Tom G Schwan, Sandra J Raffel, Stacy M Ricklefs, Daniel P Bruno, Craig Martens
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To better assess the taxonomic relationship of these two genomic groups to each other and other species of <i>Borrelia</i>, DNA sequences of the entire linear chromosome were determined. <b><i>Materials and Methods:</i></b> Genomic DNA samples were prepared from 11 spirochete isolates grown in Barbour-Stoenner-Kelly-H medium. From these preparations, DNA sequences of the entire linear chromosome of two isolates of <i>B. hermsii</i> belonging to each genomic group and seven additional species were determined. <b><i>Results:</i></b> Chromosomal sequences of four isolates of <i>B. hermsii</i> contained 919,212 to 922,307 base pairs. DNA sequence identities between the two genomic groups of <i>B. hermsii</i> were 95.86-95.99%, which were more divergent than chromosomal sequences comparing <i>Borrelia parkeri</i> and <i>Borrelia turicatae</i> (97.13%), <i>Borrelia recurrentis</i> and <i>Borrelia duttonii</i> (97.07%), and <i>Borrelia crocidurae</i> and <i>B. duttonii</i> (97.09%). The 3' end of the chromosome of the two GGII isolates also contained a unique intact <i>oppA</i> gene absent from all other species examined. <b><i>Conclusion:</i></b> Previous MLST and the chromosomal sequences presented herein support the division of the <i>B. hermsii</i> species complex into two species, <i>B. hermsii</i> sensu stricto ( = GGI) and <i>Borrelia nietonii</i> sp. nov. ( = GGII). We name this unique relapsing fever spirochete in honor of our late friend and colleague Dr. Nathan Nieto for his outstanding contributions to our understanding of tick-borne relapsing fever.</p>","PeriodicalId":23683,"journal":{"name":"Vector borne and zoonotic diseases","volume":" ","pages":"278-284"},"PeriodicalIF":1.8000,"publicationDate":"2024-05-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11238836/pdf/","citationCount":"0","resultStr":"{\"title\":\"<i>Borrelia nietonii</i> sp. nov.: Relapsing Fever Spirochetes Transmitted By the Tick <i>Ornithodoros hermsi</i> Designated Previously as <i>Borrelia hermsii</i> Genomic Group II.\",\"authors\":\"Tom G Schwan, Sandra J Raffel, Stacy M Ricklefs, Daniel P Bruno, Craig Martens\",\"doi\":\"10.1089/vbz.2023.0090\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p><b><i>Background:</i></b> The taxonomic status of the relapsing fever spirochete <i>Borrelia hermsii</i> in western North America was established in 1942 and based solely on its specific association with the soft tick vector <i>Ornithodoros hermsi</i>. Multilocus sequence typing (MLST) of the <i>16S rRNA</i>, <i>flaB</i>, <i>gyrB</i>, <i>glpQ</i>, and <i>16S-23S rRNA</i> intergenic spacer of <i>B. hermsii</i> isolates collected over many years from various geographic locations and biological sources identified two distinct clades designated previously as <i>B. hermsii</i> Genomic Group I (GGI) and Genomic Group II (GGII). To better assess the taxonomic relationship of these two genomic groups to each other and other species of <i>Borrelia</i>, DNA sequences of the entire linear chromosome were determined. <b><i>Materials and Methods:</i></b> Genomic DNA samples were prepared from 11 spirochete isolates grown in Barbour-Stoenner-Kelly-H medium. From these preparations, DNA sequences of the entire linear chromosome of two isolates of <i>B. hermsii</i> belonging to each genomic group and seven additional species were determined. <b><i>Results:</i></b> Chromosomal sequences of four isolates of <i>B. hermsii</i> contained 919,212 to 922,307 base pairs. DNA sequence identities between the two genomic groups of <i>B. hermsii</i> were 95.86-95.99%, which were more divergent than chromosomal sequences comparing <i>Borrelia parkeri</i> and <i>Borrelia turicatae</i> (97.13%), <i>Borrelia recurrentis</i> and <i>Borrelia duttonii</i> (97.07%), and <i>Borrelia crocidurae</i> and <i>B. duttonii</i> (97.09%). The 3' end of the chromosome of the two GGII isolates also contained a unique intact <i>oppA</i> gene absent from all other species examined. <b><i>Conclusion:</i></b> Previous MLST and the chromosomal sequences presented herein support the division of the <i>B. hermsii</i> species complex into two species, <i>B. hermsii</i> sensu stricto ( = GGI) and <i>Borrelia nietonii</i> sp. nov. ( = GGII). 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引用次数: 0
摘要
背景:北美西部复发性热螺旋体 Borrelia hermsii 的分类地位于 1942 年确立,其唯一依据是它与软蜱载体 Ornithodoros hermsi 的特殊关联。对多年来从不同地理位置和生物来源收集到的 B. hermsii 分离物的 16S rRNA、laB、gyrB、glpQ 和 16S-23S rRNA 基因间距进行多焦点序列分型(MLST),发现了两个不同的支系,即先前命名的 B. hermsii 基因组 I 群(GGI)和基因组 II 群(GGII)。为了更好地评估这两个基因组相互之间以及与其他包柔氏菌种之间的分类关系,我们测定了整个线性染色体的 DNA 序列。材料与方法:从在 Barbour-Stoenner-Kelly-H 培养基中生长的 11 个螺旋体分离物中制备基因组 DNA 样本。从这些制备的样本中,测定了属于每个基因组群的两个 B. hermsii 分离物和另外七个物种的整个线性染色体的 DNA 序列。结果4 个分离株的染色体序列包含 919 212 至 922 307 个碱基对。hermsii 的两个基因组之间的 DNA 序列相同度为 95.86%-95.99%,比 Parkeri Borrelia 和 turicatae Borrelia(97.13%)、Recurrentis Borrelia 和 duttonii Borrelia(97.07%)以及 crocidurae Borrelia 和 duttonii Borrelia(97.09%)之间的染色体序列差异更大。两个 GGII 分离物的染色体 3' 端还含有一个独特的完整 oppA 基因,这是所有其他受检物种所没有的。结论hermsii sensu stricto ( = GGI) 和 Borrelia nietonii sp. nov. ( = GGII) 。我们将这种独特的复发性热螺旋体命名为 Bermsii,以纪念我们已故的朋友和同事 Nathan Nieto 博士,感谢他为我们了解蜱传复发性热所做出的杰出贡献。
Borrelia nietonii sp. nov.: Relapsing Fever Spirochetes Transmitted By the Tick Ornithodoros hermsi Designated Previously as Borrelia hermsii Genomic Group II.
Background: The taxonomic status of the relapsing fever spirochete Borrelia hermsii in western North America was established in 1942 and based solely on its specific association with the soft tick vector Ornithodoros hermsi. Multilocus sequence typing (MLST) of the 16S rRNA, flaB, gyrB, glpQ, and 16S-23S rRNA intergenic spacer of B. hermsii isolates collected over many years from various geographic locations and biological sources identified two distinct clades designated previously as B. hermsii Genomic Group I (GGI) and Genomic Group II (GGII). To better assess the taxonomic relationship of these two genomic groups to each other and other species of Borrelia, DNA sequences of the entire linear chromosome were determined. Materials and Methods: Genomic DNA samples were prepared from 11 spirochete isolates grown in Barbour-Stoenner-Kelly-H medium. From these preparations, DNA sequences of the entire linear chromosome of two isolates of B. hermsii belonging to each genomic group and seven additional species were determined. Results: Chromosomal sequences of four isolates of B. hermsii contained 919,212 to 922,307 base pairs. DNA sequence identities between the two genomic groups of B. hermsii were 95.86-95.99%, which were more divergent than chromosomal sequences comparing Borrelia parkeri and Borrelia turicatae (97.13%), Borrelia recurrentis and Borrelia duttonii (97.07%), and Borrelia crocidurae and B. duttonii (97.09%). The 3' end of the chromosome of the two GGII isolates also contained a unique intact oppA gene absent from all other species examined. Conclusion: Previous MLST and the chromosomal sequences presented herein support the division of the B. hermsii species complex into two species, B. hermsii sensu stricto ( = GGI) and Borrelia nietonii sp. nov. ( = GGII). We name this unique relapsing fever spirochete in honor of our late friend and colleague Dr. Nathan Nieto for his outstanding contributions to our understanding of tick-borne relapsing fever.
期刊介绍:
Vector-Borne and Zoonotic Diseases is an authoritative, peer-reviewed journal providing basic and applied research on diseases transmitted to humans by invertebrate vectors or non-human vertebrates. The Journal examines geographic, seasonal, and other risk factors that influence the transmission, diagnosis, management, and prevention of this group of infectious diseases, and identifies global trends that have the potential to result in major epidemics.
Vector-Borne and Zoonotic Diseases coverage includes:
-Ecology
-Entomology
-Epidemiology
-Infectious diseases
-Microbiology
-Parasitology
-Pathology
-Public health
-Tropical medicine
-Wildlife biology
-Bacterial, rickettsial, viral, and parasitic zoonoses