H. Vanden Bossche

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.

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.

Inhibitors of P450-dependent steroid biosynthesis: from research to medical treatment.

A number of cytochrome P450-dependent enzymes are major targets for both steroidal and nonsteroidal compounds that may be of use in the treatment of a number of androgen-independent, androgen-, estrogen- and other steroid-dependent diseases. Compounds of interest are for example aminoglutethimide and derivatives; esters of 4-pyridineacetic acid; imidazole derivatives, such as ketoconazole, liarozole, fadrozole, CGS 18320 B; bis-chlorophenyl-pyrimidine analogues; triazole derivatives vorozole and CGS 20267, and steroidal aromatase inhibitors such as 4-hydroxyandrostenedione. Some of them (e.g. ketoconazole) triggered studies to find new possibilities in medical treatment. Others are of use clinically or under clinical evaluation to provide a palliative treatment and/or cure to patients with for example prostatic carcinoma, breast cancer, hypercortisolism and benign prostatic hyperplasia.A number of cytochrome P450-dependent enzymes are major targets for both steroidal and nonsteroidal compounds that may be of use in the treatment of a number of androgen-independent, androgen-, estrogen- and other steroid-dependent diseases. Compounds of interest are for example aminoglutethimide and derivatives; esters of 4-pyridineacetic acid; imidazole derivatives, such as ketoconazole, liarozole, fadrozole, CGS 18320 B; bis-chlorophenyl-pyrimidine analogues; triazole derivatives vorozole and CGS 20267, and steroidal aromatase inhibitors such as 4-hydroxyandrostenedione. Some of them (e.g. ketoconazole) triggered studies to find new possibilities in medical treatment. Others are of use clinically or under clinical evaluation to provide a palliative treatment and/or cure to patients with for example prostatic carcinoma, breast cancer, hypercortisolism and benign prostatic hyperplasia.

Effects of itraconazole on cytochrome P-450-dependent sterol 14 alpha-demethylation and reduction of 3-ketosteroids in Cryptococcus neoformans.

As in other pathogenic fungi, the major sterol synthesized by Cryptococcus neoformans var. neoformans is ergosterol. This yeast also shares with most pathogenic fungi a susceptibility of its cytochrome P-450-dependent ergosterol synthesis to nanomolar concentrations of itraconazole. Fifty percent inhibition of ergosterol synthesis was reached after 16 h of growth in the presence of 6.0 +/- 4.7 nM itraconazole, and complete inhibition was reached at approximately 100 nM itraconazole. This inhibition coincided with the accumulation of mainly eburicol and the 3-ketosteroid obtusifolione. The radioactivity incorporated from [14C]acetate in both compounds represents 64.2% +/- 12.9% of the radioactivity incorporated into the sterols plus squalene extracted from cells incubated in the presence of 10 nM itraconazole. The accumulation of obtusifolione as well as eburicol indicates that itraconazole inhibits not only the 14 alpha-demethylase but also (directly or indirectly) the NADPH-dependent 3-ketosteroid reductase, i.e., the enzyme catalyzing the last step in the demethylation at C-4. This latter inhibition obviates the synthesis of 4,4-demethylated 14 alpha-methylsterols that may function at least partly as surrogates of ergosterol. Eburicol and obtusifolione are unable to support cell growth, and the 3-ketosteroid has been shown to disturb membranes. The complete inhibition of ergosterol synthesis and the accumulation of the 4,4,14-trimethylsterol and of the 3-ketosteroid together with the absence of sterols, such as 14 alpha-methylfecosterol and lanosterol, which can partly fulfill some functions of ergosterol, are at the origin of the high activity of itraconazole against C. neoformans. Fifty percent inhibition of growth achieved after 16 h of incubation in the presence of 3.2 +/- 2.6 nM itraconazole.

Effects of etomidate on steroid biosynthesis in subcellular fractions of bovine adrenals

The imidazole derivative, etomidate, inhibits the 11 beta-hydroxylase in cell-free systems and mitochondria isolated from bovine adrenal cortex. Fifty per cent inhibition is achieved at 3.10(-7) M. The less active hypnotic L-enantiomer is also a less potent inhibitor of the 11-hydroxylation. At a 2 times higher concentration, etomidate affects the cholesterol side chain cleavage. The inhibition of both steroidogenic enzyme systems may be due to binding of the unhindered nitrogen of the imidazole ring of etomidate to the heme iron atom of the adrenal cortex mitochondrial cytochrome P-450 species.

New non-steroidal aromatase inhibitors: Focus on R76713

R76713 is a novel triazole derivative which selectively blocks the cytochrome P450-dependent aromatase. In human placental microsomes, in FSH-stimulated rat and human granulosa cells and in human adipose stromal cells, 50% inhibition of estradiol biosynthesis was obtained at drug concentrations of 2-10 nM. In PMSG-injected female rats, R76713 lowered plasma estradiol levels by 50 and 90% 2 h after single oral doses of 0.005 and 0.05 mg/kg respectively. After 1 mg/kg, estradiol levels were suppressed by 90% for 16 h. In male cynomolgus monkeys, R76713 dose-dependently (0.03-10 micrograms/kg) inhibited peripheral aromatization with an ED50 of 0.13 microgram/kg without altering metabolic clearance rates and conversion ratios. In vitro R76713 had no effect on other P450-dependent steroidogenic enzymes up to 1000 nM at least. In rats, LHRH-, ACTH- and sodium-deprived diet stimulated plasma testosterone, corticosterone and aldosterone levels were not modified 2 h after single oral administrations of R76713 (up to 20 mg/kg). Furthermore, R76713 did not show any in vitro or in vivo estrogenic or antiestrogenic property. R76713 also induced regression of DMBA-induced mammary tumors after daily oral administration of 1 mg/kg b.i.d. In male volunteers (n = 4), a single oral dose of 5 and 10 mg lowered median plasma estradiol levels from 70 pM to the detection limit of the assay (40 pM) 4, 8 and 24 h after intake whereas no changes were detected after placebo administration. In premenopausal women (n = 15), receiving a single oral dose of 20 mg, median plasma estradiol levels decreased from 389 pM (before) to 168, 133 and 147 pM, 4, 8 and 24 h after intake whereas they remained above 420 pM after placebo (n = 7).

Review Article Cytochromes P450 in fungi

Summary. The article gives an overview on the history of the discovery of P450 cytochromes and on their occurrence in nature, especially on their interactions with metabolic pathways in fungi. The significance of the P450 cytochromes in the ergosterol synthesis as well as in the inhibitory mechanisms caused by imidazole and triazole antimycotics is described is detail.

Importance and Role of Sterols in Fungal Membranes

The basic role of biomembranes is to provide a barrier between a cell or organelle and its environment and at the same time to serve as a matrix for the association of proteins with lipids (Gibbons et al. 1982) or, as pointed out by Lewis Thomas (1974), “it takes a membrane to make sense out of disorder”. In these membranes, sterols play a major role both architecturally and functionally. The most common membrane sterol in animals is cholesterol (Fig. 1).

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.

In Vitro and In Vivo Activities of the Novel Azole Antifungal Agent R126638

ABSTRACT R126638 is a new triazole agent with potent antifungal activity in vitro against various dermatophytes, Candida spp., and Malassezia spp. Its activity against Malassezia spp. in vitro was superior to that of ketoconazole, the agent currently used for the treatment of Malassezia-related infections. R126638 showed activity comparable to or lower than that of itraconazole against dermatophytes in vitro; however, in guinea pig models of dermatophyte infections, R126638 given orally consistently showed antifungal activity superior to that of itraconazole, with 50% effective doses (ED50s) three- to more than eightfold lower than those of itraconazole, depending on the time of initiation and the duration of treatment. The ED50 of R126638 in a mouse dermatophytosis model was more than fivefold lower than that of itraconazole. These data indicate that if the effects of R126638 seen when it is used to treat animals can be extrapolated to humans, the novel compound would be expected to show effects at doses lower than those of existing drugs and, hence, present a lower risk for side effects.