Ibuprofen reverts antifungal resistance on Candida albicans showing overexpression of CDR genes

Several mechanisms may be associated with Candida albicans resistance to azoles. Ibuprofen was described as being able to revert resistance related to efflux activity in Candida . The aim of this study was to uncover the molecular base of antifungal resistance in C. albicans clinical strains that could be reverted by ibuprofen. Sixty-two clinical isolates and five control strains of C. albicans were studied: the azole susceptibility phenotype was determined according to the Clinical Laboratory for Standards Institute, M27-A2 protocol and minimal inhibitory concentration values were recalculated with ibuprofen (100 μg mL⁻¹); synergistic studies between fluconazole and FK506, a Cdr1p inhibitor, were performed using an agar disk diffusion assay and were compared with ibuprofen results. Gene expression was quantified by real-time PCR, with and without ibuprofen, regarding CDR1 , CDR2 , MDR1 , encoding for efflux pumps, and ERG11 , encoding for azole target protein. A correlation between susceptibility phenotype and resistance gene expression profiles was determined. Ibuprofen and FK506 showed a clear synergistic effect when combined with fluconazole. Resistant isolates reverting to susceptible after incubation with ibuprofen showed CDR1 and CDR2 overexpression especially of the latter. Conversely, strains that did not revert displayed a remarkable increase in ERG11 expression along with CDR genes. Ibuprofen did not alter resistance gene expression significantly ( P >0.05), probably acting as a Cdrp blocker.     

The Absence of PDR16 Gene Restricts the Overexpression of CaSNQ2 Gene in the Presence of Fluconazole in Candida albicans

In yeast, the PDR16 gene encodes one of the PITP proteins involved in lipid metabolism and is regarded as a factor involved in clinical azole resistance of fungal pathogens. In this study, we prepared Candida albicans CaPDR16/pdr16Δ and Capdr16Δ/Δ heterozygous and homozygous mutant strains and assessed their responses to different stresses. The CaPDR16 deletion strains exhibited increased susceptibility to antifungal azoles and acetic acid. The addition of Tween80 restored the growth of Capdr16 mutants in the presence of azoles. However, the PDR16 gene deletion has not remarkable influence on sterol profile or membrane properties (membrane potential, anisotropy) of Capdr16Δ and Capdr16Δ/Δ mutant cells. Changes in halotolerance of C. albicans pdr16 deletion mutants were not observed. Fluconazole treatment leads to increased expression of ERG genes both in the wild-type and Capdr16Δ and Capdr16Δ/Δ mutant cells, and the amount of ergosterol and its precursors remain comparable in all three strains tested. Fluconazole treatment induced the expression of ATP-binding cassette transporter gene CaSNQ2 and MFS transporter gene CaTPO3 in the wild-type strain but not in the Capdr16Δ and Capdr16Δ/Δ mutants. The expression of CaSNQ2 gene markedly increased also in cells treated with hydrogen peroxide irrespective of the presence of CaPdr16p. CaPDR16 gene thus belongs to genes whose presence is required for full induction of CaSNQ2 and CaTPO3 genes in the presence of fluconazole in C. albicans.

     

Heterozygosity and functional allelic variation in the Candida albicans efflux pump genes CDR1 and CDR2

Elevated expression of the plasma membrane drug efflux pump proteins Cdr1p and Cdr2p was shown to accompany decreased azole susceptibility in Candida albicans clinical isolates. DNA sequence analysis revealed extensive allelic heterozygosity, particularly of CDR2. Cdr2p alleles showed different abilities to transport azoles when individually expressed in Saccharomyces cerevisiae. Loss of heterozygosity, however, did not accompany decreased azole sensitivity in isogenic clinical isolates. Two adjacent non-synonymous single nucleotide polymorphisms (NS-SNPs), G1473A and I1474V in the putative transmembrane (TM) helix 12 of CDR2, were found to be present in six strains including two isogenic pairs. Site-directed mutagenesis showed that the TM-12 NS-SNPs, and principally the G1473A NS-SNP, contributed to functional differences between the proteins encoded by the two Cdr2p alleles in a single strain. Allele-specific PCR revealed that both alleles were equally frequent among 69 clinical isolates and that the majority of isolates (81%) were heterozygous at the G1473A/I1474V locus, a significant (P < 0.001) deviation from the Hardy-Weinberg equilibrium. Phylogenetic analysis by maximum likelihood (Paml) identified 33 codons in CDR2 in which amino acid allelic changes showed a high probability of being selectively advantageous. In contrast, all codons in CDR1 were under purifying selection. Collectively, these results indicate that possession of two functionally different CDR2 alleles in individual strains may confer a selective advantage, but that this is not necessarily due to azole resistance.     

RTA2, a novel gene involved in azole resistance in Candida albicans

Widespread and repeated use of azoles, particularly fluconazole, has led to the rapid development of azole resistance in Candida albicans. Overexpression of CDR1, CDR2, and CaMDR1 has been reported contributing to azole resistance in C. albicans. In this study, hyper-resistant C. albicans mutant, with the above three genes deleted, was obtained by exposure to fluconazole and fluphenezine for 28 passages. Thirty-five differentially expressed genes were identified in the hyper-resistant mutant by microarray analysis; among the 13 up-regulated genes, we successfully constructed the rta2 and ipf14030 null mutants in C. albicans strain with deletions of CDR1, CDR2 and CaMDR1. Using spot dilution assay, we demonstrated that the disruption of RTA2 increased the susceptibility of C. albicans to azoles while the disruption of IPF14030 did not influence the sensitivity of C. albicans to azoles. Meanwhile, we found that ectopic overexpression of RTA2 in C. albicans strain with deletions of CDR1, CDR2 and CaMDR1 conferred resistance to azoles. RTA2 expression was found elevated in clinical azole-resistant isolates of C. albicans. In conclusion, our findings suggest that RTA2 is involved in the development of azole resistance in C. albicans.     

The ATP-binding cassette transporter-encoding gene CgSNQ2 is contributing to the CgPDR1-dependent azole resistance of Candida glabrata

Our previous investigation on Candida glabrata azole-resistant isolates identified two isolates with unaltered expression of CgCDR1 / CgCDR2 , but with upregulation of another ATP-binding cassette transporter, CgSNQ2 , which is a gene highly similar to ScSNQ2 from Saccharomyces cerevisiae. One of the two isolates (BPY55) was used here to elucidate this phenomenon. Disruption of CgSNQ2 in BPY55 decreased azole resistance, whereas reintroduction of the gene in a CgSNQ2 deletion mutant fully reversed this effect. Expression of CgSNQ2 in a S. cerevisiae strain lacking PDR5 mediated not only resistance to azoles but also to 4-nitroquinoline N -oxide, which is a ScSNQ2 -specific substrate. A putative gain-of-function mutation, P822L, was identified in CgPDR1 from BPY55. Disruption of CgPDR1 in BPY55 conferred enhanced azole susceptibility and eliminated CgSNQ2 expression, whereas introduction of the mutated allele in a susceptible strain where CgPDR1 had been disrupted conferred azole resistance and CgSNQ2 upregulation, indicating that CgSNQ2 was controlled by CgPDR1 . Finally, CgSNQ2 was shown to be involved in the in vivo response to fluconazole. Together, our data first demonstrate that CgSNQ2 contributes to the development of CgPDR1 -dependent azole resistance in C. glabrata . The overlapping in function and regulation between CgSNQ2 and ScSNQ2 further highlight the relationship between S. cerevisiae and C. glabrata .     

The Candida albicans Cdr2p ATP-binding cassette (ABC) transporter confers resistance to caspofungin

Multidrug resistance may pose a serious problem to antifungal therapy. The Candida albicans Cdr2p is one of two ATP-binding cassette (ABC) transporters mediating antifungal resistance in vivo through increased drug efflux. Echinocandins such as caspofungin represent the newest class of antifungals that target cell wall synthesis. We show here by agar plate resistance assays that cross-resistant clinical isolates of C. albicans display high minimal inhibitory concentrations (MICs) to caspofungin when compared with a sensitive ATCC reference strain. Northern analysis and immunoblotting indicate that these isolates also show high levels of CDR1 and CDR2 expression. To determine a possible contribution of Cdr1p or Cdr2p to caspofungin resistance, we have functionally expressed Cdr1p and Cdr2p in appropriate recipient strains of the yeast Saccharomyces cerevisiae. Yeast cells expressing Cdr1p or Cdr2p exhibit cross-resistance to established antifungal drugs such as azoles and terbinafine. However, Cdr2p and, to a much lesser extent, Cdr1p confer caspofungin hyper-resistance when expressed in yeast. Likewise, Cdr2p confers caspofungin resistance when constitutively overexpressed in a drug-sensitive C. albicans strain. We therefore propose that Cdr2p may contribute to clinical candin resistance. Finally, our data suggest that cross-resistance phenotypes of clinical isolates are the consequence of distinct mechanisms that may operate simultaneously.     

Mechanisms of antifungal resistance

The many drugs that are available at present to treat fungal infections can be divided into four broad groups on the basis of their mechanism of action. These antifungal agents either inhibit macromolecule synthesis (flucytosine), impair membrane barrier function (polyenes), inhibit ergosterol synthesis (allylamines, thiocarbamates, azole derivatives, morpholines), or interact with microtubules (griseofulvin). Drug resistance has been identified as the major cause of treatment failure among patients treated with flucytosine. A lesion in the UMP-pyrophosphorylase is the most frequent clinical determinant of resistance to 5FC in Candida albicans. Despite extensive use of polyene antibiotics for more than 30 years, emergence of acquired resistance seems not be a significant clinical problem. Polyene-resistant Candida isolates have a marked decrease in their ergosterol content. Acquired resistance to allylamines has not been reported from human pathogens, but, resistant phenotypes have been reported for variants of Saccharomyces cerevisiae and of Ustilago maydis. Tolerance to morpholines is seldom found. Intrinsic resistance to griseofulvin is due to the absence of a prolonged energy-dependent transport system for this antibiotic. Resistance to azole antifungal agents is known to be exceptional, although it does now appear to be increasing in importance in some groups of patients infected with e.g. Candida spp., Histoplasma capsulatum or Cryptococcus neoformans. For example, resistance to fluconazole is emerging in C. albicans, the major agent of oro-pharyngeal candidosis in AIDS patients, after long-term suppressive therapy. In the majority of cases, primary and secondary resistance to fluconazole and cross-resistance to other azole antifungal agents seems to originate from decreased intracellular accumulation of the azoles, which may result from reduced uptake or increased efflux of the molecules. In most C. albicans isolates the decreased intracellular levels can be correlated with enhanced azole efflux, a phenomenon linked to an increase in the amounts of mRNA of a C. albicans ABC transporter gene CDR1 and of a gene (BEN(r) or CaMDR) coding for a transporter belonging to the class of major facilitator multidrug efflux transporters. Not only fluconazole, ketoconazole and itraconazole are substrates for CDR1, terbinafine and amorolfine have also been established as substrates, BEN(r) overexpression only accounts for fluconazole resistance. Other sources of resistance: changes in membrane sterols and phospholipids, altered or overproduced target enzyme(s) and compensatory mutations in the Delta5,6-desaturase.     

Expression of the CDR1 efflux pump in clinical Candida albicans isolates is controlled by a negative regulatory element

Resistance to azole antifungal drugs in clinical isolates of the human fungal pathogen Candida albicans is often caused by constitutive overexpression of the CDR1 gene, which encodes a multidrug efflux pump of the ABC transporter superfamily. To understand the relevance of a recently identified negative regulatory element (NRE) in the CDR1 promoter for the control of CDR1 expression in the clinical scenario, we investigated the effect of mutation or deletion of the NRE on CDR1 expression in two matched pairs of azole-sensitive and resistant clinical isolates of C. albicans. Expression of GFP or lacZ reporter genes from the wild type CDR1 promoter was much higher in the azole-resistant C. albicans isolates than in the azole-susceptible isolates, reflecting the known differences in CDR1 expression in these strains. Deletion or mutation of the NRE resulted in enhanced reporter gene expression in azole-sensitive strains, but did not further increase the already high CDR1 promoter activity in the azole-resistant strains. In agreement with these findings, electrophoretic mobility shift assays showed a reduced binding to the NRE of nuclear extracts from the resistant C. albicans isolates as compared with extracts from the sensitive isolates. These results demonstrate that the NRE is involved in maintaining CDR1 expression at basal levels and that this repression is overcome in azole-resistant clinical C. albicans isolates, resulting in constitutive CDR1 overexpression and concomitant drug resistance.     

Engineered bakers yeast as a sensitive bioassay indicator organism for the trichothecene toxin deoxynivalenol

The aim of this study was to increase the sensitivity of Saccharomyces cerevisiae towards trichothecene toxins, in particular to deoxynivalenol (DON), in order to improve the utility of this yeast as a bioassay indicator organism. We report the construction of a strain with inactivated genes (PDR5, PDR10, PDR15) encoding ABC transporter proteins with specificity for the trichothecene deoxynivalenol, with inactivated AYT1 (encoding a trichothecene-3-O-acetyltransferase), and inactivated UBI4 and UBP6 genes. Inactivation of the stress inducible polyubiquitin gene UBI4 or the ubiquitin protease UBP6 increased DON sensitivity, the inactivation of both genes had a synergistic effect. The resulting pdr5 pdr10 pdr15 ayt1 ubp6 ubi4 mutant strain showed 50% growth inhibition at a DON concentration of 5 mg/l under optimal conditions. The development of a simple two step assay for microbial DON degradation in 96 well microtiter format and its testing with the DON detoxifying bacterium BBSH 797 is reported.