Project description:Dehalococcoides mccartyi strain BTF08 has the unique property to couple complete dechlorination of tetrachloroethene and 1,2-dichloroethane to ethene with growth by using the halogenated compounds as terminal electron acceptor. The genome of strain BTF08 encodes 20 genes for reductive dehalogenase homologous proteins (RdhA) including those described for dehalogenation of tetrachloroethene (PceA, PteA), trichloroethene (TceA) and vinyl chloride (VcrA). Thus far it is unknown under which conditions the different RdhAs are expressed, what their substrate specificity is and if different reaction mechanisms are employed. Here we found by proteomic analysis from differentially activated batches that PteA and VcrA were expressed during dechlorination of tetrachloroethene to ethene, while TceA was expressed during 1,2-dichloroethane dehalogenation. Carbon and chlorine compound-specific stable isotope analysis suggested distinct reaction mechanisms for the dechlorination of (i) cis-dichloroethene and vinyl chloride and (ii) tetrachloroethene. This differentiation was observed independent of the expressed RdhA proteins. Differently, two stable isotope fractionation patterns were observed for 1,2-dichloroethane transformation, for cells with distinct RdhA inventories. Conclusively, we could link specific RdhA expression with functions and provide an insight into the apparently substrate-specific reaction mechanisms in the pathway of reductive dehalogenation in D. mccartyi strain BTF08.

Project description:Polybrominated diphenyl ethers (PBDEs) are persistent, highly toxic, and widely distributed environmental pollutants. The microbial populations and functional reductive dehalogenases (RDases) responsible for PBDEs debromination in anoxic systems remain poorly understood, which confounds bioremediation of PBDE-contaminated sites. Here we report a PBDE-debrominating enrichment culture dominated by a previously undescribed Dehalococcoides mccartyi population. A D. mccartyi strain, designated TZ50, whose genome contains 25 putative RDase encoding genes was isolated from the debrominating enrichment culture. Strain TZ50 dehalogenated a mixture of penta- and tetra-BDE congeners (total BDEs 1.48 uM) to diphenyl ether within two weeks (0.58 uM Br- /d) via ortho- and meta- bromine elimination; strain TZ50 also dechlorinated tetrachloroethene (PCE) to vinyl chloride and ethene (260.2 M Cl- /d). Native-PAGE, proteomic profiling, and in vitro enzymatic activity assays implicated the involvement of three RDases in PBDEs and PCE dehalogenation. Two RDases, TZ50_0172 (PteATZ50) and TZ50_1083 (TceATZ50), were responsible for debromination of penta- and tetra-BDEs to di-BDE. TZ50_0172 and TZ50_1083 were also implicated in dechlorination of PCE to TCE and of TCE to vinyl chloride/ethene, respectively. The other expressed dehalogenase, TZ50_0090, was associated with debromination of di-BDE to diphenyl ether, but its role in PCE dechlorination was unclear. Comparatively few RDases are known to be involved in PBDE debromination and the identification of PteATZ50, TceATZ50, and TZ50_0090 provides additional information for evaluating debromination potential at contaminated sites. Moreover, the bifunctionality of the PteATZ50 and TceATZ50 in both PBDEs and PCE dehalogenation makes strain TZ50 a suitable candidate for remediation of co-contaminated sites.

Project description:Extensive use of polybrominated diphenyl ethers (PBDEs) has resulted in widespread environmental distribution and concerns remain about risks to human health and ecosystems from legacy PBDE contamination. Though bioremediation has been proven to be a cost-effective and efficient technology for treating halogenated pollutants in situ, application of bioremediation technologies at PBDE-contaminated sites is restricted by a lack of knowledge about functional PBDE-dehalogenating microbes. In the current study, we observed distinct PBDE-dehalogenation activity by three previously isolated Dehalococcoides mccartyi strains (CG1, CG4, and 11a5). PBDE debromination proceeded via distinct pathways in each D. mccartyi strain and involved previously characterized (TceA11a5, PcbA1, and PcbA4) and uncharacterized (11a5_e001) reductive dehalogenases (RDase), suggesting that this phenotype may be more widespread among the Dehalococcoides than is currently recognized.

Project description:Transcriptional profiling of the Donna II mixed community containing Dehalococcoides mccartyi strain 195 comparing a batch starved control to the mixed community being fed 1,2,3,4-tetrachlorobenzene as an electron acceptor. The goal was to determine which transcripts are regulated in response to a shift in a different electron acceptor rather than the consistent tetrachloroethene (PCE) that the parent reactor was maintained on.

Project description:The proteome of the anaerobic bacterium Dehalococcoides mccartyi strain CBDB1 from the phylum Chloroflexi was investigated. D. mccartyi strain CBDB1 is a model organism for organohalide respiration where halogenated organic compounds serve as terminal electron acceptors. A wide range of halogenated organic compounds have been shown to be dehalogenated by the strain CBDB1. Therefore, D. mccartyi strain CBDB1 is a promising candidate for bioremediation application. Proteomic analysis of cultures grown with hexachlorobenzene as only electron acceptor resulted in identification of 8,491 distinct peptides which represents 1,023 proteins. A coverage of 70% of the 1,458 annotated proteins for strain CBDB1 was achieved. In addition, a spectral library was created from the annotated spectra. By using proteogenomics, 18 previously not annotated peptides were identified which contribute to four proteins previously not annotated and corrections in length of eight protein coding sequences.

Project description:The strictly anaerobic bacterium Dehalococcoides mccartyi is obligatory dependent on organohalide respiration for energy conservation and growth. Due to its capability to reductively dehalogenate a multitude of toxic halogenated electron acceptors, it plays an important role in the attenuation of these compounds at respective contaminated sites. Here, D. mccartyi strain CBDB1, specialized on the dehalogenation of chloroaromatic compounds, was grown in a two-liquid phase system with 1,2,3-trichlorobenzene as electron acceptor, acetate plus CO2 as carbon source and hydrogen as electron donor. The proteome and Nε-lysine acetylome were analyzed in the lag, exponential and stationary phases. The high and almost invariable abundance of the membrane-localized organohalide respiration complex consisting of the reductive dehalogenases CbrA and CbdbA80, the uptake hydrogenase HupLS and the organohalide respiration molybdoenzyme OmeAB was shown throughout growth and also after a prolonged stationary phase. Quantification of transcripts of reductive dehalogenase genes revealed their major synthesis starting in the lag phase, which might be a prerequisite for balanced growth in the exponential phase. The analyses of the coverage of functional pathways as well as indicator analysis revealed the growth-phase specificity of the proteome, with regulatory proteins identified as important indicators for the stationary phase. The number of acetylated proteins increased from the lag to the stationary phase. We detected pronounced acetylation of key proteins of the acetate metabolism, i.e. the synthesis of acetyl-CoA and its processing via gluconeogenesis and the incomplete Wood-Ljungdahl pathway, as well as of proteins central for the biosynthesis of amino acids, co-factors and terpenoids. In addition, the partial acetylation of the reductive dehalogenases as well as of TatA, a component of the twin-arginine translocation machinery, suggests that acetylation might be directly involved in the maintenance of the organohalide respiration capacity of D. mccartyi over periods without access to halogenated electron acceptors.

Project description:Organohalide-respiring Dehalococcoidia bacteria are one of the few microorganisms capable of transforming chlorinated solvents to benign ethene in anoxic environments. The tceA gene found in these bacteria, coding the trichloroethene-dechlorinating RDase TceA, is frequently detected in contaminated groundwater but not recognized as a biomarker for vinyl chloride detoxification. Here, we demonstrate that the tceA-carrying Dehalococcoides mccartyi (Dhc) strains FL2 and 195 grow with VC as electron acceptor when sufficient vitamin B12 is provided. Global proteomic profiling confirmed the predominant TceA expression in VC-grown Dhc FL2 cells, providing a line of evidence for the implication of TceA in respiratory VC reductive dechlorination.

Project description:Dehalococcoides mccartyi are functionally important bacteria that catalyze the reductive dechlorination of chlorinated ethenes. However, these anaerobic bacteria are fastidious to isolate, making downstream genomic characterization challenging. In order to facilitate genomic analysis, a fluorescence-activated cell sorting (FACS) method was developed in this study to separate D. mccartyi cells from a microbial community, and the DNA of the isolated cells was processed by whole genome amplification (WGA) and hybridized onto a D. mccartyi microarray for comparative genomics against four sequenced strains. First, FACS was successfully applied to a D. mccartyi isolate as positive control, and then microarray results verified that WGA from 106 cells or M-bM-^HM-<1 ng of genomic DNA yielded high-quality coverage detecting nearly all genes across the genome. As expected, some inter- and intrasample variability in WGA was observed, but these biases were minimized by performing multiple parallel amplifications. Subsequent application of the FACS and WGA protocols to two enrichment cultures containing M-bM-^HM-<10% and M-bM-^HM-<1% D. mccartyi cells successfully enabled genomic analysis. As proof of concept, this study demonstrates that coupling FACS with WGA and microarrays is a promising tool to expedite genomic characterization of target strains in environmental communities where the relative concentrations are low. The genomic DNA (gDNA) of each culture or sorted and amplifed DNA was analyzed in triplicate.

Project description:Dechlorinates tetrachloroethene

Project description:Dehalococcoides mccartyi are functionally important bacteria that catalyze the reductive dechlorination of chlorinated ethenes. However, these anaerobic bacteria are fastidious to isolate, making downstream genomic characterization challenging. In order to facilitate genomic analysis, a fluorescence-activated cell sorting (FACS) method was developed in this study to separate D. mccartyi cells from a microbial community, and the DNA of the isolated cells was processed by whole genome amplification (WGA) and hybridized onto a D. mccartyi microarray for comparative genomics against four sequenced strains. First, FACS was successfully applied to a D. mccartyi isolate as positive control, and then microarray results verified that WGA from 10(6) cells or ~1 ng of genomic DNA yielded high-quality coverage detecting nearly all genes across the genome. As expected, some inter- and intrasample variability in WGA was observed, but these biases were minimized by performing multiple parallel amplifications. Subsequent application of the FACS and WGA protocols to two enrichment cultures containing ~10% and ~1% D. mccartyi cells successfully enabled genomic analysis. As proof of concept, this study demonstrates that coupling FACS with WGA and microarrays is a promising tool to expedite genomic characterization of target strains in environmental communities where the relative concentrations are low.