Eight new genomes of organohalide-respiring Dehalococcoides mccartyi reveal evolutionary trends in reductive dehalogenase enzymes

Abstract

ABSTRACTBackgroundBioaugmentation is now a well-established approach for attenuating toxic groundwater and soil contaminants, particularly for chlorinated ethenes and ethanes. The KB-1 and WBC-2 consortia are cultures used for this purpose. These consortia contain organisms belonging to the Dehalococcoidia, including strains of Dehalococcoides mccartyi in KB-1 and of both D. mccartyi and Dehalogenimonas in WBC-2. These tiny anaerobic bacteria couple respiratory reductive dechlorination to growth and harbour multiple reductive dehalogenase genes (rdhA) in their genomes, the majority of which have yet to be characterized.ResultsUsing a combination of Illumina mate-pair and paired-end sequencing we closed the genomes of eight new strains of Dehalococcoides mccartyi found in three related KB-1 sub-cultures that were enriched on trichloroethene (TCE), 1,2-dichloroethane (1,2-DCA) and vinyl chloride (VC), bringing the total number of genomes available in NCBI to 24. A pangenome analysis was conducted on 24 Dehalococcoides genomes and five Dehalogenimonas genomes (2 in draft) currently available in NCBI. This Dehalococcoidia pangenome generated 2875 protein families comprising of 623 core, 2203 accessory, and 49 unique protein families. In Dehalococcoides mccartyi the complement of reductive dehalogenase genes varies by strain, but what was most surprising was how the majority of rdhA sequences actually exhibit a remarkable degree of synteny across all D. mccartyi genomes. Several homologous sequences are also shared with Dehalogenimonas genomes. Nucleotide and predicted protein sequences for all reductive dehalogenases were aligned to begin to decode the evolutionary history of reductive dehalogenases in the Dehalococcoidia.ConclusionsThe conserved synteny of the rdhA genes observed across Dehalococcoides genomes indicates that the major differences between strain rdhA gene complement has resulted from gene loss rather than recombination. These rdhA have a long evolutionary history and trace their origin in the Dehalococcoidia prior to the speciation of Dehalococcoides and Dehalogenimonas. The only rdhA genes suspected to have been acquired by lateral gene transfer are protein-coding rdhA that have been identified to catalyze dehalogenation of industrial pollutants. Sequence analysis suggests that evolutionary pressures resulting in new rdhA genes involve adaptation of existing dehalogenases to new substrates, mobilization of rdhA between genomes or within a genome, and to a lesser degree manipulation of regulatory regions to alter expression.