马黎萍

2012-2016      香港大学 环境工程  博士 （师从张彤教授）

2010-2012      南京大学 环境科学  硕士（师从张徐祥教授）

2006-2010     南京大学 环境科学  学士

2006-2010     南京大学 管理学   第二学士

2024年1月至今      华东师范大学  教授

2019年1月-2023年12月  华东师范大学  研究员

2016年1月-2019年1月         香港大学              博士后

Environmental Technology & Innovation 编委，mLife青年编委；

Microbiome, Environmental Science & Technology, Water Research, Chemosphere, FEMS Microbiology Ecology, Environmental Research, Ecotoxicology, Ecological Engineering, Scientific reports 等期刊审稿人

基于环境生物学、微生物技术与生物信息学交叉学科研究：

1. 新兴环境污染物抗生素抗性基因在环境中的赋存与归趋；

2. 水处理工艺对新兴污染物的去除效率研究；

3. 饮用水管网微生物及其健康效应评价；

4. 有机固废厌氧消化微生物代谢机理研究；

5. 微生物功能基因挖掘与数据库开发。

我们热忱欢迎有志于从事相关研究的同学报考硕士博士研究生，或申请博士后和专职科研职位(详见“‍‍‍‍研究助理招聘信息‍‍‍‍”和“博士后招聘信息”)；同时也非常欢迎有兴趣从事相关研究的本科同学与我们联系。

《环境工程专业英语》

《环境与健康》

《生态规划与管理》

承担项目

1. 国家自然科学基金面上项目(2025-2028)，负责；

2. 国家重点研发计划“固废资源化”子课题(2020-2023)，负责；

3. 上海市高校特聘教授（东方学者）(2019-2022)，负责；

4. 国家自然科学基金青年项目(2020-2022)，负责；

5. 上海市浦江人才计划A类(2019-2021)，负责；

6. 华东师范大学基础创新科研项目(2019-2020)，负责；

7. 华东师范大学紫江青年学者启动项目(2019-2025)，负责；

8. 国家重点研发计划“深渊生物资源专项”(2018-2021)，参与。

目前已在The ISME Journal, Microbiome, Environmental Science & Technology, Water Research, Journal of Hazardous Materials, Bioresource Technology, Bioinformatics 等学术期刊上发表论文50余篇，谷歌引用次数 6100余次，h指数32。

[52] XX Zhang, X-X Zhang, L Ma* (2024) New Horizons in Micro/nanoplastic-induced Oxidative Stress: Overlooked Free Radical Contributions and Microbial Metabolic Dysregulations in Anaerobic Digestion. Environmental Science & Technology, 58:21251-21264.

[51] PB Jiao, Y Zhou, XX Zhang, HH Jian, X-X Zhang, L Ma* (2024) Mechanisms of Horizontal Gene Transfer and Viral Contribution to the Fate of Intracellular and Extracellular Antibiotic Resistance Genes in Anaerobic Digestion Supplemented with Conductive Materials under Ammonia Stress. Water Research, 267:122549.

[50] HF Liu, PB Jiao, L Guan, X-X Zhang, L Ma* (2024) Functional Traits and Health Implications of the Global Household Drinking-water Microbiome Retrieved using an Integrative Genome-centric Approach. Water Research, 250:121094.

[49] XX Zhang, YW Wang, PB Jiao, M Zhang, Y Deng, CY Jiang, X-W Liu, LP Lou, YM Li, X-X Zhang, L Ma* (2024) Microbiome-functionality in Anaerobic Digesters: A critical review. Water Research, 249:120891.

[48] J Zhang, Z Xu*, W Chu*, ‍L Ma, H He, W Jin, C Fang (2024) Optimizing the Placement of Medical Wastewater Outlets in Sewer Systems to Reduce Chemical Consumption at Wastewater Treatment Plants. Water Research, 264:122205.

[47] XX Zhang, L Ma*, X-X Zhang (2024) Neglected Risks of Enhanced Antimicrobial Resistance and Pathogenicity in Anaerobic Digestion during Transition from Thermophilic to Mesophilic. Journal of Hazardous Materials, 475:134886.

[46] XX Zhang, PB Jiao, YW Wang, YY Dai, M Zhang, P Wu*, L Ma* (2024) Optimizing Anaerobic Digestion: Benefits of Mild Temperature Transition from Thermophilic to Mesophilic Conditions. Environmental Science and Ecotechnology, 21:100440.

[45] C Wang, HY Yang, HF Liu, X-X Zhang, L Ma* (2023) Anthropogenic Contributions to Antibiotic Resistance Gene Pollution in Household Drinking Water Revealed by Machine-learning-based Source-tracking. Water Research, 246:120682.

[44] R An, YT Qi, X-X Zhang, L Ma* (2023) Xenogenetic Evolutionary of Integrons Promotes the Environmental Pollution of Antibiotic Resistance Genes –– Challenges, Progress and Prospects. Water Research, 231:119629.

[43] HY Shi, XY Hu, J Zhang, WX Li, J Xu, BL Hu, L Ma*, LP Lou* (2023) Soil Minerals and Organic Matters Affect ARGs Transformation by Changing the Morphology of Plasmid and Bacterial Responses. Journal of Hazardous Materials, 457(5):131727. 

[42] XX Zhang, PB Jiao, M Zhang, P Wu, YF Zhang, YW Wang, KY Xu, JZ Yu, L Ma* (2023) Impacts of Organic Loading Rate and Hydraulic Retention Time on Organics Degradation, Interspecies Interactions and Functional Traits in Thermophilic Anaerobic Co-digestion of Food Waste and Sewage Sludge. Bioresource Technology, 370:128578.

[41] PB Jiao, XX Zhang, SW Qiu, XY Zhou, ZX Tian, YJ Liang, YF Zhang, L Ma* (2023) Pyrite-enhanced Sludge Digestion via Stimulation of Direct Interspecies Electron Transfer between Syntrophic Propionate- and Sulfur-oxidizing Bacteria and Methanogens: Genome-centric Metagenomics Evidence. Chemical Engineering Journal, 456:141089.

[40] HY Shi, XY Hu, J Xu, BL Hu, ‍L Ma, LP Lou* (2023) Conjugation-mediated Transfer of Antibiotic Resistance Genes Influenced by Primary Soil Components and Underlying Mechanisms. Science of The Total Environment, 865:161232.

[39] XX Zhang, PB Jiao, YW Wang, P Wu, YM Li, L Ma* (2022) Enhancing Methane Production in Anaerobic Co-digestion of Sewage Sludge and Food Waste by Regulating Organic Loading Rate. Bioresource Technology, 363:127988.

[38] L Ma, XT Jiang, L Guan, B Li, T Zhang* (2022) Nationwide Biogeography and Health Implications of Bacterial Communities in Household Drinking Water. Water Research, 215(3):118238.

[37] Q Ping, ZP Zhang, L Ma, TT Yan, L Wang, YM Li* (2022) The Prevalence and Removal of Antibiotic Resistance Genes in Full-scale Wastewater Treatment Plants: Bacterial Host, Influencing Factors and Correlation with Nitrogen Metabolic Pathway. Science of the Total Environment, 827(9):154154.

[36] XY Hu, YL Fu, HY Shi, WJ Xu, CF Shen, BL Hu,  L Ma*, LP Lou* (2022) Neglected Resistance Risks: Cooperative Resistance of Antibiotic Resistant Bacteria Influenced by Primary Soil Components. Journal of Hazardous Materials, 429:128229.

[35] L Ma*, HY Yang, L Guan, XY Liu, T Zhang (2022) Risks of Antibiotic Resistance Genes and Antimicrobial Resistance under Chlorination Disinfection with Public Health Concerns. Environment International, 158(4):106978.

[34] HY Yang, RL Liu, HF Liu, C Wang, XL Yin, M Zhang, JS Fang, T Zhang,  L Ma* (2021) Evidence for Long-Term Anthropogenic Pollution: The Hadal Trench as a Depository and Indicator for Dissemination of Antibiotic Resistance Genes. Environmental Science & Technology, 55: 15136-15148.

[33] XX Zhang, P Wu, LZ Xu,  L Ma* (2021) A Novel Simultaneous Partial Nitritation, Denitratation and Anammox (SPNDA) Process in Sequencing Batch Reactor for Advanced Nitrogen Removal from Ammonium and Nitrate Wastewater. Bioresource Technology, 343:126105.

[32] XX Zhang, XN Zhang, P Wu*,  L Ma*, JJ Chen, CC Wang, X Li, WR Liu, LZ Xu (2021) Hydroxylamine Metabolism in Mainstream DEnitrifying AMmonium OXidation (DEAMOX) Process: Achieving Fast Start-up and Robust Operation with Bio-augmentation Assistance under Ambient Temperature. Journal of Hazardous Materials, 421:126736.

[31] 张星星，焦彭博，杨汇莹，吴睿敏，李咏梅，马黎萍*（2021）剩余污泥与餐厨垃圾协同厌氧消化研究进展。中国环境科学。

[30] 杨兴盛,王尚*,何晴,王朱珺,张照婧,姜成英,马黎萍,刘贤伟,胡宝兰,李咏梅,邓晔*(2021)典型有机固废厌氧消化微生物研究现状与发展方向。生物工程学报，274(10):3425-3438.

[29] XX Zhang, P Wu*,  L Ma, JJ Chen, CC Wang, WR Liu, LZ Xu (2021) A Novel Simultaneous Partial Nitrification and Denitratation (SPND) Process in Single Micro-aerobic Sequencing Batch Reactor for Stable Nitrite Accumulation under Ambient Temperature. Chemical Engineering Journal, 425(6):130646.

[28] P Wu*, XX Zhang, YG Wang, CC Wang, L Ma, FWV Jenario, WR Liu, LZ Xu (2021) Development of A Novel Denitrifying Phosphorus Removal and Partial Denitrification Anammox (DPR+PDA) Process for Advanced Nitrogen and Phosphorus Removal from Domestic and Nitrate Wastewaters.  Bioresource Technology, 327:124795.

[27] XX Zhang, YK Xia, CC Wang, JJ Li, P Wu*, L Ma, YG Wang, Y Wang, FH Da, WR Liu, LZ Xu (2020) Enhancement of nitrite production via addition of hydroxylamine to partial denitrification (PD) biomass: Functional genes dynamics and enzymatic activities. Bioresource Technology, 318:124274.

[26] RX Zhao, K Yu, JY Zhang, GJ Zhang, J Huang, L Ma, CF Deng, XY Li, B Li* (2020) Deciphering the mobility and bacterial hosts of antibiotic resistance genes under antibiotic selection pressure by metagenomic assembly and binning approaches. Water Research, 186:116318.

[25] GJ Zhang, YT Guan, RX Zhao, J Feng, J Huang, L Ma, B Li* (2020) Metagenomic and network analyses decipher profiles and co-occurrence patterns of antibiotic resistome and bacterial taxa in the reclaimed wastewater distribution system. Journal of Hazardous Materials, 400:123170.

[24] Q Zhang, EG Xu, JN Li, QQ Chen, L Ma, EY Zeng, HH Shi* (2020) A Review of Microplastics in Table salt, Drinking Water, and Air: Direct Human Exposure. Environmental Science & Technology, 54(7):3740-3751.

[23] J Liang, G Mao, X Yin, L Ma, L Liu, Y Bai*, T Zhang, J Qu (2020) Identification and quantification of bacterial genomes carrying antibiotic resistance genes and virulence factor genes for aquatic microbiological risk assessment. Water Research, 160:115160.

[22] L Ma, B Li, T Zhang* (2019) New Insights into Antimicrobial Resistome in Drinking Water and Management Perspectives: A Metagenomic based Study of Small-sized Microbes. Water Research, 152:191-201.

[21] X Yin, Y Deng, L Ma, Y Wang, YL Chan, T Zhang* (2019) Exploration of the antibiotic resistome in a wastewater treatment plant by a nine-year longitudinal metagenomic study. Environment International, 133:105270.

[20] JM Tiedje, F Wang*, CM Manaia, M Virta, HJ Sheng, L Ma, T Zhang, E Topp (2019) Antibiotic Resistance Genes in the Human-Impacted Environment: A One Health Perspective. Pedosphere, 29(3):273-282.

[19] XT Jiang, L Ye, B Li, F Ju, L Ma, Tong Zhang*. (2018) Temporal dynamics of activated sludge bacterial communities in two diversity variant full-scale sewage treatment plants. Applied Microbiology and Biotechnology,102:9379-9388.

[18] AN Zhang, LG Li, L Ma, MR Gillings, JM Tiedje, Tong Zhang* (2018) Conserved Phylogenetic Distribution of Class 1 Integrons Revealed by Assessing the Bacterial Genome Collection. Microbiome, 6:130.

[17] WG Xiong, YL Wang, TX Sun, L Ma, QL Zeng, XT Jiang, AD Li, ZL Zeng*, T Zhang* (2018) Antibiotic-mediated changes in the faecal microbiome of broiler chickens defines the incidence of antibiotic resistance genes. Microbiome, 6:34.

[16] L Ma, B Li, XT Jiang, YL Wang, Y Xia, AD Li, Tong Zhang* (2017) Catalogue of Antibiotic Resistome and Host-tracking in Drinking Water Deciphered by a Large Scale Survey. Microbiome, 5:154.

[15] L Ma, AD Li, XL Yin, T Zhang* (2017) The prevalence of integrons as the carrier of antibiotic resistance genes in natural and man-made Environments. Environmental Science & Technology, 51(10): 5721-5728. 

[14] AD Li, L Ma, YP Mao, XT Jiang, T Zhang* (2017) Cultivation-dependent and high-throughput sequencing approaches studying the co-occurrence of antibiotic resistance genes in municipal sewage system. Applied Microbiology and Biotechnology, 101: 8197-8207. 

[13] YL Wang, L Ma, YP Mao, XT Jiang, Y Xia, K Yu, B Li, T Zhang* (2017) Comammox in two drinking water systems. Water Research,116: 332-341. 

[12] L Ma, Y Xia, B Li, Y Yang, LG Li, JM Tiedje*, T Zhang* (2016) Metagenomic Assembly Reveals Hosts of Antibiotic Resistance Genes and the Shared Resistome in Pig, Chicken and Human Feces. Environmental Science & Technology, 50:420-427. 

[11] Y Yang, XT Jiang, BL Cai, L Ma, B Li, AN Zhang, JR Cole, JM Tiedje*, T Zhang*(2016) ARGs-OAP: Online Analysis Pipeline for Antibiotic Resistance Genes Detection from Metagenomic Data Using an Integrated Structured ARG-database. Bioinformatics,32: 2346-2351.

[10] KQ Xiao, LG Li, L Ma, SY Zhang, P Bao, T Zhang*, YG Zhu* (2016) Metagenomic analysis revealed highly diverse microbial arsenic metabolism genes in paddy soils with low-arsenic contents. Environmental Pollution, 211:1-8. 

[9] KQ Xiao, B Li, L Ma, P Bao, X Zhou, T Zhang*, YG Zhu* (2016) Metagenomic profiles of antibiotic resistance genes in paddy soils from South China. FEMS Microbiology Ecology, 92:1-6.

[8] F Ju, B Li, L Ma, Y Wang, D Huang, T Zhang* (2015) Antibiotic Resistance Genes and Human Bacterial Pathogens: Co-occurrence, Removal, and Enrichment in Municipal Sewage Sludge Digesters. Water Research, 91:1-10. 

[7] B Li, Y Yang, L Ma, F Ju, F Guo, JM Tiedje, T Zhang* (2015) Metagenomic and network analysis reveal wide distribution and co-occurrence of environmental antibiotic resistance genes. The ISME Journal, 9:2490-2502. 

[6] L Ma, B Li, T Zhang* (2014) Abundant rifampin resistance genes and significant correlations of antibiotic resistance genes and plasmids in various environments revealed by metagenomic analysis. Applied Microbiology and Biotechnology, 98:5195-5204. 

[5] L Ma, XX Zhang*, F Zhao, B Wu, S Cheng, L Yang (2013) Sewage treatment plant serves as a hot-spot reservoir of integrons and gene cassettes. Journal of Environmental Biology, 34:391-399. 

[4] Y Chao, L Ma, Y Yang, F Ju, XX Zhang, WM Wu, T Zhang* (2013) Metagenomic analysis reveals significant changes of microbial compositions and protective functions during drinking water treatment.Scientific reports, 3.

[3] L Ma, XX Zhang*, S Cheng, Z Zhang, P Shi, B Liu, B Wu, Y Zhang (2011) Occurrence, abundance and elimination of class 1 integrons in one municipal sewage treatment plant. Ecotoxicology, 20:968-973.

[2] Z Zhang, L Ma, XX Zhang*, W Li, Y Zhang, B Wu, L Yang, S Cheng (2010) Genomic expression profiles in liver of mice exposed to purified terephthalic acid manufacturing wastewater.Journal of Hazardous Materials, 181:1121-1126. 

[1] XX Zhang*, Z Zhang, L Ma, N Liu, B Wu, Y Zhang, AM Li, SP Cheng (2010) Influences of hydraulic loading rate on SVOCs removal and microbial community structure in drinking water treatment biofilters. Journal of Hazardous Materials, 178:652-657. 

专利：

张徐祥,施鹏,贾舒宇,马黎萍,吴兵,李爱民,程树培,一种快速高效提取饮用水中总DNA的方法,申请号:201110339834.1,公开号:CN102382818A.

1. 上海市高校特聘教授（东方学者）,2019

2. 上海市浦江人才计划A类,2019