Dehalococcoides strains reductively dechlorinate a wide variety of halogenated compounds including chlorinated benzenes, biphenyls, naphthalenes, dioxins, and ethenes. Recent genome sequencing of the two Dehalococcoides strains CBDB1 and 195 revealed the presence of 32 and 18 reductive dehalogenase homologous genes, respectively, and therefore suggested an even higher dechlorinating potential than previously anticipated. Here, we demonstrate reductive dehalogenation of chlorophenol congeners by Dehalococcoides strains CBDB1 and 195. Strain CBDB1 completely converted 2,3-dichlorophenol, all six trichlorophenols, all three tetrachlorophenols, and pentachlorophenol to lower chlorinated phenols. Observed dechlorination rates in batch cultures with cell numbers of 10(7) mL(-1) amounted up to 35 microM day(-1). Chlorophenols were preferentially dechlorinated in the ortho position, but also doubly flanked and singly flanked meta- or para-chlorine substituents were removed. We used a newly designed computer-assisted direct cell counting protocol and quantitative PCR to demonstrate that strain CBDB1 uses chlorophenols as electron acceptors for respiratory growth. The growth yield of strain CBDB1 with 2,3-dichlorophenol was 7.6 x 10(13) cells per mol of Cl- released, and the growth rate was 0.41 day(-1). For strain 195, fast ortho dechlorination of 2,3-dichlorophenol, 2,3,4-trichlorophenol, and 2,3,6-trichlorophenol was detected, with only the ortho chlorine removed. Because chlorinated phenolic compounds are widely distributed as natural components in anaerobic environments, our results reveal one mode in which the Dehalococcoides species could have survived through earth history.
Bacteria play many important roles in animal digestive systems, including the provision of enzymes critical to digestion. Typically, complex communities of bacteria reside in the gut lumen in direct contact with the ingested materials they help to digest. Here, we demonstrate a previously undescribed digestive strategy in the wood-eating marine bivalve Bankia setacea, wherein digestive bacteria are housed in a location remote from the gut. These bivalves, commonly known as shipworms, lack a resident microbiota in the gut compartment where wood is digested but harbor endosymbiotic bacteria within specialized cells in their gills. We show that this comparatively simple bacterial community produces wood-degrading enzymes that are selectively translocated from gill to gut. These enzymes, which include just a small subset of the predicted wood-degrading enzymes encoded in the endosymbiont genomes, accumulate in the gut to the near exclusion of other endosymbiont-made proteins. This strategy of remote enzyme production provides the shipworm with a mechanism to capture liberated sugars from wood without competition from an endogenous gut microbiota. Because only those proteins required for wood digestion are translocated to the gut, this newly described system reveals which of many possible enzymes and enzyme combinations are minimally required for wood degradation. Thus, although it has historically had negative impacts on human welfare, the shipworm digestive process now has the potential to have a positive impact on industries that convert wood and other plant biomass to renewable fuels, fine chemicals, food, feeds, textiles, and paper products.Teredinidae | endosymbionts | symbiosis | xylotrophy | carbohydrate-active enzymes
Anaerobic reductive dehalogenation by Dehalococcoides spp. is an ideal system for studying functional diversity of closely related strains of bacteria. In Dehalococcoides spp., reductive dehalogenases (RDases) are key respiratory enzymes involved in the anaerobic detoxification of halogenated compounds at contaminated sites globally. Although housekeeping genes sequenced from Dehalococcoides spp. are >85% identical at the amino acid level, different strains are capable of dehalogenating diverse ranges of compounds, depending largely on the suite of RDase genes that each strain harbors and expresses. We identified RDase proteins that corresponded to known functions in four characterized cultures and predicted functions in an uncharacterized Dehalococcoides-containing mixed culture. Homologues within RDase subclusters containing PceA, TceA, and VcrA were among the most frequently identified proteins. Several additional proteins, including a formate dehydrogenase-like protein (Fdh), had high coverage in all strains and under all growth conditions.Comparative genomic studies have revealed that many of the phenotypic differences observed among closely related microbial species in nature are due to genetic islands of diversity that are frequently copied, rearranged, and laterally transferred. Pathogenicity islands, which are mobile genetic elements that confer virulence, are well known in host-associated microorganisms (8). A recent comparative genomic study of the marine photoautotroph Prochlorococcus suggests that natural populations of microorganisms may also contain genetic islands that confer unique phenotypic traits on closely related strains (3). A comparative genomic study of representatives from the Dehalococcoides lineage within the Chloroflexi phylum of bacteria, a group which reductively dehalogenates chlorinated organic pollutants (25), suggests that reductive dehalogenases (RDases) are key enzymes conferring functional differences on closely related strains of Dehalococcoides (14).Sequenced Dehalococcoides genomes (strains 195, CBDB1, and BAV1 [unfinished]) share a high degree of genomic similarity and synteny in nearly all "housekeeping" genes. There are, however, differences in the total numbers and types of RDases that these strains harbor and in their corresponding substrate ranges (1, 2, 14, 17). In Dehalococcoides ethenogenes (strain 195), RDases are responsible for reductive dechlorination of chlorinated organic compounds, such as the common groundwater contaminants and suspected human carcinogens tetrachloroethene (PCE) and trichloroethene (TCE). In strains 195 and CBDB1, the majority of putative RDase genes are in clusters located near the predicted origin of replication, and while the locations of the clusters are similar, the RDase gene contents are different. The complete genome sequence of strain 195 revealed 19 potential RDase genes, 4 of which were contained within putative integrated mobile genetic elements that may have been acquired recently or are marked for dissemination (23). Thirty...
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