Dioszegia rishiriensis sp. nov., a novel yeast species from soil collected on Rishiri Island, Hokkaido, Japan.

Anamorphic basidiomycetous yeast strains RS090(T) and RS092 were isolated from a soil sample collected on Rishiri Island in the Rishiri, Rebun, Sarobetsu National Park, Hokkaido, Japan. As the sequences of the D1/D2 domains of their large-subunit rRNA genes were identical and those of the internal transcribed spacer regions differed in only four bases, we conclude that they belong to a single species with intraspecific diversity. Phylogenetically, this species was related to Dioszegia buhagiarii and Dioszegia hungarica, in the Tremellales, Tremellomycetes, Basidiomycota, but was clearly distinct from them. Based on the results of sequence analyses and phenotypic characteristics, we conclude that they belong to a novel species in the genus Dioszegia, for which the name Dioszegia rishiriensis sp. nov. is proposed, with the type strain RS090(T) ( = JCM 16282(T)  = CBS 11844(T)).

The identity of Penicillium sp. 1, a major contaminant of the stone chambers in the Takamatsuzuka and Kitora Tumuli in Japan, is Penicillium paneum.

Penicillium appeared as the major dweller in the Takamatsuzuka Tumulus (TT) and Kitora Tumulus (KT) stone chambers, both located in the village of Asuka, Nara Prefecture, in relation to the biodeterioration of the 1,300-year-old mural paintings, plaster walls and ceilings. Of 662 Penicillium isolates from 373 samples of the TT (sampling period, May 2004-2007) and the KT (sampling period, June 2004-Sep 2007), 181 were phenotypically assigned as Penicillium sp. 1 which shared similar phenotypic characteristics of sect. Roqueforti in Penicillium subg. Penicillium. Fifteen representative isolates of Penicillium sp. 1, 13 from TT and 2 from KT, were selected for molecular phylogenetic analysis. The 28S rDNA D1/D2, ITS, beta-tubulin, and lys2 gene sequence-based phylogenies clearly demonstrated that the three known species P. roqueforti, P. carneum and P. paneum in sect. Roqueforti, and all TT and KT isolates grouped together. In addition to this, TT and KT isolates formed a monophyletic group with the ex-holotype strain CBS 101032 of P. paneum Frisvad with very strong bootstrap supports. So far, P. paneum has been isolated only from mouldy rye breads, other foods, and baled grass silage. Therefore, this is the first report of P. paneum isolation from samples relating to the biodeteriorated cultural properties such as mural paintings on plaster walls.

Polyphasic insights into the microbiomes of the Takamatsuzuka Tumulus and Kitora Tumulus.

Microbial outbreaks and related biodeterioration problems have affected the 1300-year-old multicolor (polychrome) mural paintings of the special historic sites Takamatsuzuka Tumulus (TT) and Kitora Tumulus (KT). Those of TT are designated as a national treasure. The microbiomes of these tumuli, both located in Asuka village, Nara, Japan, are critically reviewed as the central subject of this report. Using culture-dependent methods (conventional isolation and cultivation), we conducted polyphasic studies of the these microbial communities and identified the major microbial colonizers (Fusarium spp., Trichoderma spp., Penicillium spp., dark Acremonium spp., novel Candida yeast spp., Bacillus spp., Ochrobactrum spp., Stenotrophomonas tumulicola, and a few actinobacterial genera) and noteworthy microbial members (Kendrickiella phycomyces, Cephalotrichum verrucisporum (≡Doratomyces verrucisporus), Sagenomella striatispora, Sagenomella griseoviridis, two novel Cladophialophora spp., Burgoa anomala, one novel species Prototheca tumulicola, five novel Gluconacetobacter spp., three novel Bordetella spp., and one novel genus and species Krasilnikoviella muralis) involved in the biodeterioration of mural paintings, plaster walls, and stone chamber interiors. In addition, we generated microbial community data from TT and KT samples using culture-independent methods (molecular biological methods, including PCR-DGGE, clone libraries, and pyrosequence analysis). These data are comprehensively presented, in contrast to those derived from culture-dependent methods. Furthermore, the microbial communities detected using both methods are analytically compared, and, as a result, the complementary roles of these methods and approaches are highlighted. In related contexts, knowledge of similar biodeterioration problems affecting other prehistoric cave paintings, mainly at Lascaux in France and Altamira in Spain, are referred to and commented upon. Based on substrate preferences (or ecological grouping) and mapping (plotting detection sites of isolates), we speculate on the possible origins and invasion routes whereby the major microbial colonizers invaded the TT stone chamber interior. Finally, concluding remarks, lessons, and future perspectives based on our microbiological surveys of these ancient tumuli, and similar treasures outside of Japan, are briefly presented. A list of the microbial taxa that have been identified and fully or briefly described by us as known and novel taxa for TT and KT isolates since 2008 is presented in Supplementary Materials.

Aminoadipate reductase gene: a new fungal-specific gene for comparative evolutionary analyses.

BACKGROUND: In fungi, aminoadipate reductase converts 2-aminoadipate to 2-aminoadipate 6-semialdehyde. However, other organisms have no homologue to the aminoadipate reductase gene and this pathway appears to be restricted to fungi. In this study, we designed degenerate primers for polymerase chain reaction (PCR) amplification of a large fragment of the aminoadipate reductase gene for divergent fungi. RESULTS: Using these primers, we amplified DNA fragments from the archiascomycetous yeast Saitoella complicata and the black-koji mold Aspergillus awamori. Based on an alignment of the deduced amino acid sequences, we constructed phylogenetic trees. These trees are consistent with current ascomycete systematics and demonstrate the potential utility of the aminoadipete reductase gene for phylogenetic analyses of fungi. CONCLUSIONS: We believe that the comparison of aminoadipate reductase among species will be useful for molecular ecological and evolutionary studies of fungi, because this enzyme-encoding gene is a fungal-specific gene and generally appears to be single copy.

Molecular evolution of adenylating domain of aminoadipate reductase.

BACKGROUND: Aminoadipate reductase (Lys2) is a fungal-specific protein. This enzyme contains an adenylating domain. A similar primary structure can be found in some bacterial antibiotic/peptide synthetases. In this study, we aimed to determine which bacterial adenylating domain is most closely related to Lys2. In addition, we analyzed the substitution rate of the adenylating domain-encoding region. RESULTS: Some bacterial proteins contain more than two similar sequences to that of the adenylating domain of Lys2. We compared 67 amino acid sequences from 37 bacterial and 10 fungal proteins. Phylogenetic trees revealed that the lys2 genes are monophyletic; on the other hand, bacterial antibiotic/peptide synthase genes were not found to be monophyletic. Comparative phylogenetic studies among closely related fungal lys2 genes showed that the rate of insertion/deletion in these genes was lower and the nucleotide substitution rate was higher than that in the internal transcribed spacer (ITS) regions. CONCLUSIONS: The lys2 gene is one of the most useful tools for revealing the phylogenetic relationships among fungi, due to its low insertion/deletion rate and its high substitution rate. Lys2 is most closely related to certain bacterial antibiotic/peptide synthetases, but a common ancestor of Lys2 and these synthetases evolutionarily branched off in the distant past.

Molecular phylogenetic analyses based on the nuclear rRNA genes and the intron-exon structures of the nuSSU rRNA gene in Dictyocatenulata alba (anamorphic Ascomycota).

Molecular phylogenies inferred from the nuclear small subunit rRNA gene (nuSSU), nuclear large subunit rRNA gene D1/D2 region (nuLSU), and ITS-5.8S rRNA gene (ITS) indicated that five cultures of the lichenized hyphomycete Dictyocatenulata alba isolated from Japan form a monophyletic clade with high bootstrap support, and a close relationship to the Ostropomycetidae (Lecanoromycetes, Pezizomycotina, Ascomycota). Insertion sequences were found in the nuSSU of all isolates [e.g., nine insertions in the strain JCM 5358 (Japan Collection of Microorganisms)], some of which were group I introns. Five new insertion positions were found among the D. alba isolates. Using BLAST, none of the insertion sequences of D. alba were closely related to those of fungi or other organisms deposited in public DNA databases. Insertion positions were similar in some isolates, and two positions were common to all isolates. Although all phylogenetic analyses based on nuSSU, nuLSU, and ITS revealed the monophyly of D. alba, the isolates were divided into two (in the nuSSU tree) or three (in the nuLSU and ITS trees) groups. Based on the phylogenetic analyses and the intron-exon structures, the five isolates identified as D. alba belong to three cryptic species and therefore D. alba should be considered a species complex. The very slow-growing, tough agar colonies of the isolates, the occurrence of the species on both slightly lichenized and nonlichenized surfaces of trees, or pebbles (rarely on soil), suggest that the members of the D. alba complex may be lichenized. The photobiont was not clearly identified in this study.

Microbulbifer variabilis sp. nov. and Microbulbifer epialgicus sp. nov., isolated from Pacific marine algae, possess a rod-coccus cell cycle in association with the growth phase.

Phylogenetic and taxonomic characterization was performed for 14 strains of bacteria that produce anticancer antibiotics (pelagiomicins) (represented by strain Ni-2088(T)) and one strain that produces UV-absorbing substances (strain F-104(T)), isolated from marine algae and seagrass collected from coastal areas of tropical Pacific islands and a subtropical island of Japan. All 15 isolates were Gram-negative, strictly aerobic, non-motile and non-spore-forming. Sequence analysis of the 16S rRNA gene showed that the isolates occupied positions in the phylogenetic radiation of the genus Microbulbifer, with similarities of 93.6-97.6 %. The cells possessed a clearly discernible rod-coccus cell cycle in association with the growth phase; cells were rods during the growth phase and all converted to coccoid-ovoid cells when proliferation ceased. The coccoid-ovoid cells were optically denser than the rod cells and were viable for extended periods. They were considered to constitute a resting form. The type strains of described species of Microbulbifer were also found to possess identical rod-coccus cell cycles. The G+C content of the DNA was 48.1-49.7 mol%. The major respiratory quinone system was ubiquinone-8. The major fatty acids were C(18 : 1)omega7c and C(16 : 0), and the hydroxy acids comprised C(10 : 0) 3-OH, C(12 : 0) 3-OH and iso-C(11 : 0) 3-OH. The polar lipids comprised phosphatidylethanolamine, phosphatidylglycerol and phosphatidylserine. The group of 14 pelagiomicin-producing strains and strain F-104(T) each constituted a single genomic species. Based on phylogenetic affiliation, phenotypic characteristics and genomic distinctness, the isolates represent two novel species in the genus Microbulbifer, for which the names Microbulbifer variabilis sp. nov. (type strain Ni-2088(T) =MBIC01082(T) =ATCC 700307(T)) and Microbulbifer epialgicus sp. nov. (type strain F-104(T) =MBIC03330(T) =DSM 18651(T)) are proposed.