Sugarcane: an unexpected habitat for black yeasts in Chaetothyriales

Sugarcane (Saccharum officinarum, Poaceae) is cultivated on a large scale in (sub)tropical regions such as Brazil and has considerable economic value for sugar and biofuel production. The plant is a rich substrate for endo- and epiphytic fungi. Black yeasts in the family Herpotrichiellaceae (Chaetothyriales) are colonizers of human-dominated habitats, particularly those rich in toxins and hydrocarbon pollutants, and may cause severe infections in susceptible human hosts. The present study assessed the diversity of Herpotrichiellaceae associated with sugarcane, using in silico identification and selective isolation. Using metagenomics, we identified 5833 fungal sequences, while 639 black yeast-like isolates were recovered in vitro. In both strategies, the latter fungi were identified as members of the genera Cladophialophora, Exophiala, and Rhinocladiella (Herpotrichiellaceae), Cyphellophora (Cyphellophoraceae), and Knufia (Trichomeriaceae). In addition, we discovered new species of Cladophialophora and Exophiala from sugarcane and its rhizosphere. The first environmental isolation of Cladophialophora bantiana is particularly noteworthy, because this species up to now is exclusively known from the human host where it mostly causes fatal brain disease in otherwise healthy patients. Supplementary Information The online version contains supplementary material available at 10.1186/s43008-023-00124-7.


INTRODUCTION
Sugarcane (Saccharum officinarum, Poaceae) is a perennial grass cultivated on a large scale in tropical and subtropical regions (Lima et al. 2001).The economic interest in sugarcane is based on its main derivatives, which are sugar, alcohol, and bagasse, as well as a variety of by-products (Cheavegatti-Gianotto et al. 2011).In Brazil, sugarcane is an expanding crop covering the Midwest, Southeast, South, and Northeast regions (Cheavegatti-Gianotto et al. 2011;De Arruda et al. 2017).Sugarcane biomass is mainly composed of cellulose, hemicellulose, and lignin; sugar content is approximately 15.5 to 24% (Canilha et al. 2012).Upon decomposition in biotechnological processes, microbial degradation of lignin occurs through enzymes such as laccases and peroxidases (Kumar et al. 2009).Genomic studies of several black yeast-like fungi have identified the coding genes for these enzymes (Teixeira et al. 2017;Vicente et al. 2017;Moreno et al. 2017).
Clinical cases of chromoblastomycosis and phaeohyphomycosis are reported worldwide, and the World Health Organization (WHO) has classified the two diseases as Neglected Tropical Diseases (NTDs) (Queiroz-Telles et al. 2017;Revankar et al. 2017).Chromoblastomycosis is an occupational skin disease with acanthosis that affects rural workers exposed to soil and plant material.In Brazil, the highest incidence of chromoblastomycosis occurs in the Amazon region and Maranhão State, which are characterized as endemic areas (Gomes et al. 2016;Santos et al. 2020).Chromoblastomycosis is diagnosed by the presence of muriform fungal cells in expanding tissue.In contrast, phaeohyphomycosis leads to tissue invasion and necrosis by septate hyphae (Revankar et al. 2017;Arcobello & Revankar 2020).Severe, disseminated forms of these diseases are observed in patients with inherited CARD9-related immunodeficiency (Vaezi et al. 2018;Song et al. 2021).
The epidemiological data of these diseases suggest an environmental infection route, even though only few studies reported the presence of infectious species in the natural environment (Vicente et al. 2008(Vicente et al. , 2014;;Salgado et al. 2004;Lima et al. 2020).Culture-independent methods provide an additional approach to environmental studies, due to their capacity to explore large areas revealing the presence of non-cultured species in complex samples by recognition of DNA markers (Cuadros-Orellana et al. 2013).Metagenomic data have successfully been applied in the family Herpotrichiellaceae in Brazilian sugarcane (Souza et al. 2016).Molecular markers were shown to be effective in demonstrating the environmental presence of agents of chromoblastomycosis and phaeohyphomycosis (Costa et al. 2020).The present study aims to analyze the prevalence of human-opportunistic members of the family Herpotrichiellaceae in sugarcane plants through combined in silico and isolation methods.

Metagenomics dataset and molecular markers
Consulted metagenomic datasets of sugarcane are publicly available in the Sequence Read Archive (SRA) (https:// www.ncbi.nlm.nih.gov/ sra).The BioProject access number is PRJNA319259.The reads comprise the ITS2 region as described by Souza et al. (2016).

Criteria for data mining
The metagenomic project was identified in the SRA database and our runs were indexed in web BLASTn (version 2.6.0.+).The comparison was performed through an archive multifasta containing the molecular marker sequences against the reads from the metagenome.Were considered only results with the following parameters as cutoff: alignments with coverage of 100% and identity of 100% (perfect match), identical to those described in previous studies (Costa et al. 2020).

Study area and samples
A total of 11 environmental samples were analyzed, comprising five samples of living shoots of sugarcane, partitioned into leaf, stalk, and root, and six samples of soil rhizosphere.Samples were collected from two locations: (A) three shoots of sugarcane collected in Paulinia city, São Paulo State, Brazil (22°46′33.2"S,47°05′55.7"W),and (B) two shoots of sugarcane and six samples of soil rhizosphere from the greenhouse in Campinas city, São Paulo State, Brazil (22°81′90.5"S,47°05′92.8"W),being analyzed previously by Souza et al. (2016).

Fungal isolation by oil flotation
Approximately 20 g sample per sugarcane plant (rhizosphere, root, stalk, and leaf ) were subjected to oil flotation (Iwatsu et al. 1981;Vicente et al. 2008).Samples were incubated at room temperature for 30 min in 100 mL sterilized saline solution containing 200 U penicillin, 200 µg/L streptomycin, 200 µg/L chloramphenicol, and 500 µg/L cycloheximide.Subsequently, 20 mL of sterilized mineral oil was added, followed by vigorous shaking for 5 min.The flasks were left to settle for 20 min.Aliquots of the 100 µL oil-water interphase of each sample were carefully collected and inoculated onto Mycosel agar plates (Difco, Detroit, MI, U.S.A.) and incubated for 55 days at 28 °C, with a total of ten replicates per sample.Five plants were collected, separated into four samples, with ten replicates, leading to a total of 2000 replicates.

Isolation of endophytic fungi
Isolation of endophytic fungi was conducted according to protocols of Petrini (1991) adapted by Lima (2008).Sugarcane parts were divided into four fragments (approximately 0.5 cm 2 ) by a flame-sterilized blade in a laminar flow hood to prevent contamination by spores from the air.In addition, surfaces were sterilized by immersion in 70% ethanol for 1 min, sodium hypochlorite 124 (2-2.5% active chlorine) for 4 min, 70% ethanol for 30 s and washed thrice with sterile distilled water.The fragments were transferred aseptically to Mycosel agar (Difco, Detroit, MI) and incubated for 55 days at 28 °C.

Morphological identification
A preselection of black yeast-like isolates was done, strains being transferred to Sabouraud's glucose agar (SGA) at room temperature and evaluated by slide culture (de Hoog et al. 2011;Vicente et al. 2014).The fungi were inoculated onto Oatmeal agar blocks, covered with sterilized glass slides, and incubated at 28 °C for 7, 14 and 21 days.The micromorphology was used for preliminary identification and attribution to main groups.

Molecular identification
The initial identification of the isolates was based on sequencing of the rDNA Internal Transcribed Spacer (ITS) rDNA region.The taxonomic position of the isolates was confirmed by additional sequencing of the partial large subunit of the nuclear ribosomal DNA gene (LSU), β-tubulin (BT2), and translation elongation factor 1-α (TEF1).The primers used for the amplification are listed in Table 1.PCR reactions were performed in a 12.5 μL volume of a reaction mixture containing 1 × PCR buffer, 2.0 mM MgCl 2 , 25 μM dNTPs, 0.5 μM of each forward and reverse primer, 1 U DNA polymerase (Ludwig Biotec, Bela Vista, Brazil) and 20 ng genomic DNA.Amplification was performed in an ABI Prism 2720 thermocycler (Applied Biosystems, Foster City, USA) as follows: 95 °C for 5 min, followed by 35 cycles consisting of 94 °C for 45 s (denaturation), 52 °C for 45 s (annealing), and 72 °C for 2 min (extension), with a final delay step at 72 °C for 7 min, for LSU and ITS.For BT2, the annealing temperature was changed to 58 °C and for TEF1 to 56 °C.

Phylogenetic analysis
Consensus sequences of the ITS, BT2, TEF1 and the LSU regions were adjusted using the BioEdit Sequence Alignment Editor v7.2.5 (Hall 1999) and alignments of obtained sequences were performed using MAFFT (Katoh et al. 2018).The isolates provisionally identified by morphology were first identified based on ITS rDNA sequences by comparison with reference sequences available in GenBank (Additional file 3: Table S2) and in an in-house ribosomal alignment containing types of all described species (26 June 2023).Sequence comparisons were performed in the UNITE database (https:// unite.ut.ee/).Sequences with homology greater than or equal to 99% identity with type strains were considered as correctly identified.The LSU region was used to reconstruct the phylogeny of the Herpotrichiellaceae showing approximate groups that were recognized previously (Quan et al. 2020;de Hoog et al. 2011;Teixeira et al. 2017).Separate trees based on LSU sequences were built with 1000 bootstrap replicates using Maximum Likelihood implemented in MEGA v7 software (Kumar et al. 2016) (Kumar et al. 2016).For species delimitation, initially each region of ITS, TEF1 and BT2 was analyzed separately using maximum likelihood (ML) algorithm.Subsequent analysis was performed with combined data from three gene regions by ML implemented in MEGA v7.0.26 with the Tamura-Nei model.
The sequences were deposited in GenBank and compared with related reference strains (Additional file 3: Table S2).The holotype numbers were provided with the deposit of the fungal exsiccates at the Department of Botany Herbarium at the Federal University of Paraná (UPCB) with the accredited records on the MycoBank Database.The isolated strains were deposited in The Microbiological Collections of Paraná Network-CMRP/ Taxonline (https:// www.cmrp-taxon line.com/), preserved with long-term conservation methods, including cryopreservation and DNA storage.Data are registered in the database and available at the SpeciesLink network (https:// www.cmrp-taxon line.com/ catal ogue).

Physiology
Cardinal growth temperatures were determined on SGA after incubation for 3 weeks at 18-42 °C with 3 °C increments (Vicente et al. 2014).All tests were performed in triplicate and the diameters of the colonies were recorded in the last week.Experiments consisted of three simultaneous replicates for each tested strain; averages of three measurements were calculated.Growth velocities per species were obtained by calculation of the average values and the respective standard deviations.Results were plotted with temperature (°C) versus colony diameter (mm) as parameters.Optimum range (= average ± standard deviation) and maximum growth temperatures among species were determined with three replicates.
Tests for Cladophialophora bantiana (CMRP3443) were performed according to de Hoog et al. (1995).The carbon sources (D-glucose, D-ribose, L-arabinose, D-arabinose, L-rhamnose, sucrose, maltose, melibiose, lactose, soluble starch, glycerol, meso-erythritol and D-mannitol) were weighed (1.68 g) and dissolved in 100 mL yeast nitrogen base medium (Difco, Detroit, MI, U.S.A.), distributed in volumes of 4.5 mL in tubes and sterilized by filtration over 0.22 µm pore-size.Ethanol was added as 3 drops (30 µL) after sterilization of Yeast nitrogen base medium.The growth at carbon sources that showed the highest assimilation (glucose, sucrose, and soluble starch) were verified in concentrations of 5-60% of the carbon source using the same ratio of yeast nitrogen base medium as for carbon assimilation tests.For nitrogen assimilation tests, the carbon sources were prepared with 11.7 g Yeast carbon base medium (Difco, Detroit, MI) in 100 mL distilled water.Solutions were filtered using a 0.22 µm Millipore filter.Nitrogen assimilation tests were done with 0.78 g potassium nitrate, 0.26 g sodium nitrate and 0.56 g L-lysine.For halotolerance tests, 7.5 g and 15 g (NaCl) and magnesium chloride (MgCl 2 ) were weighed and dissolved separately in 150 mL glucose solution, filter-sterilized, and distributed aseptically in 4.5 mL volumes in tubes previously sterilized for 60 min at 1 ATM pressure.Osmophily was determined with sugar tolerance in a 5-60% final concentration range for glucose and sucrose in Yeast nitrogen base medium.Fungal inocula of 0.5 mL were prepared as suspensions of 10 7 conidia/ mL in Yeast nitrogen base medium (Difco, Detroit, MI).Tubes were incubated at 36 ºC in an upright position, shaken at 150 rpm.The negative control was the medium without cells.Fermentation of carbon sources was verified after incubation for two weeks in vertical tubes with Durham inserts, with fermentation basal medium (0.45% powdered yeast extract and 0.75% peptone).Biomass production was evaluated visually by turbidity after two weeks.The ( +) denominates positive growth, (-) indicates absence of growth and (w) weak growth compared to the positive control.
The new taxa obtained as cultures by isolation from sugarcane were later identified in all sugar plant samples (rhizosphere, root, stalk, and leaf ) by analysis in silico in the same database analyzed in this study.
Selective isolation by oil flotation yielded 639 cultures of black yeast-like fungi from 10 replicates per sample, with a total of 250 replicates.Forty-two isolates were selected for molecular identification based on morphological characteristics shared with agents of chromoblastomycosis and phaeohyphomycosis.Colonies of black yeast-like fungi were obtained from all sugarcane fragments (Table 2), although a higher number of isolates (n = 591) was recovered by selective isolation than by the endophytic method (n = 48).
The sugarcane samples yielded isolates of a diversity of species of black yeasts (Table 3), among which were Cladophialophora bantiana (4 isolates), C. floridana (2), Cyphellophora oxyspora (1), Exophiala cancerae (1), E. lecanii-corni (2), E. spinifera (2), and Rhinocladiella similis (6) (Additional file 1: Fig. S1).In addition, unidentifiable strains were recovered as Cladophialophora sp.(21) and Exophiala sp.(2).In order to assess the taxonomic position of new isolates that did not match with any described taxon, a tree of partial LSU rDNA (Fig. 2) was made.Judging from the LSU analysis, the cladophialophora-like isolates clustered with Cladophialophora species in different clades, while Exophiala spp.isolates were located at the salmonis-clade amidst waterborne Exophiala species (Fig. 2).Two isolates of each new species were selected for the analysis of sequences of further gene regions and to build a multilocus tree based on ITS, BT2 and TEF1 (Fig. 3).The trees were constructed using sequence data of representative species in Herpotrichiellaceae (Chaetothyriales), based on Quan et al. (2020).All reference strains used in the phylogenetic analysis are presented as in Additional file 3: Table S2.
A multilocus tree based on ITS, TEF1, and BT2 sequences was built with Maximum Likelihood implemented in RaxML v7.0.4 using the General time reversible substitution model.A total of 1,326 sites were evaluated for ITS, BT2, and TEF1, corresponding to 630, 458, and 238 sites of the respective genes.Of these, 1,326 were conserved, 743 were variable, 661 were parsimony informative (pi), and 36 were unique.The empirical base frequencies were 0.23070 for pi(A), 0.23823 for pi(C), 0.24061 for pi(G), and 0.24637 for pi(T), with 1,000 bootstrap inferences.Capronia kleinmondensis was selected as outgroup.Results of BT2 and ITS sequencing revealed a single environmental isolate of Exophiala cancerae and four of Cladophialophora bantiana among the sugarcane root and rhizosphere isolates, respectively (Fig. 3).
The phylogenetic analysis (Fig. 3) revealed that the environmental strains CMRP3553 and CMRP3556 of Cladophialophora grouped in a distinct cluster close to the type of strain C. tortuosa (BA4b006) that originates from sclerotia of the fungus Cenococcum sp., while strains CMRP3446 and CMRP3441 of Cladophialophora formed a separate cluster closely related to C. mycetomatis, a species from a human subcutaneous infection.In addition, the Cladophialophora strains CMRP3461 and CMRP3450 formed a separated group, close to C. exuberans from a decaying coconut shell.Judging from this analysis, the isolates of Cladophialophora are separate from previously described taxa (Figs. 2 and 3) and three of them will be introduced below as new species, namely C. rhizosphaerae, C. griseolivacea and C. molassis.Similarly, the Exophiala isolates CMRP3444 and CMRP3436 are close to E. pisciphila but at significant distance from known Exophiala species in the Salmonis clade (Fig. 3).Therefore, a novel taxon in Exophiala is introduced here, namely Exophiala sacchari.
Etymology: The name refers to the rhizosphere of sugarcane from which the isolates were recovered.
Etymology: The name refers to the colour of the colony of this species.

Etymology:
The name refers to a subproduct of the sugarcane, the molasses.

MycoBank no.: MB839695.
Etymology: The name refers to the source of the isolation of this species, the sugarcane plant.

PHYSIOLOGY
The above environmental Cladophialophora isolates were phylogenetically remote from clinically relevant members of the genus.The strains showed optimal development at 27 °C, while growth was observed in the entire range between 19 and 37 °C.The isolates of Exophiala also showed optimal development at 27 °C, with growth between 21 and 37 °C.The maximum growth temperature of all strains analyzed was found to be 37 °C and no growth was observed at 40 °C (Fig. 8).
Considering the ecology of species evaluated, it was observed that Cladophialophora bantiana CMRP 3443 showed the ability to assimilate the following carbon sources: D-glucose, sucrose, maltose, soluble starch, and glycerol, but did not assimilate D-ribose, D-and L-arabinose, and meso-erythritol, and showed weak growth in remaining carbon sources (Table 4) after 14 days of incubation.Moderate halophily of CMRP 3443 was shown by growth at MgCl 2 concentrations of 5% and 10% and weak growth with 5% NaCl.The strain C. bantiana (CMRP 3443) was able to assimilate all tested sugars, with optimal growth in the presence of sucrose, lactose, and soluble starch.Nitrogen assimilation abilities were evident by growth mainly in the presence of NaNO 3, KNO 3 and L-lysine.Cladophialophora bantiana CMRP 3443 showed considerable tolerance of high sugar concentrations (Table 5).Tolerance of CMRP 3443 to increasing concentrations (30% and 60%) of sucrose and 30% of glucose was indicated by weak growth after 7 days compared to the control.The growth limit was around 30% of sugar; at higher concentrations, expansion growth was neglectable.Soluble starch did not affect growth in all concentrations evaluated.Biomass production in the presence of soluble starch was larger at all concentrations compared to glucose and sucrose.

DISCUSSION
The black yeasts and their relatives comprise numerous agents of human and (mostly cold-blooded) animal infection (Hoog et al. 2011;Queiroz-Telles et al. 2017).In the environment, the species seem to occur in specific microhabitats, and because of a low competitive ability towards other microorganisms, isolation of members of Chaetothyriales requires selective methods (Vicente et al. 2014).Oligotrophism is an important characteristic that enables them to survive at low density on adverse, low-nutrient substrates where common saprobes are absent (Vicente et al. 2001(Vicente et al. , 2008;;Satow et al. 2008).Usually, agents of disease in Chaetothyriales are morphologically indistinguishable from their environmental relatives (Vicente et al. 2014), and thus reliable molecular and genomics tools are necessary for accurate identification of species (Vicente et al. 2017;Moreno et al. 2018).
In this study, we investigated the occurrence of black yeasts in sugarcane samples through in silico and in vitro methods.The culture-independent method applied was based on previous work of Souza et al. (2016), demonstrating the presence of Chaetothyriales in metagenome data from sugarcane.Using barcode and padlock probes proposed by Costa et al. (2020), it was possible to detect the presence of the genera Cladophialophora, Cyphellophora, Exophiala, Knufia, Phialophora, Rhinocladiella, and Veronaea in the sugarcane environment.The oil flotation isolation method after Vicente et al. (2014) was used to confirm the metagenomic identification of high numbers of black yeast-like fungi that were detected after in-silico analysis.The method was successfully applied in earlier environmental studies to recover etiologic agents of chromoblastomycosis and phaeohyphomycosis (Vicente et al. 2012(Vicente et al. , 2014;;Salgado et al. 2004;Marques et al. 2006;Lima et al. 2020).In the present study, the method proved to be efficient for isolation of several potential agents of disease.Rhinocladiella similis, recently described as an agent of chromoblastomycosis (Heidrich et al. 2017) was isolated as an endophyte from sugarcane stalk, root, and leaf.In addition, Exophiala spinifera (Kapatia et al. 2019) was isolated from the root (endo-and exophytic) and E. lecanii-corni (Lee et al. 2016) from the sugarcane root.Moreover, Exophiala cancerae was found in sugarcane root, a species known as causal agent of Lethargic crab disease (LCD) in Brazil (de Hoog et al. 2011), confirming earlier environmental metagenomic data (Costa et al. 2020).Cyphellophora oxyspora (syn.Phialophora oxyspora), described as an agent of mycetoma of a horse (Lopez et al. 2007), was recovered from sugarcane rhizosphere.
Surprisingly, among the species identified was the neurotropic fungus Cladophialophora bantiana, a pathogen almost entirely restricted to human brain (Badali et al. 2008), affecting immunocompromised as well as immunocompetent hosts (Kantarcioglu et al. 2017).The species causes primary brain infection (Horré and Hoog 1999), i.e., is acquired through inhalation but first symptoms are of neurological nature.Its environmental niche has remained enigmatic (Badali et al. 2008).Very few studies mentioned environmental occurrence, i.e., in bark and sawdust (Dixon et al. 1987), scrapings of a brick wall (Espinel-Ingroff et al. 1982), and in hot tub water (Jurjevic et al. 2013).These studies relied on morphological identification, while our study is the first with proof of occurrence based on molecular sequence data.The species is able to grow at 42 ºC, which is a beneficial growth temperature for clinical strains (Ganavalli & Raghavendra 2011).Sugarcane provides osmotic conditions.A high degree of osmotolerance was noted in our C. bantiana isolates, with sugar tolerance above 30%.Salt tolerance was not remarkable.The sugar tolerance of this species may be an important parameter in finding the source and route of infection of patients with this severe brain disorder.Thus far the disease has rarely been observed in  (Alves 2006).Sugarcane obviously is an overlooked substrate for Chaetothyriales.Isolation and in silico analysis showed a wide variety of fungi in the sugarcane habitat, including the known infectious species Cladophialophora bantiana, Exophiala cancerae, E. spinifera, and Rhinocladiella similis.Among the isolates recovered were also four species that we describe here as new to science.One of these belongs to the salmonis-clade (Figs. 2, 3), a cluster of waterborne species (de Hoog et al. 2011).In addition, three new Cladophialophora species were introduced, located along several Cladophialophora clades that contain primarily environmental fungi.In Herpotrichiellaceae, morphological features are highly variable within species, and are polyphyletic within the order Chaetothyriales (Quan et al. 2020).For this reason, description of phenotypes is significant to understand the ecology of the fungus at hand, but provides no reliable diagnostic features (Quan et al. 2023).Although the new species are morphologically hardly distinguishable from other species of the genera Cladophialophora and Exophiala, the multilocus analysis revealed a robust phylogenetic distance.This defines a better criterion to separate species in Herpotrichiellaceae.Furthermore, black yeasts have not previously been explored in sugarcane by selective isolation, which appears a major ecological feature of the new species.
Optimal temperature of growth for these species was 27 °C, with a mesophilic growth in the range 19-37 °C (Fig. 8).Despite the prevalence of infectious diseases by Chaetothyriales in Brazil, among which is chromoblastomycosis, only few of the potential etiologic agents have been recovered from the environment (Vicente et al. 2001(Vicente et al. , 2008(Vicente et al. , 2014)).Marques et al. (2006) and Nascimento et al. (2017) were the first to observe high diversity and density of black yeasts on rotting Babassu coconut shells.
Many species remain undiscovered until their preferred habitat is found (Vicente et al. 2008).The genus Cladophialophora is characterized by melanized hyphae and absence of differentiated conidiophores with conidia produced sympodially in long, coherent chains.This character appeared polyphyletic within the Chaetothyriales.Many such species cause human infections, but others are purely environmental.Hence, distinction of opportunists and strict saprobes, as well as elucidation of environmental niches of the infectious species is mandatory to understand the ecology and epidemiology, and potential publish health risks of these fungi (de Hoog et al. 2011).
In this work, the in-silico analysis of sugarcane samples revealed a favorable environment for black yeasts, which was confirmed by selective isolation.The in silico re-analyses performed after introduction of the new species confirmed the presence of the novel taxa in the dataset.Cyphellophora, found as an abundant genus in the in silico analysis represented by C. laciniata, C. suttonii, and C. vermispora, which were not recovered in vitro.The same was observed for Exophiala spp.represented by 13 sequences in silico (Additional file 3: Table S3), while only E. spinifera and E. cancerea were isolated.Thus, studies based on molecular tools combined with in vitro isolation methods are fundamental for understanding the ecology of taxonomic groups that have not yet been fully elucidated.
Related species in the bantiana-clade can vary significantly in their ecological preferences and ability to cause infection in humans and animals (Vicente et al. 2014).Other abilities of these species concern the assimilation of a wide diversity of carbon sources (Tintelnot et al. 1995;de Hoog et al. 1995de Hoog et al. , 2004).Among the 14 carbon sources tested, the environmental lineage of C. bantiana did not assimilate D-ribose, L-arabinose, D-arabinose and meso-erythritol.Physiological profiles are similar to those of other species in the bantiana-clade, i.e., in Fonsecaea pedrosoi and F. monophora.Differences were noted with C. bantiana (CBS 173.52, CBS 364.80, CBS 328.65, CBS 564.82, andCBS 678.69) (de Hoog et al. 1995, 2004) in assimilation of ribose, L-and D-arabinose, and erythritol.
Judging from literature, the clinical strain of C. bantiana CBS 173.52 does not tolerate 10% MgCl 2 and NaCl (de Hoog et al. 1995), while CMRP 3443 from the environment tolerated 5% and 10% MgCl 2 and 5% NaCl, but not 10% NaCl.Halotolerance may be an important factor for the ubiquity of these strains in the phyllosphere of plants.The role of tolerance of high osmotic pressure in C. bantiana is thus far unexplained, but in general, extremotolerance is often a prerequisite for opportunism (Gostinčar et al. 2018).

CONCLUSIONS
The results obtained in this study show that in silico methods such as metagenomics allied with barcodes directed the in vitro isolation to efficiently discover opportunistic black yeasts.With this combination of techniques, it was possible to establish the environmental niche of C. bantiana, as well as of other opportunistic species such as Cyphellophora oxyspora, Exophiala cancerae, E. lecanii-corni, E. spinifera, and Rhinocladiella similis in sugarcane.Four novel endophytic, saprobic black yeasts are introduced as new species in the family Herpotrichiellaceae.Future work might benefit from the use of metagenomics and barcodes, contributing to the elucidation of niches and to bioprospecting black yeasts in other substrates.
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Fig. 1
Fig. 1 Distribution of the fungi in Herpotrichiellaceae on sugarcane, based on the specific molecular markers applied in the metagenome database.I. Evaluated metagenomic samples from different parts of sugarcanes from São Paulo, Brazil.II.Percentage of metagenomic sequences from BioProject PRJNA319259: A in leaf endophytic, B in leaf exophytic, C in stalk endophytic, D in stalk exophytic, and E rhizosphere samples

Fig. 2
Fig. 2 Phylogeny of a representative selection of species in Chaetothyriales based on LSU rDNA sequences, constructed by Bayesian analysis and maximum likelihood.Values of > 70% for Bayesian probability (left) and Bootstrap values > 70% for maximum likelihood (right) from 1000 resampled datasets are shown with branches.Novel species are indicated in bold.The outgroup was Knufia epidermidis (CBS 120353).T = Ex-type strain

Fig. 8
Fig. 8 Temperature relations of Cladophialophora and Exophiala species after 3 wk incubation at temperatures ranging from 18 to 42 °C

Table 1
Primers and PCR conditions used in DNA sequencing

Table 2
Percentages of numbers of isolates of Black yeast-like fungi (100% = 639 cultures) obtained from different parts of sugarcanes growing in São Paulo, Brazil

Table 3
Molecular identification of environmental isolates from sugarcane growing in São Paulo, BrazilNovel species and ex-type strains are indicated in bold, and ex-type strains also by " T "