Your search keyword '"Bergès T"' showing total 4 results

1. Hypersusceptibility to azole antifungals in a clinical isolate of Candida glabrata with reduced aerobic growth.

Author

Vandeputte P, Tronchin G, Rocher F, Renier G, Bergès T, Chabasse D, and Bouchara JP

Subjects

Adult, Aerobiosis, Candida glabrata metabolism, Candida glabrata ultrastructure, Chromatography, High Pressure Liquid, Ergosterol metabolism, Female, Flow Cytometry, Genes, Fungal genetics, Genes, Fungal physiology, Humans, Microbial Sensitivity Tests, Microscopy, Electron, Transmission, Molecular Sequence Data, Polyenes pharmacology, Antifungal Agents pharmacology, Azoles pharmacology, Candida glabrata drug effects, Candida glabrata growth & development

Abstract

Petite mutations have been described in Saccharomyces cerevisiae and pathogenic yeasts. However, previous studies of the phenotypic traits of these petite mutants reported that they express azole resistance. We describe a clinical isolate of Candida glabrata with a striking association between increased susceptibility to azoles and respiratory deficiency. This isolate was obtained from a urine sample together with a respiration-competent C. glabrata isolate which exhibited azole resistance. The respiratory status of the two isolates was confirmed by cultivation on glycerol-containing agar and oxygraphy. Flow cytometry revealed the normal incorporation of rhodamine 123, and mitochondrial sections with typical cristae were seen by transmission electron microscopy for both isolates. Together, these results suggested a nuclear origin for the reduced respiratory capacity of the hypersusceptible isolate. The sterol contents of these isolates were similar to the sterol content of a reference strain. Sequencing of the ERG11 and PDR1 genes revealed that the sequences were identical in the two isolates, demonstrating their close relatedness. In addition to silent mutations, they carried a nonsense mutation in PDR1 that led to the truncation of transcription factor Pdr1p. They also overexpressed both PDR1 and one of its targets, CDR1, providing a possible explanation for the azole resistance of the respiration-competent isolate. In conclusion, in addition to azole resistance, which is a common feature of C. glabrata mitochondrial petite mutants, the mutation of a nuclear gene affecting aerobic growth may lead to azole hypersusceptibility; however, the mechanisms underlying this phenotype remain to be determined.

Published

2009

2. Mechanisms of azole resistance in a clinical isolate of Candida tropicalis.

Author

Vandeputte P, Larcher G, Bergès T, Renier G, Chabasse D, and Bouchara JP

Subjects

Base Sequence, Candida genetics, Candida metabolism, Cytochrome P-450 Enzyme System genetics, Genes, MDR, Humans, Microbial Sensitivity Tests, Molecular Sequence Data, Mutation, Missense, Oxidoreductases genetics, Oxygen Consumption drug effects, Rhodamines metabolism, Sterol 14-Demethylase, Sterols analysis, Azoles pharmacology, Candida drug effects, Drug Resistance, Fungal genetics

Abstract

Azole resistance has been insufficiently investigated in the yeast Candida tropicalis. Here we determined the molecular mechanisms responsible for azole resistance in a clinical isolate of this pathogenic yeast. Antifungal susceptibility testing performed by a disk diffusion method showed resistance or markedly decreased susceptibility to azoles, which was confirmed by determination of MICs. Considering the relationship between azole susceptibility and the respiration reported for other yeast species, the respiratory activity of this isolate was investigated. Flow cytometry using rhodamine 123 and oxygraphy demonstrated an increased respiratory activity, which was not linked to an overexpression or increased number of copies of the mitochondrial genome. Among previously described resistance mechanisms, an increased activity of efflux pumps was investigated by flow cytometry using rhodamine 6G. However, the efflux of rhodamine 6G was lower in the resistant isolate than in susceptible ones. Likewise, real-time reverse transcription-PCR quantification of the expression of C. tropicalis MDR1 (CtMDR1), which encodes an efflux protein belonging to the major facilitator superfamily, did not show overexpression of this gene. In contrast, the resistant isolate overexpressed the CtERG11 gene coding for lanosterol 14alpha-demethylase. This was in agreement with the larger amount of ergosterol found in this isolate. Moreover, sequencing of CtERG11 showed a point mutation leading to a tyrosine substitution in the protein sequence, which might lead to decreased binding affinity for azoles. In conclusion, overexpression of CtERG11 associated with a missense mutation in this gene seemed to be responsible for the acquired azole resistance of this clinical isolate.

Published

2005

3. Mechanisms of azole resistance in petite mutants of Candida glabrata.

Author

Brun S, Bergès T, Poupard P, Vauzelle-Moreau C, Renier G, Chabasse D, and Bouchara JP

Subjects

Blotting, Northern, DNA, Mitochondrial genetics, Drug Resistance, Multiple, Fungal, Flow Cytometry, Fluconazole pharmacology, Fluorescent Dyes, Fungal Proteins metabolism, Membrane Transport Proteins metabolism, Microbial Sensitivity Tests, Microscopy, Electron, Mutation physiology, Rhodamines, Sterols metabolism, Antifungal Agents pharmacology, Azoles pharmacology, Candida albicans drug effects, Candida albicans genetics

Abstract

We previously showed that resistant colonies of Candida glabrata inside the azole inhibition zones had respiratory deficiency due to mutations in mitochondrial DNA. Here, we analyzed the mechanisms of azole resistance in petite mutants of C. glabrata obtained by exposure to fluconazole or induced by ethidium bromide. The respiratory deficiency of these mutants was confirmed by oxygraphy and flow cytometric analysis with rhodamine 123, and its mitochondrial origin was demonstrated by transmission electron microscopy and restriction endonuclease analysis of the mitochondrial DNA. Flow cytometry with rhodamine 6G suggested an increased drug efflux in mutant cells, which was further supported by Northern blot analysis of the expression of the C. glabrata CDR1 (CgCDR1) and CgCDR2 genes, encoding efflux pumps. Conversely, the expression of CgERG11, which encodes the azole target, was not affected by petite mutations, and no differences were seen in the sequence of this gene between parent isolates and mutants. Moreover, sterol analysis showed similar overall amount of sterols in parent and mutant cells, but quantitative modifications were observed in the mutants, with almost undetectable biosynthesis intermediates. Further analysis performed after separation of free sterols from steryl esters revealed a defect in sterol esterification in mutant cells, with free ergosterol representing 92% of the overall sterol content. Thus, resistance or decreased susceptibility to azoles in petite mutants of C. glabrata is associated with increased expression of CgCDR1 and, to a lesser extent, of CgCDR2. In addition, the marked increase in free ergosterol content would explain their increased susceptibility to polyenes.

Published

2004

4. Relationships between respiration and susceptibility to azole antifungals in Candida glabrata.

Author

Brun S, Aubry C, Lima O, Filmon R, Bergès T, Chabasse D, and Bouchara JP

Subjects

Antimetabolites pharmacology, Candida glabrata genetics, Culture Media, DNA, Mitochondrial genetics, Electron Transport drug effects, Enzyme Inhibitors pharmacology, Ethidium pharmacology, Flow Cytometry, Microbial Sensitivity Tests, Microscopy, Electron, Mutation, Sodium Azide pharmacology, Antifungal Agents pharmacology, Azoles pharmacology, Candida glabrata drug effects, Candida glabrata metabolism, Oxygen Consumption drug effects, Oxygen Consumption genetics

Abstract

Over the past two decades, the incidence of infections due to Candida glabrata, a yeast with intrinsic low susceptibility to azole antifungals, has increased markedly. Respiratory deficiency due to mutations in mitochondrial DNA (mtDNA) associated with resistance to azoles frequently occurs in vitro in this species. In order to specify the relationships between respiration and azole susceptibility, the effects of respiratory chain inhibitors on a wild-type isolate of C. glabrata were evaluated. Respiration of blastoconidia was immediately blocked after extemporaneous addition of potassium cyanide, whereas a 4-h preincubation was required for sodium azide. Antifungal susceptibility determined by a disk diffusion method on Casitone agar containing sodium azide showed a significant decrease in the susceptibility to azoles. Biweekly subculturing on Casitone agar supplemented with sodium azide was therefore performed. This resulted after 40 passages in the isolation of a respiration-deficient mutant, as suggested by its lack of growth on glycerol-containing agar. This respiratory deficiency was confirmed by flow cytometric analysis of blastoconidia stained with rhodamine 123 and by oxygraphy. Moreover, transmission electron microscopy and restriction endonuclease analysis of the mtDNA of mutant cells demonstrated the mitochondrial origin of the respiratory deficiency. Finally, this mutant exhibited cross-resistance to all the azoles tested. In conclusion, blockage of respiration in C. glabrata induces decreased susceptibility to azoles, culminating in azole resistance due to the deletion of mtDNA. This mechanism could explain the induction of petite mutations by azole antifungals which have been demonstrated to act directly on the mitochondrial respiratory chain.

Published

2003