Exposition of dermatophyte Trichophyton mentagrophytes to L-cystine induces expression and activation of cysteine dioxygenase.

Cysteine dioxygenase (CDO) is involved in regulation of intracellular cysteine levels by catabolising the cysteine to sulphite and sulphate. In keratinolytic fungi, sulphite is actively excreted to reduce disulphide bridges in keratin before its enzymatic degradation. The pathogenicity role of CDO was confirmed in cysteine-hypersensitive and growth-defective ΔCdo mutant of Arthroderma benhamiae on hair and nails. We analysed the CDO expression regulation in T. mentagrophytes (anamorph of A. benhamiae) mycelia by determining the Cdo mRNA and CDO protein levels and by analysing the proportion of two molecular forms of CDO in response to l-cystine exposure. Cdo mRNA levels in mycelia lysates were detected by reverse-transcription real-time polymerase chain reaction and CDO protein by western blot using mouse CDO-specific hyperimmune serum. The Cdo mRNA level increased gradually 2.5-4.5 h after exposure of the mycelium to l-cystine. The CDO protein, detected as two bands of different mobility, appeared earlier in comparison to mRNA (1 h) and culminated after 24 h. More mobile form prevailed after 4.5 h. The comparison of the dynamics in the Cdo mRNA and CDO protein levels indicates that T. mentagrophytes responds to l-cystine by increased transcription and apparently decreased degradation of the CDO and by changing towards higher mobility molecular form, similar to previous reports describing mammalian analogue.

The possible role of dermatophyte cysteine dioxygenase in keratin degradation.

Cysteine dioxygenase (CDO, EC 1.13.11.20) is a key enzyme involved in the homeostatic regulation of cysteine level and in production of important oxidized metabolites of cysteine such as pyruvate, sulphite, sulphate, hypotaurine, and taurine in all eukaryotic cells. The intracellular CDO concentration is regulated at both transcriptional and posttranslational levels. In several fungi, CDO plays an important role as a virulence factor involved in morphological transition from yeast to mycelial forms. CDO is crucial for oxidation of cysteine to cysteine sulphinic acid and therefore for sulphite production and secretion. Because sulphite cleaves disulphide bridges as a first unavoidable step in keratinolysis, it is hypothesized that in dermatophytes, CDO is a virulence factor crucial for keratin degradation.

Keratin degradation by dermatophytes relies on cysteine dioxygenase and a sulfite efflux pump.

Millions of people suffer from superficial infections caused by dermatophytes. Intriguingly, these filamentous fungi exclusively infect keratin-rich host structures such as hair, nails, and skin. Keratin is a hard, compact protein, and its utilization by dermatophytes for growth has long been discussed as a major virulence attribute. Here, we provide strong support for the hypothesis that keratin degradation is facilitated by the secretion of the reducing agent sulfite, which can cleave keratin-stabilizing cystine bonds. We discovered that sulfite is produced by dermatophytes from environmental cysteine, which at elevated concentrations is toxic for microbes and humans. We found that sulfite formation from cysteine relies on the key enzyme cysteine dioxygenase Cdo1. Sulfite secretion is supported by the sulfite efflux pump Ssu1. Targeted mutagenesis proved that dermatophyte mutants in either Cdo1 or Ssu1 were highly growth-sensitive to cysteine, and mutants in Ssu1 were specifically sensitive to sulfite. Most notably, dermatophyte mutants in Cdo1 and Ssu1 were specifically growth-defective on hair and nails. As keratin is rich in cysteine, our identified mechanism of cysteine conversion and sulfite efflux supports both cysteine and sulfite tolerance per se and progression of keratin degradation. These in vitro findings have implications for dermatophyte infection pathogenesis.

Isolation of recombinant cysteine dioxygenase protein from Trichophyton mentagrophytes.

Cysteine dioxygenase (CDO, EC 1.13.11.20) catalyses the oxygenation of cysteine to cysteine sulphinic acid leading to the production of sulphite, sulphate and taurine as the final metabolites of cysteine catabolism. Keratinolytic fungi secrete sulphite and sulphate to reduce disulphide bridges in host tissue keratin proteins as the first step of keratinolysis. In the present study, we describe the identification of cDNA, as well as expression and characterisation of recombinant CDO protein from Trichophyton mentagrophytes. The cDNA was amplified using primers designed on the basis of high conservancy CDO regions identified in other fungi. PCR product was cloned and sequenced. Recombinant CDO was expressed in Escherichia coli, and affinity purified and identified by matrix-assisted laser desorption/ionization - time-of-flight mass spectrometry (MALDI-TOF MS). Enzyme activity was assayed by monitoring the production of cysteine sulphinate using mass spectrometry. The Cdo cDNA encodes for a protein consisting of 219 amino acids. Recombinant CDO protein C-terminally fused with a His tag was purified by affinity chromatography. The CDO purified under native condition was proved to be enzymatically active. Protein identity was confirmed by MALDI-TOF MS. Comparison of cDNA sequence with those identified in other fungi revealed significant homology. Identification of T. mentagrophytes CDO provides indispensable tools for future studies of dermatophyte pathogenicity and development of new approaches for prevention and therapy.

Sulphite efflux pumps in Aspergillus fumigatus and dermatophytes.

Dermatophytes and other filamentous fungi excrete sulphite as a reducing agent during keratin degradation. In the presence of sulphite, cystine in keratin is directly cleaved to cysteine and S-sulphocysteine, and thereby, reduced proteins become accessible to hydrolysis by a variety of secreted endo- and exoproteases. A gene encoding a sulphite transporter in Aspergillus fumigatus (AfuSSU1), and orthologues in the dermatophytes Trichophyton rubrum and Arthroderma benhamiae (TruSSU1 and AbeSSU1, respectively), were identified by functional expression in Saccharomyces cerevisiae. Like the S. cerevisiae sulphite efflux pump Ssu1p, AfuSsu1p, TruSsu1p and AbeSsu1p belong to the tellurite-resistance/dicarboxylate transporter (TDT) family which includes the Escherichia coli tellurite transporter TehAp and the Schizosaccharomyces pombe malate transporter Mae1p. Seven genes in the A. fumigatus genome encode transporters of the TDT family. However, gene disruption of AfuSSU1 and of the two more closely related paralogues revealed that only AfuSSU1 encodes a sulphite efflux pump. TruSsulp and AbeSsulp are believed to be the first members of the TDT family identified in dermatophytes. The relatively high expression of TruSSU1 and AbeSSU1 in dermatophytes compared to that of AfuSSU1 in A. fumigatus likely reflects a property of dermatophytes which renders these fungi pathogenic. Sulphite transporters could be a new target for antifungal drugs in dermatology, since proteolytic digestion of hard keratin would not be possible without prior reduction of disulphide bridges.