Patrick Marichal

Contribution of mutations in the cytochrome P450 14α-demethylase (Erg11p, Cyp51p) to azole resistance in Candida albicans

The cytochrome P450 14alpha-demethylase, encoded by the ERG11 (CYP51) gene, is the primary target for the azole class of antifungals. Changes in the azole affinity of this enzyme caused by amino acid substitutions have been reported as a resistance mechanism. Nine Candida albicans strains were used in this study. The ERG11 base sequence of seven isolates, of which only two were azole-sensitive, were determined. The ERG11 base sequences of the other two strains have been published previously. In these seven isolates, 12 different amino acid substitutions were identified, of which six have not been described previously (A149V, D153E, E165Y, S279F, V452A and G4655). In addition, 16 silent mutations were found. Two different biochemical assays, subcellular sterol biosynthesis and CO binding to reduced microsomal fractions, were used to evaluate the sensitivity of the cytochromes for fluconazole and itraconazole. Enzyme preparations from four isolates showed reduced itraconazole susceptibility, whereas more pronounced resistance to fluconazole was observed in five isolates. A three-dimensional model of C. albicans Cyp51p was used to position all 29 reported substitutions, 98 in total identified in 53 sequences. These 29 substitutions were not randomly distributed over the sequence but clustered in three regions from amino acids 105 to 165, from 266 to 287 and from 405 to 488, suggesting the existence of hotspot regions. Of the mutations found in the two N-terminal regions only Y132H was demonstrated to be of importance for azole resistance. In the C-terminal region three mutations are associated with resistance, suggesting that the non-characterized substitutions found in this region should be prioritized for further analysis.

Molecular mechanisms of drug resistance in fungi

Failures of treatment in fungal infections have drawn attention recently to the problem of antifungal resistance and its underlying mechanisms. The number of fungal isolates that are resistant to the orally active azole antifungals, especially fluconazole, is growing. Amphotericin-B-resistant isolates have been recovered during treatment of patients with candidiasis, and resistance to flucytosine is so common that this antifungal is no longer recommended as a single-drug therapy.

Characterization of an azole-resistant Candida glabrata isolate.

A Candida (Torulopsis) glabrata strain (B57149) became resistant to fluconazole after a patient carrying the organism was treated with the drug at 400 mg once daily for 9 days. Growth of the pretreatment isolate (B57148) was inhibited by 50% with 0.67 microM ketoconazole, 1.0 microM itraconazole, and 43 microM fluconazole, whereas growth of B57149 was inhibited slightly by 10 microM ketoconazole but was unaffected by 10 microM itraconazole or 100 microM fluconazole. This indicates cross-resistance to all three azole antifungal agents. The cellular fluconazole content of B57149 was from 1.5- to 3-fold lower than that of B57148, suggesting a difference in drug uptake between the strains. However, this difference was smaller than the measured difference in susceptibility and, therefore, cannot fully explain the fluconazole resistance of B57149. Moreover, the intracellular contents of ketoconazole and itraconazole differed by less than twofold between the strains, so that uptake differences did not account for the azole cross-resistance of B57149. The microsomal cytochrome P-450 content of B57149 was about twice that of B57148, a difference quantitatively similar to the increased subcellular ergosterol synthesis from mevalonate or lanosterol. These results indicate that the level of P-450-dependent 14 alpha-demethylation of lanosterol is higher in B57149. Increased ergosterol synthesis was also seen in intact B57149 cells, and this coincided with a decreased susceptibility of B57149 toward all three azoles and amphotericin B. B57149 also had higher squalene epoxidase activity, and thus, more terbinafine was needed to inhibit the synthesis of 2,3-oxidosqualene from squalene. P-450 content and ergosterol synthesis both decreased when isolate B57149 was subcultured repeatedly on drug-free medium. This repeated subculture also fully restored the strains itraconazole susceptibility, but only partly increased its susceptibility to fluconazole. The results suggest that both lower fluconazole uptake and increased P-450-dependent ergosterol synthesis are involved in the mechanism of fluconazole resistance but that only the increased ergosterol synthesis contributes to itraconazole cross-resistance.

Anti-Candida Drugs — The Biochemical Basis for Their Activity

The past years have seen a continuous effort toward the synthesis of new antifungal agents. Most of them belong to the N-substituted imidazoles and triazoles. Another interesting series of antifungals are the allylamines. Biochemically, both the azole derivatives and the allylamines belong to the class of ergosterol biosynthesis inhibitors and thus differ from the polyene macrolide antibiotics. Indeed, it is now believed that the antifungal action of the polyenes, nystatin and amphotericin B, is due to a direct interaction with ergosterol itself. A more detailed analysis of the ergosterol biosynthesis inhibitors revealed that ergosterol depletion is the consequence of the interaction of the azole derivatives, e.g., miconazole, ketoconazole, and itraconazole, with the cytochrome P-450 involved in the 14 alpha-demethylation of lanosterol. Both the accumulation of 14 alpha-methylsterols and the concomitant decreased ergosterol content affect the membranes and membrane-bound enzymes of yeast and fungi. The allylamines seem to act by inhibition of the squalene epoxidase resulting in ergosterol depletion and accumulation of squalene. The target for the fluorinated pyrimidine, flucytosine, is completely different. Its antifungal properties may result from its conversion to 5-fluorouracil. The latter is then phosphorylated and incorporated into RNA, thus disrupting the protein synthesis in the yeast cell. These different biochemical targets for the antifungals of use in candidosis are discussed in this paper.

Biochemical Approaches to Selective Antifungal Activity. Focus on Azole Antifungals

Summary: Azole antifungals (e.g. the imida‐zoles: miconazole, clotrimazole, bifona‐zole, imazalil, ketoconazole, and the tria‐zoles: diniconazole, triadimenol, propico‐nazole, fluconazole and itraconazole) inhibit in fungal cells the 14α‐demethylation of lanosterol or 24–methylenedihydro‐lanosterol. The consequent inhibition of ergosterol synthesis originates from binding of the unsubstituted nitrogen (N‐3 or N‐4) of their imidazole or triazole moiety to the heme iron and from binding of their N‐1 substituent to the apoprotein of a cytochrome P‐450 (P‐45014DM) of the endo‐plasmic reticulum.

The interaction of miconazole and ketoconazole with lipids

Staphylococcus aureus can be protected by unsaturated unesterified fatty acids against the growth inhibitory effects of miconazole and ketoconazole observed at concentrations greater than 10(-6) M and greater than 10(-5) M, respectively. Miconazoles fungicidal activity is partly antagonized by oleic acid. However, the effect of ketoconazole on the viability of Candida albicans was not affected by this fatty acid. Cytochrome oxidase and ATPase activities are more sensitive to miconazole (10(-5) M) than to ketoconazole (greater than 10(-4) M) and also liposomes are more susceptible to lysis induced by miconazole. Using differential scanning calorimetry it is shown that high concentrations of miconazole shift the lipid transition temperature of multilamellar vesicles to lower values without affecting the enthalpy of melting. Ketoconazole induces a broadening of the main transition peak only. It is suggested that miconazole changes the lipid organization without binding to the lipids, whereas ketoconazole is localized in the multilayer without having an important direct effect on the lipid organization. The results indicate that miconazole, and to a lesser extent ketoconazole, at doses that can be reached by topical application only, interfere with a third target (the two others are ergosterol synthesis and fatty acid elongation plus desaturation). It is hypothesized that the induced change in lipid organization may play some role in miconazoles topical antibacterial and fungicidal activity, whereas it does not seem to play a significant role in ketoconazoles activities.

Origin of differences in susceptibility of Candida krusei to azole antifungal agents.

Summary. Two Candida krusei isolates were used to compare the effects of fluconazole, ketoconazole and itraconazole on growth and ergosterol synthesis, and to measure intracellular drug contents. Fifty per cent inhibition (IC50) of growth was achieved at 0.05–0.08 μM itraconazole and 0.56–1.2 μM ketoconazole, whereas 91‐ > 100 μM fluconazole was needed to reach the IC50 value. Similar differences in sensitivity to these azole antifungal agents were seen when their effects on ergosterol synthesis from [14C]acetate were measured after 4 h and 24 h of growth. However, when the effects of the azoles on ergosterol synthesis from [14C]mevalonate by subcellular fractions were measured, fluconazole was only 2.3–6.1 times less active than itraconazole, and the IC50 values for ketoconazole were almost similar to those obtained with itraconazole. These results indicate that differences in susceptibility to itraconazole and ketoconazole are unrelated to differences in affinity for the C. krusei cytochrome P450. The much lower growth‐inhibitory effects of fluconazole can also be explained partly only by a lower affinity for the P450‐dependent 14α‐demethylase. The differences in sensitivity of both C. krusei isolates appeared to arise from differences in the intracellular itraconazole, ketoconazole and fluconazole contents. Depending on the experimental conditions, these isolates accumulated 6–41 times more itraconazole than ketoconazole and the intracellular ketoconazole content was 3.0–19.0 times higher than that of fluconazole.

The Novel Azole R126638 Is a Selective Inhibitor of Ergosterol Synthesis in Candida albicans, Trichophyton spp., and Microsporum canis

ABSTRACT R126638 is a novel triazole with in vitro activity similar to that of itraconazole against dermatophytes, Candida spp., and Malassezia spp. In animal models of dermatophyte infections, R126638 showed superior antifungal activity. R126638 inhibits ergosterol synthesis in Candida albicans, Trichophyton mentagrophytes, Trichophyton rubrum, and Microsporum canis at nanomolar concentrations, with 50% inhibitory concentrations (IC50s) similar to those of itraconazole. The decreased synthesis of ergosterol and the concomitant accumulation of 14α-methylsterols provide indirect evidence that R126638 inhibits the activity of CYP51 that catalyzes the oxidative removal of the 14α-methyl group of lanosterol or eburicol. The IC50s for cholesterol synthesis from acetate in human hepatoma cells were 1.4 μM for itraconazole and 3.1 μM for R126638. Compared to itraconazole (IC50 = 3.5 μM), R126638 is a poor inhibitor of the 1α-hydroxylation of 25-hydroxyvitamin D3 (IC50 > 10 μM). Micromolar concentrations of R126638 and itraconazole inhibited the 24-hydroxylation of 25-hydroxyvitamin D3 and the conversion of 1,25-dihydroxyvitamin D3 into polar metabolites. At concentrations up to 10 μM, R126638 had almost no effect on cholesterol side chain cleavage (CYP11A1), 11β-hydroxylase (CYP11B1), 17-hydroxylase and 17,20-lyase (CYP17), aromatase (CYP19), or 4-hydroxylation of all-trans retinoic acid (CYP26). At 10 μM, R126638 did not show clear inhibition of CYP1A2, CYP2A6, CYP2D6, CYP2C8, CYP2C9, CYP2C10, CYP2C19, or CYP2E1. Compared to itraconazole, R126638 had a lower interaction potential with testosterone 6β hydroxylation and cyclosporine hydroxylation, both of which are catalyzed by CYP3A4, whereas both antifungals inhibited the CYP3A4-catalyzed hydroxylation of midazolam similarly. The results suggest that R126638 has promising properties and merits further in vivo investigations for the treatment of dermatophyte and yeast infections.

Novel antifungals based on 4-substituted imidazole: a combinatorial chemistry approach to lead discovery and optimization.

A series of 4-substituted imidazole sulfonamides has been prepared by solid-phase chemistry. These compounds were found to have good in vitro antifungal activity and constitute the first examples of C-linked azoles with such activity. The most potent inhibitor (30) demonstrated inhibition of key Candida strains at an in vitro concentration of < 100nM and compared favorably with in vitro potency of itraconazole.

Novel antifungals based on 4-substituted imidazole: solid-phase synthesis of substituted aryl sulfonamides towards optimization of in vitro activity.

The in vitro activity of novel 4-substituted imidazole antifungals was optimized by solid-phase chemistry and parallel synthesis. Potent yeast-selective as well as broad-spectrum antifungal compounds (32 and 20) were discovered.