List of new names and new combinations previously effectively, but not validly, published

An update on novel taxa and revised taxonomic status of bacteria isolated from aquatic host species described in 2022-2023

The description of new taxa and nomenclature updates to currently known taxa from aquatic animal species continues. After a review of the literature from 2022 and 2023, multiple lists of bacteria, including members of Phylum Planctomycetota, were compiled. As with the previous review, most bacteria are oxidase-positive Gram-negative bacilli with familiar families including new taxa in Aeromonadaceae, Flavobacteriaceae, and Vibrionaceae. A number of Gram-positive bacilli are described including new taxa in the Nocardioides, Paenibacillus, and Streptomyces genera. Two anaerobic species are listed, and one new member of Family Planctomycetaceae is noted. Revised taxa are briefly mentioned. The majority of new and revised taxa are isolated from healthy aquatic animals, and therefore, the role of these new bacteria in health and disease is unknown. Bacteria with pathogenic association and potential production of bioactive substances are highlighted.

Update on Novel Taxa and Revised Taxonomic Status of Bacteria Isolated from Nondomestic Animals Described in 2018 to 2021

Revisions and new additions to bacterial taxonomy can have a significant widespread impact on clinical practice, infectious disease epidemiology, veterinary microbiology laboratory operations, and wildlife conservation efforts. The expansion of genome sequencing technologies has revolutionized our knowledge of the microbiota of humans, animals, and insects. Here, we address novel taxonomy and nomenclature revisions of veterinary significance that impact bacteria isolated from nondomestic wildlife, with emphasis being placed on bacteria that are associated with disease in their hosts or were isolated from host animal species that are culturally significant, are a target of conservation efforts, or serve as reservoirs for human pathogens.

Lewinella aurantiaca sp. nov., a carotenoid pigment-producing bacterium isolated from surface seawater

A Gram-stain-negative, aerobic, rod-shaped, carotenoid-pigmented, motile-by-gliding bacterium, which was designated as SSH13T, was isolated from a surface seawater sample collected from Sehwa Beach in the Republic of Korea. Strain SSH13T was oxidase-negative, catalase-positive and grew at 2–37 °C (optimum, 30 °C), in the presence of 0.5–6% NaCl and within a pH range of pH 6–10 (optimum, pH 8). The novel isolate required NaCl for growth and grew optimally with approximately 2 % NaCl. Chemotaxonomic and morphological characteristics were consistent with members of the genus Lewinella . Furthermore, phylogenetic analysis based on 16S rRNA gene sequencing revealed that strain SSH13T was most closely related to the type strains of the genus Lewinella . Strain SSH13T had highest 16S rRNA gene sequence similarities to Lewinella persica DSM 23188T (95.3 %) and Lewinella agarilytica KCTC 12774T (95.0 %). The major fatty acids of SSH13T were summed feature 3 (C16 : 1  ω7c and/or C16 : 1  ω6c) and iso-C15 : 0. Strain SSH13T contained phosphatidylethanolamine as a major polar lipid. Menaquinone-7 was the predominant respiratory quinone. The average nucleotide identity values between strain SSH13T and L. persica T-3T and L. agarilytica SST-19T were 72.9 and 72.6 %, respectively. The DNA G+C content of the genomic DNA was 52.8 mol%. The present study aimed to determine the multiple-antibiotic resistance of the novel bacterium. Based on phylogenetic and phenotypic analyses, strain SSH13T is considered to represent a novel species of the genus Lewinella , for which the name Lewinella aurantiaca sp. nov. (type strain SSH13T=KACC 21167T=NBRC 113866T) is proposed.

On neotypes and nomina nova: commentary on "Comparative analysis of Faecalibacterium prausnitzii genomes shows a high level of genome plasticity and warrants separation into new species-level taxa", by C.B. Fitzgerald et al. (BMC Genomics (2018) 19:931)

In their paper entitled “Comparative analysis of Faecalibacterium prausnitzii genomes shows a high level of genome plasticity and warrants separation into new species-level taxa” (BMC Genomics (2018) 19:931), Fitzgerald et al. proposed a neotype strain for F. prausnitzii (strain A2–165 = DSM 17677 = JCM 31915) and assigned strain ATCC 27768 = NCIMB 13872 to a newly established taxon, Faecalibacterium moorei nom. Nov. These proposals contravene the Rules of the International Code of Nomenclature of Prokaryotes (ICNP). Neotype strains can only be established following a formal proposal in the International Journal of Systematic and Evolutionary Microbiology in accordance with Rule 18c and Appendix 7 of the ICNP. A proposed neotype becomes an established neotype after 2 years, provided that no objections were submitted to the Judicial Commisson of the International Committee on Systematics of Prokaryotes within the first year following publication of the request. F. moorei as proposed by Fitzgerald et al. is a later homotypic synonym of F. prausnitzii. It cannot be a ‘nom. nov.’ (nomen novum): based on Rule 34a of the ICNP: this term is only used when an author transfers a species to another genus or a subspecies to another species as a new combination, but the original specific epithet cannot be used as ‘comb. nov.’ (combinatio nova) as a result of homonymy. Moreover, ATCC 27768 and NCIMB 13872 cannot be proposed as the type strain of F. moorei as these remain permanently associated with the type strain of F. prausnitzii unless the Judicial Commission of the ICSP will decide otherwise.

Proposal for Unification of the Genus Metakosakonia and the Genus Phytobacter to a Single Genus Phytobacter and Reclassification of Metakosakonia massiliensis as Phytobacter massiliensis comb. nov

The genus Metakosakonia, as the closest phylogenetic neighbor of the genus Kosakonia within the family Enterobacteriaceae, when proposed in 2017, consisted of M. massiliensis JC163^T and Metakosakonia spp. strains CAV1151 and GT-16. The strain CAV1151 was later classified into a novel species Phytobacter ursingii. Here, we show that the strain GT-16 shares a digital DNA-DNA hybridization (DDH) similarity of 91.0% with P. diazotrophicus DSM 17806 ^T and thus also belongs to P. diazotrophicus. M. massiliensis and the strains within the genus Phytobacter formed a monophyletic cluster on a phylogenomic tree based on the core proteins of the family Enterobacteriaceae and on a phylogenetic tree based on the 16S rRNA genes. M. massiliensis and the genus Phytobacter share average amino acid identities of 86.80‒87.41% above the threshold (86%) for genus delimitation within the family Enterobacteriaceae. Moreover, they share conserved signature indels in the intracellular growth protein IgaA and the outer membrane assembly protein AsmA. Therefore, we propose to unite the genus Metakosakonia and the genus Phytobacter to a single genus. Because the genus Phytobacter was validly published earlier in 2017 than the genus Metakosakonia in 2017, the genus name Phytobacter has priority over Metakosakonia. We propose to unite the two genera under the name Phytobacter with the type species P. diazotrophicus and reclassify M. massiliensis as P. massiliensis comb. nov. In addition, the analyses of genome relatedness and phylogenomic relationship identified one potential novel species within the genus Phytobacter and three potential novel species within the genus Kosakonia.

An Update on Mycobacterial Taxonomy, 2016-2017

This minireview provides an update on recent taxonomic changes for the genus Mycobacterium with an emphasis on newly identified species isolated from humans or associated with human disease.

Genome sequence of Acuticoccus yangtzensis JL1095T (DSM 28604T) isolated from the Yangtze Estuary

Acuticoccus yangtzensis JL1095^T is a proteobacterium from a genus belonging to the family Rhodobacteraceae; it was isolated from surface waters of the Yangtze Estuary, China. This strain displays the capability to utilize aromatic and simple carbon compounds. Here, we present the genome sequence, annotations, and features of A. yangtzensis JL1095^T. This strain has a genome size of 5,043,263 bp with a G + C content of 68.63%. The genome contains 4286 protein-coding genes, 56 RNA genes, and 83 pseudo genes. Many of the protein-coding genes were predicted to encode proteins involved in carbon metabolism pathways, such as aromatic degradation and methane metabolism. Notably, a total of 31 genes were predicted to encode form II carbon monoxide dehydrogenases, suggesting potential for carbon monoxide oxidation. The genome analysis helps better understand the major carbon metabolic pathways of this strain and its role in carbon cycling in coastal marine ecosystems.