Effectively facilitating the degradation of chloramphenicol by the synergism of Shewanella oneidensis MR-1 and the metal-organic framework.

[1]  M. Sarrà,et al.  Biotransformation of chloramphenicol by white-rot-fungi Trametes versicolor under cadmium stress. , 2022, Bioresource technology.

[2]  Hao Song,et al.  Modular Engineering Strategy to Redirect Electron Flux into the Electron-Transfer Chain for Enhancing Extracellular Electron Transfer in Shewanella oneidensis. , 2022, ACS synthetic biology.

[3]  P. R. Yaashikaa,et al.  Bioremediation of hazardous pollutants from agricultural soils: A sustainable approach for waste management towards urban sustainability. , 2022, Environmental pollution.

[4]  Xiaochuan Huang,et al.  Size-dependent acute toxicity and oxidative damage caused by cobalt-based framework (ZIF-67) to Photobacterium phosphoreum. , 2022, The Science of the total environment.

[5]  Fanghua Liu,et al.  Selectively facilitating the electron acceptance of methanogens by riboflavin , 2022, Renewable Energy.

[6]  Wenxin Zhu,et al.  Facile construction of Fe3+/Fe2+ mediated charge transfer pathway in MIL-101 for effective tetracycline degradation , 2022, Journal of Cleaner Production.

[7]  Chongli Zhong,et al.  Surface modification of bilayer structure on metal-organic frameworks towards mixed matrix membranes for efficient propylene/propane separation , 2022, Journal of Membrane Science.

[8]  T. Tran,et al.  Occurrence, toxicity and adsorptive removal of the chloramphenicol antibiotic in water: a review , 2022, Environmental Chemistry Letters.

[9]  Ning Wang,et al.  MOF-derived double-shelled Fe(OH)3@NiCo-LDH hollow cubes and their efficient adsorption for anionic organic pollutant , 2022, Journal of Porous Materials.

[10]  Boya Liu,et al.  Unveiling the chemotactic response and mechanism of Shewanella oneidensis MR-1 to nitrobenzene. , 2022, Journal of hazardous materials.

[11]  Ashok Pandey,et al.  Organic wastes bioremediation and its changing prospects. , 2022, The Science of the total environment.

[12]  Yan Li,et al.  N-acyl-homoserine lactones in extracellular polymeric substances from sludge for enhanced chloramphenicol-degrading anode biofilm formation in microbial fuel cells. , 2021, Environmental research.

[13]  Bing Li,et al.  New insights into thiamphenicol biodegradation mechanism by Sphingomonas sp. CL5.1 deciphered through metabolic and proteomic analysis. , 2021, Journal of hazardous materials.

[14]  A. Abbasi,et al.  Improving the photocatalytic activity of NH2-UiO-66 by facile modification with Fe(acac)3 complex for photocatalytic water remediation under visible light illumination. , 2021, Journal of hazardous materials.

[15]  Wei-Hai Chen,et al.  A Self-Driven Bioreactor Based on Bacterium-Metal-Organic Framework Biohybrids for Boosting Chemotherapy via Cyclic Lactate Catabolism. , 2021, ACS nano.

[16]  Hengduo Xu,et al.  In situ fabrication of gold nanoparticles into biocathodes enhance chloramphenicol removal. , 2021, Bioelectrochemistry.

[17]  Yongtao Li,et al.  Biodegradation mechanism of chloramphenicol by Aeromonas media SZW3 and genome analysis. , 2021, Bioresource technology.

[18]  Guannan Zhou,et al.  Boosting photo-Fenton process enabled by ligand-to-cluster charge transfer excitations in iron-based metal organic framework , 2021, Applied Catalysis B: Environmental.

[19]  E. Mahmoudi,et al.  Effectiveness of Shewanella oneidensis bioaugmentation in the bioremediation of phenanthrene-contaminated sediments and possible consortia with omnivore-carnivore meiobenthic nematodes. , 2021, Environmental pollution.

[20]  Bin Huang,et al.  Photoelectrocatalytic coupling system synergistically removal of antibiotics and antibiotic resistant bacteria from aquatic environment. , 2021, Journal of hazardous materials.

[21]  Yan Li,et al.  Enhanced chloramphenicol-degrading biofilm formation in microbial fuel cells through a novel synchronous acclimation strategy , 2021 .

[22]  Paul S. Weiss,et al.  Silver nanoparticles boost charge-extraction efficiency in Shewanella microbial fuel cells , 2021, Science.

[23]  Peng Liu,et al.  Reduction of antimony mobility from Sb-rich smelting slag by Shewanella oneidensis: Integrated biosorption and precipitation. , 2021, Journal of hazardous materials.

[24]  Yunwei Wei,et al.  Rapid removal of chloramphenicol via the synergy of Geobacter and metal oxide nanoparticles. , 2021, Chemosphere.

[25]  Q. Yue,et al.  Removal of chloramphenicol by sulfide-modified nanoscale zero-valent iron activated persulfate: Performance, salt resistance, and reaction mechanisms. , 2021, Chemosphere.

[26]  Hanqing Yu,et al.  Enhanced Bioreduction of Radionuclides by Driving Microbial Extracellular Electron Pumping with an Engineered CRISPR Platform. , 2021, Environmental science & technology.

[27]  M. Sillanpää,et al.  Iron-based metal-organic framework: Synthesis, structure and current technologies for water reclamation with deep insight into framework integrity. , 2021, Chemosphere.

[28]  Jia-Cheng E. Yang,et al.  Magnetic CoFe2O4 nanocrystals derived from MIL-101 (Fe/Co) for peroxymonosulfate activation toward degradation of chloramphenicol. , 2021, Chemosphere.

[29]  E. Lichtfouse,et al.  Augmentation of chloramphenicol degradation by Geobacter-based biocatalysis and electric field. , 2020, Journal of hazardous materials.

[30]  Rui Miao,et al.  Stable Forward Osmosis Nanocomposite Membrane Doped with Sulfonated Graphene Oxide@Metal-Organic Frameworks for Heavy Metal Removal. , 2020, ACS applied materials & interfaces.

[31]  Hongwen Sun,et al.  Effects of biochar on biodegradation of sulfamethoxazole and chloramphenicol by Pseudomonas stutzeri and Shewanella putrefaciens: Microbial growth, fatty acids, and the expression quantity of genes. , 2020, Journal of hazardous materials.

[32]  Yongyou Hu,et al.  Application of a heavy metal-resistant Achromobacter sp. for the simultaneous immobilization of cadmium and degradation of sulfamethoxazole from wastewater. , 2020, Journal of hazardous materials.

[33]  Wenzong Liu,et al.  Insights into palladium nanoparticles produced by Shewanella oneidensis MR-1: roles of NADH dehydrogenases and hydrogenases. , 2020, Environmental research.

[34]  Wenhui Gan,et al.  Chloramphenicol biodegradation by enriched bacterial consortia and isolated strain Sphingomonas sp. CL5.1: The reconstruction of a novel biodegradation pathway. , 2020, Water research.

[35]  Simuck F. Yuk,et al.  Hydrogen Bonding Enhances the Electrochemical Hydrogenation of Benzaldehyde in the Aqueous Phase , 2020, Angewandte Chemie.

[36]  Yan Zhou,et al.  Direct interspecies electron transfer (DIET) can be suppressed under ammonia-stressed condition - Reevaluate the role of conductive materials. , 2020, Water research.

[37]  Xiaoyan Fan,et al.  Synergistic degradation of chloramphenicol by ultrasound-enhanced nanoscale zero-valent iron/persulfate treatment , 2020 .

[38]  Rowan D. Brackston,et al.  The route to transcription initiation determines the mode of transcriptional bursting in E. coli , 2020, Nature Communications.

[39]  Shuangjiang Liu,et al.  A novel pathway for chloramphenicol catabolism in the activated sludge bacterial isolate Sphingobium sp. CAP-1. , 2020, Environmental science & technology.

[40]  E. Feil,et al.  The role of stereochemistry of antibiotic agents in the development of antibiotic resistance in the environment. , 2020, Environment international.

[41]  M. Ellabaan,et al.  Dominant resistance and negative epistasis can limit the co-selection of de novo resistance mutations and antibiotic resistance genes , 2020, Nature Communications.

[42]  Lan Zhang,et al.  A Metal–Organic Framework Nanosheet‐Assembled Frame Film with High Permeability and Stability , 2020, Advanced science.

[43]  M. Govarthanan,et al.  Rapid biodegradation of chlorpyrifos by plant growth-promoting psychrophilic Shewanella sp. BT05: An eco-friendly approach to clean up pesticide-contaminated environment. , 2020, Chemosphere.

[44]  Wenjie Fu,et al.  High-efficiency biodegradation of chloramphenicol by enriched bacterial consortia: Kinetics study and bacterial community characterization. , 2020, Journal of hazardous materials.

[45]  L. T. Angenent,et al.  Aggregation-dependent electron transfer via redox-active biochar particles stimulate microbial ferrihydrite reduction. , 2019, The Science of the total environment.

[46]  D. R. Bond,et al.  Preventing Hydrogen Disposal Increases Electrode Utilization Efficiency by Shewanella oneidensis , 2019, Front. Energy Res..

[47]  A. Porto,et al.  Study of biodegradation of chloramphenicol by endophytic fungi isolated from Bertholletia excelsa (Brazil nuts) , 2019, Biocatalysis and Agricultural Biotechnology.

[48]  Brent A. Biddy,et al.  Discovery and Characterization of a Nitroreductase Capable of Conferring Bacterial Resistance to Chloramphenicol. , 2019, Cell chemical biology.

[49]  Fanghua Liu,et al.  Reductive degradation of chloramphenicol by Geobacter metallireducens , 2019, Science China Technological Sciences.

[50]  Hanqing Yu,et al.  Degradation of rhodamine B in a novel bio-photoelectric reductive system composed of Shewanella oneidensis MR-1 and Ag3PO4. , 2019, Environment international.

[51]  Ananda Kulal,et al.  Enzymatic degradation of chloramphenicol by laccase from Trametes hirsuta and comparison among mediators , 2019, International Biodeterioration & Biodegradation.

[52]  M. Xian,et al.  Electricigens in the anode of microbial fuel cells: pure cultures versus mixed communities , 2019, Microbial Cell Factories.

[53]  Christopher M. Dundas,et al.  Microbial reduction of metal-organic frameworks enables synergistic chromium removal , 2018, Nature Communications.

[54]  Bor-Yann Chen,et al.  Comparative assessment of azo dyes and nitroaromatic compounds reduction using indigenous dye-decolorizing bacteria , 2017 .

[55]  R. Rosal,et al.  Co, Zn and Ag-MOFs evaluation as biocidal materials towards photosynthetic organisms. , 2017, The Science of the total environment.

[56]  W. Arnold,et al.  Effect of nonreactive kaolinite on 4-chloronitrobenzene reduction by Fe(II) in goethite–kaolinite heterogeneous suspensions , 2017 .

[57]  Aijie Wang,et al.  Functional Characterization of a Novel Amidase Involved in Biotransformation of Triclocarban and its Dehalogenated Congeners in Ochrobactrum sp. TCC-2. , 2017, Environmental science & technology.

[58]  Jun Wang,et al.  Transcriptome and metabolome responses of Shewanella oneidensis MR-1 to methyl orange under microaerophilic and aerobic conditions , 2017, Applied Microbiology and Biotechnology.

[59]  Aijie Wang,et al.  Response of anodic bacterial community to the polarity inversion for chloramphenicol reduction. , 2016, Bioresource technology.

[60]  S. Krivovichev,et al.  Minerals with metal-organic framework structures , 2016, Science Advances.

[61]  N. Burroughs,et al.  Regulation of Gene Expression in Shewanella oneidensis MR-1 during Electron Acceptor Limitation and Bacterial Nanowire Formation , 2016, Applied and Environmental Microbiology.

[62]  Junliang Zhou,et al.  Adsorption behavior and mechanism of chloramphenicols, sulfonamides, and non-antibiotic pharmaceuticals on multi-walled carbon nanotubes. , 2016, Journal of hazardous materials.

[63]  Y. Li,et al.  Co-occurrence of Methanosarcina mazei and Geobacteraceae in an iron (III)-reducing enrichment culture , 2015, Front. Microbiol..

[64]  Dhrubajyoti D. Das,et al.  Complete genome sequence analysis of Pseudomonas aeruginosa N002 reveals its genetic adaptation for crude oil degradation. , 2015, Genomics.

[65]  Lei Jiang,et al.  Wettability-regulated extracellular electron transfer from the living organism of Shewanella loihica PV-4. , 2015, Angewandte Chemie.

[66]  Xiaocheng Jiang,et al.  Nanoparticle facilitated extracellular electron transfer in microbial fuel cells. , 2014, Nano letters.

[67]  R. Gennis,et al.  Subunit CydX of Escherichia coli cytochrome bd ubiquinol oxidase is essential for assembly and stability of the di‐heme active site , 2014, FEBS letters.

[68]  Jochen Blumberger,et al.  Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials , 2014, Proceedings of the National Academy of Sciences.

[69]  Ji-ti Zhou,et al.  Effects of redox mediators on azo dye decolorization by Shewanella algae under saline conditions. , 2014, Bioresource technology.

[70]  J. Lorquin,et al.  H2-dependent azoreduction by Shewanella oneidensis MR-1: involvement of secreted flavins and both [Ni–Fe] and [Fe–Fe] hydrogenases , 2014, Applied Microbiology and Biotechnology.

[71]  B. Cao,et al.  Reductive formation of palladium nanoparticles by Shewanella oneidensis: role of outer membrane cytochromes and hydrogenases , 2013 .

[72]  Bin Liang,et al.  Accelerated reduction of chlorinated nitroaromatic antibiotic chloramphenicol by biocathode. , 2013, Environmental science & technology.

[73]  Jianzhong Shen,et al.  Occurrence of chloramphenicol-resistance genes as environmental pollutants from swine feedlots. , 2013, Environmental science & technology.

[74]  L. Xiaoming,et al.  Isolation, identification and characterization of human intestinal bacteria with the ability to utilize chloramphenicol as the sole source of carbon and energy. , 2012, FEMS microbiology ecology.

[75]  S. Elliott,et al.  Mind the gap: diversity and reactivity relationships among multihaem cytochromes of the MtrA/DmsE family. , 2012, Biochemical Society transactions.

[76]  Largus T Angenent,et al.  Cathodes as electron donors for microbial metabolism: which extracellular electron transfer mechanisms are involved? , 2011, Bioresource technology.

[77]  Kazuya Watanabe,et al.  Disruption of the Putative Cell Surface Polysaccharide Biosynthesis Gene SO3177 in Shewanella oneidensis MR-1 Enhances Adhesion to Electrodes and Current Generation in Microbial Fuel Cells , 2010, Applied and Environmental Microbiology.

[78]  A. Bommarius,et al.  Nitroreductase from Salmonella typhimurium: characterization and catalytic activity. , 2010, Organic & biomolecular chemistry.

[79]  Qiang Wang,et al.  High-index faceted platinum nanocrystals supported on carbon black as highly efficient catalysts for ethanol electrooxidation. , 2010, Angewandte Chemie.

[80]  Paul C Mills,et al.  Characterization of an electron conduit between bacteria and the extracellular environment , 2009, Proceedings of the National Academy of Sciences.

[81]  D. Lowy,et al.  The role of 4-hydroxyphenylpyruvate dioxygenase in enhancement of solid-phase electron transfer by Shewanella oneidensis MR-1. , 2007, FEMS microbiology ecology.

[82]  E. J. Weber,et al.  Effect of natural organic matter on the reduction of nitroaromatics by Fe(II) species. , 2008, Environmental science & technology.

[83]  Samantha B. Reed,et al.  Hydrogenase- and outer membrane c-type cytochrome-facilitated reduction of technetium(VII) by Shewanella oneidensis MR-1. , 2007, Environmental microbiology.

[84]  Y. Takayama,et al.  Functional roles of the heme architecture and its environment in tetraheme cytochrome c. , 2007, Accounts of chemical research.

[85]  D. Newman,et al.  The pio Operon Is Essential for Phototrophic Fe(II) Oxidation in Rhodopseudomonas palustris TIE-1 , 2006, Journal of bacteriology.

[86]  A. Spormann,et al.  Hydrogen Metabolism in Shewanella oneidensis MR-1 , 2006, Applied and Environmental Microbiology.

[87]  M. Tien,et al.  In Vitro Enzymatic Reduction Kinetics of Mineral Oxides by Membrane Fractions from Shewanella oneidensis MR-1 , 2006 .

[88]  R. Schwarzenbach,et al.  Reduction of nitroaromatic compounds by Fe(II) species associated with iron-rich smectites. , 2006, Environmental science & technology.

[89]  Hong Liu,et al.  Production of electricity during wastewater treatment using a single chamber microbial fuel cell. , 2004, Environmental science & technology.

[90]  G. De Luca,et al.  Reduction of Technetium(VII) byDesulfovibrio fructosovorans Is Mediated by the Nickel-Iron Hydrogenase , 2001, Applied and Environmental Microbiology.

[91]  W. Antholine,et al.  Chromium(VI) reductase activity is associated with the cytoplasmic membrane of anaerobically grown Shewanella putrefaciens MR‐1 , 2000, Journal of applied microbiology.

[92]  A. Johnson,et al.  Site-directed mutagenesis of histidine-90 in Escherichia coli L-threonine dehydrogenase alters its substrate specificity. , 1998, Archives of biochemistry and biophysics.

[93]  S. Chapman,et al.  Sequence of the gene encoding flavocytochrome c from Shewanella putrefaciens: a tetraheme flavoenzyme that is a soluble fumarate reductase related to the membrane-bound enzymes from other bacteria. , 1992, Biochemistry.