or vitamins. Glyoxylate carboligase was detected in extracts of oxalate-grown cells. Ribulose bisphosphate carboxylase was found in extracts of cells grown on formate, formamide, and thiosulfate. These data indicate that oxalate is utilized heterotrophically in the glycerate pathway, and formate and formamide are utilized autotrophically in the ribulose bisphosphate pathway. Nicotinamide adenine dinucleotide-linked formate dehydrogenase was present in extracts of oxalate-, formate-, formamide-, and methanol-grown cells but was absent in thiosulfate- and acetate-grown cells.     

Ubiquinone, dolichol, and cholesterol metabolism in aging and Alzheimer's disease.

The lipid compositions of various regions of the human brain were investigated during aging and in Alzheimer's disease. The phospholipid amounts and compositions remained unchanged during aging. There were, however, considerable differences both in phospholipid composition and amount when the various regions were compared. The level of dolichol increased severalfold in all regions up to the age of 70, but there was no further elevation thereafter. The ubiquinone level decreased significantly in all parts of the brain upon aging. In Alzheimer's disease, the dolichol level was decreased in all regions, and particularly, in those affected by the disease. In contrast, the dolichyl-P concentration increased in those regions that exhibited morphological changes. There was no modification in cholesterol distribution, but a significant elevation in ubiquinone content was observed in most regions. The only phospholipid whose level was elevated was phosphatidylinositol, and only in those parts of the brain that were affected. The content of polyunsaturated fatty acids in phosphatidylethanolamine was greatly decreased in connection with the disease, with a parallel increase in the saturated portion. The results indicate that Alzheimer's disease results in specific and significant changes in the levels of lipid products of the mevalonate pathway in the brain.     

Sulfur and methionine metabolism in sheep. II. Quantitative estimates of sulfur metabolism in the sheep's stomach.

The metabolism of dietary and supplemental DL-methionine sulfur in the stomach of sheep was studied in two experiments. In both experiments sheep were fed a 50 : 50 oaten chaff: lucerne chaff ration at two levels of intake, and some animals received intraruminal infusions of DL-methionine. In experiment 2 increasing dry matter intake (DMI) increased first approximations of total, neutral, protein and reducible sulfur flows and also sulfide sulfur flow from the reticulo-rumen. Increased DMI (from 500 to 1000 g/day) also resulted in greater true flows of total (2207 v. 1104 mg/day), neutral (1867 v. 1043 mg/day) and protein (893 v. 482 mg/day) sulfur at the duodenum. Two flow diagrams of sulfur metabolism in the compartments of the ruminant stomach were developed from the data of experiment 2. Fluid flows of sulfur in experiment 1 were used to supplement the data of experiment 2 in developing the balance models. The two models represent the extremes of dietary and supplemental sulfur metabolism in the sheep's stomach under the conditions of experiment 2, and they are discussed in relation to previous research on sulfur metabolism in the stomach.