Phylogenic and phenotypic evidence for the transfer of Eubacterium fossor to the genus Atopobium as Atopobium fossor comb. nov.

The 16S rRNA primary structure of Eubacterium fossor was determined by sequencing in vitro amplified rDNA. Sequence comparisons indicated that E. fossor has a specific phylogenetic association with the Atopobium species and is far from E. limosum, the type species of the genus Eubacterium. Phenotypic characters of E. fossor resemble those of the genus Atopobium. Therefore, we propose that E. fossor should be transferred to the genus Atopobium as Atopobium fossor comb. nov.     

Taxonomic insights into the phylogeny of Bacillus badius and proposal for its reclassification to the genus Pseudobacillus as Pseudobacillus badius comb. nov. and reclassification of Bacillus wudalianchiensis Liu et al., 2017 as Pseudobacillus wudalianchiensis comb. nov.

The species Bacillus badius is one of the oldest members of the genus Bacillus isolated from faeces of children and was classified based on its ability to form endospores [8]. In 16S rRNA gene sequence and phylogenetic analysis, Bacillus badius DSM 23^T shared low similarity (93.0%) and distant relationship with B. subtilis, the type species of the genus Bacillus indicating that it does not belong to this genus. Additional strains of the species, B. badius DSM 5610, DSM 30822 and B. encimensis SGD-V-25 (which has been recently reclassified as a member of this species) were included in the study to consider intraspecies diversity. Detailed molecular phylogenetic and comparative genome analysis clearly showed that the strains of B. badius were consistently retrieved outside the cluster of Bacillus sensu stricto and also distantly related to the genera Domibacillus and Quasibacillus. Further, the data from biochemical reactions (inability to ferment most carbohydrates), polar lipids profile (presence of diphosphatidylglycerol, phosphatidylglycerol, phosphatidylethanolamine and an aminophosphoglycolipid) and fatty acids supported the molecular analysis. Thus the four B. badius strains; DSM 23^T, DSM 5610, DSM 30822 and SGD-V-25 displayed sufficient demarcating phenotypic characteristics that warrant their classification as members of a novel genus and single species, for which the name Pseudobacillus badius gen. nov. comb. nov. is proposed with Pseudobacillus badius DSM 23^T (= ATCC 14574^T) as the type strain. Additionally, based on our findings from phenotypic, chemotaxonomic and genotypic parameters, Bacillus wudalianchiensis DSM 100757^T was reclassified as Pseudobacillus wudalianchiensis comb. nov.     

Molecular typing of isolates of the fish pathogen, Flavobacterium columnare, by single-strand conformation polymorphism analysis

Flavobacterium columnare intraspecies diversity was revealed by analyzing the 16S rRNA gene and the 16S-23S internal spacer region (ISR). Standard restriction fragment length polymorphism (RFLP) of these sequences was compared with single-strand conformation polymorphism (SSCP). Diversity indexes showed that both 16S-SSCP and ISR-SSCP improved resolution (D>or=0.9) when compared with standard RFLP. ISR-SSCP offered a simpler banding pattern than 16S-SSCP while providing high discrimination between isolates. SSCP analysis of rRNA genes proved to be a simple, rapid, and cost-effective method for routine fingerprinting of F. columnare.     

Evaluation of 16S rDNA- and gyrB-DGGE for typing members of the genus Aeromonas

The DNA sequence of the gyrB gene is a suitable phylogenetic marker for bacterial systematics. In this study, the diversity of Aeromonas spp. present in environmental samples was assessed by a PCR combined with DGGE approach. PCR primers targeting the gyrB gene of aeromonads were designed and the resulting amplicons were analyzed by DGGE. The gyrB-DGGE analysis was evaluated with Aeromonas isolates and reference strains allowing discrimination of the majority of strains. The gyrB-DGGE analysis is a powerful tool to monitor the presence and evaluate the diversity of aeromonads in complex samples, as is the case of water from a wastewater treatment plant.     

Reclassification of Bacteroides putredinis (Weinberg et al., 1937) in a new genus Alistipes gen. nov., as Alistipes putredinis comb. nov., and description of Alistipes finegoldii sp. nov., from human sources

During studies on the bacteriology of appendicitis in children, we often isolated from inflamed and non-inflamed tissue samples, an unusual bile-resistant pigment-producing strictly anaerobic gram-negative rod. Phenotypically this organism resembles members of Bacteroides fragilis group of species, as it is resistant to bile and exhibits a special-potency-disk pattern (resistance to vancomycin, kanamycin and colistin) typical for the B. fragilis group. However, the production of brown pigment on media containing haemolysed blood and a cellular fatty acid composition dominated by iso-C15:0, suggests that the organism most closely resembles species of the genus Porphyromonas. However, the unidentified organism differs from porphyromonads by being bile-resistant and by not producing butyrate as a metabolic end-product. Comparative 16S ribosomal RNA gene sequencing studies show the unidentified organism represents a distinct sub-line, associated with but distinct from, the miss-classified species Bacteroides putredinis. The clustering of the unidentified bacterium with Bacteroides putredinis was statistically significant, but they displayed > 4% sequence divergence with each other. Chromosomal DNA-DNA pairing studies further confirmed the separateness of the unidentified bacterium and Bacteroides putredinis. Based on phenotypic and phylogenetic considerations, it is proposed that Bacteroides putredinis and the unidentified bacterium from human sources be classified in a new genus Alistipes, as Alistipes putredinis comb. nov. and Alistipes finegoldii sp. nov., respectively. The type strain of Alistipes finegoldii is CCUG 46020(T) (= AHN243(T)).     

A phylogenetic analysis of the genus Catellatospora based on 16S ribosomal DNA sequences, including transfer of Catellatospora matsumotoense to the genus Micromonospora as Micromonospora matsumotoense comb. nov.

Phylogenetic studies based on the 16S ribosomal gene sequences showed that members of the genus Catellatospora revealed phylogenetic heterogeneity within the family Micromonosporaceae as well as a heterogeneous menaquinone composition. Among them, Catellatospora matsumotoense was closely related to members of the genus Micromonospora, indicating that this organism should be excluded from the genus Catellatospora. On the basis of classical taxonomic characteristics and phylogenetic evidence, Catellatospora matsumotoense is proposed to be transferred to the genus Micromonospora as M. matsumotoense comb. nov.     

Duganella phyllosphaerae sp. nov., isolated from the leaf surface of Trifolium repens and proposal to reclassify Duganella violaceinigra into a novel genus as Pseudoduganella violceinigra gen. nov., comb. nov

A bright yellow pigmented bacterium was isolated from the leaf surface of Trifolium repens in Germany. Comparative analysis of 16S rRNA gene sequences showed that this bacterium is most closely related to Duganella zoogloeoides IAM 12670(T), with a similarity of 99.3%, but revealed only a moderate similarity (96.8%) to the second Duganella species, Duganella violaceinigra YIM 31327(T). Strain T54(T) is clearly different from D. zoogloeoides IAM 12670(T) in that DNA-DNA hybridization revealed a similarity value of 46% (reciprocal 42%). Ubiquinone (Q-8) was the respiratory quinone and the predominant polar lipids consisted of phosphatidylglycerol, phosphatidylethanolamine, three unknown phospholipids and one aminolipid. Strain T54(T) can be distinguished from D. zoogloeoides by the carbon substrate utilization tests of d-trehalose, cis-aconitate, trans-aconitate, glutarate and dl-3-hydroxybutyrate, and 4-hydroxybenzoate in addition to a different polar lipid profile. The name Duganella phyllosphaerae sp. nov. is proposed for this novel species, with the type strain T54(T) (=LMG 25994 = CCM 7824(T)) [corrected]. In addition, it is proposed to reclassify D. violaceinigra into a novel genus Pseudoduganella gen. nov. as the novel species Pseudoduganella violaceinigra comb. nov. because of the low 16S rRNA gene sequence similarities to the other Duganella species (<97%) and striking differences in chemotaxonomic (lipid profiles and fatty acid patterns) and other phenotypic features, including the colony pigmentation.     

浮霉菌门严格厌氧产氢细菌(Thermopirellula anaerolimosa)的分离及其生理特性

[目的]厌氧颗粒污泥中含有大量未知微生物资源,利用低浓度底物及添加抗生素的培养基进行厌氧发酵细菌的筛选,并对分离菌株进行生理生化特性研究.[方法]利用系列稀释法及亨盖特厌氧滚管技术从制糖废水厌氧处理反应器的颗粒污泥中分离到一株高温厌氧产氢细菌VM20-7T,通过16S rRNA基因序列同源性确定其系统发育地位.[结果]菌株VM20-7T为高温、严格厌氧、革兰氏阴性梨形细菌,细胞大小为(0.7-2.0)μm×(0.7-2.0) μm,不运动,不产芽胞.其生长温度范围为35℃-50℃(最适温度45℃),pH范围为6.0-8.3(最适pH7.0-7.5),NaCl耐受范围为0％-0.5％(w/v,最适浓度0％).菌株VM20-7T可利用葡萄糖、麦芽糖、核糖等多种糖类为唯一碳源生长,葡萄糖发酵终产物是乙酸和H2.该菌株不利用硝酸盐、硫酸盐等作为电子受体生长.G+C含量为60.9 mol％,16S rRNA基因序列同源性显示菌株属于浮霉菌门,但与已培养菌株的同源性较低,与梨形菌属一红小梨形菌属-芽殖小小梨形菌属(Pirellula-Rhodopirellul -Blastopirellula,PRB)分支的亲缘关系最近,但序列相似性也仅为82.7％-84.3％.[结论]利用低浓度糖类并添加抗生素分离厌氧颗粒污泥中的微生物,获得了浮霉菌门首例严格厌氧细菌VM20-7T.生理生化特性和系统发育分析显示,菌株VM20-7T为浮霉菌目的新属新种,命名为Thermopirellula anaerolimosa.该菌株的菌种保藏号为CGMCC 1.5169T=JCM 17478T=DSM 24165T.     

Proposal to change the genus designation Serpula to Serpulina gen. nov. containing the species Serpulina hyodysenteriae comb. nov. and Serpulina innocens comb. nov.

The bacterial genus Serpula Stanton et al. 1991 is illegitimate due to the existence of a fungal genus Serpula Pers. ex S. F. Gray. Consequently, a new genus designation, Serpulina, is proposed for this spirochete genus. Serpula hyodysenteriae, the type species, and Serpula innocens Stanton et al. 1991, therefore, become Serpulina hyodysenteriae comb. nov. and Serpulina innocens comb. nov.     

Aeromonas allosaccharophila sp. nov., a new mesophilic member of the genus Aeromonas

Phenotypic and genetic studies were performed on some atypical aeromonas strains of uncertain taxonomic position. 16S rRNA gene sequence analysis revealed that these strains represent a hitherto unknown genetic line within the genus Aeromonas, for which the name Aeromonas allosaccharophila sp. nov. is proposed. The type strain is CECT 4199.     

Bacillus onubensis sp. nov., isolated from the air of two Andalusian caves

Two Gram-positive, catalase-positive, oxidase-negative, motile, endospore-forming, rod-shaped bacteria, designated as 0911MAR22V3T and 0911TES10J4, were isolated from air samples collected in two show caves, located in Andalusia, Southern Spain. Phylogenetic analysis based on 16S rRNA gene sequences indicated that both strains were indistinguishable and they were most closely related to Bacillus humi DSM 16318T (98%). DNA–DNA hybridization values of the strain 0911MAR22V3T with respect to strain 0911TES10J4 and B. humi DSM 16318T were 76.8% (73.9%, reciprocal) and 56.9% (63.3%, reciprocal analysis), respectively. Whole genome average nucleotide identity (ANI) values of both strains were in the threshold value for species delineation and less than 85% with B. humi. Strains 0911MAR22V3T and 0911TES10J4 grew at 10–47 °C (optimum 37 °C), at pH 6–9.5 and with 0–8% (w/v) NaCl (optimum 1%). In both strains the dominant isoprenoid quinone was MK-7, the major cellular polar lipids were diphosphatidylglycerol, phosphatidylglycerol, phosphatidylethanolamine, and two more phospholipids, the predominant fatty acids were iso-C15:0 and anteiso-C15:0 and the DNA G + C content was 38 mol%. On the basis of their phylogenetic relatedness and their phenotypic and genotypic features, the strains 0911MAR22V3T and 0911TES10J4 should be attributed to a novel species within the genus Bacillus, for which the name Bacillus onubensis sp. nov. is proposed. The type strain is 0911MAR22V3T (=LMG 27963T = CECT 8479T); and strain 0911TES10J4 (CECT 8478) is a reference strain.     

Methylosulfonomonas methylovora gen. nov., sp. nov., and Marinosulfonomonas methylotropha gen. nov., sp. nov.: novel methylotrophs able to grow on methanesulfonic acid

Two novel genera of restricted facultative methylotrophs are described; both Methylosulfonomonas and Marinosulfonomonas are unique in being able to grow on methanesulfonic acid as their sole source of carbon and energy. Five identical strains of Methylosulfonomonas were isolated from diverse soil samples in England and were shown to differ in their morphology, physiology, DNA base composition, molecular genetics, and 16S rDNA sequences from the two marine strains of Marinosulfonomonas, which were isolated from British coastal waters. The marine strains were almost indistinguishable from each other and are considered to be strains of one species. Type species of each genus have been identified and named Methylosulfonomonas methylovora (strain M2) and Marinosulfonomonas methylotropha (strain PSCH4). Phylogenetic analysis using 16S rDNA sequencing places both genera in the α-Proteobacteria. Methylosulfonomonas is a discrete lineage within the α-2 subgroup and is not related closely to any other known bacterial genus. The Marinosulfonomonas strains form a monophyletic cluster in the α-3 subgroup of the Proteobacteria with Roseobacter spp. and some other partially characterized marine bacteria, but they are distinct from these at the genus level. This work shows that the isolation of bacteria with a unique biochemical character, the ability to grow on methanesulfonic acid as energy and carbon substrate, has resulted in the identification of two novel genera of methylotrophs that are unrelated to any other extant methylotroph genera. Received: 19 July 1996 / Accepted: 7 October 1996     

Examination into the taxonomic position of Bacillus thermotolerans Yang et al., 2013, proposal for its reclassification into a new genus and species Quasibacillus thermotolerans gen. nov., comb. nov. and reclassification of B. encimensis Dastager et al., 2015 as a later heterotypic synonym of B. badius

Two novel Gram-staining positive, rod-shaped, moderately halotolerant, endospore forming bacterial strains 5.5LF 38TD and 5.5LF 48TD were isolated and taxonomically characterized from a landfill in Chandigarh, India. The analysis of 16S rRNA gene sequences of the strains confirmed their closest identity to Bacillus thermotolerans SgZ-8T with 99.9% sequence similarity. A comparative phylogenetic analysis of strains 5.5LF 38TD, 5.5LF 48TD and B. thermotolerans SgZ-8^T confirmed their separation into a novel genus with B. badius and genus Domibacillus as the closest phylogenetic relatives. The major fatty acids of the strains are iso-C_15:0 and iso-C_16:0 and MK-7 is the only quinone. The major polar lipids are diphosphatidylglycerol, phosphatidylglycerol and phosphatidylethanolamine. The digital DNA-DNA hybridization (DDH) and ortho average nucleotide identity (ANI) values calculated through whole genome sequences indicated that the three strains showed low relatedness with their phylogenetic neighbours. Based on evidences from phylogenomic analyses and polyphasic taxonomic characterization we propose reclassification of the species B. thermotolerans into a novel genus named Quasibacillus thermotolerans gen. nov., comb. nov with the type strain SgZ-8^T (= CCTCC AB2012108^T = KACC 16706^T). Further our analyses also revealed that B. encimensis SGD-V-25^T is a later heterotypic synonym of Bacillus badius DSM 23^T.     

Igniting taxonomic curiosity: The amazing story of Amazonocrinis with the description of a new genus Ahomia gen. nov. and novel species of Ahomia,Amazonocrinis, and Dendronalium from the biodiversity-rich northeast region of India

Five cyanobacterial strains exhibiting Nostoc-like morphology were sampled from the biodiversity hotspots of the northeast region of India and characterized using a polyphasic approach. Molecular and phylogenetic analysis using the 16S rRNA gene indicated that the strains belonged to the genera Amazonocrinis and Dendronalium. In the present investigation, the 16S rRNA gene phylogeny clearly demarcated two separate clades of Amazonocrinis. The strain MEG8-PS clustered along with Amazonocrinis nigriterrae CENA67, which is the type strain of the genus. The other three strains ASM11-PS, RAN-4C-PS, and NP-KLS-5A-PS clustered in a different clade that was phylogenetically distinct from the Amazonocrinis sensu stricto clade. Interestingly, while the 16S rRNA gene phylogeny exhibited two separate clusters, the 16S–23S ITS region analysis did not provide strong support for the phylogenetic observation. Subsequent analyses raised questions regarding the resolving power of the 16S–23S ITS region at the genera level and the associated complexities in cyanobacterial taxonomy. Through this study, we describe a novel genus Ahomia to accommodate the members clustering outside the Amazonocrinis sensu stricto clade. In addition, we describe five novel species, Ahomia kamrupensis, Ahomia purpurea, Ahomia soli, Amazonocrinis meghalayensis, and Dendronalium spirale, in accordance with the International Code of Nomenclature for algae, fungi, and plants (ICN). Apart from further enriching the genera Amazonocrinis and Dendronalium, the current study helps to resolve the taxonomic complexities revolving around the genus Amazonocrinis and aims to attract researchers to the continued exploration of the tropical and subtropical cyanobacteria for interesting taxa and lineages.     

斑鳠烂鳃病病原菌的研究

从池塘患烂鳃病的斑鳠(Mystus guttatus)亲鱼病灶中分离出一株毒力较强的致病菌-Mg2,经形态学观察、生理生化特性和16S rRNA基因序列分析鉴定,其主要特征为：菌体细长,无鞭毛和荚膜,革兰氏阴性,大小0.5×(6.5－11)μm,菌落黄色,边缘不整齐呈假树根状。氧化酶、过氧化氢酶阳性,分解酪素和明胶,硝酸盐还原阳性;不分解纤维素、几丁质、酪氨酸、七叶灵和淀粉,吲哚和葡萄糖产气阴性。对恩诺沙星、诺氟沙星、萘啶酸、红霉素、洁霉素敏感,菌株的16S rRNA基因序列分析结果表明：Mg2菌株与柱状黄杆菌聚类,基因序列的同源性在97.5%以上,综合生理生化、分子生物学两方面的分类鉴定结果,Mg2菌株应归类鉴定为柱状黄杆菌（Flavobacterium Columnare）。     

Characterization of the genus Bifidobacterium by automated ribotyping and 16S rRNA gene sequences

In order to characterize the genus Bifidobacterium, ribopatterns and approximately 500 bp (Escherichia coli positions 27 to 520) of 16S rRNA gene sequences of 28 type strains and 64 reference strains of the genus Bifidobacterium were determined. Ribopatterns obtained from Bifidobacterium strains were divided into nine clusters (clusters I-IX) with a similarity of 60%. Cluster V, containing 17 species, was further subdivided into 22 subclusters with a similarity of 90%. In the genus Bifidobacterium, four groups were shown according to Miyake et al.: (i) the Bifidobacterium longum infantis-longum-suis type group, (ii) the B. catenulatum-pseudocatenulatum group, (iii) the B. gallinarum-saeculare-pullorum group, and (iv) the B. coryneforme-indicum group, which showed higher than 97% similarity of the 16S rRNA gene sequences in each group. Using ribotyping analysis, unique ribopatterns were obtained from these species, and they could be separated by cluster analysis. Ribopatterns of six B. adolescentis strains were separated into different clusters, and also showed diversity in 16S rRNA gene sequences. B. adolescentis consisted of heterogeneous strains. The nine strains of B. pseudolongum subsp. pseudolongum were divided into five subclusters. Each type strain of B. pseudolongum subsp. pseudolongum and B. pseudolongum subsp. globosum and two intermediate groups, which were suggested by Yaeshima et al., consisted of individual clusters. B. animalis subsp. animalis and B. animalis subsp. lactis could not be separated by ribotyping using Eco RI. We conclude that ribotyping is able to provide another characteristic of Bifidobacterium strains in addition to 16S rRNA gene sequence phylogenetic analysis, and this information suggests that ribotyping analysis is a useful tool for the characterization of Bifidobacterium species in combination with other techniques for taxonomic characterization.     

Phylogenetic evidence for the transfer of Eubacterium suis to the genus Actinomyces as Actinomyces suis comb. nov.

The 16S rRNA primary structures of Eubacterium suis DSM 20639T (T = type strain) and Bifidobacterium bifidum DSM 20456T were determined by sequencing in vitro amplified rDNA. Sequence comparisons indicated that B. bifidum is moderately related to representatives of the genera Actinomyces and Mobiluncus. The closest relative of E. suis is Actinomyces pyogenes. E. suis and A. pyogenes are more closely related phylogenetically to one another than to the other Actinomyces species that have been investigated by using comparative 16S rRNA analysis. Therefore, we propose that E. suis should be transferred to the genus Actinomyces as Actinomyces suis comb. nov.     

Characterization of Desulfomicrobium escambium sp. nov. and proposal to assign Desulfovibrio desulfuricans strain Norway 4 to the genus Desulfomicrobium

A sulfate-reducing bacterium, designated strain ESC1, was isolated and found to be a new species. Strain ESC1 is a strictly anaerobic, gram-negative, non-sporeforming, motile, short, round-ended rod often occurring in pairs. Of 31 fermentative substrates tested, only pyruvate was utilized. Sulfate enhanced growth with pyruvate and allowed growth with ethanol, lactate, formate and hydrogen. Both sulfate and thiosulfate were reduced. Lactate was incompletely oxidized to acetate and CO₂. The strain was desulfoviridin negative. The G+C content is 59.9%. These data suggested placement of strain ESC1 in the genus Desulfomicrobium. Comparative 16S rRNA analysis showed that strain ESC1 shares 98% rRNA sequence similarity with Desulfomicrobium baculatum and Desulfovibrio desulfuricans strain Norway 4. The latter two strains shared greater than 99% 16S rRNA sequence similarity. Strain ESC1 has been designated as the new species Desulfomicrobium escambium. We also recommend that D. desulfuricans strain Norway 4 be considered for reclassification as a Desulfomicrobium species.