Fatty acid beta-oxidation system in microbodies of n-alkane-grown Candida tropicalis.

Localization of fatty acid beta-oxidation system in microbodies of Candida tropicalis cells growing on n-alkanes was studied. Microbodies isolated from the yeast cells showed palmitate-dependent activities of NAD reduction, acetyl-CoA formation and oxygen consumption. When sodium azide, an inhibitor of catalase, was added to the system, palmitate-dependent formation of hydrogen peroxide was observed. Stoichiometric study revealed that two moles of NAD were reduced per one mole of oxygen consumed in the absence of sodium azide and the presence of the inhibitor doubled the oxygen consumption by microbodies without an appreciable change in NAD reduction. These results indicate that the yeast microbodies contain beta-oxidation system of fatty acid, and that catalase located in the organelles participates in the degradation of hydrogen peroxide to be formed at the step of dehydrogenation of acyl-CoA.     

Effects of the anti-lipogenic antibiotic cerulenin on growth and fatty acid composition of n-alkane-utilizingCandida lipolytica

Summary The effects of cerulenin, an anti-lipogenic antibiotic, on the growth and cellular fatty acid composition ofCandida lipolytica were investigated by changing the chain length of n-alkane, the growth substrate. The antibiotic inhibited almost completely the growth of the yeast on glucose, n-undecane and n-dodecane, but partly that on n-tridecane. The yeast growth on longer alkanes, e.g., from n-tetradecane to n-octadecane, was not affected by this antibiotic, indicating that a chain elongation system and/or intact incorporation system predominantly operate in the formation of cellular fatty acids from such longer chain n-alkanes. Comparison of the fatty acid profiles between the cells grown on n-alkanes of different chain lengths, especially on n-pentadecane, in the presence and absence of cerulenin, supported the supposition that only the de novo synthesis system of the yeast would be affected by the antibiotic, whereas the chain elongation system would not.     

Studies on metabolic role of 5′-methylthioadenosine in Ochromonas malhamensis and other microorganisms

Several compounds containing a thiomethyl group were found to replace vitamin B₁₂ in a protozoan, Ochromonas malhamensis. The order of the effectiveness was as follows: 5-methylthioadenosine > S-adenosylmethionine > 5-methylthioribose > L-methionine. A similar order was obtained with respect to the permeability of these compounds into the protozoan cells, except for S-adenosylmethionine. 5-Methylthioadenosine and 5-methylthioribose as well as l-methionine markedly increased the intracellular content of l-methionine. The level of S-adenosylmethionine was also increased by them, but to a lesser degree. The thiomethyl group of the compounds was established to be incorporated into S-adenosylmethionine. The metabolic fate of the thiomethyl group of 5-methylthioadenosine cannot be distinguished from that of l-methionine. A high activity of 5-methylthioadenosine nucleosidase was detected in the cell-free extracts of the protozoan. These results strongly suggest that 5-methylthioadenosine would be metabolized to l-methionine via 5-methylthioribose and then the l-methionine would be converted to S-adenosylmethionine. Like l-methionine and vitamin B₁₂, 5-methylthioadenosine and 5-methylthioribose may play an important role in maintenance of the C-1 pool in Ochromonas malhamensis.Neither 5-methylthioadenosine nor 5-methylthioribose replaced vitamin B₁₂ in some vitamin B₁₂-requiring bacteria. This result is consistent with the fact that neither compounds was significantly taken up by these bacteria.Abbreviations MTA 5-methylthioadenosine - AdoMet S-adenosylmethionine - MTR 5-methylthioribose - TCA trichloroacetic acid Paper II in the series. The first paper of the series has been published (Sugimoto and Fukui, 1974)     

Enzymatic synthesis of poly-β-hydroxybutyrate inZoogloea ramigera

The enzyme activity synthesizing poly--hydroxybutyrate (PHB) was mainly localized in the PHB-containing particulate fraction ofZoogloea ramigera I-16-M, when it grew flocculatedly in a medium supplemented with glucose. On the other hand, the enzyme activity remained in the soluble fraction, when the bacterium grew dispersedly in a glucose-starved medium.The soluble PHB synthase activity became associated with the particulate fraction as PHB synthesis was initiated on the addition of glucose to the dispersed culture. Conversely, the enzyme activity was released from the PHB-containing granules to the soluble fraction when the flocculated culture was kept incubated without supplementing the medium with glucose.PHB synthase was also incorporated into the newly formed PHB fraction when partially purified soluble PHB synthase was incubated withd(-)--hydroxybutyryl CoA in vitro.Although attempts to solubilize the particulate enzyme were unsuccessful, and the soluble enzyme became extremely unstable in advanced stages of purification, both PHB synthases had the same strict substrate specificity ford(-)--hydroxybutyryl CoA, and showed the same pH optimum at 7.0.Non-Standard Abbreviations PHB poly--hydroxybutyrate     

Development of microbodies in Candida tropicalis during incubation in a n-alkane medium

Development of microbodies in Candida tropicalis pK 233 was studied mainly by electron microscopical observation. The yeast cells, precultured on malt extract, scarcely contained microbodies and showed very low catalase activity. When the precultured cells were transferred to a n-alkane medium and incubated with shaking, the number of microbodies increased and concomitantly the activity of catalase was enhanced. That is, both the area ratio of microbodies in the cell and the ratio of microbodies to cytoplasm in area increased significantly during the utilization of n-alkanes for 8 hrs. Localization of catalase in the microbodies was demonstrated cytochemically by use of 3,3'-diaminobenzidine, but other organella in the cell, except for vacuoles appearing in the early growth phase and mitochondria, were not stained with this reagent. Microbodies seemed to grow by division. Biogenesis of microbodies in the yeast cells is also discussed.     

Coenzyme B12-dependent diol dehydrase: purification, subunit heterogeneity, and reversible association.

A purification procedure for diol dehydrase (dl-1,2-propanediol hydro-lyase, EC 4.2.1.28) of Klebsiella pneumoniae (Aerobacter aerogenes) ATCC 8724 has been developed which gives the highest specific activity for this enzyme obtained so far. The purified enzyme is homogeneous by the criteria of ultracentrifugation (s_20,w = 8.9 S) and disc gel electrophoresis in the presence of substrate. The molecular weight of approximately 230,000 was obtained by gel filtration and ultracentrifugal sedimentation equilibrium. The enzyme is composed of components F and S whose molecular weights were determined to be approximately 26,000 and 200,000, respectively, by gel filtration. The incubation of both components F and S with the substrate leads to complete reassociation of the components. Disc gel electrophoresis in the presence of sodium dodecyl sulfate and terminal amino acid analyses indicate that component S consists of at least four nonidentical subunits. The reversible association and heterogeneity of the subunits were also demonstrated with the crude enzyme by immunoelectrophoresis.