光催化耦合生物反应器降解抗生素效能及抗生素抗性基因消长机制研究进展

葛欣玥; 刘啟迪; 刘思远; 侯俊; 尤国祥

doi:10.13205/j.hjgc.202407001

光催化耦合生物反应器降解抗生素效能及抗生素抗性基因消长机制研究进展

doi: 10.13205/j.hjgc.202407001

1. 河海大学环境学院浅水湖泊综合治理与资源开发教育部重点实验室, 南京 210024;
2. 南京大学环境学院污染控制与资源化研究国家重点实验室, 南京 210023

基金项目:

国家自然科学基金项目(42107386,42377378)

详细信息

作者简介:
葛欣玥(2001-),女,硕士研究生,主要研究方向为水污染控制与风险识别。gexinyue0607@smail.nju.edu.cn

通讯作者:
尤国祥(1990-),男,副教授,主要研究方向为水污染控制与生态修复。env_ygx@hhu.edu.cn

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- 被引次数: 0
出版历程
- 收稿日期: 2023-10-17
- 网络出版日期: 2024-12-02

REVIEW OF ANTIBIOTIC DEGRADATION EFFICACY AND EVOLUTION MECHANISM OF ANTIBIOTIC RESISTANCE GENES IN ICPB REACTORS

1. Key Laboratory of Integrated Regulation and Resources Development on Shallow Lakes of Ministry of Education, College of Environment, Hohai University, Nanjing 210024, China;
2. State Key Laboratory of Pollution Control and Resource Reuse, College of Environment, Nanjing University, Nanjing 210023, China

摘要

摘要: 近年来,抗生素的广泛使用导致环境中抗生素污染和耐药性问题愈发突出,对生态环境安全构成严重威胁。在抗生素降解的过程中,传统的单一化学或者生物处理工艺具有高能耗、低效率的缺点,而光催化耦合微生物技术(ICPB)可实现抗生素的高效降解和矿化,受到广泛关注。通过总结ICPB反应器降解抗生素的效能及影响因素,对其中抗生素的降解过程及微生物群落的演替特征进行综述,并深入分析抗性基因(ARGs)的赋存特征和演变机制。结果表明:目前ICPB反应器已被证明在降解抗生素方面有着优异的性能,反应器中微生物群落结构和细胞生理代谢功能发生了适应性调整,从而导致了ARGs的消长。建议持续加强ICPB反应器中ARGs消长机制和调控技术的研究,为研发高效去除抗生素协同ARGs削减工艺提供理论支撑和技术支持。
- 新型光催化生物反应器 /
- 耐药性 /
- 微生物群落 /
- 适应性响应 /
- 消长变化
Abstract: In recent years, the extensive use of antibiotics has led to increasingly prominent problems of antibiotic contamination and resistance in the environment, posing a serious threat to ecological security. During the degradation of antibiotics, traditional single chemical or biological treatment processes have the disadvantages of high energy consumption and low efficiency, while intimately coupled photocatalysis and biodegradation (ICPB) can achieve efficient degradation and complete mineralization of antibiotics. In this review, the efficiency and influencing factors of antibiotic degradation in ICPB reactors were summarized to review the antibiotic degradation process and microbial community succession characteristics. Furthermore, the assignment characteristics and evolution mechanism of ARGs in ICPB reactors were analyzed. The results showed that the ICPB reactors have been proven to have excellent performance in degrading antibiotics, and the microbial community structure and cell physiological and metabolic functions in the reactors have been undergoing adaptive adjustments, which led to the evolution and flow of ARGs. It is recommended to strengthen the research of ARGs in the ICPB reactors to provide theoretical and technical support for the development of processes for efficient removal of antibiotics and ARGs.
- novel photocatalytic bioreactors /
- antibiotic resistance /
- microbial community /
- adaptive response /
- dynamic changes

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参考文献(64)

[1]	周海东, 黄丽萍, 陈晓萌, 等.人工生态系统对城市河流中抗生素和ARGs的去除[J]. 环境科学, 2021, 42(2):850-859.
[2]	PRUDEN A, PEI R, STORTEBOOM H, et al. Antibiotic resistance genes as emerging contaminants: studies in northern Colorado[J]. Environmental Science & Technology, 2006, 40(23):7445-7450.
[3]	LIN Z B, YUAN T, ZHOU L, et al. Impact factors of the accumulation, migration and spread of antibiotic resistance in the environment[J]. Environmental Geochemistry and Health, 2020, 43(5):1741-1758.
[4]	CZEKALSK N, BERTHOLD T, CAUCCI S, et al. Increased levels of multiresistant bacteria and resistance genes after wastewater treatment and their dissemination into Lake Geneva, Switzerland[J]. Frontiers in Microbiology, 2012, 3:106.
[5]	王依琳, 张蕊, 张强英, 等.污水中抗生素的分布、来源及去除研究进展[J]. 再生资源与循环经济, 2022, 15(3):36-41.
[6]	周瑞飞, 王少坡, 常晶, 等.水中抗生素污染现状及高级氧化技术研究进展[J]. 天津城建大学学报, 2021, 27(5):356-362.
[7]	ZHANG H J, YU Y N, LI Y, et al. A novel BC/g-C₃N₄ porous hydrogel carrier used in intimately coupled photocatalysis and biodegradation system for efficient removal of tetracycline hydrochloride in water[J]. Chemosphere, 2023, 317:137888.
[8]	张昱, 冯皓迪, 唐妹, 等.β-内酰胺类抗生素的环境行为与制药行业源头控制技术研究进展[J]. 环境工程学报, 2020, 14(8):1993-2010.
[9]	WAGHMODE T R, KURADE M B, SAPKAL R T, et al. Sequential photocatalysis and biological treatment for the enhanced degradation of the persistent azo dye methyl red[J]. J Hazard Mater, 2019, 371: 115-122.
[10]	MARSOLEK M D, TORRES C I, HAUSNER M, et al. Intimate coupling of photocatalysis and biodegradation in a photocatalytic circulating-bed biofilm reactor[J]. Biotechnology and Bioengineering, 2008, 101(1):83-92.
[11]	郭雲.光催化与生物降解近场耦合协同作用强化方法与机制[D]. 吉林:吉林大学, 2020.
[12]	徐政雪.光催化与生物降解直接耦合体系的优化及共代谢调控[D]. 吉林:吉林大学, 2016.
[13]	DONG Y L, XU D Y, ZHANG J, et al. Enhanced antibiotic wastewater degradation by intimately coupled B-Bi₃O₄Cl photocatalysis and biodegradation reactor: elucidating degradation principle systematically[J]. Journal of Hazardous Materials, 2022, 445:130364.
[14]	MA D M, ZOU D L, ZHOU D D, et al. Phenol removal and biofilm response in coupling of visible-light-driven photocatalysis and biodegradation: effect of hydrothermal treatment temperature[J]. International Biodeterioration & Biodegradation, 2015, 104:178-185.
[15]	VINAYAK V, KHAN M J, VARJANI S, et al. Microbial fuel cells for remediation of environmental pollutants and value addition: special focus on coupling diatom microbial fuel cells with photocatalytic and photoelectric fuel cells[J]. Journal of Biotechnology, 2021, 338:5-19.
[16]	刘璐, 林慕雪, 张新颖, 等.ICPB体系降解水体污染物的研究进展[J]. 能源与环境, 2021(5):68-70.
[17]	MA Y, XIONG H F, ZHAO Z Q, et al. Model-based evaluation of tetracycline hydrochloride removal and mineralization in an intimately coupled photocatalysis and biodegradation reactor[J]. Chemical Engineering Journal, 2018, 351:967-975.
[18]	XIONG H F, ZOU D L, ZHOU D D, et al. Enhancing degradation and mineralization of tetracycline using intimately coupled photocatalysis and biodegradation (ICPB)[J]. Chemical Engineering Journal, 2017, 316:7-14.
[19]	MARSOLEK M D, RITTMANN B E. Effect of substrate characteristics on microbial community structure, function, resistance, and resilience; application to coupled photocatalytic-biological treatment[J]. Water Research, 2016, 90:1-8.
[20]	ZHOU X Y, XIONG W, LI Y, et al. A novel simultaneous coupling of memory photocatalysts and microbial communities for alternate removal of dimethyl phthalate and nitrate in water under light/dark cycles[J]. Journal of Hazardous Materials, 2022, 430:128395.
[21]	DING R, YAN W F, WU Y, et al. Light-excited photoelectrons coupled with bio-photocatalysis enhanced the degradation efficiency of oxytetracyclin[J]. Water Research, 2018, 143:589-598.
[22]	LIU Q D, HOU J, WU J, et al. Intimately coupled photocatalysis and biodegradation for effective simultaneous removal of sulfamethoxazole and COD from synthetic domestic wastewater[J]. Journal of Hazardous Materials, 2022, 423:127063.
[23]	PAN L S, WAN Z, FENG Q L, et al. Biofilm response and removal via the coupling of visible-light-driven photocatalysis and biodegradation in an environment of sulfamethoxazole and Cr(Ⅵ)[J]. Journal of Environmental Sciences, 2022, 122(12): 50-61.
[24]	袁吉林.基于光生物催化的四环素废水降解及转化性能研究[D]. 重庆:重庆理工大学, 2022.
[25]	WANG Y, QIU H, NIU H, et al. Effect and mechanism of simultaneous cadmium-tetracycline removal by a self-assembled microbial-photocatalytic coupling system[J]. Journal of Hazardous Materials, 2023, 449:131018.
[26]	WANG Y, CHEN C L, ZHOU D D, et al. Eliminating partial-transformation products and mitigating residual toxicity of amoxicillin through intimately coupled photocatalysis and biodegradation[J]. Chemosphere, 2019, 237:124491.
[27]	REYES C, FERNANDEZ J, FREER J, et al. Degradation and inactivation of tetracycline by TiO₂ photocatalysis[J]. Journal of Photochemistry & Photobiology, A: Chemistry, 2006, 184(1):141-146.
[28]	晋春虹.四环素类抗生素的去除技术研究进展与展望[J]. 山东化工, 2022, 51(18):102-106.
[29]	YANG P, YE Y X, YAN Z D, et al. Efficient removal of tetracycline in water by a novel chemical and biological coupled system with non-woven cotton fabric as carrier[J]. Chinese Chemical Letters, 2021, 32(9):2823-2827.
[30]	LI F Q, LAN X F, WANG L L, et al. An efficient photocatalyst coating strategy for intimately coupled photocatalysis and biodegradation (ICPB): powder spraying method[J]. Chemical Engineering Journal, 2020, 383:123092.
[31]	GUO Y, DONG S S, ZHOU D D. Optimization of the photocatalyst coating and operating conditions in an intimately coupled photocatalysis and biodegradation reactor: towards stable and efficient performance[J]. Environmental Research, 2022, 204:111971.
[32]	LI F Q, LAN X F, SHI J S, et al. Loofah sponge as an environment-friendly biocarrier for intimately coupled photocatalysis and biodegradation (ICPB)[J]. Journal of Water Process Engineering, 2021, 40:101965.
[33]	DAS S, GHOSH S, MISRA A J, et al. Sunlight assisted photocatalytic degradation of ciprofloxacin in water using Fe doped ZnO nanoparticles for potential public health applications[J]. International Journal of Environmental Research and Public Health, 2018, 15(11):2440.
[34]	ZHOU X T, XI H P, LI C M, et al. Ultrasmall Ag species decorated on α-Fe₂O₃ nanorods toward high-efficient photocatalytic degrading tetracycline hydrochloride in water[J]. Journal of the Chinese Chemical Society, 2021, 68(6):1013-1019.
[35]	XIONG H F, DONG S S, ZAHNG J, et al. Roles of an easily biodegradable co-substrate in enhancing tetracycline treatment in an intimately coupled photocatalytic-biological reactor[J]. Water Research, 2018, 136:75-83.
[36]	张智博, 董怡琳, 李静超, 等.可见光光催化-生物法直接耦合降解环丙沙星废水的行为及生物响应机制[J]. 环境工程, 2023, 41(4): 18-25.
[37]	LIU Q D, HOU J, ZENG Y, et al. Fabrication of an intimately coupled photocatalysis and biofilm system for removing sulfamethoxazole from wastewater: effectiveness, degradation pathway and microbial community analysis[J]. Chemosphere, 2023, 328: 138507.
[38]	LI J Y, DU Q P, PENG H Q, et al. Spectroscopic investigation of the interaction between extracellular polymeric substances and tetracycline during sorption onto anaerobic ammonium-oxidising sludge[J]. Environmental Technology, 2019, 42(11):1787-1797.
[39]	SATHISHKUMAR K, KANNAN V R, ALSALHI M S, et al. Intimately coupled gC₃N₄ photocatalysis and mixed culture biofilm enhanced detoxification of sulfamethoxazole: elucidating degradation mechanism and toxicity assessment[J]. Environmental Research, 2022, 214:113824.
[40]	WANG Y, FAN H, WONG P K, et al. Biodegradation of tetracycline using hybrid material (UCPs-TiO₂) coupled with biofilms under visible light[J]. Bioresource Technology, 2020, 323:124638.
[41]	SATHISHKUMAR K, LI Y, ALSALHI M S, et al. Enhanced biological nitrate removal by gC₃N₄/TiO₂ composite and role of extracellular polymeric substances[J]. Environmental Research, 2021, 207:112158.
[42]	XIAO Y, ZHANG E H, ZHANG J D, et al. Extracellular polymeric substances are transient media for microbial extracellular electron transfer[J]. Science Advances, 2017, 3(7): e1700623.
[43]	JIA C Y, LI P J, LI X J, et al. Degradation of pyrene in soils by extracellular polymeric substances (EPS) extracted from liquid cultures[J]. Process Biochemistry, 2011, 46(8):1627-1631.
[44]	NIMSE S B, PAL D. Free radicals, natural antioxidants, and their reaction mechanisms[J]. RSC Advances, 2015, 5(35):27986-28006.
[45]	SU J Q, WEI B, OU-YANG W Y, et al. Antibiotic resistome and its association with bacterial communities during sewage sludge composting[J]. Environmental Science & Technology, 2015, 49(12):7356-7363.
[46]	ZHANG J Y, YANG M, ZHOUG H, et al. Deciphering the factors influencing the discrepant fate of antibiotic resistance genes in sludge and water phases during municipal wastewater treatment[J]. Bioresource Technology, 2018, 265:310-319.
[47]	CAI Q Q, HU J Y. Effect of UVA/LED/TiO₂ photocatalysis treated sulfamethoxazole and trimethoprim containing wastewater on antibiotic resistance development in sequencing batch reactors[J]. Water Research, 2018, 140:251-260.
[48]	吉昊.亚致死光催化对水体环境中典型耐药细菌的耐药基因水平转移机理研究[D]. 广州:广东工业大学, 2022.
[49]	LIAO J Q, HUANG H N, CHEN Y G. CO₂ promotes the conjugative transfer of multiresistance genes by facilitating cellular contact and plasmid transfer[J]. Environment International, 2019, 129:333-342.
[50]	YIN H L, LI G Y, CHEN X F, et al. Accelerated evolution of bacterial antibiotic resistance through early emerged stress responses driven by photocatalytic oxidation[J]. Applied Catalysis B: Environmental, 2020, 269:118829.
[51]	LEE J H, LEE K L, YEO W S, et al. SoxRS-mediated lipopolysaccharide modification enhances resistance against multiple drugs in Escherichia col[J]. Journal of Bacteriology, 2009, 191(13):4441-4450.
[52]	黄璐璐, 谷宇锋, 吴翠蓉, 等.细菌的应激反应和生理代谢与耐药性及其控制策略[J]. 生物工程学报, 2020, 36(11): 2287-2297.
[53]	POOLE K. Bacterial stress responses as determinants of antimicrobial resistance[J]. The Journal of Antimicrobial Chemotherapy, 2012, 67(9):2069-2089.
[54]	SHI X D, XIA Y, WEI W, et al. Accelerated spread of antibiotic resistance genes (ARGs) induced by non-antibiotic conditions: roles and mechanisms[J]. Water Research, 2022, 224:119060.
[55]	ZHANG Y, GU A Z, CEN T Y, et al. Sub-inhibitory concentrations of heavy metals facilitate the horizontal transfer of plasmid-mediated antibiotic resistance genes in water environment[J]. Environmental Pollution, 2018, 237:74-82.
[56]	BEABER J W, HOCHHUT B, WALDOR M K. SOS response promotes horizontal dissemination of antibiotic resistance genes[J]. Nature, 2004, 427(6969):72-74.
[57]	ENGEMANN C A, ADAMS L, KNAPP C W, et al. Disappearance of oxytetracycline resistance genes in aquatic systems[J]. FEMS microbiology letters, 2006, 263(2):176-182.
[58]	王佳豪, 田湉, 李家成, 等.光化学AOPs去除水中抗生素抗性菌和抗性基因研究进展[J]. 精细化工, 2021, 38(5): 889-897.
[59]	苗荪, 陈磊, 左剑恶.环境中抗生素抗性基因丰度与抗生素和重金属含量的相关性分析:基于Web of Science数据库检索[J]. 环境科学, 2021, 42(10): 4925-4932.
[60]	KOHANSKI M A, DEPRISTO M A, COLLINS J J. Sublethal antibiotic treatment leads to multidrug resistance via radical-induced mutagenesis[J]. Molecular Cell, 2010, 37(3):311-320.
[61]	赖晓琳, 吴平霄, 阮博.四环素对大肠杆菌抗生素抗性基因进化的影响[J]. 环境科学学报, 2019, 39(8): 2475-2482.
[62]	KANG F X, HU X J, LIU J, et al. Noncovalent binding of polycyclic aromatic hydrocarbons with genetic bases reducing the in vitro lateral transfer of antibiotic resistant genes[J]. Environmental Science & Technology, 2015, 49(17):10340-10348.
[63]	SHOU W J, KANG F X, HUANG S H, et al. Substituted aromatic-facilitated dissemination of mobile antibiotic resistance genes via an antihydrolysis mechanism across an extracellular polymeric substance permeable barrier[J]. Environmental Science & Technology, 2019, 53(2):604-613.
[64]	LU J, WANG Y, LI J, et al. Triclosan at environmentally relevant concentrations promotes horizontal transfer of multidrug resistance genes within and across bacterial genera[J]. Environment International, 2018, 121:1217-1226.