Transglycosyl-Amylase of Candida tropicalis

Transglucosyl-amylase was purified 96-fold and partially characterized. The K_m value with dextrin as substrate was 9.1 mg/ml. Glycerol, an acceptor of d-glucose, appeared to inhibit dextrin hydrolysis noncompetitively. The energy of activation of the enzyme was 7,920 cal/mole. Indirect determinations showed that synthesis of d-glucosyl glycerol was significantly affected by the nature of the amylaceous substrate. Glucosyl-glycerol synthesis did not increase as incubation temperature was raised from 50 to 60 C. Direct determinations by gas-liquid chromatography indicated that the synthesis of glucosyl glycerol, as a function of the concentration of either enzyme, substrate, or glycerol, traced a curvilinear path approaching 15 mg/ml as the maximum. When enzyme, substrate, and glycerol at high concentrations were varied in all possible combinations, however, conditions for producing as much as 47.5 mg/ml of glucosyl glycerol were established.     

热带假丝酵母产生子囊孢子的条件及单倍体分离的研究

本文研究了诱导热带假丝酵母子囊孢子产生和子囊破壁的条件,以及单倍体分离和鉴别方法.结果表明:NaAc、KCl这两种成分即可满足热带假丝酵母的产孢营养要求,在含有NaAc 8.2 g/L、KCl 1.8 g/L的琼脂培养基中,28℃培养7 d,热带假丝酵母细胞的产孢率可达到47.5%;单纯使用蜗牛酶对破除热带假丝酵母子囊壁的效率甚低,酶解液加入适量的石英砂同时振荡处理4 h左右,可以显著提高对热带假丝酵母子囊破壁速率.用这种方法处理,绝大多数子囊壁均可破除.子囊破壁处理后再以52℃处理10 min杀死残余的营养体细胞,分离物的单倍体孢子比例可由灭活处理前的48%,提高到76%以上.     

Trnasglucosyl-amylase of Candida tropicalis

Transglucosyl-amylase was purified 96-fold and partially characterized. The K(m) value with dextrin as substrate was 9.1 mg/ml. Glycerol, an acceptor of d-glucose, appeared to inhibit dextrin hydrolysis noncompetitively. The energy of activation of the enzyme was 7,920 cal/mole. Indirect determinations showed that synthesis of d-glucosyl glycerol was significantly affected by the nature of the amylaceous substrate. Glucosyl-glycerol synthesis did not increase as incubation temperature was raised from 50 to 60 C. Direct determinations by gas-liquid chromatography indicated that the synthesis of glucosyl glycerol, as a function of the concentration of either enzyme, substrate, or glycerol, traced a curvilinear path approaching 15 mg/ml as the maximum. When enzyme, substrate, and glycerol at high concentrations were varied in all possible combinations, however, conditions for producing as much as 47.5 mg/ml of glucosyl glycerol were established.     

n-Alkane oxidation byCandida tropicalis

Summary The specific activity of the enzyme catalase was investigated in batch cultures ofCandida tropicalis on the following substrates: Gelsenberg 14/18, n-hexandecane, 1-octadecene, oleyl alcohol, oleic acid and glucose. The catalase activity does not change with the different oxidation levels of the hydrocarbon substrates. A correlation between specific activity and growth rate was established.Inhibition experiments with 2-amino-1,3,4-triazol (AT), a specific catalase inhibitor, gave no evidence for two kinds of hydrogen peroxide-degrading enzymes in yeast cells.Growth on hydrocarbons instead of on glucose enhanced the specific activities of both isocitratelyase (ICL) and catalase to about the same extent.On the other hand the succinate-cytochrome C-oxidoreductase, a mitochondrial enzyme, showed more or less the same activity on both substrates.All these facts suggest that the catalase enzyme is related to the degradation (- or -oxidation) or to the gluconeogenesis (glyoxylate cycle) of fatty acids, but not to the initial oxidation of the alkanes.     

Decoding development in Xenopus tropicalis

Xenopus tropicalis is rapidly being adopted as a model organism for developmental biology research and has enormous potential for increasing our understanding of how embryonic development is controlled. In recent years there has been a well-organized initiative within the Xenopus community, funded largely through the support of the National Institutes of Health in the US, to develop X. tropicalis as a new genetic model system with the potential to impact diverse fields of research. Concerted efforts have been made both to adapt established methodologies for use in X. tropicalis and to develop new techniques. A key resource to come out of these efforts is the genome sequence, produced by the US Department of Energy's Joint Genome Institute and made freely available to the community in draft form for the past three years. In this review, we focus on how advances in X. tropicalis genetics coupled with the sequencing of its genome are likely to form a foundation from which we can build a better understanding of the genetic control of vertebrate development and why, when we already have other vertebrate genetic models, we should want to develop genetic analysis in the frog.     

The Blomia tropicalis allergens

Blomia tropicalis allergens are the most important mite allergens in tropical regions. Most of them only have 30-40% sequence identity with their Dermatophagoides counterparts and they share low IgE cross reactivity and exhibit different immunobiology. Unlike the pyroglyphid counterparts, Blo t 5 is the major allergen whereas Blo t 1 only has modest allergenicity.     

Acyl-CoA oxidase from Candida tropicalis

The preparation of a highly purified acyl-CoA oxidase from the cell extract of an n-alkane-utilizing yeast, Candida tropicalis, is described. It can be crystallized from ammonium sulfate solutions without an increase in specific activity, and is homogeneous on ultracentrifuge and disc electrophoresis. The enzyme is an octamer with approximately a 600,000 molecular weight, and has an isoelectric point of 5.5. It exhibits a typical flavoprotein spectrum with absorption maxima at 277, 365 and 445 nm, and contains 8 mol of FAD per mol of enzyme. The enzyme catalyzes the stoichiometric conversion of palmitoyl-CoA and O₂ into 2-hexadecenoyl-CoA and H₂O₂. It oxidizes acyl-CoAs with carbon chain lengths of 4 to 20, and is most active toward lauroyl-CoA, but acetyl- and succinyl-CoAs are not oxidized. The enzyme is sulfhydryl dependent and is inactivated by silver and mercury compounds.     

Characteristics of trehalase inCandida tropicalis

Summary The trehalase content of different yeasts varies widely. A strain ofCandida tropicalis was found to be the best source of this enzyme among the yeasts tested. The trehalase activity in this yeast could be increased 8.5 times by growing it on trehalose rather than glucose. Thus trehalase is an adaptive enzyme inC. tropicalis. It was found that the amount of trehalase which could be solubilized increased with increasing pH during autolysis of the cells, none being released from the cell debris at pH 4.5 and most at pH 6.3. Some evidence was obtained to show that the solubilization was caused by an enzyme. The stability of trehalase under various conditions was studied. A partial purification was achieved by precipitation with 40% ethanol at a temperature of −18°C. The maximum temperature of the enzyme was 48°C., and the optimum pH ranged from 4.1 to 5.3     

Phagocyte-mediated killing of Candida tropicalis

Human peripheral monocytes (MO), neutrophils (PMN), and lymphocytes (PBL) were tested for their ability to kill Candida tropicalis. With incubation times between 30 min and 2 h, unstimulated MO and PMN, but not PBL, were efficient killers of C. tropicalis. Both leukocyte subsets were able to kill at minimum 2.5 1 effector to target ratios. Pre-incubation of MO for 24 h with interferon-gamma or tumor necrosis factor (TNF) increased their ability to kill yeast targets. TNF alone had no effect on C. tropicalis targets at concentrations up to 1000 U/ml. PBL activated for 4 d with interleukin-2 did not kill yeast targets. PMN exhibited more cytocidal efficiency per cell than MO in these assays. Direct contact of effectors and targets was required; no significant killing by PMN or MO supernatants was measured. PMN-mediated killing, but not MO killing, was inhibited by a mixture of catalase and Superoxide dismutase suggesting that oxygen-dependent killing mechanisms were partially responsible for candidacidal activity.     

Isolation of Candida tropicalis auxotrophic mutants

An enrichment scheme using nystatin was designed for the isolation of auxotrophic mutants from the diploid-alkane-utilizing yeast Candida tropicalis. A collection of 194 auxotrophs representing 7 phenotypes was isolated. One class of mutants was identified as having a defect in histidinol dehydrogenase activity and a second class of mutants was identified as having a defect in orotidine monophosphate decarboxylase activity. These strains are good candidates to be carrying mutations corresponding to the HIS4 and URA3 genes of Saccharomyces cerevisiae.     

Interaction of nystatin with nystatin-resistantCandida tropicalis

Nystatin-resistant yeast Candida tropicalis was obtained after UV illumination and plating on nystatin-containing media. The mutant contained no ergosterol in the plasma membrane but bound nystatin to a degree similar to that of the wild strain (1.2 vs. 1.5 nmol per mg dry solid). Respiration of the mutant on glucose was reduced by 36% in the presence of 25 microM nystatin. This corresponded to a 25-43% decrease of the uptake of monosaccharides. Transport of amino acids was reduced by nystatin in the mutant by 44-86%, as compared with a 84-95% reduction in the wild strain. The intracellular ATP content was reduced by nystatin equally in the wild strain and in the mutant (by 43 and 47%). Nystatin appears to affect specifically membrane transport processes of nonelectrolytes while both the H+-extruding ATPase and the membrane potential are unaffected.     

Acyl-CoA oxidase from Candida tropicalis

Acyl coenzyme A oxidase (acyl-CoA oxidase) has been isolated in good yield from Candida tropicalis pK 233 grown on n-alkanes. Gel filtration, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and measurement of flavin content suggest that the oxidase is an octamer of Mr 75 000 subunits each containing one flavin. The oxidase yields the red semiquinone form on dithionite or photochemical reduction, slowly forms an N-5 adduct with 0.16 M sulfite at pH 7.4, and is rapidly reduced by borohydride, forming the 3,4-dihydroflavin isomer. The red flavosemiquinone is only kinetically stabilized with respect to disproportionation in the free enzyme but is thermodynamically stabilized on binding enoyl-CoA derivatives. The enzyme is reduced by butyryl-, octanoyl-, and palmitoyl-CoA without formation of prominent long-wavelength bands. Acyl-CoA oxidase and the acyl-CoA dehydrogenases share many similarities in their interaction with CoA derivatives. For example, both enzymes stabilize the anionic radical on binding enoyl-CoA derivatives, both dehydrogenate 2-oxoheptadecyldethio-CoA but cannot utilize S-heptadecyl-CoA, both form long-wavelength bands with CoA persulfide species, and both enzymes are attacked by the suicide substrates 3,4-pentadienoyl-CoA and (methylene-cyclopropyl)acetyl-CoA at the flavin prosthetic group.     

A genetic map of Xenopus tropicalis

Posttranslational modifications constitute a major field of emerging biological significance as mounting evidence demonstrates their key role in multiple physiological processes. Following in the footsteps of protein phosphorylation studies, new modifications are being shown to regulate protein properties and functions in vivo. Among such modifications, an important role belongs to protein arginylation — posttranslational tRNA-mediated addition of arginine, to proteins by arginyltransferase, ATE1. Recent studies show that arginylation is essential for embryogenesis in many organisms and that it regulates such important processes as heart development, angiogenesis, and tissue morphogenesis in mammals. This review summarizes the key data in the protein arginylation field since its original discovery to date.     

Parasexuality and Ploidy Change in Candida tropicalis

Candida species exhibit a variety of ploidy states and modes of sexual reproduction. Most species possess the requisite genes for sexual reproduction, recombination, and meiosis, yet only a few have been reported to undergo a complete sexual cycle including mating and sporulation. Candida albicans, the most studied Candida species and a prevalent human fungal pathogen, completes its sexual cycle via a parasexual process of concerted chromosome loss rather than a conventional meiosis. In this study, we examine ploidy changes in Candida tropicalis, a closely related species to C. albicans that was recently revealed to undergo sexual mating. C. tropicalis diploid cells mate to form tetraploid cells, and we show that these can be induced to undergo chromosome loss to regenerate diploid forms by growth on sorbose medium. The diploid products are themselves mating competent, thereby establishing a parasexual cycle in this species for the first time. Extended incubation (>120 generations) of C. tropicalis tetraploid cells under rich culture conditions also resulted in instability of the tetraploid form and a gradual reduction in ploidy back to the diploid state. The fitness levels of C. tropicalis diploid and tetraploid cells were compared, and diploid cells exhibited increased fitness relative to tetraploid cells in vitro, despite diploid and tetraploid cells having similar doubling times. Collectively, these experiments demonstrate distinct pathways by which a parasexual cycle can occur in C. tropicalis and indicate that nonmeiotic mechanisms drive ploidy changes in this prevalent human pathogen.     

Process of Candida tropicalis adaptation to L-arabinose

When biotin (an essential growth factor) is removed from the mineral Rieder medium, a mutation process is induced, particularly, if a nutrition source (glucose) is present in the medium. Hence, a mutation process can be induced under the conditions of an unbalanced 'organism--medium' system.     

Microbial transformation of primaquine by Candida tropicalis

The microbial metabolism of primaquine, a 6-methoxy-8-aminoquinoline antimalarial agent, was investigated. The yeast Candida tropicalis was found to convert primaquine to the previously reported N-acetylated derivative. On continued incubation of C. tropicalis in the presence of the N-acetylated derivative, a minor dimeric metabolite was formed. The proposed structure of the metabolite was based primarily on the analysis of its spectroscopic properties (1H and 13C nuclear magnetic resonance spectra and field-desorption mass spectrum). The structure of the metabolite was proven by direct comparison with an authentic sample of the minor dimeric metabolite prepared by treatment of the N-acetylated derivative with formaldehyde in the presence of formic acid in methanol.