Systematic and applied microbiology最新文献

Bartonella is one of the noncore bacterial genera in the honey bee (Apis mellifera) gut. So far, only one species, Bartonella apis, has been described from the honey bee gut. Previous analyses based on the genomic information of isolates and metagenome-assembled genomes suggested the existence of multiple Bartonella species in the bee guts. Here, 10 strains were isolated and characterized from the gut of A. mellifera from Jilin Province, China. New isolates shared ＞95% 16S rRNA gene sequence similarity with other species of the genus Bartonella. Phylogenetic analysis revealed that new isolates clustered with other type strains of Bartonella, and the bee gut Bartonella could be classified into three clades. The in silico DDH and average nucleotide identity values between strains of different clusters from the honey bee gut are 29.1–32.5% and 87.6–89.3%, all below the recommended 70.0% and 95% cutoff points. Cells are Gram-staining-negative rods and can grow on the surface of Brain Heart Infusion agar plates supplemented with defibrinated sheep blood in an aerobic environment with 5% CO₂ at 35–37 °C. Strains from different species varied in both phenotypic and chemotaxonomic characterizations. Comparative genomic analysis indicated that B. choladocola had unique sets of genes encoding invasin, representing the potential for this species to both live as a gut symbiont and also as an erythrocytic pathogen. Thus, we propose two novel species Bartonella choladocola sp. nov. whose type strain is W8125^T(=JCM 35030^T = ACCC 62057^T), and Bartonella apihabitans sp. nov. whose type strain is W8097^T(=JCM 35029^T = ACCC 62056^T).

Two rod-shaped Gram negative strains, SSUT16^T and SSUT22, were isolated from root nodules of Spartocytisus supranubius in soils of the Teide National Park (Tenerife, Spain). The 16S rRNA gene sequences of these two novel strains classified them within genus Bosea with similarity values ranging from 97.65 % to 99.54 % with respect to the other species of this genus. The MLSA analysis from a concatenation of the two housekeeping- genes, recA and gyrB, showed that Bosea thiooxidans LMG 26210^T and B. robiniae LMG 26381^T are the two closest relative species with which they share similarity sequences values of 94.42 % and 94.27 %, respectively. The genome sequence analysis of strain SSUT16^T showed average nucleotide identity percentages (ANIb) and digital DNA-DNA hybridization (dDDH) below 84 % and 33 %, respectively, with the type strains of all sequenced species of genus Bosea. These values are much lower than the currently accepted cut-off values for these two parameters to delineate bacterial species, confirming that the novel strains constitute a novel Bosea species. In addition, they are also distinguished from the other closest species in their fatty acid composition and in other phenotypic characteristics. Genome sequence analysis showed the absence of the common nodulation and nitrogen fixation genes in the novel strains. Therefore, based on the results of phylogenetic, genomic, chemotaxonomic and phenotypic characterization, we propose a new species named Bosea spartocytisi sp. nov., with type strain SSUT16^T (=LMG 32510^T = CECT 30526^T = HAMBI 3759^T).

A pure culture of alkaliphilic haloarchaeon strain AArc-S^T capable of anaerobic growth by carbohydrate-dependent sulfur respiration was obtained from hypersaline lakes in southwestern Siberia. According to phylogenetic analysis, AArc-S^T formed a new genus level branch most related to the genus Natronoarchaeum in the order Halobacteriales. The strain is facultatively anaerobic with strictly respiratory metabolism growing either by anaerobic respiration with elemental sulfur and thiosulfate as the electron acceptors or by aerobic respiration at microoxic conditions. Thiosulfate is reduced partially to sulfide and sulfite. It is a first sulfur-reducing alkaliphilic haloarchaeon utilizing sugars, starch and glycerol as substrates for anaerobic growth. It is extremely halophilic (optimum at 3.5 M total Na⁺) and obligately alkaliphilic (optimum at pH 9.5). The dominant polar lipids include PG and PGP-Me with the archaeol (C₂₀-C₂₀) or extended archaeol (C₂₀-C₂₅) cores. The dominant respiratory lipoquinone is MK-8:8. On the basis of unique physiological properties and results of phylogenetic analysis, the soda lake isolate is suggested to be classified into a novel genus and species Natranaeroarchaeum sulfidigenes gen. nov., sp. nov. (=JCM 34033^T = UNIQEM U1000^T). Furthermore, on the bases of phylogenomic reconstruction, a new family Natronoarchaeaceae fam. nov. is proposed within the order Halobacteriales incorporating Natranaeroarchaeum and three related genera: Natronoarchaeum, Salinarchaeum and Halostella.

Scorpions were among the first animals on land around 430 million years ago. Like many arachnids, scorpions have evolved complex venoms used to paralyze their prey and for self-defense. Here we sequenced and analyzed the metagenomic DNA from venom glands from Vaejovis smithi scorpions. A metagenome-assembled genome (MAG) of 624,025 bp was obtained corresponding to the previously reported Scorpion Group 1 (SG1). The SG1 genome from venom glands had a low GC content (25.8%) characteristic of reduced genomes, many hypothetical genes and genes from the reported minimal set of bacterial genes. Phylogenomic reconstructions placed the uncultured SG1 distant from other reported bacteria constituting a taxonomic novelty. By PCR we detected SG1 in all tested venom glands from 30 independent individuals. Microscopically, we observed SG1 inside epithelial cells from the venom glands using FISH and its presence in scorpion embryos suggested that SG1 is transferred from mother to offspring.

Bacteria within the phylum Planctomycetota are biologically relevant due to unique characteristics among prokaryotes. Members of the genus Rhodopirellula can be abundant in marine habitats, however, only six species are currently validly described. In this study, we expand the explored genus diversity by formally describing a novel species. The pink-coloured strain ICT_H3.1^T was isolated from brackish sediments collected in the Tagus estuary (Portugal) and a 16S rRNA gene sequence-based analysis placed this strain into the genus Rhodopirellula (family Pirellulaceae). The closest type strain is Rhodopirellula rubra LF2^T, suggested by a similarity of 98.4% of the 16S rRNA gene sequence. Strain ICT_H3.1^T is heterotrophic, aerobic and able to grow under microaerobic conditions. The strain grows between 15 and 37 °C, over a range of pH 6.5 to 11.0 and from 1 to 8% (w/v) NaCl. Several nitrogen and carbon sources were utilized by the novel isolate. Cells have an elongated pear-shape with 2.0 ± 0.3 × 0.9 ± 0.2 µm in size. Cells of strain ICT_H3.1^T cluster in rosettes through a holdfast structure and divide by budding. Younger cells are motile. Ultrathin cell sections show cytoplasmic membrane invaginations and polar fimbriae. The genome size is 9,072,081 base pairs with a DNA G + C content of 56.1 mol%. Genomic, physiological and morphological comparison of strain ICT_H3.1^T with its relatives suggest that it belongs to a novel species within the genus Rhodopirellula. Hence, we propose the name Rhodopirellula aestuarii sp. nov., represented by ICT_H3.1^T (=CECT30431^T = LMG32464^T) as the type strain of this novel species.

16S rRNA gene accession number: GenBank = OK001858.

Genome accession number: The Whole Genome Shotgun project has been deposited at DDBJ/ENA/GenBank under the accession JAMQBK000000000. The version described in this paper is version JAMQBK010000000.

In Croatia, a variety of geothermal springs with a wide temperature range and varied hydrochemical conditions exist, and they may harbor different niches for the distribution of microbial communities. In this study, 19 different sites, mainly located in central and eastern Croatia, were selected for primary characterization of spring hydrochemistry and microbial community composition. Using 16S rRNA gene amplicon sequencing, it was found that the bacterial communities that dominated most geothermal waters were related to Proteobacteria and Campylobacteria, while most archaeal sequences were related to Crenarchaeota. At the genus level, the prokaryotic community was highly site-specific and was often dominated by a single genus, including sites dominated by Hydrogenophilus, Sulfuricurvum, Sulfurovum, Thiofaba and Nitrospira, while the most abundant archaeal genera were affiliated to the ammonia-oxidizing archaea, Candidatus Nitrosotenuis and Candidatus Nitrososphaera. Whereas the microbial communities were overall highly location-specific, temperature, pH, ammonia, nitrate, total nitrogen, sulfate and hydrogen sulfide, as well as dissolved organic and inorganic carbon, were the abiotic factors that significantly affected microbial community composition. Furthermore, an aquifer-type effect was observed in the community composition, but there was no pronounced seasonal variability for geothermal spring communities (i.e. the community structure was mainly stable during the three seasons sampled). These results surprisingly pointed to stable and geographically unique microbial communities that were adapted to different geothermal water environments throughout Croatia. Knowing which microbial communities are present in these extreme habitats is essential for future research. They will allow us to explore further the microbial metabolisms prevailing at these geothermal sites that have high potential for biotechnological uses, as well as the establishment of the links between microbial community structure and the physicochemical environment of geothermal waters.

The type strains of all 33 species in the genus Kribbella were tested for growth on oxalate (⁻OOC-COO⁻) as sole carbon source. Media were initially formulated to contain sodium oxalate, but even a concentration as low as 7.5 mM oxalate prevented growth. A modified medium based on calcium oxalate was very successful in characterising oxalate utilisation by Kribbella strains (metabolism of oxalate by oxalotrophic bacteria results in visible zones of clearing around the growth streaks on the opaque plates). To assess the variability of oxalate utilisation in Kribbella species, we also tested eight non-type strains for their ability to use oxalate. Thirty of 33 type strains (90.9%) and six of eight non-type strains (75%) were able to use oxalate as a sole carbon source. Based on these results, we propose that oxalate would be an excellent carbon source for the selective isolation of Kribbella strains. Based on the oxalate-utilisation phenotype and analyses of the 19 publicly available Kribbella type-strain genome sequences, we propose a pathway for oxalate metabolism in Kribbella. This pathway is significantly different from those previously proposed for oxalate metabolism in other bacteria, involving the indirect catabolism of oxalate to formate. Formate production is proposed to be involved in energy generation and to be crucial for oxalate import via an oxalate:formate antiporter. To our knowledge, this is the first report of an oxalate:formate antiporter in an aerobic, Gram-positive bacterium.

Nine bacterial strains designated MT3-5-12^T, MT3-5-27, MTV1-9, S-DT1-15^T, S-DT1-34, MTV5-3^T, MTV4-17, MTV5-12 and MTV5-13 were isolated from the upper layer (1–5 cm in depth) of tidal flat sediment in Quanzhou Bay, China. The 16S rRNA gene of these strains shared maximum sequence similarities with Aestuariivivens insulae KCTC 42350^T of 94.9–97.1%. Phylogenetic analyses based on 16S rRNA gene sequences and 120 conserved concatenated proteins placed these strains in three novel phylogenetic clades affiliated to the genus Aestuariivivens of the family Flavobacteriaceae. Strains MT3-5-12^T, MT3-5-27 and MTV1-9 were phylogenetically close to A. insulae KCTC 42350^T. The average nucleotide identity (ANI) and digital DNA-DNA hybridization (dDDH) values between strains MT3-5-12^Tand MTV1-9 and A. insulae KCTC 42350^T were estimated to be 78.5-78.7% and 22.5%, respectively. Strains S-DT1-15^T and S-DT1-34 formed a distinctly separated clade from A. insulae KCTC 42350^T. The ANI and dDDH values between strains S-DT1-15^T and S-DT1-34 and A. insulae KCTC 42350^T were 76.3–76.4% and 20.4–20.5%, respectively. The other four strains MTV5-3^T, MTV4-17, MTV5-12 and MTV5-13, formed a third novel clade, distinctly separated from A. insulae KCTC 42350^T. The ANI and dDDH values between strains MTV5-3^T and MTV4-17 and A. insulae KCTC 42350^T were 74.7% and 19.1–19.2%, respectively. The phylogenetic analyses and whole genomic comparisons, combined with phenotypic and chemotaxonomic features, strongly supported the nine strains could be classified as three novel species within the genus Aestuariivivens, for which the names Aestuariivivens marinum sp. nov. MT3-5-12^T, Aestuariivivens sediminis sp. nov. S-DT1-15^T, and Aestuariivivens sediminicola sp. nov. MTV5-3^T are proposed.