Catechin potentiates the antifungal effect of miconazole in Candida glabrata.

The rising number of invasive fungal infections caused by drug-resistant Candida strains is one of the greatest challenges for the development of novel antifungal strategies. The scarcity of available antifungals has drawn attention to the potential of natural products as antifungals and in combinational therapies. One of these is catechins-polyphenolic compounds-flavanols, found in a variety of plants. In this work, we evaluated the changes in the susceptibility of Candida glabrata strain characterized at the laboratory level and clinical isolates using the combination of catechin and antifungal azoles. Catechin alone had no antifungal activity within the concentration range tested. Its use in combination with miconazole resulted in complete inhibition of growth in the sensitive C. glabrata isolate and a significant growth reduction in the azole resistant C. glabrata clinical isolate. Simultaneous use of catechin and miconazole leads to increased intracellular ROS generation. The enhanced susceptibility of C. glabrata clinical isolates to miconazole by catechin was accompanied with the intracellular accumulation of ROS and changes in the plasma membrane permeability, as measured using fluorescence anisotropy, affecting the function of plasma membrane proteins.

Measurement of Energy-dependent Rhodamine 6G Efflux in Yeast Species.

Rhodamine 6G is a highly fluorescent dye often used to determine the transport activity of yeast membrane efflux pumps. The ATP-binding cassette transporter KlPdr5p confers resistance to several unrelated drugs in Kluyveromyces lactis. KlPdr5p also extrudes rhodamine 6G (R6G) from intact yeast cells in an energy-dependent manner. Incubation of yeast cells in the presence of 2-deoxy-D-glucose (inhibitor of glycolysis) and R6G (mitochondrial ATPase inhibitor) leads to marked depletion of intracellular ATP pool ( Kolaczkowski et al., 1996 ). An active KlPdr5p mediated extrusion of R6G from intact yeast cells can be followed by direct measurement of the fluorescence of extruded R6G in the assay buffer.

Sterol Analysis in Kluyveromyces lactis.

Sterols are essential lipids of most eukaryotic cells with multiple functions (structural, regulatory and developmental). Sterol profile of yeast cells is often determined during the studies of ergosterol synthesis mutants used to uncover a number of functions for various sterols in yeast cells. Molecular studies of ergosterol biosynthesis have been also employed to identify essential steps in the pathway against which antifungals might be developed. We present here a protocol for the isolation of non-saponifiable lipids (sterols) from Kluyveromyces lactis yeast cells and a chromatographic method for quantitative analysis of sterols in lipid extracts (HPLC) that can be performed in laboratories with standard equipment.

Gain-of-function mutation in the KlPDR1 gene encoding multidrug resistance regulator in Kluyveromyces lactis.

KlPdr1p is a single Kluyveromyces lactis homologue of Saccharomyces cerevisiae ScPdr1p/ScPdr3p, the main transcriptional regulators of genes involved in S. cerevisiae multidrug resistance. KlPDR1 deletion leads to a sharp increase in K. lactis drug susceptibility. The presence of putative PDRE and YRE regulatory elements in the KlPDR1 gene promoter suggests an autoregulation of its transcription as well as its control by KlYap1p, the transcription factor involved in oxidative stress response. In this study, one plasmid-borne Klpdr1-1 allele that led to amino acid substitution (L273P) in the KlPdr1p was isolated. Overexpression of the Klpdr1-1 allele from a multicopy plasmid in the K. lactis wild-type and Klpdr1Δ mutant strain increased the tolerance of transformants to oligomycin. The plasmid-borne Klpdr1-1 allele increased the activation of the ScPDR5 promoter and complemented the drug hypersensitivity of the S. cerevisiae pdr1Δ pdr3Δ mutant strain. The results indicate that L273P amino acid substitution is the result of a gain-of-function mutation in the KlPDR1 gene that confers KlPdr1p hyperactivity, as revealed by a high expression of the ABC transporter gene KlPDR5, leading to multidrug resistance and rhodamine 6G efflux out of the cells.

Autoactivated KlPDR1 gene in the control of multidrug resistance in Kluyveromyces lactis.

The KlPDR1 gene encodes a zinc finger transcription factor that has recently been shown to be involved in the control of multidrug resistance of Kluyveromyces lactis . In this work, we provide evidence that the K. lactis KlPDR1 gene is under positive autoregulation by KlPdr1p, which plays a role in the activation of the main multidrug resistance transporter gene KlPDR5. Electrophoretic mobility shift assays, as well as the use of gusA reporter constructs, enabled us to identify the 5'-tataTCCGGGTAactt-3' sequence motif in the KlPDR1 promoter (in the position -326 to -319 bp) as the PDRE (pleiotropic drug responsive element) for the binding of KlPdr1p. The drug sensitivity of Klpdr1Δ mutant cells was complemented by introducing the plasmid-born KlPDR1 gene. The KlPdr1p activated the expression of the P(KlPDR1)-gusA fusion gene, and the expression of the KlPDR1 gene was induced by fluconazole. The PDRE was also found in the promoter of KlPDR5, a gene encoding the ATP-dependent efflux pump responsible for the drug resistance phenomenon in K. lactis.