藻际微环境中藻体与微生物相互作用
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摘要
藻类与藻际微环境中的微生物紧密关联,存在极为复杂的关系。为了研究藻-菌互作机制,实现藻体的高效培养、污水处理、赤潮治理等,重点从藻-菌基本营养物质依赖、活性物质相互作用、信息交流三个方面总结了它们之间的复杂关系,并对在研究过程中需要解决的问题做出了展望。
Algae are closely related to microorganisms in the phycosphere,and the relationship between them is close and complicated.In order to study the mechanism of algae-bacteria interaction and realize the efficient cultivation of algae,wastewater treatment and red tide control, etc.This paper summarizes the complex relationship between algae and bacteria from three aspects: dependence on basic nutrients, interaction of active substances and information exchange, and prospects the problems that need to be solved in the research process.
Algae are closely related to microorganisms in the phycosphere,and the relationship between them is close and complicated.In order to study the mechanism of algae-bacteria interaction and realize the efficient cultivation of algae,wastewater treatment and red tide control, etc.This paper summarizes the complex relationship between algae and bacteria from three aspects: dependence on basic nutrients, interaction of active substances and information exchange, and prospects the problems that need to be solved in the research process.
引文
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[8] 吕利云.几种大型海藻对海水中重金属污染的生物修复能力研究[D].中国海洋大学,2013.
[9] 沈萍,陈向东.微生物学复兴的机遇、挑战和趋势[J].微生物学报,2010,50(01):1-6.
[10] 王华光,王文静,盛彦清.污水处理工艺对微藻及藻际细菌群落的影响[J].中国环境科学,2018,38(10):3761-3766.
[11] 王晴晴,高金伟,时晓婷,等.海洋饵料微藻与共栖细菌相互关系研究进展[J].农业与技术,2016,36(07):11-12.
[12] 周文杰,吕德国,秦嗣军.植物与根际微生物相互作用关系研究进展[J].吉林农业大学学报,2016,38(03):253-260.
[13] 崔龙波,彭国兴,吴雪,等.微藻与细菌相互关系及其在水质改良中的应用[J].水产养殖,2015,36(10):36-41.
[14] Gonzalez-Bashan L E, Lebsky V K, Hernandez J P, et al. Changes in the metabolism of the microalga Chlorella vulgaris when coimmobilized in alginate with the nitrogen-fixing Phyllobacterium myrsinacearum[J]. Canadian Journal of Microbiology, 2000, 46(7):653-659.
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[16] Tadashi T, Mari K, Tsubasa H, et al.Growth promotion of three microalgae, Chlamydomonas reinhardtii, Chlorella vulgaris and Euglena gracilis, by in situ indigenous bacteria in wastewater effluent[J].Biotechnology for Biofuels, 2018, 11(1):176-.
[17] Goecke F,Labes A,Wiese J,et al.Chemical interactions between marine macroalgae and bacteria[J].Marine Ecology Progress Series,2010,409(6):267-300.
[18] 沈梅丽,杨锐,骆其君,等.坛紫菜养殖周期中的藻际微生物多样性[J].微生物学报,2013,53(10):1087-1102.
[19] 方文雅.紫菜与藻际微生物互作研究平台的初步研究[D].宁波大学,2010.
[20] 张增虎,唐丽丽,张永雨.海洋中藻菌相互关系及其生态功能[J].微生物学通报,2018,45(09):2043-2053.
[21] 王剑.典型赤潮藻类可培养藻际细菌的分子鉴定与藻菌关系研究[D].暨南大学,2014.
[22] Murray R E,Cooksey K E,Priscu J C.Stimulation of Bacterial DNA Synthesis by Algal Exudates in Attached Algal-Bacterial Consortia[J].Applied & Environmental Microbiology,1986,52(5):1177-82.
[23] 王亚军,刘春花,林文辉,等.两种碳源对草鱼养殖水质、藻类和微生物群落的影响[J].淡水渔业,2015,45(03):57-63+83.
[24] 周进,陈国福,朱小山,等.赤潮过程中“藻-菌”关系研究进展[J].生态学报,2014,34(02):269-281.
[25] Eberlein T,Waal D B V D,Rost B.Differential effects of ocean acidification on carbon acquisition in two bloom-forming dinoflagellate species[J].Physiologia Plantarum,2014,151(4):468–479.
[26] Nelson C E,Carlson C A,Ewart C S,et al.Community differentiation and population enrichment of Sargasso Sea bacterioplankton in the euphotic zone of a mesoscale mode-water eddy[J].Environmental Microbiology,2014,16(3):871-887.
[27] Riquelm C E, Fukami K,Ishida Y.Effects of bacteria on the growth of a marine diatom,Asterionella glacialis[J].Bulletin of Japanese Society of Microbial Ecology,1988,3(1).
[28] 连玉武,王艳丽,郑天凌,等.赤潮科学中藻菌关系研究的若干进展[J].海洋科学,1999(01):35-38.
[29] 王少沛,曹煜成,李卓佳,等.水生环境中细菌与微藻的相互关系及其实际应用[J].南方水产,2008(01):76-80
[30] 李娜,毕永红,高大文,等.大气CO2浓度变化对铜绿微囊藻生长的影响[J].水生生物学报,2011,35(04):698-702.
[31] 易齐涛.海洋菌—藻关系及对营养盐的吸收作用研究[D].中国海洋大学,2006.
[32] 许丽丽,王全喜,吴双秀,等.转基因莱茵衣藻hemHc-lbac和根瘤菌共培养提高产氢培养条件的优化[J].生态科学,2014,33(01):106-112.
[33] 范琦, 肖惠杰, 吴强, 等. 群体微囊藻附生细菌特性[J].湖泊科学, 2017(3):617-624.
[34] 高亚辉.海洋微藻分类生态及生物活性物质研究[J].厦门大学学报:自然科学版,2001,40(2):566-573.
[35] 张睿.枯草芽孢杆菌对铜绿微囊藻抑制效果的研究[D].上海海洋大学,2015.
[36] 田达玮.胶州湾夜光藻种群动态及其摄食特征研究[D].中国科学院大学(中国科学院海洋研究所),2017.
[37] 林伟.海洋微藻与细菌相互关系的研究—正负相互作用的几个例证[D].中国科学院研究生院(海洋研究所),2005.
[38] Ridley C J A, Day J G, Smith A G.Cryopreservation studies of an artificial co-culture between the cobalamin-requiring green alga Lobomonas rostrata and the bacterium Mesorhizobium loti[J].Journal of Applied Phycology, 2017.
[39] 汪辉.溶藻细菌对水华与赤潮微藻的抑制效应研究[D].南京农业大学,2011.
[40] 李智卫.海藻对不同促生菌生长的影响及应用[D].山东农业大学,2010.
[41] 徐金森,郑天凌,陈霞,等.塔马亚历山大藻与细菌的共培养及其微生态效应[J].应用与环境生物学报,2002(02):111-114.
[42] 郑天凌,田蕴,苏建强,等.海洋赤潮生物与厦门海域几种细菌的生态关系研究[J].生态学报,2001,22(12):2063-2070.
[43] 谢静.溶藻细菌L7对两种水华藻类的溶藻机制研究[D].华南理工大学,2013.
[44] 陈峰, 田维娜, 孙东哲,等. 微藻对微生物的抑制作用及其抑菌机理[J]. 中国食品学报, 2014, 14(4):1-9.
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