植物营养与肥料学报
植物營養與肥料學報
식물영양여비료학보
Plant Nutrition and Fertilizer Science
2015年
5期
1343-1351
,共9页
艾超%孙静文%王秀斌%梁国庆%何萍%周卫
艾超%孫靜文%王秀斌%樑國慶%何萍%週衛
애초%손정문%왕수빈%량국경%하평%주위
根际沉积%根际微生物%碳分配%宏基因组学%植物-微生物相互作用
根際沉積%根際微生物%碳分配%宏基因組學%植物-微生物相互作用
근제침적%근제미생물%탄분배%굉기인조학%식물-미생물상호작용
rhizodeposition%rhizosphere microbiome%carbon distribution%metagenomics%plant-microbe interaction
【目的】活跃的根际微生物被喻为植物的第二套基因组,在植物的生长发育过程中发挥着关键作用。植物通过根际碳沉积影响根际土壤微生物群落的结构和功能;作为根际微生态系统中的物质流、能量流和信息流,根际碳沉积是连接大气、植物和土壤系统物质循环的重要纽带;因此,理解根际碳沉积在根际微生态中的作用对于提高植物抗逆性,增加作物产量,调控根际养分循环等方面具有重大的理论意义。【主要进展】本文就近年来关于根际微生物领域的研究成果,重点综述了根际微生物多样性和组学研究;根际碳沉积的组成和产生机理;根际微生物群落结构的形成机制;根际微生物在促进作物养分吸收、提高作物抗逆性等方面的生态功能;以及气候变化和长期施肥对植物-微生物互作关系的影响。在此基础上我们提出了未来可能的研究重点和发展方向:1)植物根际沉积物原位收集方法和检测技术的改进和发展;2)稳定同位素探针与分子生态学技术的结合,将植物、土壤和微生物三者有机地联系起来,综合分析根际界面中微生物的活性与功能;3)高通量测序、组学技术和生物信息学等新技术的引入势必使根际微生物学研究发生革命性的变化;4)随着全球气候变化和土壤肥力改变,例如全球变暖、CO2浓度升高和长期施用化肥,根际沉积物在植物-土壤-微生物中的分配与调节机制,以及这种环境选择压力下植物如何诱导根际促生菌发挥更大作用。希望通过平衡作物与微生物之间的相互关系来实现作物的高产高效,促进农田的可持续利用。
【目的】活躍的根際微生物被喻為植物的第二套基因組,在植物的生長髮育過程中髮揮著關鍵作用。植物通過根際碳沉積影響根際土壤微生物群落的結構和功能;作為根際微生態繫統中的物質流、能量流和信息流,根際碳沉積是連接大氣、植物和土壤繫統物質循環的重要紐帶;因此,理解根際碳沉積在根際微生態中的作用對于提高植物抗逆性,增加作物產量,調控根際養分循環等方麵具有重大的理論意義。【主要進展】本文就近年來關于根際微生物領域的研究成果,重點綜述瞭根際微生物多樣性和組學研究;根際碳沉積的組成和產生機理;根際微生物群落結構的形成機製;根際微生物在促進作物養分吸收、提高作物抗逆性等方麵的生態功能;以及氣候變化和長期施肥對植物-微生物互作關繫的影響。在此基礎上我們提齣瞭未來可能的研究重點和髮展方嚮:1)植物根際沉積物原位收集方法和檢測技術的改進和髮展;2)穩定同位素探針與分子生態學技術的結閤,將植物、土壤和微生物三者有機地聯繫起來,綜閤分析根際界麵中微生物的活性與功能;3)高通量測序、組學技術和生物信息學等新技術的引入勢必使根際微生物學研究髮生革命性的變化;4)隨著全毬氣候變化和土壤肥力改變,例如全毬變暖、CO2濃度升高和長期施用化肥,根際沉積物在植物-土壤-微生物中的分配與調節機製,以及這種環境選擇壓力下植物如何誘導根際促生菌髮揮更大作用。希望通過平衡作物與微生物之間的相互關繫來實現作物的高產高效,促進農田的可持續利用。
【목적】활약적근제미생물피유위식물적제이투기인조,재식물적생장발육과정중발휘착관건작용。식물통과근제탄침적영향근제토양미생물군락적결구화공능;작위근제미생태계통중적물질류、능량류화신식류,근제탄침적시련접대기、식물화토양계통물질순배적중요뉴대;인차,리해근제탄침적재근제미생태중적작용대우제고식물항역성,증가작물산량,조공근제양분순배등방면구유중대적이론의의。【주요진전】본문취근년래관우근제미생물영역적연구성과,중점종술료근제미생물다양성화조학연구;근제탄침적적조성화산생궤리;근제미생물군락결구적형성궤제;근제미생물재촉진작물양분흡수、제고작물항역성등방면적생태공능;이급기후변화화장기시비대식물-미생물호작관계적영향。재차기출상아문제출료미래가능적연구중점화발전방향:1)식물근제침적물원위수집방법화검측기술적개진화발전;2)은정동위소탐침여분자생태학기술적결합,장식물、토양화미생물삼자유궤지련계기래,종합분석근제계면중미생물적활성여공능;3)고통량측서、조학기술화생물신식학등신기술적인입세필사근제미생물학연구발생혁명성적변화;4)수착전구기후변화화토양비력개변,례여전구변난、CO2농도승고화장기시용화비,근제침적물재식물-토양-미생물중적분배여조절궤제,이급저충배경선택압력하식물여하유도근제촉생균발휘경대작용。희망통과평형작물여미생물지간적상호관계래실현작물적고산고효,촉진농전적가지속이용。
[Objectives]The active rhizosphere microbiome, also referred as the second genome of plant, is crucial for plant growth and development. The structure and function of microbial community in the rhizosphere are affected by plant-derived carbon through rhizodeposition, which is considered as the main modality of material flow, energy flow and information flow in plant rhizosphere system, and play a role of interconnects in the air-plant-soil system. Hence, understanding the function of rhizodeposition is of theoretically meaning to study to plant stress tolerance improvement, crop yield increase and nutrient cycling regulation in the rhizosphere soil. [Main advances] In this paper, the latest results and trends of the rhizosphere microbiome research were reviewed, especially focused on 1) rhizosphere microbial diversity and omics research, 2)components and generation mechanism of rhizodeposition, 3) formation mechanism of microbial community structure in the rhizosphere, 4)the ecological functions of rhizosphere microbiome in enhancing nutrient uptake and plant stress tolerance, and 5 ) the influences of climate change and long-term fertilization on plant-microbe interaction. On this basis, the future research and development direction were discussed:1 ) Improvement and development of the in-situ collection method and measurement technique ofplant rhizodeposits. 2 ) The combination of the stable isotope probing ( SIP ) and molecular ecology techniques to plant, soil and microorganism could be used to analyze the functions and roles of rhizosphere microbiome. 3) The applications of new technologies ( e. g. next-generation sequencing technologies, ‘omics ’ technologies and bioinformatics tools) might revolutionize the development of rhizosphere microbiome research. 4 ) With the changes in global climate and soil fertility, such as global warming, elevated atmospheric CO2 concentration and long-term inorganic fertilization, environmental factors will play a more important role on the regulation mechanism of root-derived carbon in the plant-soil-microorganism system, and the inductive effect of plant under such specific environment on plant growth promoting rhizobacteria(PGPR). These knowledge will provide a view on how to establish a sustainable soil-crop system with high productivity and high efficiency through coordinating the interaction between crop and rhizosphere microbiome.