Tubeufia asiana, the teleomorph of Aquaphila albicans in the tubeufiaceae, pleosporales, based on cultural and molecular data

The teleomorph of Aquaphila albicans was discovered on submerged wood collected in Thailand. Its black, soft-textured, setose ascomata, bitunicate asci and hyaline to pale brown, multiseptate ascospores indicated an affinity to Tubeufiaceae (Dothideomycetes). After morphological or molecular comparisons with related species in Tubeufia, Acanthostigma and Taphrophila, it is described and illustrated as a new species, T. asiana Sivichai & K.M. Tsui, sp. nov. Finding this Tubeufia teleomorph was surprising, given the falcate conidia of its A. albicans anamorph, which superficially resemble the conidia of Fusarium and not the coiled, helicosporous conidia of other species in Tubeufiaceae. We assessed the phylogenetic relationships of A. albicans-T. asiana with ribosomal sequences from SSU and ITS and partial LSU regions by parsimony and Bayesian analysis. An initial set of 40 taxa representing a wide range of ascomycete families and their SSU sequences from GenBank showed A. albicans-T. asiana to be nested within the Tubeufiaceae with 100% bootstrap support. Their placement was inferred with ITS and partial LSU ribosomal sequences. The nearly identical ITS sequences of two isolates of A. albicans and one isolate of Tubeufia asiana united these fungi as a monophyletic group with 100% bootstrap support and further nested them, with 88% bootstrap support, in a clade containing Helicoon gigantisporum and Helicoma chlamydosporum. This is the first molecular phylogenetic study to place a nonhelicosporous species within the Tubeufiaceae and to show that helical conidia were lost at least once within the family.     

Molecular systematics of Helicoma, Helicomyces and Helicosporium and their teleomorphs inferred from rDNA sequences

Three genera of asexual, helical-spored fungi, Helicoma, Helicomyces and Helicosporium traditionally have been differentiated by the morphology of their conidia and conidiophores. In this paper we assessed their phylogenetic relationships from ribosomal sequences from ITS, 5.8S and partial LSU regions using maximum parsimony, maximum likelihood and Bayesian analysis. Forty-five isolates from the three genera were closely related and were within the teleomorphic genus Tubeufia sensu Barr (Tubeufiaceae, Ascomycota). Most of the species could be placed in one of the seven clades that each received 78% or greater bootstrap support. However none of the anamorphic genera were monophyletic and all but one of the clades contained species from more than one genus. The 15 isolates of Helicoma were scattered through the phylogeny and appeared in five of the clades. None of the four sections within the genus were monophyletic, although species from Helicoma sect. helicoma were concentrated in Clade A. The Helicosporium species also appeared in five clades. The four Helicomyces species were distributed among three clades. Most of the clades supported by sequence data lacked unifying morphological characters. Traditional characters such as the thickness of the conidial filament and whether conidiophores were conspicuous or reduced proved to be poor predictors of phylogenetic relationships. However some combinations of characters including conidium colour and the presence of lateral, tooth-like conidiogenous cells did appear to be predictive of genetic relationships.     

Phylogenetic relationships and convergence of helicosporous fungi inferred from ribosomal DNA sequences

Helicosporous fungi form elegant, coiled, and multicellular mitotic spores (conidia). In this paper, we investigate the phylogenetic relationships among helicosporous fungi in the asexual genera Helicoma, Helicomyces, Helicosporium, Helicodendron, Helicoon, and in the sexual genus Tubeufia (Tubeufiaceae, Dothideomycetes, and Ascomycota). We generated ribosomal small subunit and partial large subunit sequences from 39 fungal cultures. These and related sequences from GenBank were analyzed using parsimony, likelihood, and Bayesian analysis. Results showed that helicosporous species arose convergently from six lineages of fungi in the Ascomycota. The Tubeufiaceae s. str. formed a strongly supported monophyletic lineage comprising most species from Helicoma, Helicomyces, and Helicosporium. However, within the Tubeufiaceae, none of the asexual genera were monophyletic. Traditional generic characters, such as whether conidiophores were conspicuous or reduced, the thickness of the conidial filament, and whether or not conidia were hygroscopic, were more useful for species delimitation than for predicting higher level relationships. In spite of their distinctive, barrel-shaped spores, Helicoon species were polyphyletic and had evolved in different ascomycete orders. Helicodendron appeared to be polyphyletic although most representatives occurred within Leotiomycetes. We speculate that some of the convergent spore forms may represent adaptation to dispersal in aquatic environments.     

Detecting morphological convergence in true fungi, using 18S rRNA gene sequence data.

For the true fungi, phylogenetic relationships inferred from 18S ribosomal DNA sequence data agree with morphology when (1) the fungi exhibit diagnostic morphological characters, (2) the sequence-based phylogenetic groups are statistically supported, and (3) the ribosomal DNA evolves at roughly the same rate in the lineages being compared. 18S ribosomal RNA gene sequence data and biochemical data provide a congruent definition of true fungi. Sequence data support the traditional fungal subdivisions Ascomycotina and Basidiomycotina. In conflict with morphology, some zygomycetes group with chytrid water molds rather than with other terrestrial fungi, possibly owing to unequal rates of nucleotide substitutions among zygomycete lineages. Within the ascomycetes, the taxonomic consequence of simple or reduced morphology has been a proliferation of mutually incongruent classification systems. Sequence data provide plausible resolution of relationships for some cases where reduced morphology has created confusion. For example, phylogenetic trees from rDNA indicate that those morphologically simple ascomycetes classified as yeasts are polyphyletic and that forcible spore discharge was lost convergently from three lineages of ascomycetes producing flask-like fruiting bodies.     

Labyrinthulomycetes phylogeny and its implications for the evolutionary loss of chloroplasts and gain of ectoplasmic gliding

The labyrinthulomycetes, also known as the 'Labyrinthulomycota' are saprotrophic or less frequently parasitic stramenopilan protists, usually in marine ecosystems. Their distinguishing feature is an 'ectoplasmic net,' an external cytoplasmic network secreted by a specialized organelle that attaches the cell to its substrate and secretes digestive enzymes for absorptive nutrition. In this study, one of our aims was to infer the phylogenetic position of the labyrinthulomycetes relative to the non-photosynthetic bicoeceans and oomycetes and the photosynthetic ochrophytes and thereby evaluate patterns of change from photosynthesis to saprotrophism among the stramenopiles. For the labyrinthulomycetes, we determined sequences of the actin, beta-tubulin, and elongation factor 1-alpha gene fragments and where necessary, ribosomal small subunit (SSU) genes. Multilocus analysis using standard tree construction techniques not only strongly supported the oomycetes as the sister group to the phototrophic stramenopiles, but also, for the first time with moderate statistical support, showed that the labyrinthulomycetes and the bicoecean as sister groups. The paraphyly of the non-photosynthetic groups was consistent with independent loss of photosynthesis in labyrinthulomycetes and oomycetes. We also wished to develop a phylogenetically based hypothesis for the origin of the gliding cell bodies and the ectoplasmic net found in some labyrinthulomycetes. The cells of species in Labyrinthula and Aplanochytrium share a specialized form of motility involving gliding on ectoplasmic tracks. Before our study, only ribosomal DNA genes had been determined for these genera and their phylogenetic position in the labyrinthulomycetes was equivocal. Multilocus phylogenies applying our newly determined protein-coding sequences divided the labyrinthulomycetes between sister clades 'A' and 'B' and showed that the monophyletic group containing all of the gliding species was nested among non-gliding species in clade B. This phylogeny suggested that species that glide via an ectoplasm evolved from species that had used the ectoplasm mainly for anchorage and assimilation rather than motility.     

Specific induction of encystment ofLagenidium giganteum zoospores by concanavalin A and derivatives of chitin and chitosan

Summary Zoospores of the mosquito pathogenic fungusLagenidium giganteum preferentially attach to and encyst on the cuticular surface of the immature stages of many species of mosquitoes as the initial step in the infection process. Recognition by zoospores of specific chemical or physical signals on the cuticular surface triggers attachment. A number of compounds likely to be present on the surface of mosquito larvae were evaluated for efficacy in eliciting zoospore encystment. Free amino acids and oligomers, a number of phenolic and polyphenolic compounds and most carbohydrates did not induce encystment at concentrations less than 500 g/ml. Colloidal chitin and chitin films were also ineffective as was O-carboxy-methylchitin; however, glycol chitin and glycol chitosan induced rapid encystment at concentrations at or below 1 g/ml. Zoospores also attached to and encysted in great numbers on fibers of oxycellulose, but not on cellulose. Concanavalin A was the only lectin which induced encystment at concentrations less than 10 g/ml, which suggests that a glycoprotein with terminal mannose and/or glucose residues is involved in encystment. A number of phenols were metabolized by peroxidase on the zoospore surface. Addition of hydrogen peroxide to zoospore suspensions reduced the time needed to induce zoospore encystment by some phenols; however, there was no consistent relationship between the presence or absence of this synergistic effect and the ability ofL. giganteum peroxidase to metabolize a given substrate. The sterol-binding compound amphotericin B induced immediate encystment at 3.5 g/ml, suggesting that sterols, which are required for the induction of zoosporogenesis, were present on the zoospore membrane.     

Decorospora, a new genus for the marine ascomycete Pleospora gaudefroyi

In this paper, we investigate the phylogenetic placement of Pleospora gaudefroyi using partial SSU as well as ITS ribosomal DNA sequences. Both SSU and ITS data sets agreed in the placement of P. gaudefroyi. Parsimony and neighbor-joining analyses of each data set placed P. gaudefroyi within the Pleosporaceae with 100% bootstrap support. Pleospora gaudefroyi was sister taxon in the Pleosporaceae represented by Alternaria alternata, Cochliobolus sativus, Pleospora herbarum, Pyrenophora tritici-repentis and Setosphaeria rostrata. Pleospora gaudefroyi was separated from other genera in the Pleosporaceae in 94% of the bootstrap replicates in parsimony and neighbor-joining analyses. When P. gaudefroyi was constrained to monophyly with P. herbarum, all resulting trees were significantly worse than the optimal tree in both Kishino-Hasegawa and Shimodaira-Hasegawa tests. Pleospora gaudefroyi was therefore excluded from Pleospora, and transferred to the new genus Decorospora placed in the Pleosporaceae. Decorospora (Dothideomycetes) has characteristic ascospores enclosed in a sheath with 4-5 apical extensions. The distribution and substrate types for D. gaudefroyi are summarized and updated based on additional collections.