Comparative Genomic Analysis Reveals Preserved Features in Organohalide-Respiring Sulfurospirillum Strains

Sulfurospirillum species strains are frequently detected in various pristine and contaminated environments and participate in carbon, sulfur, nitrogen, and halogen elements cycling. Recently we obtained the complete genome sequences of two newly isolated Sulfurospirillum strains, ACS(DCE) and ACS(TCE), capable of dechlorinating tetrachloroethene to cis-1,2-dichloroethene and trichloroethene under low-pH conditions, but a detailed analysis of these two genomes in reference to other Sulfurospirillum genomes for an improved understanding of Sulfurospirillum evolution and ecophysiology has not been accomplished. Here, we performed phylogenetic and pangenome analyses with 12 completed Sulfurospirillum genomes, including those of strain ACS(TCE) and strain ACS(DCE), to unravel the evolutionary and metabolic potentials in the genus Sulfurospirillum. Based on 16S rRNA gene and whole-genome phylogenies, strains ACS(TCE), ACS(DCE), and JPD-1 could be clustered into a single species, proposed as Candidatus Sulfurospirillum acididehalogenans. TimeTree analysis suggested that the organohalide-respiring (OHR) Sulfurospirillum might acquire the ability to use chlorinated electron acceptors later than other energy conservation processes. Nevertheless, the ambiguity of the phylogenetic relations among Sulfurospirillum strains complicated the interpretation of acquisition and loss of metabolic traits. Interestingly, all OHR Sulfurospirillum genomes except the ones of Sulfurospirillum multivorans strains harbor a well-aligned and conserved region comprising the genetic components required for the organohalide respiration chain. Pangenome results further revealed that a total of 34,620 gene products, annotated from the 12 Sulfurospirillum genomes, can be classified into 4,118 homolog families and 2,075 singleton families. Various Sulfurospirillum species strains have conserved metabolisms as well as individual enzymes and biosynthesis capabilities. For instance, only the OHR Sulfurospirillum species strains possess the quinone-dependent pyruvate dehydrogenase (PoxB) gene, and only Ca. Sulfurospirillum acididehalogenans strains harbor urea transporter and urease genes. The plasmids found in strain ACS(TCE) and strain ACS(DCE) feature genes coding for type II toxin-antitoxin systems and transposases and are promising tools for the development of robust gene editing tools for Sulfurospirillum. IMPORTANCE Organohalide-respiring bacteria (OHRB) play critical roles in the detoxification of chlorinated pollutants and bioremediation of subsurface environments (e.g., groundwater and sediment) impacted by anthropogenic chlorinated solvents. The majority of known OHRB cannot perform reductive dechlorination below neutral pH, hampering the applications of OHRB for remediating acidified groundwater due to fermentation and reductive dechlorination. Previously we isolated two Sulfurospirillum strains, ACS(TCE) and ACS(DCE), capable of dechlorinating tetrachloroethene under acidic conditions (e.g., pH 5.5), and obtained the complete genomes of both strains. Notably, two plasmid sequences were identified in the genomes of strain ACS(TCE) and strain ACS(DCE) that may be conducive to unraveling the genetic modification mechanisms in the genus Sulfurospirillum. Our findings improve the current understanding of Sulfurospirillum species strains regarding their biogeographic evolution, genome dynamics, and functional diversity. This study has applied values for the bioremediation of toxic and persistent organohalide pollutants in low-pH environments.

Automated summary

This study conducted phylogenetic and pangenome analyses of Sulfurospirillum genomes to understand their evolutionary and metabolic potentials. The results revealed conserved regions in the genomes of organohalide-respiring Sulfurospirillum strains that are involved in the organohalide respiration process. Additionally, various Sulfurospirillum species strains were found to have conserved metabolisms and biosynthesis capabilities. This study contributes to the understanding and potential applications of Sulfurospirillum in bioremediation of organohalide pollutants in low-pH environments.