将重新分类为的基因组变种：基于基因组的指标改进细菌分类学分类。（原文中存在信息缺失，推测可能是两个未明确的细菌名称，这里按照格式直接翻译）

Reclassification of as a Genomovar of : Genome-Based Metrics Improve Bacterial Taxonomic Classification.

作者信息

Sant'Anna Fernando H, Ambrosini Adriana, de Souza Rocheli, de Carvalho Fernandes Gabriela, Bach Evelise, Balsanelli Eduardo, Baura Valter, Brito Luciana F, Wendisch Volker F, de Oliveira Pedrosa Fábio, de Souza Emanuel M, Passaglia Luciane M P

机构信息

Departamento de Genética, Instituto de Biociências, Universidade Federal do Rio Grande do Sul, Porto Alegre, Brazil.

Departamento de Bioquímica e Biologia Molecular, Centro Politécnico, Universidade Federal do Paraná, Curitiba, Brazil.

出版信息

Front Microbiol. 2017 Oct 4;8:1849. doi: 10.3389/fmicb.2017.01849. eCollection 2017.

DOI:10.3389/fmicb.2017.01849

PMID:29046663

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5632714/

Abstract

Species from the genus are widely studied due to their biotechnological relevance. Dozens of novel species descriptions of this genus were published in the last couple of years, but few utilized genomic data as classification criteria. Here, we demonstrate the importance of using genome-based metrics and phylogenetic analyses to identify and classify strains. For this purpose, SBR5, X19-5, and their close relatives were compared through phenotypic, genotypic, and genomic approaches. With respect to X19-5, SBR5, sp. CAR114, and sp. CAS34 presented ANI (average nucleotide identity) values ranging from 95.61 to 96.32%, gANI (whole-genome average nucleotide identity) values ranging from 96.78 to 97.31%, and dDDH (digital DNA-DNA hybridization) values ranging from 68.2 to 73.2%. Phylogenetic analyses of 16S rRNA, , and genes and concatenated proteins supported the monophyletic origin of these strains. Therefore, we propose to assign sp. CAR114 and sp. CAS34 to species, and reclassify SBR5 as a later heterotypic synonym of (type strain X19-5), with the creation of three novel genomovars, genomovar Sonchi (type strain X19-5), genomovar Riograndensis (type strain SBR5), genomovar Oryzarum (type strain CAS34 = DSM 102041; = BR10511).

摘要

由于其生物技术相关性，该属的物种受到广泛研究。在过去几年中发表了几十种关于该属的新物种描述，但很少有人将基因组数据用作分类标准。在这里，我们证明了使用基于基因组的指标和系统发育分析来鉴定和分类该菌株的重要性。为此，通过表型、基因型和基因组方法对SBR5、X19-5及其近缘种进行了比较。关于X19-5、SBR5、CAR114种和CAS34种，平均核苷酸同一性（ANI）值在95.61%至96.32%之间，全基因组平均核苷酸同一性（gANI）值在96.78%至97.31%之间，数字DNA-DNA杂交（dDDH）值在68.2%至73.2%之间。对16S rRNA、基因和串联蛋白的系统发育分析支持了这些菌株的单系起源。因此，我们建议将CAR114种和CAS34种归入该物种，并将SBR5重新分类为该物种（模式菌株X19-5）的晚出异名，同时创建三个新的基因组变种，即Sonchi基因组变种（模式菌株X19-5）、Riograndensis基因组变种（模式菌株SBR5）、Oryzarum基因组变种（模式菌株CAS34 = DSM 102041；= BR10511）。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8e35/5632714/7108ea011270/fmicb-08-01849-g001.jpg

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将 重新分类为 的基因组变种：基于基因组的指标改进细菌分类学分类。 （原文中存在信息缺失，推测可能是两个未明确的细菌名称，这里按照格式直接翻译）

Reclassification of as a Genomovar of : Genome-Based Metrics Improve Bacterial Taxonomic Classification.

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将重新分类为的基因组变种：基于基因组的指标改进细菌分类学分类。（原文中存在信息缺失，推测可能是两个未明确的细菌名称，这里按照格式直接翻译）