Oscar Zaragoza

Protective role of trehalose during severe oxidative stress caused by hydrogen peroxide and the adaptive oxidative stress response in Candida albicans.

The cellular response to the oxidative stress caused by hydrogen peroxide and its putative correlation with the stress protector trehalose was investigated in Candida albicans CAI.4 and the tps1/tps1 double mutant, which is deficient in trehalose synthesis. When exponential wild-type blastoconidia were exposed to high concentrations of hydrogen peroxide, they displayed a high cell survival, accompanied by a marked rise of intracellular trehalose. The latter is due to a moderate activation of trehalose synthase and the concomitant inactivation of neutral trehalase. Identical challenge in the tps1/tps1 double mutant severely reduced cell viability, a phenotype which was suppressed by overexpression of the TPS1 gene. Pretreatment of growing cultures from both strains with either a low, non-lethal concentration of H(2)O(2) (0.5 mM) or a preincubation at 37 degrees C, induced an adaptive response that protected cells from being killed by a subsequent exposure to oxidative stress. During these mild oxidative preincubations, trehalose was not induced in CAI.4 cells and remained undetectable in their tps1/tps1 counterpart. Blastoconidia from the two strains exhibited a similar degree of cell protection during the adaptive response. The induction of trehalose accumulation by H(2)O(2) was not due to an increased expression of TPS1 mRNA. These results are consistent with a mainly protective role of trehalose in C. albicans during direct oxidative stress but not during acquired oxidative tolerance.

Disruption in Candida albicans of the TPS2 gene encoding trehalose-6-phosphate phosphatase affects cell integrity and decreases infectivity

The gene CaTPS2 encoding trehalose-6-phosphate (T6P) phosphatase from Candida albicans has been cloned and disrupted in this organism. The Catps2/Catps2 mutant did not accumulate trehalose but accumulated high levels of T6P. Disruption of the two copies of the CaTPS2 gene did not abolish growth even at 42 degrees C, but decreased the growth rate. In the stationary phase, the Catps2/Catps2 mutant aggregated, more than 50% of its cells became permeable to propidium iodide and a large amount of protein was found in the culture medium. Aggregation occurred only at pH values higher than 7 and was avoided by osmoprotectants; it was never observed during the exponential phase of growth. The mutant formed colonies with a smooth border on Spider medium. Mice inoculated with 1.5 x 10(6) c.f.u. of wild-type cells died after 8 days, while 80% of those inoculated with the same number of c.f.u. of the Catps2/Catps2 mutant survived for at least 1 month. Reintroduction of the wild-type CaTPS2 gene in the Catps2/Catps2 mutant abolished the phenotypes described. It is hypothesized that the accumulation of T6P interferes with the assembly of a normal cell wall.

Pseudohyphal growth is induced in Saccharomyces cerevisiae by a combination of stress and cAMP signalling.

In Saccharomyces cerevisiae pseudohyphae formation may be triggered by nitrogen deprivation and is stimulated by cAMP. It was observed that even in a medium with an adequate nitrogen supply, cAMP can induce pseudohyphal growth when S. cerevisiae uses ethanol as carbon source. This led us to investigate the effects of the carbon source and of a variety of stresses on yeast morphology. Pseudohyphae formation and invasive growth were observed in a rich medium (YP) with poor carbon sources such as lactate or ethanol. External cAMP was required for the morphogenetic transition in one genetic background, but was dispensable in strain Σ1278b which has been shown to have an overactive Ras2/cAMP pathway. Pseudohyphal growth and invasiveness also took place in YPD plates when the yeast was subjected to different stresses: a mild heat-stress (37 °C), an osmotic stress (1 m NACl), or addition of compounds which affect the lipid bilayer organization of the cell membrane (aliphatic alcohols at 2%) or alter the glucan structure of the cell wall (Congo red). We conclude that pseudohyphal growth is a physiological response not only to starvation but also to a stressful environment; it appears to require the coordinate action of a MAP kinase cascade and a cAMP-dependent pathway.

Isolation of the MIG1 gene from Candida albicans and effects of its disruption on catabolite repression.

We have cloned a Candida albicans gene (CaMIG1) that encodes a protein homologous to the DNA-binding protein Mig1 from Saccharomyces cerevisiae (ScMig1). The C. albicans Mig1 protein (CaMig1) differs from ScMig1, in that, among other things, it lacks a putative phosphorylation site for Snf1 and presents several long stretches rich in glutamine or in asparagine, serine, and threonine and has the effector domain located at some distance (50 amino acids) from the carboxy terminus. Expression of CaMIG1 was low and was similar in glucose-, sucrose-, or ethanol-containing media. Disruption of the two CaMIG1 genomic copies had no effect in filamentation or infectivity. Levels of a glucose-repressible alpha-glucosidase, implicated in both sucrose and maltose utilization, were similar in wild-type or mig1/mig1 cells. Disruption of CaMIG1 had also no effect on the expression of the glucose-repressed gene CaGAL1. CaMIG1 was functional in S. cerevisiae, as judged by its ability to suppress the phenotypes produced by mig1 or tps1 mutations. In addition, CaMig1 formed specific complexes with the URS1 region of the S. cerevisiae FBP1 gene. The existence of a possible functional analogue of CaMIG1 in C. albicans was suggested by the results of band shift experiments.

Elements from the cAMP signaling pathway are involved in the control of expression of the yeast gluconeogenic gene FBP1

cAMP represses the transcription of some Saccharomyces cerevisiae genes sensitive to catabolite repression. The effect of cAMP on the expression of FBP1, encoding fructose‐1,6‐bisphosphatase (FbPase), has been further investigated. In yeast cells shifted to a derepressing medium, synthesis of FbPase was delayed if the strong decrease in intracellular cAMP, which occurs during the shift, was prevented. A similar delay occurred in a RAS2val19 strain, while in a tpk1w strain, with weak protein kinase A activity, induction of FbPase occurred earlier than in a TPK1 strain. In the tpk1w strain, proteins which bind the UAS1 element of FBP1 were present during growth on glucose but they were only weakly operative. Expression of CAT8 and SIP4, encoding proteins which bind the UAS2 element, was blocked by a high concentration of cAMP, but catabolite repression of these genes was not much relieved in a tpk1w strain. We conclude that in S. cerevisiae, as reported for Schizosaccharomyces pombe, control of FBP1 requires both cAMP‐dependent and independent pathways; however, the mechanisms operating in the two yeasts are different.

Generation of disruption cassettes in vivo using a PCR product and Saccharomyces cerevisiae.

A method to obtain disruption cassettes based on the homologous recombination in Saccharomyces cerevisiae is described. The disruption marker is amplified by PCR using oligonucleotides containing 50 bp homologous to the disruptable gene and 20 bp from the marker. The PCR product is cotransformed into yeast with a plasmid containing the gene. After recombination, a plasmid that carries the disruption cassette for the gene is produced.

Functional analysis of upstream activating elements in the promoter of the FBP1 gene from Saccharomyces cerevisiae.

Abstract We have investigated the effect of different carbon sources and of different mutations on the capacity of two elements, UAS1 and UAS2, from the promoter of the FBP1 gene to form specific DNA-protein complexes and to activate expression of a reporter gene. The complexes are observed with nuclear extracts from yeast derepressed on glycerol or ethanol. When hxk2 mutants are grown on glucose the nuclear extracts are able to complex UAS1 but not UAS2, while for wild-type cells grown on galactose only the complex with UAS2 is formed. In contrast, in vivo the operation of both UASs is high in ethanol, moderate to low in glycerol, and negligible in galactose; no expression is observed in glucose even in a hxk2 background. There is no effect of a MIG1 deletion, either in the formation of DNA-protein complexes or on the expression of reporter genes.