Isolation of Microsporum gypseum in soil samples from different geographical regions of Brazil, evaluation of the extracellular proteolytic enzymes activities (keratinase and elastase) and molecular sequencing of selected strains

Giudice, Mauro Cintra; Reis-Menezes, Adriana Araújo; Rittner, Glauce Mary Gomes; Mota, Adolfo José; Gambale, Walderez

doi:10.1590/S1517-83822012000300007

Abstract

A survey of Microsporum gypseum was conducted in soil samples in different geographical regions of Brazil. The isolation of dermatophyte from soil samples was performed by hair baiting technique and the species were identified by morphology studies. We analyzed 692 soil samples and the recuperating rate was 19.2%. The activities of keratinase and elastase were quantitatively performed in 138 samples. The sequencing of the ITS region of rDNA was performed in representatives samples. M. gypseum isolates showed significant quantitative differences in the expression of both keratinase and elastase, but no significant correlation was observed between these enzymes. The sequencing of the representative samples revealed the presence of two teleomorphic species of M. gypseum (Arthroderma gypseum and A. incurvatum). The enzymatic activities may play an important role in the pathogenicity and a probable adaptation of this fungus to the animal parasitism. Using the phenotypical and molecular analysis, the Microsporum identification and their teleomorphic states will provide a useful and reliable identification system.

Microsporum gypseum; Brazil; Elastase; Keratinase; Sequencing

MEDICAL MICROBIOLOGY

Isolation of Microsporum gypseum in soil samples from different geographical regions of Brazil, evaluation of the extracellular proteolytic enzymes activities (keratinase and elastase) and molecular sequencing of selected strains

Mauro Cintra Giudice^I,III,^* * Corresponding Author. Mailing address: Bacteriology Laboratory LIM 54/ HCFMUSP and Institute of Tropical Medicine, University of São Paulo, São Paulo, SP, Brazil, Av. Dr. Enéas de Carvalho Aguiar, 470 São Paulo, SP. CEP 05403000, Brazil.; Tel.: +55-11-3061-7030 Fax: +55-11-30617043.; E-mail: mauro.giudice@gmail.com ; Adriana Araújo Reis-Menezes^I; Glauce Mary Gomes Rittner^I; Adolfo José Mota^II; Walderez Gambale^I

^IInstituto de Ciências Biomédicas, Departamento de Microbiologia, Universidade de São Paulo, SP, Brasil

^IILaboratório de Genética Molecular e Genomas, São José dos Campos, SP, Brasil

^IIILaboratório de Bacteriologia, Laboratório de Investigação Médica/54, Hospital das Clínicas, Faculdade de Medicina, Instituto de Medicina Tropical, Universidade de São Paulo, São Paulo, SP, Brasil

ABSTRACT

A survey of Microsporum gypseum was conducted in soil samples in different geographical regions of Brazil. The isolation of dermatophyte from soil samples was performed by hair baiting technique and the species were identified by morphology studies. We analyzed 692 soil samples and the recuperating rate was 19.2%. The activities of keratinase and elastase were quantitatively performed in 138 samples. The sequencing of the ITS region of rDNA was performed in representatives samples. M. gypseum isolates showed significant quantitative differences in the expression of both keratinase and elastase, but no significant correlation was observed between these enzymes. The sequencing of the representative samples revealed the presence of two teleomorphic species of M. gypseum (Arthroderma gypseum and A. incurvatum). The enzymatic activities may play an important role in the pathogenicity and a probable adaptation of this fungus to the animal parasitism. Using the phenotypical and molecular analysis, the Microsporum identification and their teleomorphic states will provide a useful and reliable identification system.

Key words:Microsporum gypseum; Brazil; Elastase; Keratinase; Sequencing.

INTRODUCTION

Microsporum gypseum is a geophilic dermatophyte, and in this group, is the main representative that affects humans and other animals (4, 21). The human infections are rare which may suggest a natural resistance to this infection or limited mechanisms of virulence of the fungus (12), furthermore, some outbreaks have been reported in different parts of the world (21). Atypical clinical manifestations, refractory to either topic or systemic treatments have already been described in literature in patients HIV positive, epidemiologically related to the source of geophilic infection (10, 11, 24).

The isolation of M. gypseum and other geophilic dermatophytes from soil can be obtained through the hair-baiting technique (Vambreuseghem method) (19). Several reports describe the M. gypseum on soils with distinct characteristics in different parts of the world (9, 10, 16, 25, 31, 41, 44).

The dermatophytes are capable of producing enzymes as a mechanism to degrade various substrates. Several enzymes have been described and eventually correlated with dermatophytes virulence (28, 37), like the keratinase (2, 14, 20, 26, 39, 42, 45), elastase (2, 18, 33, 37, 42), DNase (22, 42) and collagenase (17, 23, 30, 32). The keratinase seems to have a direct relation to the pathogenicity (13, 41). The elastase has an important role in the pathogenicity of other fungi such as Aspergillus fumigatus (8, 20, 39) and also, probably, to the dermatophytes (14, 17, 30).

The objectives of this study were evaluate the frequency of M. gypseum in Brazil's soil, demonstrate quantitatively the activities of both keratinase and elastase from these isolates, and identify representative samples through the sequence to examine the distribution of the teleomorphic states.

MATERIAL AND METHODS

Collection of soil samples and fungal identification

Samples of soil from different states of Brazil were collected in the cities' public places (parks, squares, bus-stops etc.) and at peripheral regions with a spatula and transferred to a plastic bag. The fungi were isolated from the soil with the Vambreuseghem technique (19) .Macroscopic and microscopic characterization, through giant colony and microculture techniques, respectively were performed (19).

Determination of the strain enzymatic profile

The quantitative evaluation for both enzymes was made in line with the procedures previously described, with some modifications (42,43).The M. gypseum samples were cultivated in Sabouraud dextrose broth (Oxoid) at 25ºC for 15 days. The conidia were harvested in sterile saline, and using a Newbauer Chamber, the conidial suspension was adjusted to 1.0 x 10⁶ conidia/ml.

Keratinase: One milliliter of suspension was inoculated in 50 ml of basal medium (6 g MgSO₄, 1.0 ml Protovit vitamin mixture (Roche, São Paulo, Brazil), 0,111 g CaCl₂, in 1000 ml distilled water) with 3 g keratin powder from hooves and horns (ICN, Montreal, Canada) and incubated at 25º for 28 days in the dark (36,43). One milliliter of 1500 g centrifuged culture supernatant was then mixed with 2 ml of buffer 200 mM Tris-HCI, CaCl₂ 100 mM, pH 8.0 plus 10 mg of Keratin Azure (Sigma, St. Louis, MO, USA) plus 2.0 mL of and afterwards incubated at 37 ºC for 24 h. Substrate degradation was measured in a spectrophotometer at 595 nm using uninoculated substrate buffer as a negative control. A keratinase unit (UK) was defined as an increase of 0.01 in the absorbance, when compared to the control.

Elastase: One milliliter of adjusted suspension was inoculated in 50 mL of the same basal medium with 3.0 g of elastin (Sigma St. Louis, MO, USA) and incubated at 25ºC for 28 days in the dark (43). Two milliliters of 1500 g centrifuged culture supernatant was then mixed with 2.0 mL of phosphate buffer (10 mM pH, 7.0) with 20 mg of Elastin Congo-Red (Sigma St. Louis, MO, USA) was incubated at 37ºC for 2 hours. The elastin degradation was evaluated by spectrophotometer in 495 nm wavelength. A unit of elastase (UE) was defined as the 0.1 increase in the absorption reading, when compared to the control.

DNA extraction

Extraction protocol was modified from Bir et al., 1995 (5), with some modifications. M. gypseum samples were incubated in Sabouraud broth medium for 14 days at 25ºC and the mycelia was powdered with liquid nitrogen and 3.0 mL of 10 mM phosphate buffer pH 6.0. Volumes of 20 µL chitinase (5U/mL) (Sigma) were added and it was incubated for 90 minutes at 25ºC temperature, shaking it many times. Equal volume of lysis buffer (50 mM Tris HCl, 50 mM EDTA, 3% SDS, 1% β-mercaptoethanol, pH 7.2) was added and the suspension was incubated at 55ºC for one hour, shaking it many times. The products were then subjected to heat treatment in a microwave oven for 3 seconds each for 3 times. Extraction with phenol:chloroform:isoamylalcohol (25:24:1) was performed and the DNA was precipitated with isopropyl alcohol at -20ºC for about 18 hours. DNA was washed with 70% ethanol and it was dried at environment temperature, rehydrated in 25 µL of TE buffer (10 mM Tris-HCl, 1 mM EDTA, pH 8.0) with RNase (10 µg/mL) and it was incubated in a dry bath for 30 minutes at 37ºC. The product was again drawn up with isoamilic phenol-chloroform-alcohol and the DNA was dissolved in 50 µL of sterile ultrapure water. The DNA concentration was determined spectrophotometrically. Quality of the DNA was evaluated by agarose 0.8 % in TAE buffer (1X) gel electrophoresis and stained with ethidium bromide. The visualization for confirmation of the extraction was done in the chamber of the GEL DOC 1000 equipment under ultraviolet rays (Bio-Rad).

PCR amplification

The amplification of the conserved regions of rDNA (ITS-PCR Internal Transcribed Spacers - Primer Chain Reaction) was performed with a pair of primes ITS1 (5' TCCGTAGGTGAACCTGCGG 3'), and ITS 4 (5' TCCTCCGCTTATTGATATGC 3') (6).

The mixture for a PCR was prepared in total volume of 25 µL containing the reaction buffer (10 mM Tris-HCl in pH 8.0, 50 mM of KCl, 1.5 mM of MgCl₂ 10 mM of each DNTP (Fermentas, USA), 0.125 µM of each primer, 2 U of Taq Polimerase and 50 ng of DNA). The amplification was performed in thermocycler (PTC 100, MJ Research, INC.) on the following conditions: 94ºC, 5 min (94ºC 1 min, 56ºC 30 s, 72ºC 1 min.) per 25 cycles and final extension at 72º 5 min.

Sequencing

Five specimens (three from Rondônia and two from São Paulo states) were arbitrarily selected to the sequencing. These isolates were chosen because they represent respectively the most sampled state (RO) and state where we have had the highest recuperating rate (SP) of Microsporum gypseum . After amplification, the PCR products were purified using QIAquick Spin Columns (Qiagen Corp.., Chatsworth, Calif.), and were reconstituted with 30 µL of distilled water. The sequencing was carried out in platforms for dna sequencing PDTIS, which we used Big Dye reagent (Applied Biosystem, Foster City CA, USA) and automated sequencer Applied Biosystems ABI Prism 3730 (Applied Biosystem, Foster CA, USA).. The sequences were submitted to a search on the BLASTn by using the databank of the National Center of Biotechnology (NCBI; http://www.ncbi.nlm.nih.gov/BLAST).

RESULTS

The soil samples were collected from all Brazilian regions. The largest Microsporum gypseum positivity percentual was obtained from the samples originated in the Southeast (SE), followed by the North (N), Southern (S) and Center-West (CW). In Northeast region, in the states evaluated, there was no isolation of M. gypseum (Table 1, Fig. 1). The number of soil samples collected was differed in each region, as well as the positivity percentage. In total, 692 soil samples were analyzed and the recuperating rate was 19.2%. In samples from some states it was not possible to obtain growth of M. gypseum (Bahia, Tocantins, Maranhão, Ceará and Rio de Janeiro). The state of São Paulo demonstrated larger fungus recuperation from the soil samples, proportionally, with a recuperating rate of 44.7%. The state of Rondônia contributed with the largest number of soil samples, but the recuperating rate was only 20.4% (Table 1, Fig. 1).

Thumbnail

The evaluation of both the elastinolytic and keratinolytic activities was performed in Microsporum gypseum (n=121) isolated from the soil from different states. The means and the standard deviations of the two enzymatic activities (UK and UE) were 6.90 ± 8.48 to UK and 1.60 ± 2.20 to UE. The median were 5.0 UK and 0.92 UE

The results of absolute and relative frequencies from both enzymatic activities for 121 samples of M. gypseum, are showed on Fig. 2 (a and b).

The Spearman's coefficient of correlation from two enzymatic activities (UK and UE) was very weak. In soils samples the coefficient of correlation was -0.014, a low negative, which suggests the absence of correlation among the enzymatic activities.

The sequencing of the representative samples revealed the presence of two teleomorphic species of M. gypseum (Arthroderma gypseum and A. incurvatum) and A. incurvatum was identified in only one of the isolated.

DISCUSSION

The isolation of M. gypseum can be obtained from human clinic sources, as well as from veterinarian or from the soil. The recuperating rate of this dermatophyte in clinic cases is very limited (21). However, reports of outbreaks, extensive cases and refractory therapeutics are already presented by the literature (10, 21). In this research, 692 samples of soil of different Brazilian regions were evaluated and the recuperating rate was 19.2%. Microsporum gypseum was isolated in almost all sampled regions, except for the Northeast. The great majority of the samples were collected both in urban environments and public parks places (parks and squares), at random and in different times of the year. The absence of homogeneity in the sampled areas and in the collecting period makes it difficult to compare the analyzed areas.

In the Northeast, a very extensive geographic area, which comprises different type of soil and population distribution variable, a more thorough study, must be done studying soil from all states in different seasons of the year, considering local environmental variables.

Some studies demonstrate that the recuperation of this fungus can change with the sampled environment. When one evaluates either public areas of both parks or public squares or areas of confinement of animals (breeding, slaughtering and zoos) the isolating rates may be very high, differently from those found in closed environments (domestic or hospital) (4, 9, 16, 21, 25, 31, 41, 44).

Both the synthesis and the enzymes secretion are important metabolic activities in filamentous fungi and their production is an indispensable condition to the fungi's development (1). Proteolytic enzymes, such as the keratinases, collagenases and elastases are important in various processes, some of that are implicated in the pathogenesis of fungal diseases, thereby causing damages to the host's tissue (2, 14, 34, 42).

The dermatophytes can produce various proteolytic enzymes and their lythic activities on different substrates, have already been described (3, 7, 8, 15, 17, 27, 29, 33, 36, 40, 42). The keratinase, among other enzymes, was considered as a virulence factor, which correlated with clinic forms of dermatophytosis (13).

In M. gypseum, T. mentagrophytes, T. verrucosum, Muhsin et al. (27) demonstrated the presence of elastase. However, the elastinolytic activity was not observed in strains of M. canis.

The data obtained from this work refer to the first report in the literature on hydrolytic enzymes activities in samples of Microsporum gypseum isolated from Brazilians soil samples,

This research was made to evaluate the degree of correlation as well as the description of both keratinase and elastase activities. The results suggested that the expressions of these enzymes, which are produced by M. gypseum, occur in samples isolated from environmental fonts.

The mean and median values obtained were higher in the keratinolytic activity than in the elastinolytic one.

In strains isolated from soil originated in 16 Brazil's different geographic regions, the larger intensity of keratinolytic activity occurred in one samples (sample 19, with 77.7 UK) and the same occurred to the elastinolytic activity (sample 26, with 12.85 UE), both recuperated in São Paulo state, but from different places. The correlation grade, however, was both low and negative between the two enzymatic activities evaluated.

More detailed studies with the samples that showed high grade of enzymatic activities and with other samples with low enzymatic activities must be performed, including both experimental infection and evaluation of the tissue compromise, with the intention of evaluating the host's compromising degree with the fungus and their metabolites.

In a previous study, which was performed to quantitatively evaluate both the keratinolytic and elastinolytic activities in M. canis, strains isolated from animals with and without clinic lesion, the results showed statistically significant differences, suggesting that the elastase like the keratinase, can influence the tissue reactions in the dermatophytosis (6).

There was no correlation among the strains with the production of each enzyme, suggesting that there is not only a proteinase with keratinolytic, elastinolytic activities, but specific enzymes to each substrate. Brouta et al. (7) demonstrated that two described proteases can exert activity on the keratin, the elastin and collagen by suggesting that these two proteases should be responsible for the observed keratinase, elastase and collagenase activities.

The differentiation among six species of the Microsporum, based on the characterization of ITS of rDNA region, was evaluated, demonstrating to be sufficient to separate them (35, 38) and, despite the fact that the Microsporum gypseum is endemic in different parts of the world, few studies of molecular analysis have been performed in this specie.

Molecular methods based on the rDNA amplification and associated with the enzymatic restriction have been used both to differentiate species and to biotype microorganisms (14, 35). The use of different restriction enzymes has afforded results which, when associated with phenotypic characteristics, can help the identification of isolated ones (7).

The PCR-RFLP with Mval enzyme in Microsporum species has often been used. Sharma et al. (35), when using the RFLP sequencing of the ITS region of rDNA plus phenotypic described a new taxon, Microsporum appendiculatum which is highly related to M. gypseum.

In our study, when evaluated the sequencing, a high identity was noted, showing that the ITS region is highly preserved in this specie. The sequencing revealed the presence of two teleomorphic species of M. gypseum (Arthroderma gypseum and A. incurvatum). Despite the fact that only few samples have been sequenced, A. incurvatum was identified in one of the isolated. The obtaining of the teleomorphic stage in vitro and the characterization of the species are very time consuming and, in the great majority, the results depend upon a very accurate morphological evaluation. Therefore the molecular methods of sequencing are promising.

In spite of the fact that the asexual reproduction among the dermatophytes is much more frequent than the sexual reproduction, constituting their principal way propagation, the molecular methods utilized here are still limited to characterize differences in these isolated and, possibly, the expression of the enzymatic activities must be related to genotypes not yet characterized by the techniques used in this study.

Geophilic dermatophytes are very common in Brazil soils and the relationship between the characterization based on morphological, biochemical and molecular aspects seems to be very important in demonstrate the real role in its pathogenicity. However, this fungal and its biological relationship requires to be better clarified once these fungi are found as human and veterinarian pathogens causing distinct clinic manifestations that are sometimes refractory to the available treatments at present.

ACKNOWLEDGEMENTS

We are grateful to the financial Foundation of Research Support of São Paulo Program for Centers of (FAPESP-PRONEX), National Council for Scientific and Technological (CNPq) and the group of Biomedical Center of University of São Paulo in Monte Negro (RO), Brazil.

Submitted: January 20, 2011; Approved: June 07, 2012.

1. Alvarez, D.P.; Luque, A.G.; Bracalenti, B.C. (1986). La influencia de factores ecológicos in el aislamento de dermatofitos queratinolíticos y geofílicos. Rev. Latinoam. Microbiol 28, 351-354.
2. Apodaca, G; Mckerrow J.H. (1989). Purification and characterization of a 27,000 Mr extracelullar proteinase from Trichophyton rubrum Infect. Immun 57(10), 3072-3080.
3. Aubaid, A.H.; Muhsin, T.M. (1998). Partial purification and kinetic studies of exocellular proteinase from Trichophyton mentagrophytes var. erinacei Mycoses 41, 163168.
4. Bársena-Asensio, .M.C.; Cabo, J.F.G. (1996). Ecología de los dermatofitos. Rev. Iberoam. Micol. 13(2), 47-54.
5. Bir, N.; Paliwal, A.; Muralidhar, K.; Reddy, P.; Usha-Sarma, P. (1995) A rapid method for the isolation of genomic DNA from Aspergillus fumigatus Prep. Biochem. 25(4), 171-181.
6. Blanz, P.; Buzia, W.; Ginter, G.; Gräser, Y. (2000). Molekularbiologische methoden und ihre konsequenzen für taxonomie und diagnostik dei dermatophyten. Mycoses 43(suppl. 1), 11-16.
7. Brouta, F.; Descamps, F.; Feti, T., et al. (2001). Purification and characterization of a 43.5 kDa keratinolytic metalloprotease from Microsporum canis Med. Mycol. 39, 269-275.
8. Chattaway, F.W.; Ellls, D.A.; Barlow, E.J. A.( 1963). Peptidases of Dermatophytes. The J. Invest. Dermatol. 41(1), 31-37.
9. Deshmukh, S.K. (2004). Isolation of dermatophytes and other keratinophilic fungi from the vicinity of salt pan soils of Mumbai, India. Mycopathologia157:265267.
10. Fernandes, N.C.; Lamy, F.; Akiti, T.; Da Barreiros, M.G.C. (1998). Microsporum gypseum infection in AIDS patient: a case report. An. Bras. Dermatol. 73, 39-41.
11. Giudice, M.C.; Szeszs, M.W,; Scarpini, R.L. et al.(1997). Clinical and epidemiological study in an AIDS patient case with Microsporum gypseum infection. Rev. Iberoam. Micol. 14(4), 184-187.
12. Gordon, M.A.; Perrin, N.; Little, G.N. (1967). Differences in pathogencit between M. gypseum and M. fulvum Sabouraudia5,366-390.
13. Grappel, S.F.; Blank, F. Role of keratinase in dermatophytosis. (1972). Dermatologica 145, 245-255.
14. Gupta, R.; Ramnani, P. (2006) Microbial keratinases and their prospective applications: an overview. Appl. Microbiol. Biotechnol 70, 21-33.
15. Hamaguchi, T.; Morishita, N.; Usui, R.; Takiuchi, I. (2000). Characterization of an extracellular keratinase from Microsporum canis Japanese J. Med. Mycol. 41, 257-262.
16. Hedayat, M.T.; Mohseni-Bandpi, A.; Moradi, S. ( 2004). A survey on the pathogenic fungi in soil samples of potted plants from Sari hospitals, Iran. J. Hosp. Infect. 58 (1), 59-62.
17. Ibrahim-Granet, O.; Hernandez, F..; Chevrier, G.; Dupont, B. (1996) Expression of PZ-peptidases by cultures of several pathogenic fungi. Purification and characterization of a collagenase from Trichophyton schoenleinii J.Med. Vet. Mycol 34, 83-90.
18. Kothary, M.H.; Chase, T.; Macmillan, J.D. (1984) Correlation of elastase production by strain of Aspergillus fumigatus with ability to cause pulmonary invasive aspergillosis in mice. Infect. Immun43(1), 320-325.
19. Lacaz, C.S.; Porto, E.; Martins, J.E.C.; Heins-Vaccari, E.M.;, Melo, N.T. (2002) Tratado de Micologia Médica 9th ed. Sarvier, São Paulo, 2002.
20. Lee, K.H.; Park, K.K.; Park, S.H.; Lee, J.B. (1987). Isolation, purification and characterization of keratinolytic proteinase from Microsporum canis Yonsei Med. J. 28(2), 131-138.
21. Londero, A.T.; Ramos, C.D. (1989). Agentes de dermatofitoses humanas no interior do Estado do Rio Grande do Sul, no período de 1960-1987. An. Bras. Dermatol. 64(3), 161-164.
22. Lópes-Martinez, R.; Manzano-Gayosso, P.; Mier, T.; Mendez-Tovar, L.J.; Hernández-Hernández, F. (1994). Exoenzimas de dermatofitos aislados de tiñas agudas y crônicas. Rev. Latinoam. Microbiol 36, 17-20.
23. Lupan, D.M.; Nziramasanga, P. (1986). Collagenolytic Activity of Coccidioides immitis Infect. Immun 51(1), 360-361.
24. Luque, A.G.; Biasoli, M.S.; Ortino, M.A.; Lupo, S.H.; Bussy, R.F. (2001). Atypical tinea corporis caused by Microsporum gypseum in a subject with acquired immune deficiency syndrome. J. Eur. Acad. Dermatol. Venereol15, 374-375.
25. Mercantini, R.; Marsella, R.; Cervellati, M.C. (1989).Keratinophylic fungi isolated from Antartic soil. Mycophatologia106, 47-52.
26. Mignon, B.R.; Nikkles, A.F.; Piérard, G.E.; Losson, B.J. (1998). The in vitro and in vivo production of a 31.5 kDa keratinolitic subtilase from Microsporum canis and the clinical status in naturally infected cats. Dermatology196, 438-441.
27. Muhsin, T.M.; Aubaid, A.H.; Al-Duboon, A.H. (1997). Extracellular enzyme activities of dermatophytes and yeast isolates on solid media. Mycoses. 40, 465-469.
28. Muhsin, T.M.; Salih, T.H. (2001). Exocellular enzyme activity of dermatophytes and other fungi isolated from ruminants in Southern Iraq. Mycopathologia150(2), 49-52.
29. Okafor, J.; Ngwogu, A. (2000). Keratinolytic activity of five human isolates of dermatophytes. J. Commun. Dis 32(4), 300-305.
30. Okeke, C.N.; Müller, J. (1991). Production of extracellelar collagenolytic proteinases by Histoplasma capsulatum var. duboisii and Histoplasma capsulatum var. capsulatum in the yeast phase. Mycoses 34, 453-460.
31. Periasamy, A.; Hilda, A.; Gopinath, S.C.B. (2004). Keratinophilic fungi of poultry farm and feather dumping soil in Tamil Nadu, India. Mycopathologia158, 303309.
32. Rippon, J.W.; Varadi, D.P. (1968). The elastases of pathogenic fungi and actinomycetes. The J. Invest. Dermatol 50(1), 54-58.
33. Rippon, J.W. (1967). Elastase production by ringworm fungi. Science157, 947.
34. Scott, J.A,.; Untereiner, W.A. (2004). Determination of keratin degradation by fungi using keratin azure. Med. Mycol 42, 239-246.
35. Sharma, R.; Rajak, R.C.; Pandey, A.K.; Gräser, Y. (2006)Internal Transcribed Spacer (ITS) of rDNA of appendaged and non-appendaged strains of Microsporum gypseum reveals Microsporum appendiculatum as its synonym. Antonie van Leeuwenhoek. 89(1), 197-202.
36. Siesenop, U.; Bohm, K. H. (1995). Comparative studies on keratinase production of Trichophyton mentagrophytes strains of animal origin. Mycoses38, 205-209.
37. Simpanya, M.F.; Baxter, M. (1996). Multiple proteinases from two Microsporum species. J. Med. Vet. Mycol. 34, 31-36.
38. Summerbel, R.C.; Moore, M.K.; Starink-Willemse, M.; Van Iperen, A. (2007) ITS barcodes for Trichophyton tonsurans and T. Equinum. Med. Mycol 45, 193-200.
39. Takiuchi, I.; Higuchi, D.; Sei, Y.; Koga, M. (1982). Isolation of an extracellular proteinase (keratinase) from Microsporum canis Sabouraudia. 20, 281-288.
40. Takiuchi, I.; Youshihiro, S.; Hisae, T.; Makoto, N. (1984). Partial characterization of the extracelular keratinase from Microsporum canis Sabouraudia 22(3), 219 - 224.
41. Ulfig, K.; Plaza, G.; Sztyler, A.; Bronder, J.; Terakowiski, M.; Guarro, J. (2000) General assessment of the influence of a municipal landfill site and environmental factors on the occurrence of keratinolytic fungi in soil. Rocz. Panstw. Zakl. Hig. 51(2), 167-81.
42. Viani, F.C.; Dos Santos, J.I.; Paula, C.R.; Larsson, C.E.; Gambale, W. (2001) Production of extracellular enzymes by Microsporum canis and their role in its virulence. Med. Mycol. 39 (5), 463-468.
43. Viani, F.C.; Viani, P.R.C.; Rivera, I.N.G.; Silva, E.G.; Paula, C.R.; Gambale, W. (2007). Extracellular proteolytic activity and molecular analysis of Microsporum canis strains isolated from symptomatic and asymptomatic cats. Rev. Iberoam. Micol. 24(1), 19-23.
44. Vidyasagar, G.M.; Narayan, H.; Shivkumar, D. (2005) Keratinophilic fungi isolated from hospital dust and soils of public places at Gulbarga, India. Mycopathologia159, 1321.
45. Yu, R.J.; Harmon, S.R, (1968). Isolation and purification of an extracellular keratinase of Trichophyton mentagrophytes J. Bacteriol. 96(4), 1435-1436.

*

Corresponding Author. Mailing address: Bacteriology Laboratory LIM 54/ HCFMUSP and Institute of Tropical Medicine, University of São Paulo, São Paulo, SP, Brazil, Av. Dr. Enéas de Carvalho Aguiar, 470 São Paulo, SP. CEP 05403000, Brazil.; Tel.: +55-11-3061-7030 Fax: +55-11-30617043.; E-mail:

mauro.giudice@gmail.com

Publication Dates

Publication in this collection
26 Nov 2012
Date of issue
Sept 2012

History

Received
20 Jan 2011
Accepted
07 June 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Alvarez, D.P.; Luque, A.G.; Bracalenti, B.C. (1986). La influencia de factores ecológicos in el aislamento de dermatofitos queratinolíticos y geofílicos. Rev. Latinoam. Microbiol 28, 351-354.

[2] 2. Apodaca, G; Mckerrow J.H. (1989). Purification and characterization of a 27,000 Mr extracelullar proteinase from Trichophyton rubrum Infect. Immun 57(10), 3072-3080.

[3] 3. Aubaid, A.H.; Muhsin, T.M. (1998). Partial purification and kinetic studies of exocellular proteinase from Trichophyton mentagrophytes var. erinacei Mycoses 41, 163168.

[4] 4. Bársena-Asensio, .M.C.; Cabo, J.F.G. (1996). Ecología de los dermatofitos. Rev. Iberoam. Micol. 13(2), 47-54.

[5] 5. Bir, N.; Paliwal, A.; Muralidhar, K.; Reddy, P.; Usha-Sarma, P. (1995) A rapid method for the isolation of genomic DNA from Aspergillus fumigatus Prep. Biochem. 25(4), 171-181.

[6] 6. Blanz, P.; Buzia, W.; Ginter, G.; Gräser, Y. (2000). Molekularbiologische methoden und ihre konsequenzen für taxonomie und diagnostik dei dermatophyten. Mycoses 43(suppl. 1), 11-16.

[7] 7. Brouta, F.; Descamps, F.; Feti, T., et al. (2001). Purification and characterization of a 43.5 kDa keratinolytic metalloprotease from Microsporum canis Med. Mycol. 39, 269-275.

[8] 8. Chattaway, F.W.; Ellls, D.A.; Barlow, E.J. A.( 1963). Peptidases of Dermatophytes. The J. Invest. Dermatol. 41(1), 31-37.

[9] 9. Deshmukh, S.K. (2004). Isolation of dermatophytes and other keratinophilic fungi from the vicinity of salt pan soils of Mumbai, India. Mycopathologia157:265267.

[10] 10. Fernandes, N.C.; Lamy, F.; Akiti, T.; Da Barreiros, M.G.C. (1998). Microsporum gypseum infection in AIDS patient: a case report. An. Bras. Dermatol. 73, 39-41.

[11] 11. Giudice, M.C.; Szeszs, M.W,; Scarpini, R.L. et al.(1997). Clinical and epidemiological study in an AIDS patient case with Microsporum gypseum infection. Rev. Iberoam. Micol. 14(4), 184-187.

[12] 12. Gordon, M.A.; Perrin, N.; Little, G.N. (1967). Differences in pathogencit between M. gypseum and M. fulvum Sabouraudia5,366-390.

[13] 13. Grappel, S.F.; Blank, F. Role of keratinase in dermatophytosis. (1972). Dermatologica 145, 245-255.

[14] 14. Gupta, R.; Ramnani, P. (2006) Microbial keratinases and their prospective applications: an overview. Appl. Microbiol. Biotechnol 70, 21-33.

[15] 15. Hamaguchi, T.; Morishita, N.; Usui, R.; Takiuchi, I. (2000). Characterization of an extracellular keratinase from Microsporum canis Japanese J. Med. Mycol. 41, 257-262.

[16] 16. Hedayat, M.T.; Mohseni-Bandpi, A.; Moradi, S. ( 2004). A survey on the pathogenic fungi in soil samples of potted plants from Sari hospitals, Iran. J. Hosp. Infect. 58 (1), 59-62.

[17] 17. Ibrahim-Granet, O.; Hernandez, F..; Chevrier, G.; Dupont, B. (1996) Expression of PZ-peptidases by cultures of several pathogenic fungi. Purification and characterization of a collagenase from Trichophyton schoenleinii J.Med. Vet. Mycol 34, 83-90.

[18] 18. Kothary, M.H.; Chase, T.; Macmillan, J.D. (1984) Correlation of elastase production by strain of Aspergillus fumigatus with ability to cause pulmonary invasive aspergillosis in mice. Infect. Immun43(1), 320-325.

[19] 19. Lacaz, C.S.; Porto, E.; Martins, J.E.C.; Heins-Vaccari, E.M.;, Melo, N.T. (2002) Tratado de Micologia Médica 9th ed. Sarvier, São Paulo, 2002.

[20] 20. Lee, K.H.; Park, K.K.; Park, S.H.; Lee, J.B. (1987). Isolation, purification and characterization of keratinolytic proteinase from Microsporum canis Yonsei Med. J. 28(2), 131-138.

[21] 21. Londero, A.T.; Ramos, C.D. (1989). Agentes de dermatofitoses humanas no interior do Estado do Rio Grande do Sul, no período de 1960-1987. An. Bras. Dermatol. 64(3), 161-164.

[22] 22. Lópes-Martinez, R.; Manzano-Gayosso, P.; Mier, T.; Mendez-Tovar, L.J.; Hernández-Hernández, F. (1994). Exoenzimas de dermatofitos aislados de tiñas agudas y crônicas. Rev. Latinoam. Microbiol 36, 17-20.

[23] 23. Lupan, D.M.; Nziramasanga, P. (1986). Collagenolytic Activity of Coccidioides immitis Infect. Immun 51(1), 360-361.

[24] 24. Luque, A.G.; Biasoli, M.S.; Ortino, M.A.; Lupo, S.H.; Bussy, R.F. (2001). Atypical tinea corporis caused by Microsporum gypseum in a subject with acquired immune deficiency syndrome. J. Eur. Acad. Dermatol. Venereol15, 374-375.

[25] 25. Mercantini, R.; Marsella, R.; Cervellati, M.C. (1989).Keratinophylic fungi isolated from Antartic soil. Mycophatologia106, 47-52.

[26] 26. Mignon, B.R.; Nikkles, A.F.; Piérard, G.E.; Losson, B.J. (1998). The in vitro and in vivo production of a 31.5 kDa keratinolitic subtilase from Microsporum canis and the clinical status in naturally infected cats. Dermatology196, 438-441.

[27] 27. Muhsin, T.M.; Aubaid, A.H.; Al-Duboon, A.H. (1997). Extracellular enzyme activities of dermatophytes and yeast isolates on solid media. Mycoses. 40, 465-469.

[28] 28. Muhsin, T.M.; Salih, T.H. (2001). Exocellular enzyme activity of dermatophytes and other fungi isolated from ruminants in Southern Iraq. Mycopathologia150(2), 49-52.

[29] 29. Okafor, J.; Ngwogu, A. (2000). Keratinolytic activity of five human isolates of dermatophytes. J. Commun. Dis 32(4), 300-305.

[30] 30. Okeke, C.N.; Müller, J. (1991). Production of extracellelar collagenolytic proteinases by Histoplasma capsulatum var. duboisii and Histoplasma capsulatum var. capsulatum in the yeast phase. Mycoses 34, 453-460.

[31] 31. Periasamy, A.; Hilda, A.; Gopinath, S.C.B. (2004). Keratinophilic fungi of poultry farm and feather dumping soil in Tamil Nadu, India. Mycopathologia158, 303309.

[32] 32. Rippon, J.W.; Varadi, D.P. (1968). The elastases of pathogenic fungi and actinomycetes. The J. Invest. Dermatol 50(1), 54-58.

[33] 33. Rippon, J.W. (1967). Elastase production by ringworm fungi. Science157, 947.

[34] 34. Scott, J.A,.; Untereiner, W.A. (2004). Determination of keratin degradation by fungi using keratin azure. Med. Mycol 42, 239-246.

[35] 35. Sharma, R.; Rajak, R.C.; Pandey, A.K.; Gräser, Y. (2006)Internal Transcribed Spacer (ITS) of rDNA of appendaged and non-appendaged strains of Microsporum gypseum reveals Microsporum appendiculatum as its synonym. Antonie van Leeuwenhoek. 89(1), 197-202.

[36] 36. Siesenop, U.; Bohm, K. H. (1995). Comparative studies on keratinase production of Trichophyton mentagrophytes strains of animal origin. Mycoses38, 205-209.

[37] 37. Simpanya, M.F.; Baxter, M. (1996). Multiple proteinases from two Microsporum species. J. Med. Vet. Mycol. 34, 31-36.

[38] 38. Summerbel, R.C.; Moore, M.K.; Starink-Willemse, M.; Van Iperen, A. (2007) ITS barcodes for Trichophyton tonsurans and T. Equinum. Med. Mycol 45, 193-200.

[39] 39. Takiuchi, I.; Higuchi, D.; Sei, Y.; Koga, M. (1982). Isolation of an extracellular proteinase (keratinase) from Microsporum canis Sabouraudia. 20, 281-288.

[40] 40. Takiuchi, I.; Youshihiro, S.; Hisae, T.; Makoto, N. (1984). Partial characterization of the extracelular keratinase from Microsporum canis Sabouraudia 22(3), 219 - 224.

[41] 41. Ulfig, K.; Plaza, G.; Sztyler, A.; Bronder, J.; Terakowiski, M.; Guarro, J. (2000) General assessment of the influence of a municipal landfill site and environmental factors on the occurrence of keratinolytic fungi in soil. Rocz. Panstw. Zakl. Hig. 51(2), 167-81.

[42] 42. Viani, F.C.; Dos Santos, J.I.; Paula, C.R.; Larsson, C.E.; Gambale, W. (2001) Production of extracellular enzymes by Microsporum canis and their role in its virulence. Med. Mycol. 39 (5), 463-468.

[43] 43. Viani, F.C.; Viani, P.R.C.; Rivera, I.N.G.; Silva, E.G.; Paula, C.R.; Gambale, W. (2007). Extracellular proteolytic activity and molecular analysis of Microsporum canis strains isolated from symptomatic and asymptomatic cats. Rev. Iberoam. Micol. 24(1), 19-23.

[44] 44. Vidyasagar, G.M.; Narayan, H.; Shivkumar, D. (2005) Keratinophilic fungi isolated from hospital dust and soils of public places at Gulbarga, India. Mycopathologia159, 1321.

[45] 45. Yu, R.J.; Harmon, S.R, (1968). Isolation and purification of an extracellular keratinase of Trichophyton mentagrophytes J. Bacteriol. 96(4), 1435-1436.