Fluconazole upregulates sconC expression and inhibits sulphur metabolism in Microsporum canis.

Azole derivatives such as fluconazole are the mainstay of therapeutic agents for the treatment of fungal infections. Their mode of action involving alteration in the conversion of lanosterol to ergosterol is well established. Here we report the effect of fluconazole on the sulphur metabolism negative regulator gene (sconC) in Microsporum canis. Characterization of the M. canis sconC gene revealed that its ORF is comprised of 495bp interrupted by four introns of 47-70bp. Exposure of M. canis in suspension to fluconazole upregulates sconC mRNA level and protein expression as determined by Northern and Western blot analysis, respectively. Upregulation of sconC was accompanied by inhibition of sulphur metabolism of the fungus resulting in a greatly reduced incorporation of radioactive labelled sulphuric acid into fungal proteins. These data establish that in addition to its action on ergosterol synthesis, fluconazole acts on other biological pathways in fungal cells.

High-frequency of quinolone-resistant Neisseria gonorrhoeae in Austria with a common pattern of triple mutations in GyrA and ParC genes.

OBJECTIVE: Quinolones have a broad spectrum of antimicrobial activity and are widely used for the treatment of uncomplicated Neisseria gonorrhoeae infections. A dramatic increase in the number of reported N. gonorrhoeae infections as well as quinolone-resistant isolates in Vienna prompted us to investigate the pattern of mutations in these isolates. GOALS: The goal of this study was to investigate the pattern of mutations in GyrA and ParC genes in quinolone-resistant N. gonorrhoeae clinical isolates in Vienna from 1999 to 2002. STUDY: The antibiotic susceptibility of N. gonorrhoeae clinical isolates and point mutations of the GyrA and ParC genes of 104 clinical isolates were analyzed. RESULTS: Quinolone-resistant N. gonorrhoeae isolates increased from 3.9% (3 of 77) in 1999 to 59.4% (120 of 202) in 2002. As expected, none of the 46 N. gonorrhoeae quinolone-sensitive strains showed mutations at these positions of GyrA and ParC genes with the exception of 1 isolate, which had a single mutation at GyrA 91. Unlike what has been previously reported for other geographic areas, 96.6% (56 of 58) of the quinolone-resistant isolates harbored common triple mutations at Gyr 91, 95, and ParC 86. The majority of these isolates (76.8%) belong to the PPNG phenotype. CONCLUSIONS: Our data indicate that the pattern of mutations in GyrA and ParC subunits of N. gonorrhoeae in Austria differs from that reported from other geographic areas. The differences may either be the result of the difference in bacterial subtypes or various antibiotic regimens used in these regions.

Fluconazole downregulates metallothionein expression and increases copper cytotoxicity in Microsporum canis.

Azole antifungals are widely used to treat infections with dermatophyte fungi. Whereas it is well established that this class of drugs interferes with fungal ergosterol synthesis, little is known about its potential other biological effects. Here we report the isolation and structural organization of Microsporum canis metallothionein gene and demonstrate that fluconazole is able to downregulate the baseline as well as copper-induced expression of this gene. Since this effect occurred within 30 min after exposure of the fungus to fluconazole, it is unlikely that it is due to impaired ergosterol synthesis. Our additional demonstration that fluconazole enhances copper toxicity for M. canis suggests that inhibition of metallothionein expression by fluconazole is biologically relevant and may represent an important additional mode of the antifungal action of this drug. Therefore our data indicate that antifungal effects of azole derivatives might not only be due to interference with cell wall synthesis but may also affect other biological circuits within the fungal cells.