王旭明
博士/研究員,中國農業生物技術學(xué)會常務理(lǐ)事、微生物生物技術分會常務理(lǐ)事,現代農業産業技術體系北京市創新團隊崗位專家。1993年(nián)畢業于中國農業大學(xué)微生物學(xué)專業,獲理(lǐ)學(xué)學(xué)士學(xué)位。2006年(nián)畢業于哈爾濱工業大學(xué)環境工程專業,獲工學(xué)博士學(xué)位。曾就職于解放軍軍需大學(xué)(1993-2004)和(hé)吉林大學(xué)(2004-2007)。2007-2009年(nián)于清華大學(xué)核能與新能源技術研究院從事博士後研究工作。2009年(nián)6月入職北京市農林科學(xué)院生物中心。近年(nián)來主持國家自(zì)然科學(xué)基金、北京市自(zì)然科學(xué)基金、北京市科技計劃等科研課題10餘項。發表科研論文100餘篇。獲省部級科學(xué)技術獎3項、農業技術推廣獎2項。
聯系方式:wangxuming@baafs.net.cn, wangxm413@163.com; 010-51503803
研究方向
環境生物技術與環境抗生素抗性組研究
科研成果
主持項目:
| [1] | 北京市自(zì)然科學(xué)基金面上項目“畜禽糞便堆肥過程中噬菌體編碼的(de)抗生素抗性基因賦存特征與驅動機制”(5222005,20萬,2022-2024) |
| [2] | 國家自(zì)然科學(xué)基金面上項目“農田土壤中噬菌體攜帶抗生素抗性基因的(de)多樣性及水平轉移研究”(32070089,58萬,2021-2024) |
| [3] | 現代農業産業技術體系北京市創新團隊建設專項資金(2011-2023,800萬) |
| [4] | 國家重點研發計劃子(zǐ)課題“農田抗生素污染及抗性基因增殖擴散機制”(2016YFD0800205,111萬,2016-2020) |
| [5] | 北京市科技計劃課題“飼用微生物與酶制劑共性技術研發與服務平台建設”(D161100006116001,40萬,2016-2018) |
| [6] | 北京市農林科學(xué)院科技創新能力建設專項“抗旱促生菌劑的(de)創制及其生态效應研究” (KJCX20161502-4,150萬,2016-2018) |
| [7] | 北京市農林科學(xué)院科技創新能力建設專項“規模化養雞場生物氣溶膠污染特征及控制措施的(de)研究與應用”(KJCX20151204,180萬,2015-2017) |
| [8] | 北京市自(zì)然科學(xué)基金面上項目“基于生物膜和(hé)微生物群落結構特征的(de)固相反硝化機理(lǐ)研究”(8152016,18萬,2015-2017) |
| [9] | 國民核生化災害防護國家重點實驗室基礎研究項目“氯酚類污染物的(de)微生物降解研究”(SKLNBC2013-03K,15萬,2013) |
| [10] | 北京市農業科技項目(北京市農村工作委員會)“微生物發酵床養殖北京鴨技術集成與示範”(20140125, 30萬,2014-2015) |
| [11] | 北京市科技計劃課題“水産養殖水體修複與淨化技術研究與示範”(Z121100001512008,49.06萬,2012.6-2014.6) |
| [12] | 國家自(zì)然科學(xué)基金面上項目“基于固相反硝化同時去(qù)除地(dì)下水中硝酸鹽與農藥的(de)新技術”(21077014,2011-2013,36萬) |
代表性論文
| [1] | Guo Y, Qiu T, Gao M, Ru S, Gao H, Wang X*. Does increasing the organic fertilizer application rate always boost the antibiotic resistance level in agricultural soils? Environmental Pollution, 2023, 322: 121251 |
| [2] | Xin H#, Gao M#, Wang X#, Qiu T, Guo Y, Zhang L*. Animal farms are hot spots for airborne antimicrobial resistance. Science of the Total Environment, 2022, 851: 158050 |
| [3] | Gao M, Yu A, Chen M, Qiu T, Guo Y, Sun X*, Wang X*. Airborne fungi and human exposure in different areas of composting facilities. Ecotoxicology and Environmental Safety, 2022, 243: 113991 |
| [4] | Shen L, Qiu T, Guo Y, Gao M, Gao H, Zhao G*, Wang X*. Enhancing control of multidrug-resistant plasmid and its host community with a prolonged thermophilic phase during composting. Frontiers in Microbiology, 2022, 13: 989085. |
| [5] | Qiu T, Huo L, Guo Y, Gao M, Wang G, Hu D, Li C, Wang Z, Liu G*, Wang X*. Metagenomic Assembly Reveals Hosts and Mobility of Common Antibiotic Resistome in Animal Manure and Commercial Compost. Environmental Microbiome, 2022, 17: 42 |
| [6] | Zhang Y, Guo Y, Qiu T, Gao M, Wang X*. Bacteriophages: underestimated vehicles of antibiotic resistance genes in the soil. Frontiers in Microbiology, 2022, 13:936267. |
| [7] | Gao M, Zhang X, Yue Yang, Qiu T, Wang Jing*, Wang X*. Air path of antimicrobial resistance related genes from layer farms: Emission inventory, atmospheric transport, and human exposure. Journal of Hazardous Materials, 2022, 430: 128417 |
| [8] | Guo Y, Qiu T, Gao M, Sun Y, Cheng S, Gao H, Wang X*. Diversity and abundance of antibiotic resistance genes in rhizosphere soil and endophytes of leafy vegetables: Focusing on the effect of the vegetable species. Journal of Hazardous Materials, 2021, 415: 125595 |
| [9] | Zhang S, Fan Y, Zhang N, Wang X*. Relationship between denitrification performance and microbial community structure in a PHBV-supported denitrification reactor. Desalination and Water Treatment, 2021, 215: 23-30 |
| [10] | Qiu T, Wu D, Zhang L, Zou D, Sun Y, Gao M, Wang X*. A comparison of antibiotics, antibiotic resistance genes, and bacterial community in broiler and layer manure following composting. Environmental Science and Pollution Research. 2021, 28 (12): 14707-14719 |
| [11] | Cheng S, Chen M, Gao M, Qiu T, Tian S*, Li S, Wang X*. Effects of Enterococcus faecalis administration on the community structure of airborne bacteria in weanling piglet and layer hen houses. The Journal of General and Applied Microbiology, 2021, 67: 162–169 |
| [12] | Gao M#, Yang Z#, Guo Y, Chen M, Qiu T, Sun X*, Wang X*. The size distribution of airborne bacteria and human pathogenic bacteria in a commercial composting plant. Front. Environ. Sci. Eng. 2021, 15 (3): 39 |
| [13] | Sun Y, Guo Y, Shi M, Qiu T, Gao M, Tian S*, Wang X*. Effect of antibiotic type and vegetable species on antibiotic accumulation in soil-vegetable system, soil microbiota, and resistance genes. Chemosphere, 2021, 263: 128099 |
| [14] | Cheng S, Shi M, Xing L, Wang X*, Gao H, Sun Y*. Sulfamethoxazole affects the microbial composition and antibiotic resistance gene abundance in soil and accumulates in lettuce. Environmental Science and Pollution Research , 2020, 27: 29257–29265 |
| [15] | Sun Y, Qiu T, Gao M, Shi M, Zhang H, Wang X*. Inorganic and organic fertilizers application enhanced 1 antibiotic resistome in greenhouse soils growing vegetables. Ecotoxicology and Environmental Safety, 2019, 179: 24-30. |
| [16] | Yin A, Jia Y, Qiu T, Gao M, Cheng S, Wang X*, Sun Y*. Poly-γ-glutamic acid improves the drought resistance of maize seedlings by adjusting the soil moisture and microbial community structure. Applied Soil Ecology, 2018, 129: 128–135 |
| [17] | Zhang S, Sun X, Wang X*, Qiu T, Gao M, Sun Y, Cheng S, Zhang Q. Bioaugmentation with Diaphorobacter polyhydroxybutyrativorans to enhance nitrate removal in a poly (3-hydroxybutyrate-co-3-hydroxyvalerate)-supported denitrification reactor. Bioresource Technology, 2018, 263: 499-507 |
| [18] | Gao M, Qiu T, Sun Y, Wang X*. The abundance and diversity of antibiotic resistance genes in the atmospheric environment of composting plants. Environment International, 2018, 116: 229–238 |
| [19] | Zhang S, Sun X, Fan Y, Qiu T, Gao M, Wang X*. Heterotrophic nitrification and aerobic denitrification by Diaphorobacter polyhydroxybutyrativorans SL-205 using poly (3-hydroxybutyrate-co-3-hydroxyvalerate) as the sole carbon source. Bioresource Technology, 2017, 241: 500–507 |
| [20] | Gao M, Jia R, Qiu T, Han M, Wang X*. Size-related bacterial diversity and tetracycline resistance gene abundance in the air of concentrated poultry feeding operations. Environmental Pollution, 2017, 220: 1342-1348 |
| [21] | Qiu T, Xu Y, Gao M, Han M, Wang X*. Bacterial community dynamics in a biodenitrification reactor packed with polylactic acid/poly (3-hydroxybutyrate-co-3-hydroxyvalerate) blend as the carbon source and biofilm carrier. J Biosci Bioeng, 2017, 123 (5): 606-612. |
| [22] | Qiu T, Liu L, Gao M, Zhang L, Tursun H*, Wang X*. Effects of solid-phase denitrification on the nitrate removal and bacterial community structure in recirculating aquaculture system. Biodegradation, 2016, 27 (2): 165–178 |
| [23] | Gao M, Yan X, Qiu T, Han M, Wang X*. Variation of correlations between factors and culturable airborne bacteria and fungi. Atmospheric Environment, 2016, 128: 10-19 |
| [24] | Qiu T, Zuo Z, Gao J, Gao M, Han M, Sun L, Zhang L*, Wang X*. Diaphorobacter polyhydroxybutyrativorans sp. nov., a novel poly (3-hydroxybutyrate-co-3-hydroxyvalerate)-degrading bacterium isolated from biofilms. Int J Syst Evol Microbiol, 2015, 65: 2913-2918 |
| [25] | Gao M, Jia R, Qiu T, Han M, Song Y, Wang X*. Seasonal size distribution of airborne culturable bacteria and fungi and preliminary estimation of their deposition in human lungs during non-haze and haze days. Atmospheric Environment, 2015, 118: 203-210 |
| [26] | Gao M, Qiu T, Jia R, Han M, Song Y, Wang X*. Concentration and size distribution of viable bioaerosols during non-haze and haze days in Beijing. Environmental Science and Pollution Research, 2015, 22 (6): 4359-4368 |
| [27] | Wang X, Wang J*. Nitrate removal from groundwater using solid-phase denitrification process without inoculating with external microorganisms. Int J Environ Sci Technol, 2013, 10 (5): 955–960 |
| [28] | Wang X*, Xing L, Qiu T, Han M. Simultaneous removal of nitrate and pentachlorophenol from simulated groundwater using a biodenitrification reactor packed with corncob. Environmental Science and Pollution Research, 2013, 20 (4): 2236-2243 |
| [29] | Wang X, Wang J*. Denitrification of nitrate-contaminated groundwater using biodegradable snack ware as carbon source under low-temperature condition. Int J Environ Sci Technol, 2012, 9 (1): 113–118 |
授權專利
| [1] | 王旭明,仇天雷,韓梅琳,高(gāo)敏,孫立嬌,崔鑫鑫,魏建華. Diaphorobacter菌株、其應用以及包含其的(de)水體改良劑, ZL201210425988.7 |
| [2] | 王旭明,仇天雷,高(gāo)敏,韓梅琳,崔鑫鑫. 一(yī)種發酵床養殖北京填鴨的(de)方法, ZL201410274187.4 |
獲獎
| [1] | 2014-2016年(nián)度全國農牧漁業豐收獎二等獎,北京鴨生态健康養殖與質量安全控制模塊化技術集成與應用,第5完成人 |
| [2] | 2016年(nián)度北京市農業技術推廣獎三等獎,漁業高(gāo)效節水技術研究與示範推廣,第3完成人 |
| [3] | 2016年(nián)度吉林省科學(xué)技術獎二等獎,同步脫氮除磷AOA工藝的(de)開發與應用,第2完成人 |
| [4] | 2015年(nián)度吉林省科學(xué)技術獎三等獎,城市中水回用于工業循環水關鍵技術與裝備,第3完成人 |
| [5] | 2014年(nián)度吉林省科技進步二等獎,化學(xué)預氧化協同生物濾池污水深度處理(lǐ)關鍵技術研究,第4完成人 |
