Your search keyword '"Dehalobacter"' showing total 9 results

1. Investigations on a chloroform reductive dehalogenase

Author

Marquis, Christopher, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW, Lee, Matthew, Civil & Environmental Engineering, Faculty of Engineering, UNSW, Jugder, Bat-Erdene, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW, Marquis, Christopher, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW, Lee, Matthew, Civil & Environmental Engineering, Faculty of Engineering, UNSW, and Jugder, Bat-Erdene, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

Abstract

Halogenated organic compounds (organohalides) are globally prevalent, recalcitrant toxic and carcinogenic environmental pollutants contaminating soil and groundwater. Organohalide respiring bacteria provide a potential solution to remediate contaminated sites, as they are capable of utilising organohalides as electron acceptors for the generation of cellular energy. At the heart of these processes are reductive dehalogenases (RDase; EC 1.97.1.8), which are membrane bound enzymes that catalyse reductive dehalogenation reactions resulting in the generation of lesser-halogenated compounds that may be less toxic and more biodegradable.Chloroform (CF), primarily used in the production of refrigerants, is very prevalent and recalcitrant organohalide contamination and its improper disposal also caused groundwater pollution at industrial sites in Sydney, Australia. Its hazardous effect on environment and carcinogenic and organo-toxic effects on human health prompts bioremediation research towards its detoxification. Recently, Dehalobacter (Dhb) sp. strain UNSWDHB, which is capable of respiring CF and converting it to dichloromethane has been identified. The UNSWDHB strain was revealed to produce CF-RDase, as termed TmrA, which has been the focus of the research carried out in this thesis.Firstly, the response of Dhb sp. UNSWDHB to the addition of CF was evaluated from a transcriptomic and proteomic perspective. The elevated expressions of TmrABC proteins, key bioenergetics related membrane-associated and cytoplasmic proteins, enzymes associated with functional Wood-Ljungdahl pathway and complete corrinoid de novo synthesis were revealed, providing a broader view on the bioenergetics and general physiology of the Dehalobacter cells actively respiring with CF. Furthermore, TmrA was produced and purified from the membrane fraction of the UNSWDHB cells to apparent homogeneity, using detergent-based membrane solubilisation and anion exchange chromatographic purification. This al

Published

2017

2. Dechlorination of three tetrachlorobenzene isomers by contaminated harbor sludge-derived enrichment cultures follows thermodynamically favorable reactions

Author

Lu, Yue, Ramiro-Garcia, Javier, Vandermeeren, Pieter, Herrmann, Steffi, Cichocka, Danuta, Springael, Dirk, Atashgahi, Siavash, Smidt, Hauke, Lu, Yue, Ramiro-Garcia, Javier, Vandermeeren, Pieter, Herrmann, Steffi, Cichocka, Danuta, Springael, Dirk, Atashgahi, Siavash, and Smidt, Hauke

Abstract

Dechlorination patterns of three tetrachlorobenzene isomers, 1,2,3,4-, 1,2,3,5-, and 1,2,4,5-TeCB, were studied in anoxic microcosms derived from contaminated harbor sludge. The removal of doubly, singly, and un-flanked chlorine atoms was noted in 1,2,3,4- and 1,2,3,5-TeCB fed microcosms, whereas only singly flanked chlorine was removed in 1,2,4,5-TeCB microcosms. The thermodynamically more favorable reactions were selectively followed by the enriched cultures with di- and/or mono-chlorobenzene as the main end products of the reductive dechlorination of all three isomers. Based on quantitative PCR analysis targeting 16S rRNA genes of known organohalide-respiring bacteria, the growth of Dehalococcoides was found to be associated with the reductive dechlorination of all three isomers, while growth of Dehalobacter, another known TeCB dechlorinator, was only observed in one 1,2,3,5-TeCB enriched microcosm among biological triplicates. Numbers of Desulfitobacterium and Geobacter as facultative dechlorinators were rather stable suggesting that they were not (directly) involved in the observed TeCB dechlorination. Bacterial community profiling suggested bacteria belonging to the phylum Bacteroidetes and the order Clostridiales as well as sulfate-reducing members of the class Deltaproteobacteria as putative stimulating guilds that provide electron donor and/or organic cofactors to fastidious dechlorinators. Our results provide a better understanding of thermodynamically preferred TeCB dechlorinating pathways in harbor environments and microbial guilds enriched and active in anoxic TeCB dechlorinating microcosms.

Published

2017

3. Functional genomics of corrinoid starvation in the organohalide-respiring bacterium Dehalobacter restrictus strain PER-K23

Author

Rupakula, A., Lu, Y., Kruse, T., Boeren, S., Holliger, C., Smidt, H., Maillard, J., Rupakula, A., Lu, Y., Kruse, T., Boeren, S., Holliger, C., Smidt, H., and Maillard, J.

Abstract

De novo corrinoid biosynthesis represents one of the most complicated metabolic pathways in nature. Organohalide-respiring bacteria (OHRB) have developed different strategies to deal with their need of corrinoid, as it is an essential cofactor of reductive dehalogenases, the key enzymes in OHR metabolism. In contrast to Dehalococcoides mccartyi, the genome of Dehalobacter restrictus strain PER-K23 contains a complete set of corrinoid biosynthetic genes, of which cbiH appears to be truncated and therefore non-functional, possibly explaining the corrinoid auxotrophy of this obligate OHRB. Comparative genomics within Dehalobacter spp. revealed that one (operon-2) of the five distinct corrinoid biosynthesis associated operons present in the genome of D. restrictus appeared to be present only in that particular strain, which encodes multiple members of corrinoid transporters and salvaging enzymes. Operon-2 was highly up-regulated upon corrinoid starvation both at the transcriptional (346-fold) and proteomic level (46-fold on average), in line with the presence of an upstream cobalamin riboswitch. Together, these data highlight the importance of this operon in corrinoid homeostasis in D. restrictus and the augmented salvaging strategy this bacterium adopted to cope with the need for this essential cofactor

Published

2015

4. Ecogenomics of microbial communities in bioremediation of chlorinated contaminated sites

Author

Maphosa, F., Lieten, S., Dinkla, I., Stams, A.J.M., Fennel, D.E., Maphosa, F., Lieten, S., Dinkla, I., Stams, A.J.M., and Fennel, D.E.

Abstract

Organohalide compounds such as chloroethenes, chloroethanes, and polychlorinated benzenes are among the most significant pollutants in the world. These compounds are often found in contamination plumes with other pollutants such as solvents, pesticides, and petroleum derivatives. Microbial bioremediation of contaminated sites, has become commonplace whereby key processes involved in bioremediation include anaerobic degradation and transformation of these organohalides by organohalide respiring bacteria and also via hydrolytic, oxygenic, and reductive mechanisms by aerobic bacteria. Microbial ecogenomics has enabled us to not only study the microbiology involved in these complex processes but also develop tools to better monitor and assess these sites during bioremediation. Microbial ecogenomics have capitalized on recent advances in high-throughput and -output genomics technologies in combination with microbial physiology studies to address these complex bioremediation problems at a system level. Advances in environmental metagenomics, transcriptomics, and proteomics have provided insights into key genes and their regulation in the environment. They have also given us clues into microbial community structures, dynamics, and functions at contaminated sites. These techniques have not only aided us in understanding the lifestyles of common organohalide respirers, for example Dehalococcoides, Dehalobacter, and Desulfitobacterium, but also provided insights into novel and yet uncultured microorganisms found in organohalide respiring consortia. In this paper, we look at how ecogenomic studies have aided us to understand the microbial structures and functions in response to environmental stimuli such as the presence of chlorinated pollutants

Published

2012

5. Metagenome analysis reveals yet unexplored reductive dechlorinating potential of Dehalobacter sp. E1 growing in coculture with Sedimentibacter sp.

Author

Maphosa, F., van Passel, M.W.J., de Vos, W.M., Smidt, H., Maphosa, F., van Passel, M.W.J., de Vos, W.M., and Smidt, H.

Abstract

Dehalobacter sp. E1 grows in strict coculture with Sedimentibacter sp. B4. The metagenome of the coculture and genome of strain B4 were sequenced. Filtering of the Dehalobacter genome sequence data from the metagenomic sequence of the coculture was done based on BLAST hits and G+C content. The Sedimentibacter genome sequence was used to query the metagenomic coculture sequence. Contigs of more than 150 bp in length, with at least 2 reads, and having no hit with the Sedimentibacter contigs of more than 90% identity for at least 100 bp were binned as Dehalobacter., Dehalobacter sp. E1 grows in strict coculture with Sedimentibacter sp. B4. The metagenome of the coculture and genome of strain B4 were sequenced. Filtering of the Dehalobacter genome sequence data from the metagenomic sequence of the coculture was done based on BLAST hits and G+C content. The Sedimentibacter genome sequence was used to query the metagenomic coculture sequence. Contigs of more than 150 bp in length, with at least 2 reads, and having no hit with the Sedimentibacter contigs of more than 90% identity for at least 100 bp were binned as Dehalobacter.

Published

2012

6. Natural and enhanced anaerobic degradation of 1,1,1-trichloroethane and its degradation products in the subsurface – A critical review

Author

Scheutz, Charlotte, Durant, Neal D., Hansen, Maria Heisterberg, Bjerg, Poul Løgstrup, Scheutz, Charlotte, Durant, Neal D., Hansen, Maria Heisterberg, and Bjerg, Poul Løgstrup

Abstract

1,1,1-Trichloroethane (TCA) in groundwater is susceptible to a variety of natural degradation mechanisms. Evidence of intrinsic decay of TCA in aquifers is commonly observed; however, TCA remains a persistent pollutant at many sites and some of the daughter products that accumulate from intrinsic decay of TCA have been determined to be more toxic than the parent compound. Research advances from the past decade indicate that in situ enhanced reductive dechlorination (ERD) offers promise as a cost-effective solution toward the cleanup of groundwater contaminated with TCA and its transformation daughter products. Laboratory studies have demonstrated that pure or mixed cultures containing certain Dehalobacter (Dhb) bacteria can catalyze respiratory dechlorination of TCA and 1,1-dichloroethane (1,1-DCA) to monochloroethane (CA) in groundwater systems. 16S rRNA Dhb gene probes have been used as biomarkers in groundwater samples to both assess ERD potential and quantify growth of Dhb in ERD applications at TCA sites. Laboratory findings suggest that iron-bearing minerals and methanogenic bacteria that co-occur in reduced aquifers may synergistically affect dechlorination of TCA. Despite these advances, a number of significant challenges remain, including an inability of any known cultures to completely dechlorinate TCA to ethane. CA is commonly observed as a terminal product of the biological reductive dechlorination of TCA and 1,1-DCA. Also important is the lack of rigorous field studies demonstrating the utility of bioaugmentation with Dhb cultures for remediation of TCA in the field. In this paper we review the state-of-the-science of TCA degradation in aquifers, examining results from both laboratory experiments and twenty-two field case studies, focusing on the capabilities and limits of ERD technology, and identifying aspects of the technology that warrant further development.

Published

2011

7. Assessment of the natural attenuation of chlorinated ethenes in an anaerobic contaminated aquifer in the Bitterfeld/Wolfen area using stable isotope techniques, microcosm studies and molecular biomarkers

Author

Nijenhuis, Ivonne, Nikolausz, Marcell, Köth, A., Felföldi, T., Weiß, Holger, Drangmeister, J., Großmann, J., Kästner, Matthias, Richnow, Hans Hermann, Nijenhuis, Ivonne, Nikolausz, Marcell, Köth, A., Felföldi, T., Weiß, Holger, Drangmeister, J., Großmann, J., Kästner, Matthias, and Richnow, Hans Hermann

Abstract

The in situ degradation of chlorinated ethenes was assessed in an anaerobic aquifer using stable isotope fractionation approaches, microcosm studies and taxon specific detection of specific dehalogenating groups of bacteria. The aquifer in the Bitterfeld/Wolfen region in Germany contained all chlorinated ethenes, benzene and toluene as contaminants. The concentrations and isotope composition of the chlorinated ethenes indicated biodegradation of the contaminants. Microcosm studies confirmed the presence of in situ microbial communities capable of the complete dechlorination of tetrachloroethene. Taxon specific investigation of the microbial communities indicated the presence of various potential dechlorinating organisms including Dehalococcoides, Desulfuromonas, Desulfitobacterium and Dehalobacter. The integrated approach, using metabolite spectra, molecular marker analysis and isotope studies, provided several lines of evidence for natural attenuation of the chlorinated ethenes.

Published

2007

8. Untersuchungen zur mikrobiellen Diversität einer anaeroben, Trichlorbenzol-dechlorierenden Mischkultur

Author

Friedrich, B., Stackebrandt, E., Göbel, Ulf B., Wintzingerode-Knorr, Friedrich Wasmuth Lotar Frhr., Friedrich, B., Stackebrandt, E., Göbel, Ulf B., and Wintzingerode-Knorr, Friedrich Wasmuth Lotar Frhr.

Abstract

Chlorbenzole sind aufgrund ihrer weiten Verbreitung in Industrie und Landwirtschaft und ihrer geringen chemischen Reaktivität sowie guten Fettlöslichkeit ubiquitäre Umweltkontaminanten, die sich in der Nahrungskette anreichern. Eine natürliche, mikrobielle Dechlorierung dieser Verbindungen ist von besonderem Interesse, da die Toxizität chlorierter Benzole mit der Anzahl der Chlorsubstituenten steigt. Im Gegensatz zu Mono- und Dichlorbenzol, die durch aerobe Laborreinkulturen dechlorierbar sind, werden höher chlorierte Benzole bevorzugt unter anaeroben Bedingungen in Mischkulturen mit unbekannter Spezieszusammensetzung dechloriert. Bioreaktoren, in denen solche undefinierten Mischkulturen kontinuierlich kultiviert werden, sind eine vielversprechende Technik bei der Behandlung Chlorbenzol-kontaminierter Abwässer. Aufgrund der unbekannten Zusammensetzung der Population muß die mikrobielle Aktivität jedoch als "black box" betrachtet werden, was eine direkte Steuerung und Optimierung solcher Bioreaktoren erschwert. Zur Bestimmung der mikrobiellen Diversität einer in ihrer Zusammensetzung unbekannten, Trichlorbenzol(TCB)-dechlorierenden Bioreaktorkultur wurde aufgrund der bekannten Limitierungen kulturabhängiger Methoden die kulturunabhängige, vergleichende Sequenzanalyse direkt amplifizierter und klonierter 16S-rDNA gewählt. Die durch eine neuentwickelte Hybridisierungsmethode wesentlich vereinfachte Analyse der 16S-rDNA-Genbibliotheken erlaubte eine phylogenetische Klassifizierung der in der TCB-dechlorierenden Mischkultur abundanten Mikroorganismen (Bakterien und Archaea) und zeigte das Auftreten von 51 bakteriellen 16S-rDNA-Klonfamilien, mit einem weiten phylogenetischen Spektrum und teilweise enge Verwandtschaften zu anaerob dechlorierenden Dehalobacter spp. oder zu unkultivierten Bakterien eines vergleichbaren Biotops. Dieser Diversität stand eine dominierende Methanosaeta-ähnliche Klonfamilie innerhalb der Archaea gegenüber. Die aus der phylogenetischen Klassifizie, Due to their widespread application in industry and agriculture and their chemical stability chlorobenzenes (CB) are ubiquitous pollutants in soil, sediments, and aquifers. Since toxicity of CBs increases with the number of chlorine substituents, microbial dechlorination of CBs is of major interest. In contrast to di- and monochlorobenzenes (DCB and MCB) higher chlorinated benzenes are more resistant to aerobic dechlorination. However, for these compounds reductive dechlorination by different anaerobic microbial communities is well known. Bioreactors inoculated with complex dechlorinating anaerobic microbiota seem to be promising technologies for bioremediation of CB-contaminated aquifers. Several studies showed the efficiency of such bioreactors in treating chloroaromatic contaminated wastewaters. However, due to the unknown species diversity microbial activity had to be treated as a "black box" and direct optimization was hampered. To determine the microbial diversity of an anaerobic consortium in a fluidized bed reactor used for dechlorination of trichlorobenzene (TCB) I employed comparative sequence analysis of 16S rRNA genes after direct PCR-amplification and cloning from community DNA since culture-based methods have shown to be strongly biased. The application of a new hybridization based screening approach for bacterial 16S rDNA clone libraries drastically simplified the analysis and allowed the phylogenetic classification of the abundant bacteria and archaea. A total of 51 bacterial 16S rDNA clone families were found, which showed a wide distribution among the main bacterial phyla. Several bacterial 16S rDNA clone families were closely related to anaerobic, dechlorinating Dehalobacter spp. and to yet-uncultured bacteria of a similar habitat. In contrast to the high bacterial diversity archaeal 16S rDNA clone libraries were clearly dominated by a Methanosaeta concilii-like clone family. Some yet-uncultured bacteria and archaea of the TCB-dechlorinating conso

Published

1999

9. Untersuchungen zur mikrobiellen Diversität einer anaeroben, Trichlorbenzol-dechlorierenden Mischkultur

Author

Friedrich, B., Stackebrandt, E., Göbel, Ulf B., Wintzingerode-Knorr, Friedrich Wasmuth Lotar Frhr., Friedrich, B., Stackebrandt, E., Göbel, Ulf B., and Wintzingerode-Knorr, Friedrich Wasmuth Lotar Frhr.

Abstract

Chlorbenzole sind aufgrund ihrer weiten Verbreitung in Industrie und Landwirtschaft und ihrer geringen chemischen Reaktivität sowie guten Fettlöslichkeit ubiquitäre Umweltkontaminanten, die sich in der Nahrungskette anreichern. Eine natürliche, mikrobielle Dechlorierung dieser Verbindungen ist von besonderem Interesse, da die Toxizität chlorierter Benzole mit der Anzahl der Chlorsubstituenten steigt. Im Gegensatz zu Mono- und Dichlorbenzol, die durch aerobe Laborreinkulturen dechlorierbar sind, werden höher chlorierte Benzole bevorzugt unter anaeroben Bedingungen in Mischkulturen mit unbekannter Spezieszusammensetzung dechloriert. Bioreaktoren, in denen solche undefinierten Mischkulturen kontinuierlich kultiviert werden, sind eine vielversprechende Technik bei der Behandlung Chlorbenzol-kontaminierter Abwässer. Aufgrund der unbekannten Zusammensetzung der Population muß die mikrobielle Aktivität jedoch als "black box" betrachtet werden, was eine direkte Steuerung und Optimierung solcher Bioreaktoren erschwert. Zur Bestimmung der mikrobiellen Diversität einer in ihrer Zusammensetzung unbekannten, Trichlorbenzol(TCB)-dechlorierenden Bioreaktorkultur wurde aufgrund der bekannten Limitierungen kulturabhängiger Methoden die kulturunabhängige, vergleichende Sequenzanalyse direkt amplifizierter und klonierter 16S-rDNA gewählt. Die durch eine neuentwickelte Hybridisierungsmethode wesentlich vereinfachte Analyse der 16S-rDNA-Genbibliotheken erlaubte eine phylogenetische Klassifizierung der in der TCB-dechlorierenden Mischkultur abundanten Mikroorganismen (Bakterien und Archaea) und zeigte das Auftreten von 51 bakteriellen 16S-rDNA-Klonfamilien, mit einem weiten phylogenetischen Spektrum und teilweise enge Verwandtschaften zu anaerob dechlorierenden Dehalobacter spp. oder zu unkultivierten Bakterien eines vergleichbaren Biotops. Dieser Diversität stand eine dominierende Methanosaeta-ähnliche Klonfamilie innerhalb der Archaea gegenüber. Die aus der phylogenetischen Klassifizie, Due to their widespread application in industry and agriculture and their chemical stability chlorobenzenes (CB) are ubiquitous pollutants in soil, sediments, and aquifers. Since toxicity of CBs increases with the number of chlorine substituents, microbial dechlorination of CBs is of major interest. In contrast to di- and monochlorobenzenes (DCB and MCB) higher chlorinated benzenes are more resistant to aerobic dechlorination. However, for these compounds reductive dechlorination by different anaerobic microbial communities is well known. Bioreactors inoculated with complex dechlorinating anaerobic microbiota seem to be promising technologies for bioremediation of CB-contaminated aquifers. Several studies showed the efficiency of such bioreactors in treating chloroaromatic contaminated wastewaters. However, due to the unknown species diversity microbial activity had to be treated as a "black box" and direct optimization was hampered. To determine the microbial diversity of an anaerobic consortium in a fluidized bed reactor used for dechlorination of trichlorobenzene (TCB) I employed comparative sequence analysis of 16S rRNA genes after direct PCR-amplification and cloning from community DNA since culture-based methods have shown to be strongly biased. The application of a new hybridization based screening approach for bacterial 16S rDNA clone libraries drastically simplified the analysis and allowed the phylogenetic classification of the abundant bacteria and archaea. A total of 51 bacterial 16S rDNA clone families were found, which showed a wide distribution among the main bacterial phyla. Several bacterial 16S rDNA clone families were closely related to anaerobic, dechlorinating Dehalobacter spp. and to yet-uncultured bacteria of a similar habitat. In contrast to the high bacterial diversity archaeal 16S rDNA clone libraries were clearly dominated by a Methanosaeta concilii-like clone family. Some yet-uncultured bacteria and archaea of the TCB-dechlorinating conso

Published

1999