<Emphasis Type="Italic">Cortinarius majestaticus</Emphasis> comb. nov.: phylogenetic evidence for the transfer of <Emphasis Type="Italic">Descolea majestatica</Emphasis> to <Emphasis Type="Italic">Cortinarius</Emphasis>

Descolea majestatica is an agaric with features described as intermediate between the genera Descolea Singer and Rozites P. Karst. (≡ Cortinarius). Molecular phylogenetic analysis of nuclear ribosomal internal transcribed spacer (ITS), large ribosomal subunit (LSU) and RNA polymerase second largest subunit (RPB2) sequences indicates that D. majestatica is nested within the genus Cortinarius, with its closest relative a sequestrate Cortinarius species from Argentina. Taxonomic recombination is made to restore the monophyly of Cortinarius and Descolea.     

New and interesting chaetothyrialean fungi from Spain

In the course of taxonomic studies on saprobic microfungi from Spain, several slow-growing, dematiaceous hyphomycetes were isolated from soil, submerged plant material and river sediments. Sixteen of these strains were identified as members of the ascomycete order Chaetothyriales on the basis of morphology and DNA sequence analyses of the internal transcribed spacer region and partial large subunit ribosomal RNA gene. These included three novel species (Cladophialophora pseudocarrionii, Cyphellophora chlamydospora, and Rhinocladiella amoena) and five interesting, little-known or clinically-relevant species (Cyphellophora suttonii, Exophiala aquamarina, E. lacus, E. radicis, and Rhinocladiella similis). In addition, Exophiala oligosperma, an emerging opportunistic fungus, was found for the first time in an aquatic freshwater environment (river sediments). Cladophialophora pseudocarrionii resembles C. carrionii in the branching pattern of its conidial chains, but differs from the latter species in its inability to grow at 30 °C. Cyphellophora chlamydospora differs from other species of the genus in the absence of conidiation, producing only chlamydospores in vitro. Rhinocladiella amoena shows branched conidiophores similar to those of R. anceps, R. atrovirens, R. basitona and R. similis, but differs from them in conidial shape and size. The ex-type strain of Phialophora livistonae, included in the phylogenetic study, clustered with high statistical support with members of the genus Cyphellophora and is transferred to this genus.     

Revision of the taxonomic status of the genus <Emphasis Type="Italic">Gloeoporus</Emphasis> (Polyporales,Basidiomycota) reveals two new species

Gloeoporus Mont. is characterized by an easily separated gelatinous hymenophore and a continuous hymenium over the pore mouth. Recent molecular taxonomic and phylogenetic research showed that morphological grouping of Gloeoporus is polyphyletic. The lack of comprehensive phylogenetic studies of Gloeoporus exacerbates confusion in determining the taxonomic position of the genus. To delimit the genus Gloeoporus, we performed multi-locus phylogenetic analysis using the internal transcribed spacer (ITS) region, the nuclear large subunit ribosomal DNA (LSU), and the second-largest subunit of RNA polymerase II (rpb2). The phylogenetic analyses revealed that current delimitation of Gloeoporus is not monophyletic. Gloeoporus s.s. includes mostly clamped species lacking cystidia. Some species of Gloeoporus featuring simple septa and cystidia are proposed to be renamed to Meruliopsis. Two new species of Gloeoporus were also observed and they are named Gloeoporus africanus and Gloeoporus orientalis.     

Soil spore banks of ectomycorrhizal fungi in endangered Japanese Douglas-fir forests

Interactions between trees and ectomycorrhizal fungi are critical to the growth and survival of both partners. However, ectomycorrhizal symbiosis has barely been explored in endangered trees, and no information is available regarding soil spore banks of ectomycorrhizal fungi from forests of threatened trees. Here, we evaluated soil spore banks of ectomycorrhizal fungi from endangered Japanese Douglas-fir (Pseudotsuga japonica) forests using bioassay approaches with congeneric P. menziesii and Pinus densiflora seedlings in combination with molecular identification techniques. Rhizopogon togasawariana was predominant in soil propagule banks and was found in all remaining P. japonica forests when assayed with P. menziesii, while no colonization of this fungus was observed on Pinus seedlings. Given the observed specificity of R. togasawariana for P. menziesii and its phylogenetic position within the Pseudotsuga-specific Rhizopogon lineage, its geographical distribution is likely restricted to the remaining Japanese Douglas-fir forests, indicating a high extinction risk for this fungus as well as its endangered host. Spore banks of R. togasawariana remained highly infective after preservation for 1 year or heat treatment at 70 °C, suggesting an ecological strategy of establishing ectomycorrhizal associations on regenerating Japanese Douglas-fir seedlings after disturbance, as observed in other Rhizopogon–Pinaceae combinations. Therefore, the regeneration of Japanese Douglas-fir seedlings may depend largely on the soil spore banks dominated by R. togasawariana, which has co-evolved with the Japanese Douglas-fir for over 30 million years. More attention must be paid to underground ectomycorrhizal fungi for the conservation of endangered tree species, especially in the era of human-induced mass extinction.     

Revisiting phylogenetic diversity and cryptic species of <Emphasis Type="Italic">Cenococcum geophilum</Emphasis> sensu lato

The fungus Cenococcum geophilum Fr. (Dothideomycetes, Ascomycota) is one of the most common ectomycorrhizal fungi in boreal to temperate regions. A series of molecular studies has demonstrated that C. geophilum is monophyletic but a heterogeneous species or a species complex. Here, we revisit the phylogenetic diversity of C. geophilum sensu lato from a regional to intercontinental scale by using new data from Florida (USA) along with existing data in GenBank from Japan, Europe, and North America. The combination of internal transcribed spacer (ITS) ribosomal DNA and the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene resolved six well-supported lineages (87–100 % bootstrap values) that are closely related to each other and a seventh lineage that is phylogenetically distinct. A multi-locus analysis (small subunit (SSU), large subunit (LSU), translational elongation factor (TEF), and the largest and second-largest subunits of RNA polymerase II (RPB1 and RPB2)) revealed that the divergent lineage is the sister group to all other known Cenococcum isolates. Isolates of the divergent lineage grow fast on nutrient media and do not form ectomycorrhizas on seedlings of several pine and oak species. Our results indicate that C. geophilum sensu lato includes more phylogenetically distinct cryptic species than have previously been reported. Furthermore, the divergent lineage appears to be a non-mycorrhizal sister group. We discuss the phylogenetic diversity of C. geophilum sensu lato and argue in favor of species recognition based on phylogenetic and ecological information in addition to morphological characteristics. A new genus and species (Pseudocenococcum floridanum gen. et sp. nov.) is proposed to accommodate a divergent and putatively non-mycorrhizal lineage.     

<Emphasis Type="Italic">Ramaria chocoënsis</Emphasis> sp. nov., a gomphoid member of <Emphasis Type="Italic">Ramaria</Emphasis> sect. <Emphasis Type="Italic">Dendrocladium</Emphasis> from Colombia,El Chocó, with special regards to rhizomorph anatomy

The new species Ramaria chocoënsis (Gomphales, Basidiomycota) from Colombian Pacific rainforest is described. Despite the gomphoid habit, the new species is inserted in Ramaria sect. Dendrocladium due to rhizomorph anatomy. In rhizomorphs of members of Ramaria sect. Dendrocladium, as in the new species R. chocoënsis, peculiar, thick-walled, gnarled, sphere-bearing hyphae are found, a feature unknown for any other higher fungi. A short survey of hitherto known rhizomorph features within the Gomphales is given. The possibility of putting the members of Ramaria sect. Dendrocladium in a separate genus is taken into account. It would be advisable to have additional data by screening the anatomy of the rhizomorphs in other species, to more accurately predict the classification of Ramaria chocoënsis sp. nov.     

Application of quantitative measures of gene order similarity to phylogenetic reconstructions (exemplified by bacteria of the genus <Emphasis Type="Italic">Rickettsia</Emphasis>)

Data reflecting evolutionary changes in chromosomal gene order can be used for phylogenetic reconstructions along with the results of nucleotide sequence comparison. By the example of bacteria of the genus Rickettsia, we have shown that phylogenetic reconstructions based on quantitative estimates of the similarity and cladistic analysis of gene order data, may, in some cases, amend and fill up classical phylogenetic trees. When applied, these approaches enabled us to substantiate the hypothesis that Rickettsia felis species had split before the typhus (R. typhi, R. prowazekii) and spotted fever (R. connorii) group divergence and thus R. felis does not belong to the latter group. In general, rickettsias evolved towards increasing intracellular parasitic specialization. Five Rickettsia species whose genomes have been sequenced and annotated completely actually form an evolutionary series R. bellii—R. felis—R. conorii—R. prowazekii—R. typhi. Within this series, a reduction in genome size and rapid decrease of genome rearrangement rates (genome plasticity loss) gradually occur.     

Taxonomy and multi-gene phylogeny of <Emphasis Type="Italic">Haploporus</Emphasis> (Polyporales,Basidiomycota)

Taxonomic and phylogenetic studies of Haploporus were carried out. Three species in Haploporus, H. cylindrosporus, H. septatus and H. subpapyraceus, are described as new based on morphological differences and molecular phylogenetic analyses inferred from the internal transcribed spacer (ITS), the large subunit nuclear ribosomal RNA gene (nLSU), the small subunit mitochondrial rRNA gene (mtSSU), the second subunit of RNA polymerase II (rpb2) and the translation elongation factor 1-α gene (TEF1) sequences. Haploporus cylindrosporus is characterized by big irregular crystals occasionally present in the subiculum, an abundant oily substance among hyphae and typically cylindrical basidiospores 10–11.5?×?4.5–5 μm; H. septatus differs from other species in the genus by its leathery to corky basidiomata when dry, small round pores (5–6 per mm), simple septate skeletal hyphae at the edge of the dissepiments, and oblong to ellipsoid basidiospores 8.5–11?×?5–6 μm; H. subpapyraceus is separated by white to cream basidiomata, numerous apically simple septate cystidioles and ellipsoid basidiospores 9–12?×?5.5–8 μm. An identification key to accepted species of Haploporus is provided.     

Identification of Japanese <Emphasis Type="Italic">Lymantria</Emphasis> species (Lepidoptera: Lymantriidae) based on DNA sequences

We examined the utility of the cytochrome c oxidase subunit I (COI) and II (COII) genes of mitochondrial DNA (mtDNA) as a tool to identify nine Japanese Lymantria species, including four Asian gypsy moth species [Lymantria dispar japonica (Motschulsky), Lymantria umbrosa (Butler), Lymantria albescens Hori and Umeno, and Lymantria postalba Inoue]. In phylogenetic trees constructed for the COI and COII genes using the maximum likelihood methods, we could identify seven out of the nine Lymantria species (L. albescens and L. postalba could not be identified). These results suggest that the DNA sequences of the COI and COII genes are useful for identifying Japanese Lymantria species.     

ITS2 sequence–structure phylogeny reveals diverse endophytic <Emphasis Type="Italic">Pseudocercospora</Emphasis> fungi on poplars

For matching the new fungal nomenclature to abolish pleomorphic names for a fungus, a genus Pseudocercospora s. str. was suggested to host holomorphic Pseudocercosproa fungi. But the Pseudocercosproa fungi need extra phylogenetic loci to clarify their taxonomy and diversity for their existing and coming species. Internal transcribed spacer 2 (ITS2) secondary structures have been promising in charactering species phylogeny in plants, animals and fungi. In present study, a conserved model of ITS2 secondary structures was confirmed on fungi in Pseudocercospora s. str. genus using RNAshape program. The model has a typical eukaryotic four-helix ITS2 secondary structure. But a single U base occurred in conserved motif of U-U mismatch in Helix 2, and a UG emerged in UGGU motif in Helix 3 to Pseudocercospora fungi. The phylogeny analyses based on the ITS2 sequence–secondary structures with compensatory base change characterizations are able to delimit more species for Pseudocercospora s. str. than phylogenic inferences of traditional multi-loci alignments do. The model was employed to explore the diversity of endophytic Pseudocercospora fungi in poplar trees. The analysis results also showed that endophytic Pseudocercospora fungi were diverse in species and evolved a specific lineage in poplar trees. This work suggested that ITS2 sequence–structures could become as additionally significant loci for species phylogenetic and taxonomic studies on Pseudocerospora fungi, and that Pseudocercospora endophytes could be important roles to Pseudocercospora fungi’s evolution and function in ecology.     

Taxonomic revisions in the Microstromatales: two new yeast species,two new genera,and validation of <Emphasis Type="Italic">Jaminaea</Emphasis> and two <Emphasis Type="Italic">Sympodiomycopsis</Emphasis> species

Environmental sampling yielded two yeast species belonging to Microstromatales (Exobasidiomycetes, Ustilaginomycotina). The first species was collected from a leaf phylloplane infected by the rust fungus Coleosporium plumeriae, and represents a new species in the genus Jaminaea, for which the name Jaminaea rosea sp. nov. is proposed. The second species was isolated from air on 50% glucose media and is most similar to Microstroma phylloplanum. However, our phylogenetic analyses reveal that species currently placed in Microstroma are not monophyletic, and M. phylloplanum, M. juglandis and M. albiziae are not related to the type species of this genus, M. album. Thus, Pseudomicrostroma gen. nov. is proposed to accommodate the following species: P. glucosiphilum sp. nov., P. phylloplanum comb. nov. and P. juglandis comb. nov. We also propose Parajaminaea gen. nov. to accommodate P. albizii comb. nov. and P. phylloscopi sp. nov. based on phylogenetic analyses that show these are not congeneric with Jaminaea or Microstroma. In addition, we validate the genus Jaminaea, its respective species and two species of Sympodiomycopsis and provide a new combination, Microstroma bacarum comb. nov., for the anamorphic yeast Rhodotorula bacarum. Our results illustrate non-monophyly of Quambalariaceae and Microstromataceae as currently circumscribed. Taxonomy of Microstroma and the Microstromataceae is reviewed and discussed. Finally, analyses of all available small subunit rDNA sequences for Jaminaea species show that J. angkorensis is the only known species that possess a group I intron in this locus, once considered a potential feature indicating the basal placement of this genus in Microstromatales.     

Morphological and molecular evidence support a new truffle, <Emphasis Type="Italic">Tuber lannaense</Emphasis>, from Thailand

A new truffle species, Tuber lannaense, is described based on collections from northern Thailand. This species is characterized by yellow-brown to brown ascomata with dark brown gleba and ellipsoid to narrow ellipsoid spores with spiny reticulum. It grows in mycorrhizal association with Betula alnoides and Carpinus poilanei. Tuber lannaense is similar to T. huidongense, but differs in the thinner outer peridium layer. Molecular phylogenetic analysis of the internal transcribed spacers (ITS1?+?ITS2) and large subunit of nuclear ribosomal DNA, as well as genetic distance analysis of ITS1?+?ITS2, support T. lannaense as being distinct from other Tuber species. Moreover, based on genetic distance analysis, we consider that T. furfuraceum and T. huidongense, which have previously been synonymized, are different species.     

Molecular phylogeny and morphology of <Emphasis Type="Italic">Ophiocordyceps unituberculata</Emphasis> sp. nov. (Ophiocordycipitaceae), a pathogen of caterpillars (Noctuidae,Lepidoptera) from Yunnan,China

Ophiocordyceps unituberculata, a new insect pathogenic fungus from southwestern China, is described using molecular phylogenetic and morphological data. This fungus differs from other Ophiocordyceps species by its enormously long monophialidic conidiogenous cells and a large periclinal protuberance often growing near the apex of conidiogenous cells, single conidia (lanceolate to fusiform) embedded in mucous sheath, and much larger conidial dimensions. Four-locus (nrSSU, nrLSU, tef-1α and rpb1) and ITS data phylogenetic analyses show that O. unituberculata belongs to the Hirsutella nodulosa clade within the genus Ophiocordyceps of Ophiocordycipitaceae and is a separate clade from other allied species. Molecular phylogeny and morphology both strongly support the distinctiveness of this taxon. The interspecific relationships in the H. nodulosa clade are discussed.