Biosynthesis and Functions of a Melanoid Pigment Produced by Species of the Sporothrix Complex in the Presence of l-Tyrosine

Sporothrix schenckii is the etiological agent of sporotrichosis, the main subcutaneous mycosis in Latin America. Melanin is an important virulence factor of S. schenckii, which produces dihydroxynaphthalene melanin (DHN-melanin) in conidia and yeast cells. Additionally, l-dihydroxyphenylalanine (l-DOPA) can be used to enhance melanin production on these structures as well as on hyphae. Some fungi are able to synthesize another type of melanoid pigment, called pyomelanin, as a result of tyrosine catabolism. Since there is no information about tyrosine catabolism in Sporothrix spp., we cultured 73 strains, including representatives of newly described Sporothrix species of medical interest, such as S. brasiliensis, S. schenckii, and S. globosa, in minimal medium with tyrosine. All strains but one were able to produce a melanoid pigment with a negative charge in this culture medium after 9 days of incubation. An S. schenckii DHN-melanin mutant strain also produced pigment in the presence of tyrosine. Further analysis showed that pigment production occurs in both the filamentous and yeast phases, and pigment accumulates in supernatants during stationary-phase growth. Notably, sulcotrione inhibits pigment production. Melanin ghosts of wild-type and DHN mutant strains obtained when the fungus was cultured with tyrosine were similar to melanin ghosts yielded in the absence of the precursor, indicating that this melanin does not polymerize on the fungal cell wall. However, pyomelanin-producing fungal cells were more resistant to nitrogen-derived oxidants and to UV light. In conclusion, at least three species of the Sporothrix complex are able to produce pyomelanin in the presence of tyrosine, and this pigment might be involved in virulence.     

Efficient insertional mutagenesis system for the dimorphic pathogenic fungus Sporothrix schenckii using Agrobacterium tumefaciens

Sporothrix schenckii is a dimorphic pathogenic fungus that causes human and animal sporotrichosis globally. Here we developed and optimized an Agrobacterium tumefaciens-mediated transformation (ATMT) system of S. schenckii for insertional mutagenesis. The transformation efficiency reached more than 600 transformants per 10⁶ conidia. Using this protocol enabled us to obtain a large number of T-DNA insertional mutants within a short experimental period. Several mutants with altered phenotypes were obtained during the transformation experiments. The mutants displayed mitotic stability. Transferred DNA (T-DNA) flanking sequences were cloned by thermal asymmetric interlaced PCR (TAIL-PCR). Our results demonstrated that the ATMT system can be an effective tool for insertional mutagenesis in S. schenckii. This is the first report of a suitable mutagenesis system which may provide valuable mutants and information for both forward and reverse genetics research in the future for this medically important fungus.     

Melanin biosynthesis in pathogenic species of Sporothrix

Melanins are dark polymers found in the cell wall of pathogenic fungi, including species from the genus Sporothrix that are causative agents of sporotrichosis. In vitro experiments strongly suggest that these pigments are important for fungal virulence and survival in the host. In S. schenckii, melanin biosynthesis occurs via three different common pathways, which generate dihydroxynaphthalene (DHN)-melanin, DOPA-melanin or pyomelanin. Moreover, melanin biosynthesis can be enhanced when the fungus is in contact with some bacteria, such as Pseudomonas aeruginosa and Klebsiella pneumoniae. Melanin pigments have protective effects against antifungals in this genus. New scanning transmission electron tomography data indicates the accumulation of dark pigments in membrane-bound cytoplasmic organelles (melanosomes) in S. schenckii yeasts. Here, we provide an up to date of review the biosynthesis and role of melanins and discuss its roles on the cell biology and pathogenesis of Sporothrix spp.     

Ex vivo determination of potentially virulent Sporothrix schenckii

Hyphae from 30 isolants ofSporothrix andOphiostoma species were washed, dried and pyrolyzed at 350°C. Pyrolysis products were separated on a Carbowax column heated 7.5°C/min to and maintained for 50 min at 160°C. Hydrogen flame detector responses were recorded graphically. Fifteen clinical isolants ofS. schenckii from geographically separated sources produced qualitatively identical pyrograms.S. foliorum, 8 avirulentS. schenckii and otherSporothrix species isolants from soils, andSporothrix states of 6Ophiostoma species yielded pyrograms readily distinguished from each other and from those of virulentS. schenckii. Taxonomic and clinical implications of the pyrograms are mentioned.     

Melanins Protect Sporothrix brasiliensis and Sporothrix schenckii from the Antifungal Effects of Terbinafine

Terbinafine is a recommended therapeutic alternative for patients with sporotrichosis who cannot use itraconazole due to drug interactions or side effects. Melanins are involved in resistance to antifungal drugs and Sporothrix species produce three different types of melanin. Therefore, in this study we evaluated whether Sporothrix melanins impact the efficacy of antifungal drugs. Minimal inhibitory concentrations (MIC) and minimal fungicidal concentrations (MFC) of two Sporothrix brasiliensis and four Sporothrix schenckii strains grown in the presence of the melanin precursors L-DOPA and L-tyrosine were similar to the MIC determined by the CLSI standard protocol for S. schenckii susceptibility to amphotericin B, ketoconazole, itraconazole or terbinafine. When MICs were determined in the presence of inhibitors to three pathways of melanin synthesis, we observed, in four strains, an increase in terbinafine susceptibility in the presence of tricyclazole, a DHN-melanin inhibitor. In addition, one S. schenckii strain grown in the presence of L-DOPA had a higher MFC value when compared to the control. Growth curves in presence of 2×MIC concentrations of terbinafine showed that pyomelanin and, to a lesser extent, eumelanin were able to protect the fungi against the fungicidal effect of this antifungal drug. Our results suggest that melanin protects the major pathogenic species of the Sporothrix complex from the effects of terbinafine and that the development of new antifungal drugs targeting melanin synthesis may improve sporotrichosis therapies.     

Sporotrichosis in Rio de Janeiro,Brazil: Sporothrix brasiliensis Is Associated with Atypical Clinical Presentations

Background

There have been several recent changes in the taxonomy of Sporothrix schenckii as well as new observations regarding the clinical aspects of sporotrichosis. In this study, we determined the identification of the Sporothrix species associated with both classic and unusual clinical aspects of sporotrichosis observed in the endemic area of sporotrichosis in Rio de Janeiro, Brazil.

Methodology/Principal Findings

To verify whether S. brasiliensis is associated with clinical manifestations of sporotrichosis, a cross-sectional study was performed in which Sporothrix isolates from 50 patients with different clinical manifestations were analyzed and their isolates were studied by phenotypic and genotypic methods. Data from these patients revealed a distinct clinical picture and therapeutic response in infections caused by Sporothrix brasiliensis (n = 45) compared to patients with S. schenckii sensu stricto (n = 5). S. brasiliensis was associated with disseminated cutaneous infection without underlying disease, hypersensitivity reactions, and mucosal infection, whereas patients with S. schenckii presented with less severe and more often localized disease, similar to the majority of previously described sporotrichosis cases. Interestingly, S. brasiliensis-infected patients overall required shorter durations of itraconazole (median 16 weeks) compared to the individuals with S. schenckii (median 24 weeks).

Conclusions/Significance

These findings suggest that Sporothrix species are linked to different clinical manifestations of sporotrichosis and that S. brasiliensis is effectively treated with oral itraconazole.     

Sporothrix schenckii sensu stricto Isolated from Soil in an Armadillo’s Burrow

Sporotrichosis is a polymorphic disease of man and animals caused by traumatic implantation of propagules into the skin and subcutaneous tissue. Pathogenic species includes S. brasiliensis, S. schenckii, S. globosa and S. luriei. The disease is remarkable for its occurrence as sapronoses and/or zoonosis outbreaks in tropical and subtropical areas; although, the ecology of the clinical clade is still puzzling. Here, we describe an anamorphic Sporothrix strain isolated from soil in an armadillo’s burrow, which was located in a hyper endemic area of Paracoccidioidomycosis in Brazil. This isolate was identified as S. schenckii sensu stricto (Clade IIa) based on morphological and physiological characteristics and phylogenetic analyses of calmodulin sequences. We then discuss the role of the nine-banded armadillo Dasypus novemcinctus as a natural carrier of Sporothrix propagules to better understand Sporothrix sources in nature and reveal essential aspects about the pathogen’s eco-epidemiology.     

A new duplex PCR assay for the rapid screening of mating-type idiomorphs of pathogenic Sporothrix species

Sporothrix schenckii and allied species are thermodimorphic fungi widely distributed in nature which causes human and animal sporotrichosis, the most common subcutaneous mycosis globally. Sporotrichosis is acquired after a traumatic inoculation of soil or plant material contaminated with Sporothrix propagules or through bites and scratches from diseased cats. In Ascomycota, the master regulators of sex are MAT genes that lie in a single mating-type locus, in Sporothrix these are determined by two nonhomologous alleles, MAT1-1 and MAT1-2. We assessed the whole-genome sequences of medically relevant Sporothrix to develop a single-tube duplex PCR assay to screen S. brasiliensis, S. schenckii, S. globosa, and S. luriei idiomorphs (MAT1-1 or MAT1-2) and understand the distribution and incidence of mating-type strains from natural populations. Using our duplex PCR assay, a 673 bp amplicon (α-box protein) was consistently amplified from all MAT1-1 isolates, while a 291 bp fragment was only amplified from the isolates harboring MAT1-2 (HMG box). Molecular evidence suggests heterothallism (self-sterility) as the unique mating strategy among the species evaluated. The mating-type identity of 93 isolates revealed a nearly equal distribution (1:1 ratio) of mating type alleles within species but deviating between different outbreak areas. Remarkably, for S. brasiliensis in Rio de Janeiro, we report an overwhelming occurrence of MAT1-2 (1:13 ratio; χ² = 10.286, P = 0.0013) opposing the high prevalence MAT1-1 in the Rio Grande do Sul (10:1 ratio; χ² = 7.364, P = 0.0067). Therefore, the population structure of Sporothrix species refers from paucity to regular cycles of sexual recombination in most of the studied regions. Our PCR-based mating-type diagnostic assay is proposed here as an important marker to track the geographical expansion during the long-lasting outbreak of cat-transmitted sporotrichosis driven by S. brasiliensis.     

Asexual Propagation of a Virulent Clone Complex in a Human and Feline Outbreak of Sporotrichosis

Sporotrichosis is one of the most frequent subcutaneous fungal infections in humans and animals caused by members of the plant-associated, dimorphic genus Sporothrix. Three of the four medically important Sporothrix species found in Brazil have been considered asexual as no sexual stage has ever been reported in Sporothrix schenckii, Sporothrix brasiliensis, or Sporothrix globosa. We have identified the mating type (MAT) loci in the S. schenckii (strain 1099-18/ATCC MYA-4821) and S. brasiliensis (strain 5110/ATCC MYA-4823) genomes by using comparative genomic approaches to determine the mating type ratio in these pathogen populations. Our analysis revealed the presence of a MAT1-1 locus in S. schenckii while a MAT1-2 locus was found in S. brasiliensis representing genomic synteny to other Sordariomycetes. Furthermore, the components of the mitogen-activated protein kinase (MAPK)-pheromone pathway, pheromone processing enzymes, and meiotic regulators have also been identified in the two pathogens, suggesting the potential for sexual reproduction. The ratio of MAT1-1 to MAT1-2 was not significantly different from 1:1 for all three Sporothrix species, but the population of S. brasiliensis in the outbreaks originated from a single mating type. We also explored the population genetic structure of these pathogens using sequence data of two loci to improve our knowledge of the pattern of geographic distribution, genetic variation, and virulence phenotypes. Population genetics data showed significant population differentiation and clonality with a low level of haplotype diversity in S. brasiliensis isolates from different regions of sporotrichosis outbreaks in Brazil. In contrast, S. schenckii isolates demonstrated a high degree of genetic variability without significant geographic differentiation, indicating the presence of recombination. This study demonstrated that two species causing the same disease have contrasting reproductive strategies and genetic variability patterns.     

Gastrointestinal inoculation of Sporothrix schenckii in mice

Antibiotic-decontaminated and untreated conventional mice were inoculated intragastrically with 10⁷ viable cells of Sporothrix schenckii to compare the incidence of gastrointestinal (GI) colonization. In control mice, S. schenckii was completely eliminated from the GI tract by 12 h post-inoculation. Antibiotictreated mice also failed to become colonized with this fungus, however, higher population levels of Sporothrix cells remained in the GI tract for a longer period of time before being eliminated. The ability of S. schenckii to disseminate from the lumen of the bowel to infect other organs was also tested. Results indicate that the gastrointestinal tract is not a portal of entry into the host for S. schenckii.     

Phylogenetic Analysis Reveals a High Prevalence of Sporothrix brasiliensis in Feline Sporotrichosis Outbreaks

Sporothrix schenckii, previously assumed to be the sole agent of human and animal sporotrichosis, is in fact a species complex. Recently recognized taxa include S. brasiliensis, S. globosa, S. mexicana, and S. luriei, in addition to S. schenckii sensu stricto. Over the last decades, large epidemics of sporotrichosis occurred in Brazil due to zoonotic transmission, and cats were pointed out as key susceptible hosts. In order to understand the eco-epidemiology of feline sporotrichosis and its role in human sporotrichosis a survey was conducted among symptomatic cats. Prevalence and phylogenetic relationships among feline Sporothrix species were investigated by reconstructing their phylogenetic origin using the calmodulin (CAL) and the translation elongation factor-1 alpha (EF1α) loci in strains originated from Rio de Janeiro (RJ, n = 15), Rio Grande do Sul (RS, n = 10), Paraná (PR, n = 4), São Paulo (SP, n = 3) and Minas Gerais (MG, n = 1). Our results showed that S. brasiliensis is highly prevalent among cats (96.9%) with sporotrichosis, while S. schenckii was identified only once. The genotype of Sporothrix from cats was found identical to S. brasiliensis from human sources confirming that the disease is transmitted by cats. Sporothrix brasiliensis presented low genetic diversity compared to its sister taxon S. schenckii. No evidence of recombination in S. brasiliensis was found by split decomposition or PHI-test analysis, suggesting that S. brasiliensis is a clonal species. Strains recovered in states SP, MG and PR share the genotype of the RJ outbreak, different from the RS clone. The occurrence of separate genotypes among strains indicated that the Brazilian S. brasiliensis epidemic has at least two distinct sources. We suggest that cats represent a major host and the main source of cat and human S. brasiliensis infections in Brazil.     

Chemical composition and immunological properties of glycoproteins of Sporothrix species

Glycoproteins of 11Sporothrix species were purified from their respective culture filtrates by use of DEAE-Sephadex A-50 and QAE-Sephadex A-25 column chromatography and investigated for their chemical and immunological properties. On the basis of sugar composition, the glycoproteins of the 11Sporothrix species could be divided into two groups, i.e., rhamnose containing (i.e., Rha⁺), and non rhamnose containing (i.e., Rha^?) groups. The species in the former group wereS. curviconia, S. inflata, S. schenckii andS. schenckii var. luriei, and those in the latter group wereS. cyanescens, S. foliorum, S. fungorum, S. ghanensis, S. imectorum, S. luteoalba andS. ramosissima. The glycoproteins of four of the (Rha⁺) species were relatively similar in elution patterns of DEAE-Sephadex A-50 chromatograms, sugar and amino acid compositions, serological reactivity with rabbit andS. schenckii serum and rabbit antiKlebsiella pneumoniae K47 serum, and cutaneous delayed hypersensitivity. In the case of the (Rha^?) species, the glycoproteins of five species cross-reacted with rabbit antiS. schenckii serum and all, but theS. cyanescens, glycoprotein were reactive to some degree in skin tests in sporotrichotic patients. These results strongly suggest that the chemical and immunological properties of these glycoproteins correspond with the morphological observations amongSporothrix species.     

Chemical composition and immunological properties of glycoproteins of Sporothrix species

Glycoproteins of 11Sporothrix species were purified from their respective culture filtrates by use of DEAE-Sephadex A-50 and QAE-Sephadex A-25 column chromatography and investigated for their chemical and immunological properties. On the basis of sugar composition, the glycoproteins of the 11Sporothrix species could be divided into two groups, i.e., rhamnose containing (i.e., Rha⁺), and non rhamnose containing (i.e., Rha^–) groups. The species in the former group wereS. curviconia, S. inflata, S. schenckii andS. schenckii var. luriei, and those in the latter group wereS. cyanescens, S. foliorum, S. fungorum, S. ghanensis, S. imectorum, S. luteoalba andS. ramosissima. The glycoproteins of four of the (Rha⁺) species were relatively similar in elution patterns of DEAE-Sephadex A-50 chromatograms, sugar and amino acid compositions, serological reactivity with rabbit andS. schenckii serum and rabbit antiKlebsiella pneumoniae K47 serum, and cutaneous delayed hypersensitivity. In the case of the (Rha^–) species, the glycoproteins of five species cross-reacted with rabbit antiS. schenckii serum and all, but theS. cyanescens, glycoprotein were reactive to some degree in skin tests in sporotrichotic patients. These results strongly suggest that the chemical and immunological properties of these glycoproteins correspond with the morphological observations amongSporothrix species.     

Serological cross-reactivity betweenKlebsiella pneumoniae K47 andSporothrix species

The serological cross-reactivity ofKlebsiella pneumoniae K47 antiserum with antigens of 11Sporothrix species was investigated by use of immunodiffusion. Cross-reactions occurred withK. pneumoniae K47 and theSporothrix speciesS. schenckii, S. schenckii var.luriei, S. curviconia, andS. inflata.     

Proteomics-Based Characterization of the Humoral Immune Response in Sporotrichosis: Toward Discovery of Potential Diagnostic and Vaccine Antigens

Background

Sporothrix schenckii and associated species are agents of human and animal sporotrichosis that cause large sapronoses and zoonoses worldwide. Epidemiological surveillance has highlighted an overwhelming occurrence of the highly pathogenic fungus Sporothrix brasiliensis during feline outbreaks, leading to massive transmissions to humans. Early diagnosis of feline sporotrichosis by demonstrating the presence of a surrogate marker of infection can have a key role for selecting appropriate disease control measures and minimizing zoonotic transmission to humans.

Methodology

We explored the presence and diversity of serum antibodies (IgG) specific against Sporothrix antigens in cats with sporotrichosis and evaluated the utility of these antibodies for serodiagnosis. Antigen profiling included protein extracts from the closest known relatives S. brasiliensis and S. schenckii. Enzyme-linked immunosorbent assays and immunoblotting enabled us to characterize the major antigens of feline sporotrichosis from sera from cats with sporotrichosis (n = 49), healthy cats (n = 19), and cats with other diseases (n = 20).

Principal Findings

Enzyme-linked immunosorbent assay-based quantitation of anti-Sporothrix IgG exhibited high sensitivity and specificity in cats with sporotrichosis (area under the curve, 1.0; 95% confidence interval, 0.94–1; P<0.0001) versus controls. The two sets of Sporothrix antigens were remarkably cross-reactive, supporting the hypothesis that antigenic epitopes may be conserved among closely related agents. One-dimensional immunoblotting indicated that 3-carboxymuconate cyclase (a 60-kDa protein in S. brasiliensis and a 70-kDa protein in S. schenckii) is the immunodominant antigen in feline sporotrichosis. Two-dimensional immunoblotting revealed six IgG-reactive isoforms of gp60 in the S. brasiliensis proteome, similar to the humoral response found in human sporotrichosis.

Conclusions

A convergent IgG-response in various hosts (mice, cats, and humans) has important implications for our understanding of the coevolution of Sporothrix and its warm-blooded hosts. We propose that 3-carboxymuconate cyclase has potential for the serological diagnosis of sporotrichosis and as target for the development of an effective multi-species vaccine against sporotrichosis in animals and humans.     

Molecular Diagnosis of Pathogenic Sporothrix Species

Background

Sporotrichosis is a chronic (sub)cutaneous infection caused by thermodimorphic fungi in the order, Ophiostomatales. These fungi are characterized by major differences in routes of transmission, host predilections, species virulence, and susceptibilities to antifungals. Sporothrix species emerge in the form of outbreaks. Large zoonoses and sapronoses are ongoing in Brazil and China, respectively. Current diagnostic methods based on morphology and physiology are inaccurate due to closely related phenotypes with overlapping components between pathogenic and non-pathogenic Sporothrix. There is a critical need for new diagnostic tools that are specific, sensitive, and cost-effective.

Methodology

We developed a panel of novel markers, based on calmodulin (CAL) gene sequences, for the large-scale diagnosis and epidemiology of clinically relevant members of the Sporothrix genus, and its relative, Ophiostoma. We identified specific PCR-based markers for S. brasiliensis, S. schenckii, S. globosa, S. mexicana, S. pallida, and O. stenoceras. We employed a murine model of disseminated sporotrichosis to optimize a PCR assay for detecting Sporothrix in clinical specimens.

Results

Primer-BLAST searches revealed candidate sequences that were conserved within a single species. Species-specific primers showed no significant homology with human, mouse, or microorganisms outside the Sporothrix genus. The detection limit was 10–100 fg of DNA in a single round of PCR for identifying S. brasiliensis, S. schenckii, S. globosa, S. mexicana, and S. pallida. A simple, direct PCR assay, with conidia as a source of DNA, was effective for rapid, low-cost genotyping. Samples from a murine model of disseminated sporotrichosis confirmed the feasibility of detecting S. brasiliensis and S. schenckii DNA in spleen, liver, lungs, heart, brain, kidney, tail, and feces of infected animals.

Conclusions

This PCR-based method could successfully detect and identify a single species in samples from cultures and from clinical specimens. The method proved to be simple, high throughput, sensitive, and accurate for diagnosing sporotrichosis.     

Molecular Identification and Antifungal Susceptibility of Clinical Isolates of Sporothrix schenckii Complex in Medellin,Colombia

Background

Sporotrichosis is a subcutaneous mycosis that affects humans and other animals. Infection prevails in tropical and subtropical countries. Until a few years ago, it was considered that two varieties of Sporothrix schenckii caused this mycosis, but by applying molecular taxonomic markers, it has been demonstrated that there are several cryptic species within S. schenckii complex which varies in susceptibility, virulence, and geographic distribution.

Objective

This study aimed to identify the clinical isolates of Sporothrix spp. from patients with sporotrichosis in Medellin, Colombia, using two markers and to evaluate the in vitro susceptibility to itraconazole.

Methods

Thirty-four clinical isolates of Sporothrix spp. from Colombia, three from Mexico, and one from Guatemala were identified through sequencing of the noncoding region ITS-1?+?5.8SDNAr?+?ITS-2 and of the fragment containing exons 3 and 4 of the β-tubulin gene. Clinical isolate sequences were compared with GenBank reference sequences using the BLASTN tool, and then, phylogenetic analysis was performed. Besides, the in vitro susceptibility to itraconazole was evaluated by determining the minimum inhibitory concentrations according to the CLSI M38-A2 method.

Results

Clinical isolates were identified by morphology as Sporothrix spp. Using the molecular markers, ITS and β-tubulin, isolates were identified as S. schenckii sensu stricto (25) and Sporothrix globosa (13). Susceptibility to itraconazole was variable among clinical isolates.

Conclusion

This is the first scientific publication that identifies species that cause sporotrichosis in Colombia, along with the antifungal susceptibility to itraconazole.