纳米气泡对枝孢菌锰氧化过程的影响及其机理

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (1191 KB) HTML (0 KB)
输出: BibTeX | EndNote (RIS)

摘要以锰氧化枝孢菌Cladosporium sp.XM01作为研究对象，通过检测不同浓度纳米气泡水配制的培养基中枝孢菌的锰去除速率和表观形态，探究纳米气泡对单菌种锰氧化枝孢菌锰氧化过程的影响，并通过枝孢菌在不同浓度的纳米气泡培养下基因表达结果探究其机理.结果表明，由于纳米气泡的缓释性和富氧作用，7.49×10⁶particles/mL的低浓度纳米气泡能促进枝孢菌的锰氧化过程；而浓度为7.49×10⁷particles/mL的高浓度纳米气泡则可能因高氧压力抑制枝孢菌的锰氧化过程.因此，可利用低浓度纳米气泡高效获取生物锰氧化物.这一发现在提高制备生物锰氧化物的效率和经济性的同时拓展了纳米气泡和生物锰氧化在环境领域的应用范围.

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	朱丽娜
	刘蕴思
	李攀

关键词 ：纳米气泡, 生物锰氧化, 枝孢菌, 基因表达, 经济性, 机理

Abstract：Manganese-oxidizing fungus Cladosporium sp. XM01 was selected as the organism. The appearance and Mn(Ⅱ) removal rate of Cladosporium sp. XM01in the culture prepared by nanobubble water at different concentrations were monitored to evaluate the impact of nanobubbles on the manganese oxidation of XM01. Meanwhile, XM01gene expression in the culture of various concentration nanobubble water was also assessed to explore the mechanism. The results indicated that, due to the sustained-release and oxygen-enrichment properties of nanobubbles, low concentration nanobubble promoted the manganese oxidation of XM01, while high concentration nanobubble showed opposing result because of high oxygen pressure. Therefore, low concentration nanobubbles could be effectively used to obtain biogenic manganese oxides. In summary, this study aimed to reveal the effects of nanobubbles on the manganese oxidation of manganese-oxidizing microorganisms and further expand the application of nanobubbles and biogenic manganese oxidation in environmental area.

Key words： nanobubbles biogenic manganese oxidation Cladosporium gene expression economy mechanism

收稿日期: 2023-03-28

PACS:

X172

基金资助:国家重点研发项目（2020YFC1908703）

通讯作者: 李攀,副教授,lipan@tongji.edu.cn E-mail: lipan@tongji.edu.cn

作者简介: 朱丽娜(1997-)女,河南焦作人,同济大学硕士研究生,主要从事水环境生态修复方面研究.15225830050@163.com.

引用本文:

朱丽娜, 刘蕴思, 李攀. 纳米气泡对枝孢菌锰氧化过程的影响及其机理[J]. 中国环境科学, 2023, 43(11): 6141-6148. ZHU Li-na, LIU Yun-si, LI Pan. Effects of nanobubbles on the manganese oxidation of a manganese-oxidizing fungus Cladosporium sp. and the biogenic mechanism. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(11): 6141-6148.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2023/V43/I11/6141

[1]	Guo Z, Wang X, Wang H, et al. Effects of nanobubble water on the growth of Lactobacillus acidophilus 1028and its lactic acid production [J]. Rsc Advances, 2019,9(53):30760-30767.
[2]	Lyu T, Wu S, Mortimer R J G, et al. Nanobubble technology in environmental engineering:revolutionization potential and challenges [J]. Environmental Science & Technology, 2019,53(13):7175-7176.
[3]	Park B, Yoon S, Choi Y, et al. Stability of engineered micro or nanobubbles for biomedical applications [J]. Pharmaceutics, 2020, 12(11):1089.
[4]	Temesgen T, Thi Thuy B, Han M, et al. Micro and nanobubble technologies as a new horizon for water-treatment techniques:A review [J]. Advances in Colloid and Interface Science, 2017,246:40-51.
[5]	Azevedo A, Oliveira H, Rubio J. Bulk nanobubbles in the mineral and environmental areas:Updating for research and applications [J]. Advances in Colloid and Interface Science, 2019,271:101992.
[6]	Shin D, Park J B, Kim Y J, et al. Growth dynamics and gas transport mechanism of nanobubbles in graphene liquid cells [J]. Nature Communications, 2015,6:6068.
[7]	徐彬,郑之奇,张珂.微纳米气泡改善太湖入湖河道水质的工程实例研究——以苏州南北华翔河水质改善工程为例[J]. 环境监控与预警, 2013,5(1):15-16. Xu B, Zhen Z Q, Zhang K, et al. The study of engineering case of improving the water quality of inflowing rivers of Taihu Lake with micro-nano bubbles-water quality improvement project of the north-south Huaxiang river in Suzhou [J]. Environmental Monitoring and Forewarning, 2013,5(1):15-16.
[8]	杨强,沈旭,唐伟,等.微纳米气泡改善杭州城市河道水生态环境的工程应用研究[J]. 环境科学与管理, 2014,39(9):76-79. Shen Q, Zhang X, Tang W, et al. Study on improving water ecological environment of Hangzhou urban river with micro-nano bubble technology [J]. Envionmental Science and Management, 2014,39(9):76-79.
[9]	叶春,张保君,李春华,等.微纳米曝气对植物浮床处理支浜水脱氮效果的影响[J]. 环境科学研究, 2012,25(10):1173-1179. Ye C, Zhang B J, Li C H, et al. Effects of micro-nanometer aeration on nitrogen removal by plant floating-beds [J]. Research of Environmental Sciences, 2012,25(10):1173-1179.
[10]	Jenkins K B, Michelsen D L, Novak J T. Application of oxygen microbubbles for in-situ biodegradation of p-xylene-contaminated groundwater in a soil column [J]. Biotechnology Progress, 1993,9(4):394-400.
[11]	陈旭露,王洪臣,齐鲁,等.阴离子表面活性剂对微孔曝气氧传质过程影响的研究[J]. 环境科学学报, 2013,33(2):395-400. Chen X L, Wang H C, Qi L, et al. Effects of anionic surfactant on oxygen mass transfer in the fine bubble aeration [J]. Acta Scientiae Circumstantiae, 2013,33(2):395-400.
[12]	Zhang H, Lyu T, Bi L, et al. Combating hypoxia/anoxia at sediment-water interfaces:A preliminary study of oxygen nanobubble modified clay materials [J]. Science of the Total Environment, 2018,637:550-560.
[13]	Liu S, Oshita S, Makino Y, et al. Oxidative capacity of nanobubbles and its effect on seed germination [J]. Acs Sustainable Chemistry & Engineering, 2016,4(3):1347-1353.
[14]	Ahmed A K A, Shi X, Hua L, et al. Influences of air, oxygen, nitrogen, and carbon dioxide nanobubbles on seed germination and plant growth [J]. Journal of Agricultural and Food Chemistry, 2018,66(20):5117-5124.
[15]	Schmidt J A, Crowe F L, Appleby P N, et al. Serum uric acid concentrations in meat eaters, fish eaters, vegetarians and vegans:A cross-sectional analysis in the EPIC-Oxford Cohort [J]. Plos One, 2013,8(2):e56339.
[16]	Owen J, Mcewan C, Nesbitt H, et al. Reducing tumour hypoxia via oral administration of oxygen nanobubbles [J]. Plos One, 2016,11(12):e0168088.
[17]	王硕,刘蕴思,李攀.微纳米气泡对小微水体中好氧微生物群落的影响[J]. 中国给水排水, 2020,36(15):29-34. Wang S, Liu Y S, Li P. Effect of micro-nano bubble aeration on aerobic microbial community in small water body [J]. China Water & Wastewater, 2020,36(15):29-34.
[18]	Hou T, Zhao J, Lei Z, et al. Addition of air-nanobubble water to mitigate the inhibition of high salinity on co-production of hydrogen and methane from two-stage anaerobic digestion of food waste [J]. Journal of Cleaner Production, 2021,314:127942.
[19]	金圣圣,张丽梅,贺纪正.锰氧化物与环境中有机物的作用及其在环境修复中的应用[J]. 环境科学学报, 2008,12:2394-2403. Jin S S, Zhang L M, He J Z. Review of reactions of manganese oxides with organic compounds and applications of MnOx in enivormental remediation [J]. Acta Science Circumstantiae, 2008,12:2394-2403.
[20]	刘凡,冯雄汉,陈秀华,等.氧化锰矿物的生物成因及其性质的研究进展[J]. 地学前缘, 2008,15(6):66-73. Liu F, Feng X H, Chen X H, et al. Advances in the study of biological genesis of manganese oxide minerals and their characteristics [J]. Earth Science Frontiers, 2008,15(6):66-73.
[21]	Villalobos M, Bargar J, Sposito G. Trace metal retention on biogenic manganese oxide nanoparticles [J]. Elements, 2005,1(4):223-226.
[22]	Morgan J J. Kinetics of reaction between O-2 and Mn(II) species in aqueous solutions [J]. Geochimica Et Cosmochimica Acta, 2005, 69(1):35-48.
[23]	Cerrato J M, Falkinham J O, III, Dietrich A M, et al. Manganese-oxidizing and reducing microorganisms isolated from biofilms in chlorinated drinking water systems [J]. Water Research, 2010,44(13):3935-3945.
[24]	梁金松,柏耀辉,胡承志,等.锰生物氧化的研究进展及在水处理中的应用[J]. 应用与环境生物学报, 2013,19(1):11-19. Liang J S, Bo Y H, Hu C Z, et al. Research progress of biogenic manganese oxides and application potential in water treatment process [J]. Chinese Journal of Applied and Environmental Biology, 2013,19(1):11-19.
[25]	Zhu M, Ginder-Vogel M, Sparks D L. Ni(II) sorption on biogenic Mn-oxides with varying Mn octahedral layer structure [J]. Environmental Science & Technology, 2010,44(12):4472-4478.
[26]	Tang W, Xia J, Zeng X, et al. Biological characteristics and oxidation mechanism of a new manganese-oxidizing bacteria FM-2[J]. Bio-Medical Materials and Engineering, 2014,24(1):703-709.
[27]	Wang Y-N, Tsang Y F, Wang H, et al. Effective stabilization of arsenic in contaminated soils with biogenic manganese oxide (BMO) materials [J]. Environmental Pollution, 2020,258:113481.
[28]	Xie H, Yang Y, Liu J, et al. Enhanced triclosan and nutrient removal performance in vertical up-flow constructed wetlands with manganese oxides [J]. Water Research, 2018,143:457-466.
[29]	Pacini V A, Ingallinella A M, Sanguinetti G. Removal of iron and manganese using biological roughing up flow filtration technology [J]. Water Research, 2005,39(18):4463-4475.
[30]	Wang M, Xu Z, Dong B, et al. An efficient manganese-oxidizing fungus Cladosporium halotolerans strain XM01:Mn(II) oxidization and Cd adsorption behavior [J]. Chemosphere, 2022,287:132026.
[31]	Lee J H, Kennedy D W, Dohnalkova A, et al. Manganese sulfide formation via concomitant microbial manganese oxide and thiosulfate reduction [J]. Environmental Microbiology, 2011,13(12):3275-3288.
[32]	Terasaka K, Tanaka S. Storage, transportation, concentration, dilution, and removal of ultrafine bubbles in Ultrapure Water [J]. Japanese Journal of Multiphase flow, 2022,36(1):4-11.
[33]	Wang S, Liu Y, Lyu T, et al. Aquatic macrophytes in morphological and physiological responses to the nanobubble technology application for water restoration [J]. Acs Es&T Water, 2021,1(2):376-387.
[34]	Sun Y, Zhang Y, Li W, et al. Combination of the endophytic manganese-oxidizing bacterium Pantoea eucrina SS01and biogenic Mn oxides:An efficient and sustainable complex in degradation and detoxification of malachite green [J]. Chemosphere, 2021,280:130785.
[35]	Li K, Xu A, Wu D, et al. Degradation of ofloxacin by a manganese-oxidizing bacterium Pseudomonas sp. F2and its biogenic manganese oxides [J]. Bioresource Technology, 2021,328:124826.
[36]	Zhou N Q, Liu D F, Min D, et al. Continuous degradation of ciprofloxacin in a manganese redox cycling system driven by Pseudomonas putida MnB-1[J]. Chemosphere, 2018,211:345-351.
[37]	Parikh S J, Chorover J. Infrared spectroscopy studies of cation effects on lipopolysaccharides in aqueous solution [J]. Colloids and Surfaces B-Biointerfaces, 2007,55(2):241-250.
[38]	Beekes M, Lasch P, Naumann D. Analytical applications of Fourier transform-infrared (FT-IR) spectroscopy in microbiology and prion research [J]. Veterinary Microbiology, 2007,123(4):305-319.
[39]	李磊,李忠佩,刘明,等.基于FTIR分析猪场废水有机物分解过程中组成结构变化[J]. 光谱学与光谱分析, 2016,36(11):3517-3522. Li L, Li P Z, Liu M, et al. Structural analysis of organic matter composition in piggery wastewaterduring the process of organic degradation based on FTIR Spectroscopy [J]. Spectroscopy and Spectral Analysis, 2016,36(11):3517-3522.
[40]	司光正,杨清晨,董佳,等.1株汞挥发真菌的分离及特性分析[J]. 环境工程, 2020,38(9):247-252. Si G Z, Yang Q C, Dong J, et al. Solation and characterization of A stain of mercury volatizing fungus [J]. Environmental Engineering, 2020,38(9):247-252.
[41]	朱燕云,孔祥平,吴娥娇,等.耐高盐枯草芽孢杆菌XP合成球形纳米硒及其抑制草莓病原真菌生物活性[J]. 生物工程学报, 2021,37(8):2825-2835. Zhu Y Y, Kong X P, Wu E Q, et al. Biosynthesis of spherical selenium nanoparticles with halophilic Bacillus subtilis subspecies stercoris strain XP for inhibition of strawberry pathogens [J]. Chinese Journal of Biotechnology, 2021,37(8):2825-2835.
[42]	Trong Quan L, Phung Ngoc Hong T, Zitzmann K, et al. Effects of ultrafine bubbles on gram-negative bacteria:inhibition or selection? [J]. Langmuir, 2019,35(42):13761-13768.
[43]	Zhou L, Wang X, Shin H J, et al. Ultrahigh density of gas molecules confined in surface nanobubbles in ambient water [J]. Journal of the American Chemical Society, 2020,142(12):5583-5593.
[44]	Wang S, Liu Y, Li P, et al. Micro-nanobubble aeration promotes senescence of submerged macrophytes with low total antioxidant capacity in urban landscape water [J]. Environmental Science-Water Research & Technology, 2020,6(3):523-531.