Impact of Farnesol as a Modulator of Efflux Pumps in a Fluconazole-Resistant Strain of Candida albicans.

Aim: This work studied the impact of the quorum-sensing molecule, farnesol (FAR), on fluconazole (FLC)-resistant Candida albicans isolate CY 1123 compared with the susceptible standard strain C. albicans SC5314. The genes encoding efflux pumps belonging to the ATP-binding cassette (ABC) and major facilitator superfamilies, together with overexpression or point mutation of the ERG11 gene, are the main resistance mechanisms to azole antifungal drugs. Results: The upregulation of genes coding for CDR1, CDR2, and MDR1 were confirmed by qPCR with respect to the housekeeping gene ACT1 in the resistant strain. The contribution of the ERG11 gene was also observed. Markedly, increased pump activity (Cdr1 and/or Cdr2) in the CY 1123 strain was confirmed using diS-C3(3) assay. However, the addition of FAR to the yeasts diminished the difference in staining levels between the SC5314 and CY 1123 strains, demonstrating the concentration-dependent character that could be caused by an effective modulation of Cdr pumps. FAR (60 and 100 µM) was also able to decrease the minimal inhibitory concentrations (MIC50), denoting the inhibition of planktonic cells by 50%, from 8 to 4 µg/mL of FLC when the resistant strain CY 1123 was not cultivated with FLC. However, when it was exposed to 64 µg/mL of FLC, the MIC50 shifted from 64 to 8 µg/mL. Conclusion: Besides the many other effects of FAR on eukaryotic and prokaryotic cells, it also affects ABC efflux transporters, resulting in changes in resistance to azoles in C. albicans isolates. However, this effect is dependent on FAR concentrations.

Erg6 gene is essential for stress adaptation in Kluyveromyces lactis.

We investigated the effect of Kluyveromyces lactis ERG6 gene deletion on plasma membrane function and showed increased susceptibility of mutant cells to salt stress, cationic drugs and weak organic acids. Contrary to Saccharomyces cerevisiae, Klerg6 mutant cells exhibited increased tolerance to tunicamycin. The content of cell wall polysacharides did not significantly vary between wild-type and mutant cells. Although the expression of the NAD+-dependent glycerol 3-phosphate dehydrogenase (KlGPD1) in the Klerg6 mutant cells was only half of that in the parental strain, it was induced in the presence of calcofluor white. Also, cells exposed to this drug accumulated glycerol. The absence of KlErg6p led to plasma membrane hyperpolarization but had no statistically significant influence on the plasma membrane fluidity. We propose that the phenotype of Klerg6 mutant cells to a large extent was a result of the reduced activity of specific plasma membrane proteins that require proper lipid composition for full activity.

Differences in the arrangement of the Pdr5p multidrug transporter binding pocket of Saccharomyces cerevisiae and Kluyveromyces lactis.

Multidrug transporters are often responsible for failure of medical treatment, since they expel a variety of structurally and functionally unrelated drugs out of the cell. We found that the fluorescent probe diS-C3(3) is a substrate of not only Pdr5p of Saccharomyces cerevisiae (ScPdr5p) but also of its less-explored Kluyveromyces lactis homologue (KlPdr5p). This enabled us to compare the ability of azoles to competitively inhibit the Pdr5p-mediated probe efflux in the two species. In K. lactis, these azoles completely inhibit probe transport by KlPdr5p and also compete with each other for transport. This indicates that the probe and the azoles are bound by the same site(s) of the KlPdr5p binding pocket. On the other hand, the azoles' capacity to inhibit the probe transport by ScPdr5p is limited, as a result of their partial cotransport with the probe. While the azoles bind to only one or two separate binding sites, the probe is able to bind to all three of them. Moreover, the bulky ScPdr5p substrate enniatin B, which effectively inhibits both probe and azole transport by the pump, has negligible effect on KlPdr5p. Our data point to a tighter arrangement of the KlPdr5p binding pocket compared to that of ScPdr5p.

Yeast Tok1p channel is a major contributor to membrane potential maintenance under chemical stress.

Tok1p is a highly specific yeast plasma membrane potassium channel with strong outward directionality. Its opening is induced by membrane depolarization. Although the biophysical properties of Tok1p are well-described, its potentially important physiological role is currently largely unexplored. To address this issue, we examined the Tok1p activity following chemically-induced depolarization by measuring changes of plasma membrane potential (ΔΨ) using the diS-C3(3) fluorescence assay in a Tok1p-expressing and a Tok1p-deficient strain. We report that Tok1p channel activity in response to chemical stress does not depend solely on the extent of depolarization, as might have been expected, but may also be negatively influenced by accompanying effects of the used compound. The stressors may interact with the plasma membrane or the channel itself, or cause cytosolic acidification. All of these effects may negatively influence the Tok1p channel opening. While ODDC-induced depolarization exhibits the cleanest Tok1p activation, restoring an astonishing 75% of lost ΔΨ, higher BAC concentrations reduce Tok1p activity, probably because of direct interactions with the channel and/or its lipid microenvironment. This is not only the first study of the physiological role of Tok1p in ΔΨ maintenance under chemical stress, but also the first estimate of the extent of depolarization the channel is able to counterbalance.

Synergy between azoles and 1,4-dihydropyridine derivative as an option to control fungal infections.

With emerging fungal infections and developing resistance, there is a need for understanding the mechanisms of resistance as well as its clinical impact while planning the treatment strategies. Several approaches could be taken to overcome the problems arising from the management of fungal diseases. Besides the discovery of novel effective agents, one realistic alternative is to enhance the activity of existing agents. This strategy could be achieved by combining existing antifungal agents with other bioactive substances with known activity profiles (combination therapy). Azole antifungals are the most frequently used class of substances used to treat fungal infections. Fluconazole is often the first choice for antifungal treatment. The aim of this work was to study potential synergy between azoles and 1,4-dihydropyridine-2,3,5-tricarboxylate (termed derivative H) in order to control fungal infections. This article points out the synergy between azoles and newly synthesized derivative H in order to fight fungal infections. Experiments confirmed the role of derivative H as substrate/inhibitor of fungal transporter Cdr1p relating to increased sensitivity to fluconazole. These findings, plus decreased expression of ERG11, are responsible for the synergistic effect.

A novel method for assessment of local pH in periplasmic space and of cell surface potential in yeast.

Yeast cells exhibit a negative surface potential due to negative charges at the cell membrane surface. Consequently, local concentrations of cations at the periplasmic membrane surface may be significantly increased compared to their bulk environment. However, in cell suspensions only bulk concentrations of cations can be measured directly. Here we present a novel method enabling the assessment of local pH at the periplasmic membrane surface which can be directly related to the underlying cell surface potential. In this proof of concept study using Saccharomyces cerevisiae cells with episomally expressed pH reporter, pHluorin, intracellular acidification induced by the addition of the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) was measured using synchronously scanned fluorescence spectroscopy (SSF). The analysis of titration curves revealed that the pH at the periplasmic surface of S. cerevisiae cells was about two units lower than the pH of bulk medium. This pH difference was significantly decreased by increasing the ionic strength of the bulk medium. The cell surface potential was estimated to amount to -130 mV. Comparable results were obtained also with another protonophore, pentachlorophenol (PCP).

Deletion of the PDR16 gene influences the plasma membrane properties of the yeast Kluyveromyces lactis.

The plasma membrane is the first line of cell defense against changes in external environment, thus its integrity and functionality are of utmost importance. The plasma membrane properties depend on both its protein and lipid composition. The PDR16 gene is involved in the control of Kluyveromyces lactis susceptibility to drugs and alkali metal cations. It encodes the homologue of the major K. lactis phosphatidylinositol transfer protein Sec14p. Sec14p participates in protein secretion, regulation of lipid synthesis, and turnover in vivo. We report here that the plasma membrane of the Klpdr16Δ mutant is hyperpolarized and its fluidity is lower than that of the parental strain. In addition, protoplasts prepared from the Klpdr16Δ cells display decreased stability when subjected to hypo-osmotic conditions. These changes in membrane properties lead to an accumulation of radiolabeled fluconazole and lithium cations inside mutant cells. Our results point to the fact that the PDR16 gene of K. lactis (KlPDR16) influences the plasma membrane properties in K. lactis that lead to subsequent changes in susceptibility to a broad range of xenobiotics.

Depolarization affects the lateral microdomain structure of yeast plasma membrane.

We report the transmembrane voltage-induced lateral reorganization of highly-ordered lipid microdomains in the plasma membrane of living Saccharomyces cerevisiae. Using trans-parinaric acid (all-trans-9,11,13,15-octadecatetraenoic acid) as a probe of lipid order and different methods of membrane depolarization, we found that depolarization always invokes a significant reduction in the amount of gel-like microdomains in the membrane. Different depolarization mechanisms, including the application of ionophores, cell depolarization by an external electric field, depolarization by proton/hexose co-transport facilitated by HUP1 protein and a reduction of membrane potential caused by compromised respiration efficiency, yielded the same results independently of the yeast strain used. The data suggest that the voltage-induced reorganization of lateral membrane structure could play significant role in fast cellular response to acute stress conditions, as well as in other membrane microdomain-related regulatory mechanisms.