Methionine-defective mutants inCandida utilis

Ethionine-resistant mutants ofCandida utilis CCY-158 overproducing methionine have been isolated. In these mutants the intracellular methionine concentration decreased significantly during the stationary phase. The wild-type strain CCY-158 and the ethionine-resistant mutants isolated were able to use methionine as the nitrogen source but not as the carbon source. From these ethionine-resistant mutants we isolated mutants unable to use methionine as nitrogen source (Mec^- mutants), the principal alteration being at the level of methionine uptake. Some of the Mec mutants lost also the ability to use other amino acids as nitrogen source.     

Sulphate transport inCandida utilis

Sulphate uptake byCandida utilis follows Michaelis-Menten type kinetics characterized by a K_m of 1.43 mM for sulphate. The process is unidirectional, pH, temperature and energy dependent. Molybdate, selenate, thiosulphate, chromate and sulphite are competitive inhibitors. Dithionite is a mixed-type inhibitor of sulphate uptake. If cells are pre-incubated with sulphate, sulphite, thiosulphate, dithionite or sulphide, sulphate uptake is severely blocked. Inhibition by endogenous sulphate, sulphite and thiosulphate was specific for sulphate uptake. Thus, incorporation of extracellular sulphate seems to be under the control of a heterogeneous pool of sulphur compounds. These results are discussed in connection with the regulation of sulphur ammo acid biosynthesis inC.utilis.     

Location of monitorial fluorophores inCandida utilis

Summary The fluorescent spectra of whole broth, cell-free broth and resuspended cells were compared during the fermentation ofCandida utilis growing in ethanol for the purposes of identifying the location of monitorial fluorophores in cellular systems. Four cellular fluorophores, tryptophan, pyridoxine, NADH and riboflavin were examined. The results indicated that the fluorescence signal of tryptophan and NADH came mainly from intracellular fluorophores, and the fluorescence signal of pyridoxine and riboflavin mainly came from extracellular fluorophores. The contributions of intracellular and extracellular fluorophores to culture fluorescence signals were found to change during the fermentation.     

Molecular approaches of a mitochondrial mutation inCandida utilis

Analysis of the cytochrome spectra of a mitochondrial mutant ofCandida utilis showed complete absence of apocytochromeb; this suggests a certain degree of damage, probably a small deletion in themit genes of mitochondrial DNA. Oxygen uptake measurements with and without cyanide of the respiratory-competentCandida utilis parent strain and its derivative mitochondrial mutant P_1,2 indicated the absence of the cyanide-sensitive or normal respiratory chain and a lowered rate of cyanide-insensitive or alternate respiration. Mitochondrial profiles and distribution of parental and mutant cells account for an altered mitochondrial DNA which affects mitochondria in the latter cell shape and function. The mutant cells ofCandida utilis were considered asmit ^– mutants from the observations reported here.     

Differential location of regulatory and nonregulatory trehalases inCandida utilis cells

The isolation of vacuoles by density gradient centrifugation of protoplast lysates fromCandida utilis cells showed a high specific activity for nonregulatory trehalase in vacuoles whereas the regulatory trehalase activatable by phosphorylation behaves as a cytoplasmic enzyme. The vacuolar trehalase is a glycoprotein that can be precipitated by Con A-Sepharose. Treatment of this enzyme with endo H reduced its reactivity with the lectin without loss of enzyme activity and decreased its apparent molecular weight by gel filtration.Abbreviations cAMP adenosine 3, 5-cyclic monophosphate - Con A Concanavalin A - CP buffer 10mM sodium citrate-phosphate pH 6.8 - endo H endo--N-acetyl glucosaminidase H - PMSF phenyl-methyl-sulphonylfluoride - PNPG p-nitrophenyl--glucoside - PNPP p-nitrophenyl-phosphate     

A sulfate,sulfite and thiosulfate incorporating system inCandida utilis

Sulfate, sulfite and thiosulfate incorporation in the yeastCandida utilis is inhibited by extracellular sulfate, sulfite and thiosulfate and by sulfate analogues selenate, chromate and molybdate. The three processes are blocked if sulfate, sulfite, thiosulfate, cysteine and homocysteine are allowed to accumulate endogenously. Incorporation of the three inorganic sulfur oxy anions is inactivated by heat at the same rate. Mutants previously shown to be defective in sulfate incorporation are also affected in sulfite and thiosulfate uptake. Revertants of these mutants selected by plating in ethionine-supplemented minimal medium recovered the capacity to incorporate sulfate, sulfite and thiosulfate. These results taken together with previous evidence demonstrate the existence of a common sulfate, sulfite and thiosulfate incorporating system in this yeast.     

Preliminary genetic study inCandida utilis: II. Conditions controlling mating and sporulation

Hybrid formation inCandida utilis was studied by assaying for the formation of prototrophs after mixing different auxotrophic strains. Various physiological conditions were considered following a mathematical experimental design. Parental cells grown in minimal medium up to stationary phase and mated for 16 hours gave the highest yield of prototrophs. The sporulation capacity of hybrid cells was tested under different conditions and was significantly stimulated by acetate. The presence of ascus-like structures in different media, the detection of recombinants among the progeny, and analyses of DNA content in different strains suggest thatC. utilis is a homothallic organism and the hybrids are true diploid cells.     

H+ and K+ fluxes and attendant processes inCandida utilis induced by inhibitory ethanol concentration

In oxygen-aerated non-growing cells a subinhibitory ethanol concentration (1 g/L) causes an H⁺/K⁺ exchange. An inhibitory ethanol concentration (30 g/L) slows down acidification but has no effect on its extent. The transmembrane ΔpH depends directly on the ethanol level in the medium and is not lowered at high ethanol concentrations. Changes in membrane potential induced by ethanol are also concentration dependent. The high ethanol level does not increase the passive permeability of cell membrane to H⁺.     

Specific rate of growth of buds related to the genealogical age of the parent cell inCandida utilis

Specific growth rate, specific rate of oxygen consumption calculated per unit cell mass and substrate consumption were followed during the (S + G2) phase of the cell cycle of Candida utilis, when the cell mass increase occurs due to bud growth. Scar-free cells and cells with one and more scars were investigated. Buds of the mother scar-bearing cells grew more slowly. Oxygen was used up at the same rate, whereas glucose was utilized more rapidly.     

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     

CUG codons inCandida spp.

Codon CUG is used for serine instead of for leucine, its usual assignment, in several yeasts of the genusCandida. We propose a series of steps for the reassignment, including disappearance of leucine CUG and its anticodon CAG, formation of a new serine tRNA, with anticodon CAG, from a duplication of the gene for serine tRNA (IGA), and then production of CUG codons by mutation at sites that are mostly nonessential.     

Ultrastructure of the septum inCandida albicans

The ultrastructure of the septum in the mycelial phase of the dimorphic fungusCandida albicans has been studied both in thin sections of fixed material and in shadow casts of the chemically purified chitinous wall layer. The septum has a 25-nm central micropore which would not allow the passage of nuclei or mitochondria, thus delimiting these organelles within the mycelial compartments without preventing cytoplasmic continuity.      

Uphill transport of monosaccharides inCandida beverwijkii

The yeastCandida beverwijkii was found to transport several monosaccharides against a concentration gradient. The process is mediated by a mobile carrier and shows a pronounced pH dependence. It is tightly coupled with metabolism and only potassium sorbate uncoupled the equilibrating from the active transport component. Kinetic analysis of uptake and efflux at high monosaccharide concentrations indicates an active transport operating either into or out of cells. T. Deák carried out the work in Prague while supported by the Hungarian Academy of Sciences.     

Biosynthesis of major phospholipids inCandida albicans

Biosynthesis of major phospholipids was examined by identifying enzymes and in vitro uptake of specific labeled precursors through various pathways inCandida albicans. The presence of PS synthetase, choline kinase, and ethanolamine kinase was demonstrated in this organism. Phosphatidylcholine was found to be synthesized mainly through cytidine diphosphate-choline (CDP)-choline and methylation pathways. The presence of a methylation pathway was further confirmed by blocking methyltransferases with 2-hydroxyethyl hydrazine. Phosphatidylethanolamine was synthesized by all three, CDP-ethanolamine, Phosphatidylserine (PS)-decarboxylase, and base exchange pathways, while PS was formed by PS-synthetase and base exchange mechanisms.     

Evidence of morphology-specific isozymes inCandida albicans

S-Adenosylmethionine (SAM) synthetase of yeast and hyphal-phase cells of the dimorphic fungusCandida albicans was characterized by kinetic analysis and response to inhibitors. The enzyme from yeast-phase cells has a Km of 0.17 mM for methionine, 0.14 mM for ATP, and is inhibited (in vitro) by dimethyl-sulfoxide, methionine sulfone, and methionine sulfoxide. The hyphal-phase SAM synthetase has a Km of 0.06 mM for methionine, 0.02 mM for ATP, and its activity (in vitro) is enhanced by the substances that inhibit the yeast-phase enzyme. These data strongly suggest that isozymes of SAM synthetase are present inC. albicans and that they are possibly morphology specific. In vivo studies revealed that synthesis of the enzyme is repressed by the addition of methionine to the growth medium and that specific activity of the enzyme increases when intracellular SAM levels are lowered. In addition, it was shown that the increase in specific activity seen during yeast hypha morphogenesis and in yeast cells grown in a methionine-free medium involves de novo protein synthesis.     

Transport kinetics of 6-deoxy-D-glucose inCandida parapsilosis

The strictly aerobic yeastCandida parapsilosis transports the nonmetabolizable monosaccharide 6-deoxy-D-glucose by an active process (inhibition by 2.4-dinitrophenol and other uncouplers but not by iodoacetamide), the accumulation ratio decreasing with increasing substrate concentration. Measured accumulation ratios are in agreement with those predicted from kinetic constants for influx and efflux. Energy for transport is probably required in the translocation step. The maximum rate is temperature-dependent with a transition point at 21 °C. the accumulation ratio is not, The uptake is most active at pH 4.5–8.5. It appears not to involve stoichiometric proton symport. The transport system is shared by D-glucose, D-mannose, D-galactose and possibly maltose but not by fructose, sucrose or pentoses. The apparent half-life of the transport system was 3.5–4 h.