A review on application of stable isotope probing combined with metagenomics in studying the biotransformation and degradation of environmental pollutants
ZHANG Huan-jun, ZHOU Jing-ya, LI Yi
Key Laboratory of Integrated Regulation and Resource Development of Shallow Lakes of Ministry of Education, College of Environment, Hohai University, Nanjing 210098, China
Abstract:The application of stable isotope probing (SIP) combined with metagenomics in the research of environmental pollutants biotransformation and degradation has gradually become a trend. This combined technology provides a culture-independent method to identify functional microbial community with specific metabolic activities and to reveal key metabolic pathways in complex environment, so it has significant advantages in studying in situ biotransformation and degradation of environmental pollutants. This review introduces the application of this combined technology in studying the biotransformation and degradation of hydrocarbons and their derivatives, pesticides, heavy metals and emerging contaminants in different environments, including identification of functional microbial community and mechanism of pollutants biotransformation and degradation. Finally, future prospect is presented based on the current application status of this combined technology. The combined technology associated with multiple approaches to in situ characterization will provide more accurate and comprehensive information for studying the mechanism of biotransformation and degradation of pollutants driven by microorganisms.
张焕军, 周晶雅, 李轶. 稳定同位素探针技术结合宏基因组学在探究环境污染物微生物转化/降解过程中的应用进展[J]. 中国环境科学, 2023, 43(6): 3173-3182.
ZHANG Huan-jun, ZHOU Jing-ya, LI Yi. A review on application of stable isotope probing combined with metagenomics in studying the biotransformation and degradation of environmental pollutants. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(6): 3173-3182.
Carabeo-Perez A, Guerra-Rivera G, Ramos-Leal M, et al. Metagenomic approaches:effective tools for monitoring the structure and functionality of microbiomes in anaerobic digestion systems[J]. Applied Microbiology and Biotechnology, 2019,103(23/24):9391-9391.
[2]
Boschker H T S, Nold S C, Wellsbury P, et al. Direct linking of microbial populations to specific biogeochemical processes by C-13-labelling of biomarkers[J]. Nature, 1998,392(6678):801-805.
[3]
Radajewski S, Ineson P, Parekh N R, et al. Stable-isotope probing as a tool in microbial ecology[J]. Nature, 2000,403(6770):646-649.
[4]
Manefield M, Whiteley A S, Griffiths R I, et al. RNA stable isotope probing, a novel means of linking microbial community function to phylogeny[J]. Applied and Environmental Microbiology, 2002,68 (11):5367-5373.
[5]
Handelsman J, Rondon M R, Brady S F, et al. Molecular biological access to the chemistry of unknown soil microbes:a new frontier for natural products[J]. Chemistry & Biology, 1998,5(10):R245-R249.
[6]
Tyson G W, Chapman J, Hugenholtz P, et al. Community structure and metabolism through reconstruction of microbial genomes from the environment[J]. Nature, 2004,428(6978):37-43.
[7]
Kalu C M, Ogola H J O, Selvarajan R, et al. Correlations between root metabolomics and bacterial community structures in the Phragmites australis under acid mine drainage-polluted wetland ecosystem[J]. Current Microbiology, 2022,79(1):34.
[8]
张光亚,方柏山.宏基因组——生物催化剂的新来源[J]. 生命的化学, 2005,25(4):278-281. Zhang G Y, Fang B S. Metagenome——a novel source for biocatalysts[J]. Chemistry of Life, 2005,25(4):278-281.
[9]
Ntougias S, Bourtzis K, Tsiamis G. The microbiology of olive mill wastes[J]. Biomed Research International, 2013,2013:784591.
[10]
Schmeisser C, Steele H, Streit W R. Metagenomics, biotechnology with non-culturable microbes[J]. Applied Microbiology and Biotechnology, 2007,75(5):955-962.
[11]
Lorenz P, Eck J. Metagenomics and industrial applications[J]. Nature Reviews Microbiology, 2005,3(6):510-516.
[12]
马海霞,张丽丽,孙晓萌,等.基于宏组学方法认识微生物群落及其功能[J]. 微生物学通报, 2015,42(5):902-912. Ma H X, Zhang L L, Sun X M, et al. Understanding microbial communities and their functions by meta-omics approaches[J]. Microbiology China, 2015,42(5):902-912.
[13]
Krober E, Eyice O. Profiling of active microorganisms by stable isotope probing-metagenomics[J]. Methods in Molecular Biology (Clifton, N.J.), 2019,2046:151-161.
[14]
Gabor E M, de Vries E J, Janssen D B. Construction, characterization, and use of small-insert gene banks of DNA isolated from soil and enrichment cultures for the recovery of novel amidases[J]. Environmental Microbiology, 2004,6(9):948-958.
[15]
Knietsch A, Bowien S, Whited G, et al. Identification and characterization of coenzyme B-12-dependent glycerol dehydratase-and diol dehydratase-encoding genes from metagenomic DNA libraries derived from enrichment cultures[J]. Applied and Environmental Microbiology, 2003,69(6):3048-3060.
[16]
Wackett L P. Stable isotope probing in biodegradation research[J]. Trends in Biotechnology, 2004,22(4):153-154.
[17]
Dumont M G, Murrell J C. Stable isotope probing-linking microbial identity to function[J]. Nature Reviews Microbiology, 2005,3(6):499-504.
[18]
Madsen E L. The use of stable isotope probing techniques in bioreactor and field studies on bioremediation[J]. Current Opinion in Biotechnology, 2006,17(1):92-97.
[19]
Megharaj M, Ramakrishnan B, Venkateswarlu K, et al. Bioremediation approaches for organic pollutants:a critical perspective[J]. Environment International, 2011,37(8):1362-1375.
[20]
Schloss P D, Handelsman J. Biotechnological prospects from metagenomics[J]. Current Opinion in Biotechnology, 2003,14(3):303-310.
[21]
Teng T T, Liang J D, Wu Z J. Identification of pyrene degraders via DNA-SIP in oilfield soil during natural attenuation, bioaugmentation and biostimulation[J]. Science of the Total Environment, 2021,800:149485.
[22]
Sauret C, Severin T, Vetion G, et al. 'Rare biosphere' bacteria as key phenanthrene degraders in coastal seawaters[J]. Environmental Pollution, 2014,194:246-253.
[23]
Rizoulis A, Al Lawati W M, Pancost R D, et al. Microbially mediated reduction of FeIII and AsV in Cambodian sediments amended with 13C-labelled hexadecane and kerogen[J]. Environmental Chemistry, 2014,11(5):538-546.
[24]
Song M K, Luo C L, Jiang L F, et al. Identification of Benzo[a]pyrene-metabolizing bacteria in forest soils by using DNA-based stable-isotope probing[J]. Applied and Environmental Microbiology, 2015,81(21):7368-7376.
[25]
Song M K, Jiang L F, Zhang D Y, et al. Bacteria capable of degrading anthracene, phenanthrene, and fluoranthene as revealed by DNA based stable-isotope probing in a forest soil[J]. Journal of Hazardous Materials, 2016,308:50-57.
[26]
Dumont M G, Radajewski S M, Miguez C B, et al. Identification of a complete methane monooxygenase operon from soil by combining stable isotope probing and metagenomic analysis[J]. Environmental Microbiology, 2006,8(7):1240-1250.
[27]
Wang Y, Chen Y, Zhou Q, et al. A culture-independent approach to unravel uncultured bacteria and functional genes in a complex microbial community[J]. Plos One, 2012,7(10):e47530.
[28]
Wilhelm R C, Hanson B T, Chandra S, et al. Community dynamics and functional characteristics of naphthalene-degrading populations in contaminated surface sediments and hypoxic/anoxic groundwater[J]. Environmental Microbiology, 2018,20(10):3543-3559.
[29]
Rochman F F, Sheremet A, Tamas I, et al. Benzene and naphthalene degrading bacterial communities in an oil sands tailings pond[J]. Frontiers in Microbiology, 2017,8:1845.
[30]
Chemerys A, Pelletier E, Cruaud C, et al. Characterization of novel polycyclic aromatic hydrocarbon dioxygenases from the bacterial metagenomic DNA of a contaminated soil[J]. Applied and Environmental Microbiology, 2014,80(21):6591-600.
[31]
Chen S C, Budhraja R, Adrian L, et al. Novel clades of soil biphenyl degraders revealed by integrating isotope probing, multi-omics, and single-cell analyses[J]. ISME Journal, 2021,15(12):3508-3521.
[32]
Chen S C, Duan G L, Ding K, et al. DNA stable-isotope probing identifies uncultivated members of Pseudonocardia associated with biodegradation of pyrene in agricultural soil[J]. Fems Microbiology Ecology, 2018,94(3):fiy026.
[33]
Mosbaek F, Kjeldal H, Mulat D G, et al. Identification of syntrophic acetate-oxidizing bacteria in anaerobic digesters by combined protein-based stable isotope probing and metagenomics[J]. ISME Journal, 2016,10(10):2405-2418.
[34]
Ziels R M, Sousa D Z, Stensel H D, et al. DNA-SIP based genome-centric metagenomics identifies key long-chain fatty acid-degrading populations in anaerobic digesters with different feeding frequencies[J]. ISME Journal, 2018,12(1):112-123.
[35]
Pacifico F, Harrison S P, Jones C D, et al. Isoprene emissions and climate[J]. Atmospheric Environment, 2009,43(39):6121-6135.
[36]
Carrion O, Gibson L, Elias D M O, et al. Diversity of isoprene-degrading bacteria in phyllosphere and soil communities from a high isoprene-emitting environment:a Malaysian oil palm plantation[J]. Microbiome, 2020,8(1):81.
[37]
Larke-Mejia N L, Crombie A T, Pratscher J, et al. Novel Isoprene-degrading proteobacteria from soil and leaves identified by cultivation and metagenomics analysis of stable isotope probing experiments[J]. Frontiers in Microbiology, 2019,10:2700.
[38]
Gibson L, Crombie A T, McNamara N P, et al. Isoprene-degrading bacteria associated with the phyllosphere of Salix fragilis, a high isoprene-emitting willow of the Northern Hemisphere[J]. Environmental Microbiome, 2021,16(1):17.
[39]
Crombie A T, Larke-Mejia N L, Emery H, et al. Poplar phyllosphere harbors disparate isoprene-degrading bacteria[J]. Proceedings of the National Academy of Sciences of the United States of America, 2018,115(51):13081-13086.
[40]
Gieg L M, Fowler S J, Berdugo-Clavijo C. Syntrophic biodegradation of hydrocarbon contaminants[J]. Current Opinion in Biotechnology, 2014,27:21-29.
[41]
Harindintwali J D, Xiang L L, Wang F, et al. Syntrophy of bacteria and archaea in the anaerobic catabolism of hydrocarbon contaminants[J]. Critical Reviews in Environmental Science and Technology, 2022, 53(13):1331-1357.
[42]
Leigh M B, Pellizari V H, Uhlik O, et al. Biphenyl-utilizing bacteria and their functional genes in a pine root zone contaminated with polychlorinated biphenyls (PCBs)[J]. ISME Journal, 2007,1(2):134-148.
[43]
Wang J, Yao H Y. Applications of DNA/RNA-stable isotope probing (SIP) in environmental microbiology[J]. Methods in Microbiology, 2021,48:227-267.
[44]
Mason O U, Hazen T C, Borglin S, et al. Metagenome, metatranscriptome and single-cell sequencing reveal microbial response to Deepwater Horizon oil spill[J]. ISME Journal, 2012, 6(9):1715-1727.
[45]
Marozava S, Mouttaki H, Muller H, et al. Anaerobic degradation of 1-methylnaphthalene by a member of the Thermoanaerobacteraceae contained in an iron-reducing enrichment culture[J]. Biodegradation, 2018,29(1):23-39.
[46]
Toth C R A, Berdugo-Clavijo C, O'Farrell C M, et al. Stable isotope and metagenomic profiling of a methanogenic naphthalene-degrading enrichment culture[J]. Microorganisms, 2018,6(3):65.
[47]
Thomas F, Corre E, Cebron A. Stable isotope probing and metagenomics highlight the effect of plants on uncultured phenanthrene-degrading bacterial consortium in polluted soil[J]. ISME Journal, 2019,13(7):1814-1830.
[48]
Kroeber E, Wende S, Kanukollu S, et al. 13C-chloromethane incubations provide evidence for novel bacterial chloromethane degraders in a living tree fern[J]. Environmental Microbiology, 2021, 23(8):4450-4465.
[49]
赵 玲,滕 应,骆永明.中国农田土壤农药污染现状和防控对策[J]. 土壤, 2017,49(3):417-427. Zhao L, Teng Y, Luo Y M. Present pollution status and control strategy of pesticides in agricultural soils in China:a review[J]. Soils, 2017,49(3):417-427.
[50]
Damalas C A, Eleftherohorinos I G. Pesticide exposure, safety issues, and risk assessment indicators[J]. International Journal of Environmental Research and Public Health, 2011,8(5):1402-1419.
[51]
Bose S, Kumar P S, Vo D-V N, et al. Microbial degradation of recalcitrant pesticides:a review[J]. Environmental Chemistry Letters, 2021,19(4):3209-3228.
[52]
Doolotkeldieva T, Konurbaeva M, Bobusheva S. Microbial communities in pesticide-contaminated soils in Kyrgyzstan and bioremediation possibilities[J]. Environmental Science and Pollution Research, 2018,25(32):31848-31862.
[53]
Finley S D, Broadbelt L J, Hatzimanikatis V. In silico feasibility of novel biodegradation pathways for 1,2,4-trichlorobenzene[J]. BMC Systems Biology, 2010,4:7.
[54]
Hu S L, Liu G P, Zhang L, et al. A synergistic consortium involved in rac-dichlorprop degradation as revealed by DNA stable isotope probing and metagenomic analysis[J]. Applied and Environmental Microbiology, 2021,87(22):e01562-21.
[55]
Hou J Y, Zhang Y, Wu X H, et al. Zero-valent iron-induced successive chemical transformation and biodegradation of lindane in historically contaminated soil:an isotope-informed metagenomic study[J]. Journal of Hazardous Materials, 2022,433:128802.
[56]
Vasileiadis S, Perruchon C, Scheer B, et al. Nutritional inter-dependencies and a carbazole-dioxygenase are key elements of a bacterial consortium relying on a Sphingomonas for the degradation of the fungicide thiabendazole[J]. Environmental Microbiology, 2022, 24(11):5105-5122.
[57]
Sarma H, Joshi S J. Metagenomics combined with stable isotope probe (SIP) for the discovery of novel dehalogenases producing bacteria[J]. Bulletin of Environmental Contamination and Toxicology, 2022, 108(3):478-484.
[58]
刘 颖.微生物在重金属污染土壤修复中的作用研究[J]. 化工设计通讯, 2021,47(10):196-197. Liu Y. Study on the role of microorganisms in the remediation of heavy metal contaminated soil[J]. Chemical Engineering Design Communications, 2021,47(10):196-197.
[59]
Griffiths B S, Philippot L. Insights into the resistance and resilience of the soil microbial community[J]. Fems Microbiology Reviews, 2013, 37(2):112-129.
[60]
Pratush A, Kumar A, Hu Z. Adverse effect of heavy metals (As, Pb, Hg, and Cr) on health and their bioremediation strategies:a review[J]. International Microbiology, 2018,21(3):97-106.
[61]
Zhang M M, Li Z, Häggblom M M, et al. Characterization of nitrate-dependent As(III)-oxidizing communities in arsenic-contaminated soil and investigation of their metabolic potentials by the combination of DNA-stable isotope probing and metagenomics[J]. Environmental Science & Technology, 2020,54(12):7366-7377.
[62]
Xu R, Huang D Y, Sun X X, et al. Diversity and metabolic potentials of As(III)-oxidizing bacteria in activated sludge[J]. Applied and Environmental Microbiology, 2021,87(23):e01769-21.
[63]
Zhang M M, Li Z, Haggblom M M, et al. Bacteria responsible for nitrate-dependent antimonite oxidation in antimony-contaminated paddy soil revealed by the combination of DNA-SIP and metagenomics[J]. Soil Biology & Biochemistry, 2021,156:108194.
[64]
Zhang M M, Kolton M, Li Z, et al. Bacteria responsible for antimonite oxidation in antimony-contaminated soil revealed by DNA-SIP coupled to metagenomics[J]. Fems Microbiology Ecology, 2021, 97(5):fiab057.
[65]
Sun W M, Sun X X, Haggblom M M, et al. Identification of antimonate reducing bacteria and their potential metabolic traits by the combination of stable isotope probing and metagenomic-pangenomic analysis[J]. Environmental Science & Technology, 2021,55(20):13902-13912.
[66]
Yan G, Sun X X, Dong Y R, et al. Vanadate reducing bacteria and archaea may use different mechanisms to reduce vanadate in vanadium contaminated riverine ecosystems as revealed by the combination of DNA-SIP and metagenomic-binning[J]. Water Research, 2022,226:119247.
[67]
Macedo W V, Poulsen J S, Zaiat M, et al. Proteogenomics identification of TBBPA degraders in anaerobic bioreactor[J]. Environmental Pollution, 2022,310:119786.
[68]
Ouyang W Y, Su J Q, Richnow H H, et al. Identification of dominant sulfamethoxazole-degraders in pig farm-impacted soil by DNA and protein stable isotope probing[J]. Environment International, 2019, 126:118-126.
[69]
Chen J F, Yang Y Y, Ke Y C, et al. Sulfonamide-metabolizing microorganisms and mechanisms in antibiotic-contaminated wetland sediments revealed by stable isotope probing and metagenomics[J]. Environment International, 2022,165:107332.
[70]
Chen J F, Yang Y Y, Ke Y C, et al. Anaerobic sulfamethoxazole-degrading bacterial consortia in antibiotic-contaminated wetland sediments identified by DNA-stable isotope probing and metagenomics analysis[J]. Environmental Microbiology, 2022,24(8):3751-3763.
[71]
Dai H H, Gao J F, Li D C, et al. Metagenomics combined with DNA-based stable isotope probing provide comprehensive insights of active triclosan-degrading bacteria in wastewater treatment[J]. Journal of Hazardous Materials, 2021,404(Pt B):124192.
[72]
Kasanke C P, Collins R E, Leigh M B. Identification and characterization of a dominant sulfolane-degrading Rhodoferax sp. via stable isotope probing combined with metagenomics[J]. Scientific Reports, 2019,9:3121.
[73]
Uhlik O, Leewis M-C, Strejcek M, et al. Stable isotope probing in the metagenomics era:a bridge towards improved bioremediation[J]. Biotechnology Advances, 2013,31(2):154-165.
[74]
Chen Y, Murrell J C. When metagenomics meets stable-isotope probing:progress and perspectives[J]. Trends in Microbiology, 2010, 18(4):157-163.
[75]
陈松灿,段桂兰,朱永官.多环芳烃(PAHs)微生物降解的原位表征方法[J]. 中国细胞生物学学报, 2015,37(2):168-177. Chen S C, Duan G L, Zhu Y G. Approaches to in situ characterization of microbial degradation of polycyclic aromatic hydrocarbons(PAHs)[J]. Chinese Journal of Cell Biology, 2015,37(2):168-177.
[76]
陈亚婷,姜 博,邢 奕,等.基于非培养手段的多环芳烃降解微生物解析[J]. 中国环境科学, 2018,38(9):3562-3575. Chen Y T, Jiang B, Xing Y, et al. Identification and characterization on PAHs-degrading microorganisms via cultivation-independent approaches[J]. China Environmental Science, 2018,38(9):3562-3575.
[77]
Li T L, Wu T D, Mazeas L, et al. Simultaneous analysis of microbial identity and function using NanoSIMS[J]. Environmental Microbiology, 2008,10(3):580-588.
[78]
Boxer S G, Kraft M L, Weber P K. Advances in imaging secondary ion mass spectrometry for biological samples[J]. Annual Review of Biophysics, 2009,38:53-74.
[79]
Huang W E, Stoecker K, Griffiths R, et al. Raman-FISH:combining stable-isotope Raman spectroscopy and fluorescence in situ hybridization for the single cell analysis of identity and function[J]. Environmental Microbiology, 2007,9(8):1878-1889.
[80]
李 莹,吴兴杰,贺治斌,等.宏转录组学在环境微生物生态学中的应用[J]. 中国环境科学, 2021,41(9):4341-4348. Li Y, Wu X J, He Z B, et al. Application of metatranscriptomics in environmental microbial ecology[J]. China Environmental Science, 2021,41(9):4341-4348.
[81]
Harrington E D, Singh A H, Doerks T, et al. Quantitative assessment of protein function prediction from metagenomics shotgun sequences[J]. Proceedings of the National Academy of Sciences of the United States of America, 2007,104(35):13913-13918.
[82]
Oulas A, Pavloudi C, Polymenakou P, et al. Metagenomics:tools and insights for analyzing next-generation sequencing data derived from biodiversity studies[J]. Bioinformatics and Biology Insights, 2015, 9:75-88.
