Masako Kawasaki

Sporothrix brasiliensis, S. globosa, and S. mexicana, Three New Sporothrix Species of Clinical Interest

ABSTRACT Sporothrix schenckii is the species responsible for sporotrichosis, a fungal infection caused by the traumatic implantation of this dimorphic fungus. Recent molecular studies have demonstrated that this species constitutes a complex of numerous phylogenetic species. Since the delineation of such species could be of extreme importance from a clinical point of view, we have studied a total of 127 isolates, most of which were received as S. schenckii, including the available type strains of species currently considered synonyms, and also some close morphological species. We have phenotypically characterized all these isolates using different culture media, growth rates at different temperatures, and numerous nutritional tests and compared their calmodulin gene sequences. The molecular analysis revealed that Sporothrix albicans, S. inflata, and S. schenckii var. luriei are species that are clearly different from S. schenckii. The combination of these phenetic and genetic approaches allowed us to propose the new species Sporothrix brasiliensis, S. globosa, and S. mexicana. The key phenotypic features for recognizing these species are the morphology of the sessile pigmented conidia, growth at 30, 35, and 37°C, and the assimilation of sucrose, raffinose, and ribitol.

Phylogeny of the genera Trichophyton using mitochondrial DNA analysis

Diversity of mitochondrial DNA (mtDNA) was investigated in 92 Trichophyton rubrum strains, 2 T. mentagrophytes var. mentagrophytes, 2 T. m. vor. interdigitale, 2 T. m. var. goetzii, 1 T. m. var. erinacei, 2 T. quinckeanum, 2 T. schoenleinii, 1 T. tonsurans, 2 T. verrucosum var. album, 2 T. v. var. discoides, 1 T. violaceum var. violaceum, 1 Arthroderma benhamiae, and 1 A. vanbreuseghemii using endonucleases, Hae III, Msp I, Hind III, Xba I, and Bgl II. Trichophyton species were divided into 7 groups, and a phylogenetic tree was produced based on sequence divergence within mtDNA. The following results were obtained: (1) T. rubrum was divided into 2 groups Type I and Type II, and was suggested to be a complex. (2) A. benhamiae was closely related to T. m. var. erinacei. (3) T. rubrum Type II, T. tonsurans, and A. vanbreuseghemii showed identical restriction profiles, and were suggested to be closely related to each other or identical. (4) T. quinckeanum and T. schoenlenii showed identical restriction profiles, which differed slightly from those of A. vanbreuseghemii. (5) mtDNA analysis was useful in identifying pleomorphic strains.

Rapid identification of Trichophyton tonsurans by PCR-RFLP analysis of ribosomal DNA regions

BACKGROUND Culture morphology of Trichophyton (T.) tonsurans, an emerging pathogen of dermatophytosis in Japan, varies widely and species level identification is sometimes very difficult. Reliable molecular markers are expected to be introduced for their identification. OBJECTIVE The present study was conducted to evaluate the efficacy of restriction fragment length polymorphism (RFLP) analysis of PCR amplified ribosomal (r) DNA including internal transcribed spacers (ITS), as an identification tool. METHODS Total cellular DNA was extracted from 26 Japanese isolates of T. tonsurans, along with several taxa of the members in the T. mentagrophytes complex, T. rubrum, T. violaceum and Epidermophyton floccosum, using a mini-preparation method. PCR amplicons were digested with restriction enzymes Mva I or Hinf I, then electrophoresed on 5% polyacrylamide gel. RESULTS The banding profiles were observed about 8 h from initiating DNA extraction. Intraspecies polymorphism was not detected among T. tonsurans isolates, and their profiles obtained using Mva I digestion were clearly different from those of the other dermatophyte species. The restriction profiles evaluated from nucleotide sequence of the regions by a computer analysis were compatible with the electrophoresed profiles on gel. CONCLUSION PCR-RFLP analysis is a rapid and reliable tool for the identification of T. tonsurans.

Species-identification of dermatophytes Trichophyton, Microsporum and Epidermophyton by PCR and PCR-RFLP targeting of the DNA topoisomerase II genes

BACKGROUND We have focused on the DNA topoisomerase II genes of pathogenic fungi and have previously applied polymerase chain reaction (PCR)-based identification of several species including the some of the major dermatophyte species. OBJECTIVE To identify the dermatophytes (18 species) to a species level by PCR and PCR-restriction fragment length polymorphism (RFLP) techniques, without determining the nucleotide sequence. METHODS The genomic DNAs of the dermatophytes (ten species of Trichophyton, seven species of Microsporum, and Epidermaphyton floccosum) were amplified by PCR using a common primer set (dPsD1) for the dermatophytes, followed by nested PCR using other primer sets (dPsD2, PsT and PsME) that contained primers specific for the DNA topoisomerase II genes of the dermatophytes. PCRs using PsT and PsME were used for the species-identification of Trichophyton, Microsporum and E. floccosum. The PCR products generated by dPsD2 were digested with restriction enzymes (Hinc II, Hinf, Afl II and PflM I), and the restriction profiles were analyzed. RESULTS Of the eighteen species of dermatophytes, five species (T. rubrum, T. violaceum, M. canis, M. gypseum and E. floccosum) were specifically identified by the PCR using PsT and PsME to the species level, and the remaining species were identified by the unique restriction profiles for each species in the PCR-RFLP analysis, except that the restriction profile of T. mentagrophytes var. interdigitale was identical to that of T. mentagrophytes var. quinckeanum. CONCLUSION PCR and PCR-RFLP techniques targeting the DNA topoisomerase II gene are simple and rapid, and quite useful as tools for the identification of dermatophytes to the species level.

Analysis of restriction profiles of Mitochondrial DNA from Sporothrix schenckii and related fungi

Restriction profiles by HaeIII of mitochondrial DNA were studied for classification and distinction of Sporothrix schenckii (100 strains), S. schenckii var. luriei (1), S. curviconia (1), S. inflata (7), Ceratocystis stenoceras (17) and C. minor (7). These 6 species showed unique restriction profiles which could be discriminated from each other. S. schenckii was further separable into 11 types, S. inflata into 4 types, C. stenoceras into 4 types and C. minor into 7 types based on restriction profile heterogeneity.

Taxonomy of Trichophyton interdigitale (Trichophyton mentagrophytes var. interdigitale) by restriction enzyme analysis of mitochondrial DNA

The relationship between Trichophyton interdigitale (Trichophyton mentagrophytes var. interdigitale) and the other members of the T. mentagrophytes complex was studied by restriction enzyme analysis of mitochondrial DNA (mtDNA). The mtDNA of 22 isolates of T. interdigitale from Japanese patients with dermatophytosis was extracted, digested with the restriction enzymes Hae III, Msp I, or Hind III, and the restriction profiles obtained compared with those of Arthroderma simii, Arthroderma benhamiae and Arthroderma vanbreuseghemii. The restriction profiles obtained for T. interdigitale were identical to those of A. vanbreuseghemii. Thus, these two species are considered to be closely related.

Molecular epidemiology of Arthroderma benhamiae, an emerging pathogen of dermatophytoses in Japan, by polymorphisms of the non-transcribed spacer region of the ribosomal DNA.

In Japan, several isolates of Arthroderma benhamiae, a teleomorphic member of Trichophyton mentagrophytes complex, which were not found by earlier mating studies, have recently been recovered from human and animal dermatophytoses. In the present study, intraspecies polymorphism of A. benhamiae isolated in Japan was investigated using restriction fragment length polymorphisms (RFLP) of the non-transcribed spacer (NTS) region of the ribosomal DNA (rDNA), a method introduced to detect intraspecies polymorphisms of other dermatophyte species, such as T. rubrum. Based on their restriction profiles, there were five DNA types out of eight strains of A. benhamiae isolated in Japan. None of the five DNA types were found among the registered tester strains of A. benhamiae. Therefore, several different strains of A. benhamiae may have been brought into Japan separately.

Mitochondrial DNA analysis of Exophiala jeanselmei and Exophiala dermatitidis

Mitochondrial DNA (mtDNA) analysis with Hae III, Hind. III and Msp I was performed in 45 Exophiala jeanselmei strains (30 Phialophora jeanselmei and 15 Phialophora gougerotii strains) and 31 Exophiala dermatitidis strains. The results were as follows, 1) P. jeanselmei and P. gougerotii are identical, 2) E. jeanselmei is classified into 18 types based on restriction profiles, 3) two strains of E. jeanselmei CBS 577.76 and CBS 578.76 are identified as E. dermatitidis, 4) E. dermatitidis has no intraspecific variation and is definitely distinct from E. jeanselmei, 5) E. jeanselmei is suggested to be a complex organism because of extensive mtDNA polymorphism.

Mitochondrial DNA analysis of Sporothrix schenckii in North and South America

Mitochondrial DNA (mtDNA) types based on restriction fragment length polymorphism (RFLP) patterns with HaeIII were investigated in clinical isolates of Sporothrix schenckii in North and South America. In addition to 14 mtDNA types (Types 1–14) so far reported, six new mtDNA types, Types 15–20 were found in this study. Type 3 was divided into two subtypes, Subtype 3A and Subtype 3B based on RFLP with Msp1. Type 14 was also divided into three subtypes, Subtype 14A, Subtype 14B and Subtype 14C based on RFLP with Hha1. Nineteen isolates in the United States consisted of 1 isolate of Type 1, 12 of Type 2, 2 of Type 4, 3 of Type 14 (1 of Subtype 14B and 2 of Subtype 14C) and 1 of Type 15. Twenty nine isolates in Venezuela consisted of 13 of Type 3 (Subtype 3B), 6 of Type 4, 1 of Type 18, 3 of Type 19 and 6 of Type 20. Thirteen isolates in Argentina consisted of 2 of Type 3 (Subtype 3A), 4 of Type 4, 4 of Type 16 and 3 of Type 17. One isolate in Brazil was Type 3 (Subtype 3A). Based on the phylogeny of 20 mtDNA types (Types 1–20) constructed by estimating sequence divergences of mtDNA, mtDNA types were clustered into two groups: Group A (Types 1–3, Type 11 and Types 14–19) and Group B (Types 4–10, Types 12–13 and Type 20). These results suggest that S. schenckiiisolates in North and South America mainly belong to Group A.

Phylogeny and molecular epidemiology of Sporothrix schenckii in Japan

Mitochondrial DNA(mtDNA) diversity was investigated in 257 clinical isolants of Sporothrix schenckii obtained from 4 districts in Japan. S. schenckii was classified into 10 types based on Hae III restriction profiles. Phylogeny of types constructed by the method of Fitch and Margoliash [1] on the estimated sequence divergence within mtDNA using the methods of Nei and Li [2], showed that S. schenckii are grouped into 2 clusters, one group consisting of types 1, 2 and 3, and the other group consisting of the other seven types. In addition, types 1, 2, and 5 were correlated with their geographic origin, whereas type 4 was present throughout Japan.