Operación de reactores biológicos para el tratamiento del agua

Traballo fin de mestrado (UDC.CIE). Biotecnoloxía avanzada. Curso 2011/201

Assessment of aerobic biodegradation of lower-chlorinated benzenes in contaminated groundwater using field-derived microcosms and compound-specific carbon isotope fractionation

Biodegradation of lower chlorinated benzenes (tri-, di- and monochlorobenzene) was assessed at a coastal aquifer contaminated with multiple chlorinated aromatic hydro- carbons. Field-derived microcosms, established with groundwater from the source zone and amended with a mixture of lower chlorinated benzenes, evidenced biodegradation of monochlorobenzene (MCB) and 1,4-dichlorobenzene (1,4-DCB) in aerobic microcosms, whereas the addition of lactate in anaerobic microcosms did not enhance anaerobic reduc- tive dechlorination. Aerobic microcosms established with groundwater from the plume consumed several doses of MCB and concomitantly degraded the three isomers of dichloroben- zene with no observable inhibitory effect. In the light of these results, we assessed the applicability of compound stable isotope analysis to monitor a potential aerobic remediation treatment of MCB and 1,4-DCB in this site. The carbon isotopic fractionation factors ( ε) obtained from field-derived microcosms were -0.7 ¿ ± 0.1 ¿ and -1.0 ¿ ± 0.2 ¿ for MCB and 1,4-DCB, respectively. For 1,4-DCB, the carbon isotope fractionation during aerobic biodegra- dation was reported for the first time. The weak carbon isotope fractionation values for the aerobic pathway would only allow tracing of in situ degradation in aquifer parts with high extent of biodegradation. However, based on the carbon isotope effects measured in this and previous studies, relatively high carbon isotope shifts (i.e., δ13 C > 4.0 ¿ ) of MCB or 1,4- DCB in contaminated groundwater would suggest that their biodegradation is controlled by anaerobic reductive dechlorination

Proteogenomics of the novel Dehalobacterium formicoaceticum strain EZ94 highlights a key role of methyltransferases during anaerobic dichloromethane degradation

Altres ajuts: acords transformatius de la UABDichloromethane (DCM, methylene chloride) is a toxic, high-volume industrial pollutant of long-standing. Anaerobic biodegradation is crucial for its removal from contaminated environments, yet prevailing mechanisms remain unresolved, especially concerning dehalogenation. In this study, we obtained an assembled genome of a novel DCM-degrading strain, Dehalobacterium formicoaceticum strain EZ94, from a stable DCM-degrading consortium, and we analyzed its proteome during degradation of DCM. A gene cluster recently predicted to play a major role in anaerobic DCM catabolism (the mec cassette) was found. Methyltransferases and other proteins encoded by the mec cassette were among the most abundant proteins produced, suggesting their involvement in DCM catabolism. Reductive dehalogenases were not detected. Genes and corresponding proteins for a complete Wood-Ljungdahl pathway, which could enable further metabolism of DCM carbon, were also found. Unlike for the anaerobic DCM degrader "Ca. F. warabiya," no genes for metabolism of the quaternary amines choline and glycine betaine were identifed. This work provides independent and supporting evidence that mecassociated methyltransferases are key to anaerobic DCM metabolism

Valorization of bioethanol by-products to produce unspecific peroxygenase with Agrocybe aegerita: Technological and proteomic perspectives

Unspecific peroxygenase (UPO) presents a wide range of biotechnological applications. This study targets the use of by-products from bioethanol synthesis to produce UPO by Agrocybe aegerita. Solid-state and submerged fermentations (SSF and SmF) were evaluated, achieving the highest titers of UPO and laccase in SmF using vinasse as nutrients source. Optimized UPO production of 331 U/L was achieved in 50% (v:v) vinasse with an inoculum grown for 14 days. These conditions were scaled-up to a 4 L reactor, achieving a UPO activity of 265 U/L. Fungal proteome expression was analyzed before and after UPO activity appeared by shotgun mass spectrometry proteomics. Laccase, dye-decolorizing peroxidases (DyP), lectins and proteins involved in reactive oxygen species (ROS) production and control were detected (in addition to UPO). Interestingly, the metabolism of complex sugars and nitrogen sources had a different activity at the beginning and end of the submerged fermentationS.G., A.T. and G.E. thank their grants (BES-2017-081677, FJC2019-041664-I and RYC2018-024846-I, respectively) funded by MCIN/AEI/ 10.13039/501100011033, and by “ERDF A way of making Europe” and “ESF Investing in your future”. Authors would like to thank the use of USC Mass Spectrometry and Proteomics facilities and Bioetanol Galicia S.A. for the supply of the substrates used in the fermentations. The authors belong to the Galician Competitive Research Groups (GRC)_ ED431C-2021/37. The program is co-funded by FEDER (UE)S

Sulfamethoxazole enhances specific enzymatic activities under aerobic heterotrophic conditions: a metaproteomic approach

The growing concern about antibiotic-resistant microorganisms has focused on the sludge from wastewater treatment plants (WWTPs) as a potential hotspot for their development and spread. To this end, it seems relevant to analyze the changes on the microbiota as a consequence of the antibiotics that wastewater may contain. This study aims at determining whether the presence of sulfamethoxazole (SMX), even in relatively low concentrations, modifies the microbial activities and the enzymatic expression of an activated sludge under aerobic heterotrophic conditions. For that purpose, we applied a metaproteomic approach in combination with genomic and transformation product analyses. SMX was biotransformed, and the metabolite 2,4(1H,3H)-pteridinedione-SMX (PtO-SMX) from the pterin-conjugation pathway was detected at all concentrations tested. Metaproteomics showed that SMX at 50–2000 μg/L slightly affected the microbial community structure, which was confirmed by DNA metabarcoding. Interestingly, an enhanced activity of the genus Corynebacterium and specifically of five enzymes involved in its central carbon metabolism was found at increased SMX concentrations. Our results suggest a role of Corynebacterium genus on SMX risks mitigation in our bioreactorsThis research was funded by the Spanish Government (Agencia Estatal de Investigación) through the ANTARES project (PID2019-110346RB-C21), a PhD Xunta de Galicia Grant (ED481A-2018/113, D.M.K.-V.) and a Juan de la Cierva-Formación postdoctoral grant (FJC2019-041664-I, A.T.-S.). The authors belong to the Galician Competitive Research Groups (GRC_ ED431C-2021/37)S

Use of dual element isotope analysis and microcosm studies to determine the origin and potential anaerobic biodegradation of dichloromethane in two multi-contaminated aquifers

Many aquifers around the world are impacted by toxic chlorinated methanes derived from industrial processes due to accidental spills. Frequently, these contaminants co-occur with chlorinated ethenes and/or chlorinated benzenes in groundwater, forming complex mixtures that become very difficult to remediate. In this study, a multi-method approach was used to provide lines of evidence of natural attenuation processes and potential setbacks in the implementation of bioremediation strategies in multi-contaminated aquifers. First, this study determined i) the carbon and chlorine isotopic compositions (δ¹³C, δ³⁷Cl) of several commercial pure phase chlorinated compounds, and ii) the chlorine isotopic fractionation (εCl = −5.2 ± 0.6‰) and the dual CCl isotope correlation (ΛC/Cl = 5.9 ± 0.3) during dichloromethane (DCM) degradation by a Dehalobacterium-containing culture. Such data provide valuable information for practitioners to support the interpretation of stable isotope analyses derived from polluted sites. Second, the bioremediation potential of two industrial sites contaminated with a mixture of organic pollutants (mainly DCM, chloroform (CF), trichloroethene (TCE), and mono-chlorobenzene (MCB)) was evaluated. Hydrochemistry, dual (CCl) isotope analyses, laboratory microcosms, and microbiological data were used to investigate the origin, fate and biodegradation potential of chlorinated methanes. At Site 1, δ¹³C and δ³⁷Cl compositions from field samples were consistent with laboratory microcosms, which showed complete degradation of CF, DCM and TCE, while MCB remained. Identification of Dehalobacter sp. in CF-enriched microcosms further supported the biodegradation capability of the aquifer to remediate chlorinated methanes. At Site 2, hydrochemistry and δ¹³C and δ³⁷Cl compositions from field samples suggested little DCM, CF and TCE transformation; however, laboratory microcosms evidenced that their degradation was severely inhibited, probably by co-contamination. A dual CCl isotopic assessment using results from this study and reference values from the literature allowed to determine the extent of degradation and elucidated the origin of chlorinated methanes

Biodeterioration kinetics and microbial community organization on surface of cementitious materials exposed to anaerobic digestion conditions

Anaerobic digestion is a process that can produce renewable energy through the fermentation of biodegradable biomass. Industrial anaerobic digestion tanks are usually made of concrete but the production of various aggressive compounds (CO2, NH4+ and volatile fatty acids) during the microbial fermentation leads to deterioration of the concrete structure. In addition, the formation of a microbial biofilm on the cementitious material surface could generate even more intense biodeterioration. The objective of this study is to gain a better understanding of the involvement of biofilm in the biodeterioration of cementitious materials during an anaerobic digestion process. More specifically, the study focuses on the heterogeneity of microbial populations within the biofilm and the reactive medium in anaerobic digestion. Laboratory scale anaerobic bioreactors mimicking the industrial anaerobic digestion medium were constructed and CEM I cement pastes were immersed in this medium for 2, 3, 4, 5, 10 and 15 weeks. The biodeterioration of the cement pastes was evaluated by determining the deteriorated thickness. The aggressive compounds in the medium were quantified. The biofilm attached to the surface of the cement pastes was analyzed using 16 s rRNA gene sequencing. To evaluate the heterogeneity of the biofilm, the growth of biofilm layers was successively caused to stall by using two distinct biofilm removal techniques. Three microbial fractions were defined: planktonic microorganisms, and the microorganisms within the biofilm that were loosely and strongly attached. The results showed that the planktonic lifestyle was more associated with microorganisms producing methane and consuming volatile fatty acids, while the biofilm was more associated with bacteria producing acids, mainly members of the Clostridium genus. A microbial community shift due to a reversible propionic acid accumulation during the first 5 weeks was also observed. In addition, no major differences were spotted between the loosely and strongly attached biomass, indicating homogeneity in the two layers of the biofilm. These results suggest that the biofilm could increase the biodeterioration of concrete since volatile fatty acids could be produced in massive quantities near the surface of the cement samples by the acidogenic microbial population more present within the biofilm

Enrichment and characterization of anaerobic bacteria degrading organohalide compounds

La freqüent contaminació d’aigua subterrània per compostos organohalogenats és un greu problema degut als riscs humans i ecològics que se’n deriven. La bioremediació és un tècnica sostenible que permet superar algunes de les limitacions que presenten els tractaments fisicoquímics. En aquest estudi ens proposem obtenir i caracteritzar cultius que contenen bacteris anaerobis capaços de degradar compostos organohalogenats ambientalment perillosos i que es puguin aplicar per a la bioremediació d’aqüífers in situ. En treballs previs realitzats al nostre laboratori es va obtenir un cultiu enriquit que contenia un bacteri dehalorespirador del gènere Dehalogenimonas a partir de sediments de la desembocadura del riu Besòs (Barcelona) que degrada alcans amb halògens situats en carbons adjacents. En aquesta tesis, s’ha identificat la dehalogenasa reductora (RDasa) d’aquesta Dehalogenimonas implicada en la conversió de dibromur d’etilè (EDB) al compost innocu etilè combinant tècniques de proteòmica basades en gels d’electroforesis, tests enzimàtics i nano-cromatografia líquida acoblada a espectrometria de masses (nLC-MS/MS). Aquesta RDasa es va designar com a EdbA. EdbA és la primera RDasa identificada entre les espècies d’aquest gènere bacterià que catalitza una reacció de debromació. A més, és la primera RDasa que s’ha demostrat funcional i que no té cap subunitat B de fixació a la membrana citoplasmàtica codificada de forma adjacent en el seu genoma. Addicionalment, s’ha detectat un enzim ortolog a l’enzim responsable de la degradació de 1,2-diclorpropà a propé (DcpA) com a única RDasa en cultius que transformen 1,2,3-triclorpropà a clorur d’alil mitjançant la combinació de tècniques d’ultracentrifugació, gels d’electroforesis i nLC-MS/MS. Aquesta DcpA es va detectar en la fracció de la membrana tal i com predeien les eines bioinformàtiques emprades. El mecanisme pel qual aquestes dues RDases identificades es fixen a les membranes és encara desconegut. En aquesta treball s’ha obtingut un segon consorci bacterià estable provinent de llots d’una planta de tractament d’aigües residuals industrials i aplicant estratègies de d’enriquiment del cultiu i tècniques de dilució fins a l’extinció. Aquest cultiu fermenta diclorometà (DCM) i dibromometà (DBM) en acetat i format. S’ha demostrat que el bacteri responsable de la fermentació d’aquests dihalometans és un Dehalobacterium i s’ha procedit al seu aïllament. Tanmateix, les interaccions sinèrgiques entre les espècies del consorci han impedit el seu aïllament. Mitjançant la selecció de colònies en cultius semi sòlids, canvis en la composició del medi i l’ús de antibiòtics, s’ha assolit un cultiu on l’abundància de Dehalobacterium és del 67%. L´acompanyen bacteris dels gèneres Acetobacterium i Desulfovibrio, tal i com revelen els anàlisis de genoteques. El fraccionament dels isòtops de carboni durant la fermentació de DCM per aquest cultiu s’ha determinat mitjançant l’anàlisi d’isòtops estables de compostos específics (CSIA). El valor obtingut de -27 ± 2‰ difereix del prèviament publicat per una soca de Dehalobacter (-15.5 ± 1.5‰) que també fermentava DCM. Aquests valors són significativament diferent dels obtinguts per bacteris metilotròfics degradadors de DCM (que varien de -45 a -61‰) i podria permetre la distinció entre vies de degradació de DCM en treballs de bioremediació in situ. Finalment, s’ha demostrat que la presència de co-contaminants que es detecten freqüentment amb DCM, tals com tricloroetilè (TCE), 1,2-dicloroetà (1,2-DCA), cis-dicloroetilè (cis-DCE), 1,1,2-tricloroetà (1,1,2-TCA), àcid perfluorooctanoic (PFOA) i 3,4-dicloroanilina (3,4-DCA) no provoca una inhibició significativa en la degradació de DCM pel cultiu amb Dehalobacterium a les concentracions testades. La concentració de cloroform de 100 mg/L provoca una total inhibició. De manera similar, la presència de 200 mg/L d’àcid perfluorooctanosulfonic (PFOS) i ≥ 25 mg/L de diuron provoquen una inhibició severa, impedint la degradació completa de DCM. Tanmateix, l’activitat degradadora de DCM es recupera quan els cultius inhibits es transfereixen a medi fresc sense co-contaminants.La frecuente contaminación de las aguas subterráneas por compuestos organohalogenados es un grave problema ambiental debido a los riesgos ecológicos y para la salud humana de ella derivados. La bioremediación es una tecnología sostenible que evita algunos inconvenientes que presentan los tratamientos físico-químicos. En este estudio nos proponemos obtener y caracterizar cultivos que contengan bacterias anaerobias que degraden compuestos organohalogenados ambientalmente peligrosos con potencial para la bioremediación in situ de aguas subterráneas. En trabajos previos de nuestro grupo de investigación, se obtuvo un cultivo enriquecido en bacterias del género Dehalogenimonas procedente de sedimentos del estuario del río Besós (Barcelona) que degrada alcanos con halógenos situados en carbonos adyacentes. En esta tesis se ha identificado la dehalogenasa reductora (RDasa) de esta cepa de Dehalogenimonas implicada en la conversión del dibromuro de etileno (EDB) al compuesto inocuo eteno combinando técnicas de proteómica basadas en geles de electroforesis, ensayos enzimáticos y nano-cromatografía líquida de alta resolución (nLC-MS/MS). Esta RDasa es designada EdbA, y constituye la primera RDasa identificada en este género bacteriano que cataliza una reacción de debromación. Además, es también la primera RDasa en ser demostrada funcional sin una subunidad B de anclaje a la membrana codificada de forma adyacente en el genoma. Adicionalmente, se ha detectado una única RDasa en cultivos que transforman 1,2,3-tricloropropano a cloruro de alilo combinando técnicas de ultracentrifugación, geles de electroforesis y nLC-MS/MS. Esta enzima ortóloga a DcpA, la responsable de la degradación de 1,2-dicloropropano a propeno, ha sido detectada en la fracción proteica de membrana, lo cual concuerta con las predicciones realizadas mediante herramientas bioinformáticas. El mecanismo por el cual EdbA y esta DcpA se anclan a la membrana citoplasmática es desconocido, atribuyéndose a proteínas todavía no descritas. En este trabajo se ha obtenido un segundo consorcio bacteriano estable a partir de lodos de una planta de tratamiento de aguas residuales industriales aplicando técnicas de cultivo de enriquecimiento y dilución por extinción. Este cultivo fermenta diclorometano (DCM) y dibromometano (DBM) a acetato y formato. Se ha demostrado que la bacteria responsable de la fermentación pertenece al género Dehalobacterium, y se ha procedido a su aislamiento. Sin embargo, las interacciones sinérgicas existentes entre las especies del consorcio han impedido obtener un cultivo puro. Seleccionando colonias en medio de cultivo semisólido, aplicando antibióticos y cambios en la composición del medio, se ha obtenido una abundancia relativa de Dehalobacterium del 67%. Le acompañan bacterias de los géneros Acetobacterium y Desulfovibrio, tal y como se detectó mediante análisis de genotecas. El fraccionamiento isotópico del carbono durante la fermentación del DCM por este cultivo fue determinado mediante análisis de isótopos estables de compuestos específicos (CSIA). El valor obtenido, -27 ± 2‰, difiere del publicado previamente para una cepa de Dehalobacter que también fermenta el DCM (-15.5 ± 1.5‰). Estos valores son significativamente diferentes de los obtenidos con bacterias metilotróficas degradadoras de DCM (-45 a -61‰), y podrían permitir diferenciar vías de degradación de DCM en trabajos de bioremediación in situ. Finalmente, se ha demostrado que la presencia de co-contaminantes que se detectan frecuentemente con el DCM, como el tricloroetileno (TCE), 1,2-dicloroetano (1,2-DCA), cis-dicloroetileno (cis-DCE), 1,1,2-tricloroetano (1,1,2-TCA), ácido perfluorooctanoico (PFOA) y 3,4-dicloroanilina (3,4-DCA) no provocan una inhibición significativa en la degradación de DCM por parte del cultivo de Dehalobacterium, a las concentraciones estudiadas. Una concentración de cloroformo de 100 mg/L provoca una inhibición total. De manera similar, 200 mg/L de sulfonato de perfluoroctano (PFOS), y ≥ 25 mg/L de diuron provocan una inhibición severa, impidiendo la degradación completa del DCM. Sin embargo, la actividad degradadora de DCM se recupera cuando los cultivos inhibidos se transfieren a medio libre de co-contaminantes.The widespread groundwater contamination by organohalide compounds is of a major concern due to the human and ecological risks derived from it. Bioremediation is a sustainable technology that overcomes some limitations of the physical-chemical remediation techniques on these water bodies. In this study, we aimed to obtain and characterize cultures containing anaerobic bacteria capable of degrading organohalide compounds of environmental concern with potential for in situ groundwater bioremediation. In previous work carried out in our laboratory a highly enriched culture containing organohalide-respiring bacteria from the genus Dehalogenimonas degrading vicinally halogenated alkanes was obtained from sediments of the river Besós estuary (Barcelona). In this thesis, the reductive dehalogenase (RDase) from this Dehalogenimonas strain responsible for the catalysis of ethylene dibromide (EDB) to the innocuous ethene was identified combining gel-based proteomic techniques, specific enzymatic tests and nano-scale liquid chromatography tandem mass spectrometry (nLC-MS/MS). This RDase is therefore designated as EdbA, for ethylene dibromide RDase subunit A. EdbA is the first RDase identified for debrominating catalytic activity among species of this genus. Moreover, it is the first RDase shown to be functional for respiration without an adjacent membrane-anchoring subunit B encoded on the genome. Additionally, combining ultracentrifugation, gel electrophoresis and nLC-MS/MS, an orthologous enzyme of the dichloropropane-to-propene RDase (DcpA) was the only RDase detected in 1,2,3-trichloropropane-to-allyl chloride dehalogenating cultures. This DcpA was detected in the membrane fraction of the crude protein extract, in accordance to its predicted subcellular localization by bioinformatics tools and it is also not co-localised with an rdhB gene. The membrane-anchoring mechanisms of these RDases remains not known and may rely in yet-unidentified proteins. A second stable bacterial consortium was obtained in the present work from slurry samples of an industrial wastewater treatment plant with a combination of enrichment culture strategies and the dilution-to-extinction technique. This culture was demonstrated to ferment dichloromethane (DCM) and dibromomethane (DBM) into acetate and formate. The Dehalobacterium sp. present in this culture was shown to be the responsible for the dihalomethanes fermentation, and the isolation of this strain was attempted. However, the synergic interactions existing among the different accompanying species present in the bacterial consortia impeded the isolation. Despite a pure culture was not achieved via picking up colonies from semisolid agar cultures, changes in the medium composition, and the application of selected antibiotics, a final relative abundance of Dehalobacterium sp. of 67 % was attained. As determined by clone library analysis, bacteria from the genera Acetobacterium and Desulfovibrio remained present in the culture. The carbon isotope fractionation during DCM fermentation by this culture was determined by compound-specific stable isotope analysis (CSIA). The value obtained was -27 ± 2‰ and differs from the previously published value of -15.5 ± 1.5‰ of a Dehalobacter sp. performing also DCM fermentation. These values are yet significantly different from those reported for facultative methylotrophic bacteria degrading DCM (ranging from -45 to -61‰), and this would allow for further differentiation of these degradation pathways during in situ bioremediation works. Finally, the potential inhibitory effect of selected frequent groundwater co-contaminants over DCM degradation by the Dehalobacterium-containing culture was assessed for further in situ bioremediation applications. Trichloroethylene (TCE), 1,2-dichloroethane (1,2-DCA), cis-dichloroethylene (cis-DCE), 1,1,2-trichloroethane (1,1,2-TCA), perfluorooctanoic acid (PFOA), and 3,4-dichloroaniline (3,4-DCA) did not show significant inhibitory effects at the concentrations tested. Differently, a total inhibition was caused with a chloroform concentration of 100 mg/L. Also, the presence of 200 mg/L of perfluorooctanesulfonic acid (PFOS), as well as concentrations higher than 25 mg/L of the pesticide diuron caused a severe inhibitory effect, preventing the full depletion of DCM. Nevertheless, DCM degrading activity was recovered when inhibited cultures were transferred to co-contaminant free medium

Enrichment and characterization of anaerobic bacteria degrading organohalide compounds

La freqüent contaminació d’aigua subterrània per compostos organohalogenats és un greu problema degut als riscs humans i ecològics que se’n deriven. La bioremediació és un tècnica sostenible que permet superar algunes de les limitacions que presenten els tractaments fisicoquímics. En aquest estudi ens proposem obtenir i caracteritzar cultius que contenen bacteris anaerobis capaços de degradar compostos organohalogenats ambientalment perillosos i que es puguin aplicar per a la bioremediació d’aqüífers in situ. En treballs previs realitzats al nostre laboratori es va obtenir un cultiu enriquit que contenia un bacteri dehalorespirador del gènere Dehalogenimonas a partir de sediments de la desembocadura del riu Besòs (Barcelona) que degrada alcans amb halògens situats en carbons adjacents. En aquesta tesis, s’ha identificat la dehalogenasa reductora (RDasa) d’aquesta Dehalogenimonas implicada en la conversió de dibromur d’etilè (EDB) al compost innocu etilè combinant tècniques de proteòmica basades en gels d’electroforesis, tests enzimàtics i nano-cromatografia líquida acoblada a espectrometria de masses (nLC-MS/MS). Aquesta RDasa es va designar com a EdbA. EdbA és la primera RDasa identificada entre les espècies d’aquest gènere bacterià que catalitza una reacció de debromació. A més, és la primera RDasa que s’ha demostrat funcional i que no té cap subunitat B de fixació a la membrana citoplasmàtica codificada de forma adjacent en el seu genoma. Addicionalment, s’ha detectat un enzim ortolog a l’enzim responsable de la degradació de 1,2-diclorpropà a propé (DcpA) com a única RDasa en cultius que transformen 1,2,3-triclorpropà a clorur d’alil mitjançant la combinació de tècniques d’ultracentrifugació, gels d’electroforesis i nLC-MS/MS. Aquesta DcpA es va detectar en la fracció de la membrana tal i com predeien les eines bioinformàtiques emprades. El mecanisme pel qual aquestes dues RDases identificades es fixen a les membranes és encara desconegut. En aquesta treball s’ha obtingut un segon consorci bacterià estable provinent de llots d’una planta de tractament d’aigües residuals industrials i aplicant estratègies de d’enriquiment del cultiu i tècniques de dilució fins a l’extinció. Aquest cultiu fermenta diclorometà (DCM) i dibromometà (DBM) en acetat i format. S’ha demostrat que el bacteri responsable de la fermentació d’aquests dihalometans és un Dehalobacterium i s’ha procedit al seu aïllament. Tanmateix, les interaccions sinèrgiques entre les espècies del consorci han impedit el seu aïllament. Mitjançant la selecció de colònies en cultius semi sòlids, canvis en la composició del medi i l’ús de antibiòtics, s’ha assolit un cultiu on l’abundància de Dehalobacterium és del 67%. L´acompanyen bacteris dels gèneres Acetobacterium i Desulfovibrio, tal i com revelen els anàlisis de genoteques. El fraccionament dels isòtops de carboni durant la fermentació de DCM per aquest cultiu s’ha determinat mitjançant l’anàlisi d’isòtops estables de compostos específics (CSIA). El valor obtingut de -27 ± 2‰ difereix del prèviament publicat per una soca de Dehalobacter (-15.5 ± 1.5‰) que també fermentava DCM. Aquests valors són significativament diferent dels obtinguts per bacteris metilotròfics degradadors de DCM (que varien de -45 a -61‰) i podria permetre la distinció entre vies de degradació de DCM en treballs de bioremediació in situ. Finalment, s’ha demostrat que la presència de co-contaminants que es detecten freqüentment amb DCM, tals com tricloroetilè (TCE), 1,2-dicloroetà (1,2-DCA), cis-dicloroetilè (cis-DCE), 1,1,2-tricloroetà (1,1,2-TCA), àcid perfluorooctanoic (PFOA) i 3,4-dicloroanilina (3,4-DCA) no provoca una inhibició significativa en la degradació de DCM pel cultiu amb Dehalobacterium a les concentracions testades. La concentració de cloroform de 100 mg/L provoca una total inhibició. De manera similar, la presència de 200 mg/L d’àcid perfluorooctanosulfonic (PFOS) i ≥ 25 mg/L de diuron provoquen una inhibició severa, impedint la degradació completa de DCM. Tanmateix, l’activitat degradadora de DCM es recupera quan els cultius inhibits es transfereixen a medi fresc sense co-contaminants.La frecuente contaminación de las aguas subterráneas por compuestos organohalogenados es un grave problema ambiental debido a los riesgos ecológicos y para la salud humana de ella derivados. La bioremediación es una tecnología sostenible que evita algunos inconvenientes que presentan los tratamientos físico-químicos. En este estudio nos proponemos obtener y caracterizar cultivos que contengan bacterias anaerobias que degraden compuestos organohalogenados ambientalmente peligrosos con potencial para la bioremediación in situ de aguas subterráneas. En trabajos previos de nuestro grupo de investigación, se obtuvo un cultivo enriquecido en bacterias del género Dehalogenimonas procedente de sedimentos del estuario del río Besós (Barcelona) que degrada alcanos con halógenos situados en carbonos adyacentes. En esta tesis se ha identificado la dehalogenasa reductora (RDasa) de esta cepa de Dehalogenimonas implicada en la conversión del dibromuro de etileno (EDB) al compuesto inocuo eteno combinando técnicas de proteómica basadas en geles de electroforesis, ensayos enzimáticos y nano-cromatografía líquida de alta resolución (nLC-MS/MS). Esta RDasa es designada EdbA, y constituye la primera RDasa identificada en este género bacteriano que cataliza una reacción de debromación. Además, es también la primera RDasa en ser demostrada funcional sin una subunidad B de anclaje a la membrana codificada de forma adyacente en el genoma. Adicionalmente, se ha detectado una única RDasa en cultivos que transforman 1,2,3-tricloropropano a cloruro de alilo combinando técnicas de ultracentrifugación, geles de electroforesis y nLC-MS/MS. Esta enzima ortóloga a DcpA, la responsable de la degradación de 1,2-dicloropropano a propeno, ha sido detectada en la fracción proteica de membrana, lo cual concuerta con las predicciones realizadas mediante herramientas bioinformáticas. El mecanismo por el cual EdbA y esta DcpA se anclan a la membrana citoplasmática es desconocido, atribuyéndose a proteínas todavía no descritas. En este trabajo se ha obtenido un segundo consorcio bacteriano estable a partir de lodos de una planta de tratamiento de aguas residuales industriales aplicando técnicas de cultivo de enriquecimiento y dilución por extinción. Este cultivo fermenta diclorometano (DCM) y dibromometano (DBM) a acetato y formato. Se ha demostrado que la bacteria responsable de la fermentación pertenece al género Dehalobacterium, y se ha procedido a su aislamiento. Sin embargo, las interacciones sinérgicas existentes entre las especies del consorcio han impedido obtener un cultivo puro. Seleccionando colonias en medio de cultivo semisólido, aplicando antibióticos y cambios en la composición del medio, se ha obtenido una abundancia relativa de Dehalobacterium del 67%. Le acompañan bacterias de los géneros Acetobacterium y Desulfovibrio, tal y como se detectó mediante análisis de genotecas. El fraccionamiento isotópico del carbono durante la fermentación del DCM por este cultivo fue determinado mediante análisis de isótopos estables de compuestos específicos (CSIA). El valor obtenido, -27 ± 2‰, difiere del publicado previamente para una cepa de Dehalobacter que también fermenta el DCM (-15.5 ± 1.5‰). Estos valores son significativamente diferentes de los obtenidos con bacterias metilotróficas degradadoras de DCM (-45 a -61‰), y podrían permitir diferenciar vías de degradación de DCM en trabajos de bioremediación in situ. Finalmente, se ha demostrado que la presencia de co-contaminantes que se detectan frecuentemente con el DCM, como el tricloroetileno (TCE), 1,2-dicloroetano (1,2-DCA), cis-dicloroetileno (cis-DCE), 1,1,2-tricloroetano (1,1,2-TCA), ácido perfluorooctanoico (PFOA) y 3,4-dicloroanilina (3,4-DCA) no provocan una inhibición significativa en la degradación de DCM por parte del cultivo de Dehalobacterium, a las concentraciones estudiadas. Una concentración de cloroformo de 100 mg/L provoca una inhibición total. De manera similar, 200 mg/L de sulfonato de perfluoroctano (PFOS), y ≥ 25 mg/L de diuron provocan una inhibición severa, impidiendo la degradación completa del DCM. Sin embargo, la actividad degradadora de DCM se recupera cuando los cultivos inhibidos se transfieren a medio libre de co-contaminantes.The widespread groundwater contamination by organohalide compounds is of a major concern due to the human and ecological risks derived from it. Bioremediation is a sustainable technology that overcomes some limitations of the physical-chemical remediation techniques on these water bodies. In this study, we aimed to obtain and characterize cultures containing anaerobic bacteria capable of degrading organohalide compounds of environmental concern with potential for in situ groundwater bioremediation. In previous work carried out in our laboratory a highly enriched culture containing organohalide-respiring bacteria from the genus Dehalogenimonas degrading vicinally halogenated alkanes was obtained from sediments of the river Besós estuary (Barcelona). In this thesis, the reductive dehalogenase (RDase) from this Dehalogenimonas strain responsible for the catalysis of ethylene dibromide (EDB) to the innocuous ethene was identified combining gel-based proteomic techniques, specific enzymatic tests and nano-scale liquid chromatography tandem mass spectrometry (nLC-MS/MS). This RDase is therefore designated as EdbA, for ethylene dibromide RDase subunit A. EdbA is the first RDase identified for debrominating catalytic activity among species of this genus. Moreover, it is the first RDase shown to be functional for respiration without an adjacent membrane-anchoring subunit B encoded on the genome. Additionally, combining ultracentrifugation, gel electrophoresis and nLC-MS/MS, an orthologous enzyme of the dichloropropane-to-propene RDase (DcpA) was the only RDase detected in 1,2,3-trichloropropane-to-allyl chloride dehalogenating cultures. This DcpA was detected in the membrane fraction of the crude protein extract, in accordance to its predicted subcellular localization by bioinformatics tools and it is also not co-localised with an rdhB gene. The membrane-anchoring mechanisms of these RDases remains not known and may rely in yet-unidentified proteins. A second stable bacterial consortium was obtained in the present work from slurry samples of an industrial wastewater treatment plant with a combination of enrichment culture strategies and the dilution-to-extinction technique. This culture was demonstrated to ferment dichloromethane (DCM) and dibromomethane (DBM) into acetate and formate. The Dehalobacterium sp. present in this culture was shown to be the responsible for the dihalomethanes fermentation, and the isolation of this strain was attempted. However, the synergic interactions existing among the different accompanying species present in the bacterial consortia impeded the isolation. Despite a pure culture was not achieved via picking up colonies from semisolid agar cultures, changes in the medium composition, and the application of selected antibiotics, a final relative abundance of Dehalobacterium sp. of 67 % was attained. As determined by clone library analysis, bacteria from the genera Acetobacterium and Desulfovibrio remained present in the culture. The carbon isotope fractionation during DCM fermentation by this culture was determined by compound-specific stable isotope analysis (CSIA). The value obtained was -27 ± 2‰ and differs from the previously published value of -15.5 ± 1.5‰ of a Dehalobacter sp. performing also DCM fermentation. These values are yet significantly different from those reported for facultative methylotrophic bacteria degrading DCM (ranging from -45 to -61‰), and this would allow for further differentiation of these degradation pathways during in situ bioremediation works. Finally, the potential inhibitory effect of selected frequent groundwater co-contaminants over DCM degradation by the Dehalobacterium-containing culture was assessed for further in situ bioremediation applications. Trichloroethylene (TCE), 1,2-dichloroethane (1,2-DCA), cis-dichloroethylene (cis-DCE), 1,1,2-trichloroethane (1,1,2-TCA), perfluorooctanoic acid (PFOA), and 3,4-dichloroaniline (3,4-DCA) did not show significant inhibitory effects at the concentrations tested. Differently, a total inhibition was caused with a chloroform concentration of 100 mg/L. Also, the presence of 200 mg/L of perfluorooctanesulfonic acid (PFOS), as well as concentrations higher than 25 mg/L of the pesticide diuron caused a severe inhibitory effect, preventing the full depletion of DCM. Nevertheless, DCM degrading activity was recovered when inhibited cultures were transferred to co-contaminant free medium

Metalloenzymes play major roles to achieve high-rate nitrogen removal in N-damo communities: Lessons from metaproteomics

Nitrite-driven anaerobic methane oxidation (N-damo) is a promising biological process to achieve carbon–neutral wastewater treatment solutions, aligned with the sustainable development goals. Here, the enzymatic activities in a membrane bioreactor highly enriched in N-damo bacteria operated at high nitrogen removal rates were investigated. Metaproteomic analyses, with a special focus on metalloenzymes, revealed the complete enzymatic route of N-damo including their unique nitric oxide dismutases. The relative protein abundance evidenced that “Ca. Methylomirabilis lanthanidiphila” was the predominant N-damo species, attributed to the induction of its lanthanide-binding methanol dehydrogenase in the presence of cerium. Metaproteomics also disclosed the activity of the accompanying taxa in denitrification, methylotrophy and methanotrophy. The most abundant functional metalloenzymes from this community require copper, iron, and cerium as cofactors which was correlated with the metal consumptions in the bioreactor. This study highlights the usefulness of metaproteomics for evaluating the enzymatic activities in engineering systems to optimize microbial managementThis research was supported by the European Union’s Horizon 2020 research and innovation program under the project NOWELTIES, through the Marie Sklodowska-Curie grant agreement 812880, as well as the Spanish inistry of Economy and Competitiveness through ANTARES (PID2019-110346RB-C21) project. Authors belong to Galician Competitive Research Group (GRC ED431C-2021/37). Alba Trueba-Santiso acknowledges a Juan de la Cierva-Formación postdoctoral grant (FJC2019-041664-I). The authors warmly thank all the members of the Proteomics Unit of the CIBER-BBN at SERGAS (Spain) and the Centro Interdisciplinar de Química e Bioloxía (CICA) of the University of A Coruña (Spain) and specially to Dr. Valentina Calamia for mass spectrometric analysesS