植物种子内生细菌组的研究进展

种子是种子植物的繁殖器官,也是多种有益微生物和病原菌的传递载体。种子微生物与植物的生长发育、健康程度、品质及产量等密切相关。随着微生物生态学和微生物组学技术的发展,国内外有关植物微生物组的研究突飞猛进,尤其植物微生态相关的根际微生物组和叶际微生物组的研究已经成为焦点和热点。相比之下,对植物种子内生微生物组的研究还尚未引起足够的重视。细菌是种子内生微生物的主要类群,本文将重点从种子内生细菌的类群组成、生物学功能、传播途径和核心微生物组四个方面对近年来的研究进展进行概括总结,剖析当前种子内生微生物组研究领域亟待解决的问题以及未来的研究方向与思路。     

入侵植物对根际土壤微生物群落影响的研究进展

入侵植物根际土壤微生物是地下生态系统的重要组成部分。外来植物入侵到新的栖息地后能够促进其根际土壤微生物群落结构的演替、改变土壤理化性质, 强化微生物群落功能的发挥, 进而创造更适合外来植物生长的土壤微环境, 促进外来种的入侵进程。从外来入侵植物根际土壤微生物的研究方法、外来入侵植物对根际土壤微生物群落影响以及从地下生态学对外来植物入侵的影响等方面进行了综述。土壤微生物研究方法主要包括微生物计数法、微生物生理生化指标方法及分子技术 3 类; 入侵植物对根际土壤微生物的影响主要体现在对其生物量、多样性以及功能微生物菌群等方面。在今后的研究中, 应当注重对同一区域外来入侵植物和近缘本土种、及其伴生种的根际土壤微生物进行比较研究; 加强入侵植物根际微生物功能机理、环境因子与微生物间关联性的研究; 同时在研究方法上应注重传统方法与生物标记法及其与分子技术的结合。     

现代生物技术在根际微生物群落研究中的应用

根际微生物的定义为植物的根表及受根系直接影响的土壤区域中的微生物群落.根际微生物与植物根系相互作用,是植物生态系统物质交换的主要媒介.根际微生物群落的研究对于微生物生态学与植物生态学均具有重要意义.近年来现代生物学技术发展迅速,对根际自然群落中不可培养微生物的研究取得了突破.综述了目前已取得的研究进展,对现代生物技术在根际微生物群落研究中的应用做了讨论.     

若干技术在根际微生物研究中的应用

根际微生物是指植物根表及近根土壤中的微生物。根际微生物的研究对于微生物生态学、植物生态学及工业生物技术开发均具有十分重要的意义。为了进行更全面的研究以应对根际微生物研究所面临的复杂挑战,需要将各种生物学研究方法结合起来使用。综述了目前国内外应用较广泛的基于分子生物学的根际微生物研究方法,并对若干主要方法进行了横向比较,重点论述了结合高通量测序技术和基因芯片技术的根际微生物研究方法的新进展,并对相关技术的应用现状及其未来应用前景进行了综述。     

根系分泌物介导下植物-土壤-微生物互作关系研究进展与展望

根系分泌物是植物与土壤进行物质交换和信息传递的重要载体物质, 是植物响应外界胁迫的重要途径, 是构成植物不同根际微生态特征的关键因素, 也是根际对话的主要调控者。根系分泌物对于生物地球化学循环、根际生态过程调控、植物生长发育等均具有重要功能, 尤其是在调控根际微生态系统结构与功能方面发挥着重要作用, 调节着植物-植物、植物-微生物、微生物-微生物间复杂的互作过程。植物化感作用、作物间套作、生物修复、生物入侵等都是现代农业生态学的研究热点, 它们都涉及十分复杂的根际生物学过程。越来越多的研究表明, 不论是同种植物还是不同种植物之间相互作用的正效应或是负效应, 都是由根系分泌物介导下的植物与特异微生物共同作用的结果。近年来, 随着现代生物技术的不断完善, 有关土壤这一“黑箱”的研究方法与技术取得了长足的进步, 尤其是各种宏组学技术(meta-omics technology), 如环境宏基因组学、宏转录组学、宏蛋白组学、宏代谢组学等的问世, 极大地推进了人们对土壤生物世界的认知, 尤其是对植物地下部生物多样性和功能多样性的深层次剖析, 根际生物学特性的研究成果被广泛运用于指导生产实践。深入系统地研究根系分泌物介导下的植物-土壤-微生物的相互作用方式与机理, 对揭示土壤微生态系统功能、定向调控植物根际生物学过程、促进农业生产可持续发展等具有重要的指导意义。该文综述了根系分泌物的概念、组成及功能, 论述了根系分泌物介导下植物与细菌、真菌、土壤动物群之间的密切关系, 总结了探索根际生物学特性的各种研究技术及其优缺点, 并对该领域未来的研究方向进行了展望。     

Advances and perspective in research on plant-soil-microbe interactions mediated by root exudates

根系分泌物是植物与土壤进行物质交换和信息传递的重要载体物质, 是植物响应外界胁迫的重要途径, 是构成植物不同根际微生态特征的关键因素, 也是根际对话的主要调控者。根系分泌物对于生物地球化学循环、根际生态过程调控、植物生长发育等均具有重要功能, 尤其是在调控根际微生态系统结构与功能方面发挥着重要作用, 调节着植物-植物、植物-微生物、微生物-微生物间复杂的互作过程。植物化感作用、作物间套作、生物修复、生物入侵等都是现代农业生态学的研究热点, 它们都涉及十分复杂的根际生物学过程。越来越多的研究表明, 不论是同种植物还是不同种植物之间相互作用的正效应或是负效应, 都是由根系分泌物介导下的植物与特异微生物共同作用的结果。近年来, 随着现代生物技术的不断完善, 有关土壤这一“黑箱”的研究方法与技术取得了长足的进步, 尤其是各种宏组学技术(meta-omics technology), 如环境宏基因组学、宏转录组学、宏蛋白组学、宏代谢组学等的问世, 极大地推进了人们对土壤生物世界的认知, 尤其是对植物地下部生物多样性和功能多样性的深层次剖析, 根际生物学特性的研究成果被广泛运用于指导生产实践。深入系统地研究根系分泌物介导下的植物-土壤-微生物的相互作用方式与机理, 对揭示土壤微生态系统功能、定向调控植物根际生物学过程、促进农业生产可持续发展等具有重要的指导意义。该文综述了根系分泌物的概念、组成及功能, 论述了根系分泌物介导下植物与细菌、真菌、土壤动物群之间的密切关系, 总结了探索根际生物学特性的各种研究技术及其优缺点, 并对该领域未来的研究方向进行了展望。     

基于分子生物学和基因组学的植物根际微生物研究

根际微生物是指在植物根系直接影响的土壤范围内生长繁殖的微生物。根际微生物研究对微生物生态学和工业生物技术开发均十分重要, 妨碍其研究进展的主要原因是99%的根际微生物物种在实验室中无法成功培养。近年来, 将基于分子生物学和基因组学的非培养研究技术应用于根际微生物多样性研究取得了很大进展, 本文结合作者对红豆杉根际的研究, 评述近期相关新技术的应用和其未来应用前景。     

薄荷根内生及根际细菌多样性探究

采用传统的培养方法和基于分子生物学技术的非培养方法对我国常用中药之一的薄荷植物的根内生及根际细菌进行研究,从而了解其中细菌群落的多样性。对分离得到的细菌菌株进行16S rDNA扩增和系统发育分析,结果表明,利用培养方法与非培养方法分离得到薄荷根内生细菌及根际细菌一些共有的细菌种类,但前者优势种群为g-变形杆菌,后者优势种群为芽孢杆菌,说明土壤细菌,特别是根际细菌是植物内生细菌的重要来源,但植物对其内生细菌具有选择压。首次报道了薄荷根内和根际具有丰富的微生物群落多样性,为进一步探索植物根系微生态环境中微生物群落的形成和生态功能提供了基础信息。在今后探讨植物与微生物相互作用关系时,有必要考虑土壤环境,特别是根际对其的影响的同时,更加重视植物与其相关联的细菌种类的选择作用。     

基于Biolog-ECO方法的两种不同草原中5种不同植物根际土壤微生物群落特征

【背景】土壤微生物是草原生态系统的重要组成部分,在调节植物生长、促进土壤结构的形成及维持草原生态系统功能和稳定性等方面有着不可替代的作用。【目的】探究内蒙古自治区四子王旗两种不同草原中5种不同植物根际土壤微生物群落代谢功能的多样性。【方法】利用Biolog-ECO微平板法分析四子王旗荒漠草原中阿德格和格根塔拉2个样地中短花针茅、冷蒿、细叶葱、阿尔泰狗娃花和银灰旋花5种植物根际土壤微生物群落多样性特征。【结果】两种不同草原中5种不同植物根际土壤中可培养微生物数量存在显著性差异(P0.05),阿德格草原中短花针茅根际土壤中可培养微生物总数显著高于其他植物根际,格根塔拉草原中阿尔泰狗娃花根际土壤中可培养微生物总数显著高于其他植物;两样地不同植物根际土壤微生物的平均颜色变化率(average well color development,AWCD)均表现为格根塔拉样地高于阿德格样地,而且呈"S"型变化。培养96 h后格根塔拉草原5种植物的Shannon指数与Simpson指数高于阿德格草原,同时银灰旋花根际土壤微生物多样性指数在两个草原中差异极显著;两个草原不同植物根际土壤微生物对碳源的利用主要是氨基酸类和碳水化合物碳源,对于L-天门冬酰胺、r-羟基丁酸、L-丝氨酸和D-半乳糖醛酸等碳源的功能微生物显著富集,根际土壤微生物的AWCD和多样性指数与细菌、放线菌以及土壤微生物总数呈极显著正相关性(P0.01),均匀度指数与细菌、放线菌以及土壤微生物总数量呈显著负相关性(P0.05)。【结论】不同植物根际土壤微生物对碳源的利用能力和偏好出现差异,而且根际土壤微生物数量越高,微生物碳代谢能力、微生物群落多样性越丰富。     

根际细菌群落结构与装配对烟草根系生长性状的影响

植物根际微生物与植物生长密切相关,但根际微生物群落如何影响根系的发育情况仍研究甚少。本研究利用16S rRNA基因高通量测序技术检测了烟草的根际细菌群落,并探究了烟草根系不同发育情况与根际微生物群落差异的关联机制。结果表明：相比不发达根系（UDR）,发达根系（WDR）的根际细菌物种的丰度和多样性均较高,Gallionella和Luteimona等属的丰度显著增加,而Edaphobaculum、PLTA13和Rhodobacter等属的丰度则显著降低（P<0.05）;UDR的分子生态网络更加复杂,且物种间相互作用强,特别是合作行为,而WDR的网络关键节点数较多,其碳循环相关网络模块数与UDR相比增加;此外,WDR的根际细菌群落装配更趋向于发育聚集,且环境过滤在其中发挥了更重要的作用。总体上,本研究结果强调了根际微生物群落的结构组成、网络变化和群落装配在植物根系的生长过程中的重要作用,为植物根际微生物生态学研究提供了理论依据。     

Maize germplasm chronosequence shows crop breeding history impacts recruitment of the rhizosphere microbiome

Recruitment of microorganisms to the rhizosphere varies among plant genotypes, yet an understanding of whether the microbiome can be altered by selection on the host is relatively unknown. Here, we performed a common garden study to characterize recruitment of rhizosphere microbiome, functional groups, for 20 expired Plant Variety Protection Act maize lines spanning a chronosequence of development from 1949 to 1986. This time frame brackets a series of agronomic innovations, namely improvements in breeding and the application of synthetic nitrogenous fertilizers, technologies that define modern industrial agriculture. We assessed the impact of chronological agronomic improvements on recruitment of the rhizosphere microbiome in maize, with emphasis on nitrogen cycling functional groups. In addition, we quantified the microbial genes involved in nitrogen cycling and predicted functional pathways present in the microbiome of each genotype. Both genetic relatednesses of host plant and decade of germplasm development were significant factors in the recruitment of the rhizosphere microbiome. More recently developed germplasm recruited fewer microbial taxa with the genetic capability for sustainable nitrogen provisioning and larger populations of microorganisms that contribute to N losses. This study indicates that the development of high-yielding varieties and agronomic management approaches of industrial agriculture inadvertently modified interactions between maize and its microbiome.Subject terms: Microbial ecology, Plant sciences, Agricultural genetics     

Rice domestication influences the composition and function of the rhizosphere bacterial chemotaxis systems

Plant and Soil - Specific soil bacteria can sense and respond to the selective rhizosphere recruitment of root exudates using unique systems of chemotaxis that mediate plant-microbe and...     

根际微生物与植物再植病的发生发展关系

植物再植病严重危害农作物的生长发育,形成原因复杂,最新的研究显示它与根际微生态的变化相关,其中主要涉及根际微生物菌群结构的变化。现代高通量测序技术的迅速推广使得根际微生物和再植病间关系成为新的研究热点;本文根据国内外植物再植病病因、根际土壤微生物多样性以及它们与植物生长发育关系等多方面的研究成果,综合分析植物再植病与根际微生物间的关系,以期从根际微生物种群动态变化的角度认识植物再植病的病因并为防治提供新的思路。     

Rhizosphere shapes the associations between protistan predators and bacteria within microbiomes through the deterministic selection on bacterial communities

The assembly of bacterial communities in the rhizosphere is well-documented and plays a crucial role in supporting plant performance. However, we have limited knowledge of how plant rhizosphere determines the assembly of protistan predators and whether the potential associations between protistan predators and bacterial communities shift due to rhizosphere selection. To address this, we examined bacterial and protistan taxa from 443 agricultural soil samples including bulk and rhizosphere soils. Our results presented distinct patterns of bacteria and protistan predators in rhizosphere microbiome assembly. Community assembly of protistan predators was determined by a stochastic process in the rhizosphere and the diversity of protistan predators was reduced in the rhizosphere compared to bulk soils, these may be attributed to the indirect impacts from the altered bacterial communities that showed deterministic process assembly in the rhizosphere. Interestingly, we observed that the plant rhizosphere facilitates more close interrelationships between protistan predators and bacterial communities, which might promote a healthy rhizosphere microbial community for plant growth. Overall, our findings indicate that the potential predator–prey relationships within the microbiome, mediated by plant rhizosphere, might contribute to plant performance in agricultural ecosystems.     

Temporal dynamics and genetic diversity of chemotactic‐competent microbial populations in the rhizosphere

The contribution of chemotaxis to the competitive colonization of the rhizosphere for the vast majority of the soil community is unknown. We have developed and applied a molecular diagnostic tool, based on a gene encoding the central regulator of bacterial chemotaxis (cheA), to characterize and temporally track specific populations of native microbes with chemotaxis potential that are present in soil exposed to two rhizospheres: wheat and cowpea. The data show that the chemotactic‐competent communities present in the rhizospheres of the two plants are distinct and less diverse than the bulk soil, indicating the development of unique microbial communities. Consistent with the supposition that selection and recruitment of specific soil microbes takes place in the rhizosphere, the dynamics of specific cheA phylotypes provides support for the hypothesis that chemotaxis provides a competitive advantage to some soil microbes. This is the first study to examine and profile the genetic diversity of chemotaxis genes in natural populations. As such, it illustrates our limited understanding of microbial chemotaxis for the majority of soil microbes. It also highlights the value of a culture‐independent approach for examining chemotaxis populations in order to build empirical lines of evidence for its role in structuring of microbial assemblages.     

植物根际微生物群落构建的研究进展

植物根际是指植物根系与土壤的交界面,是根系自身生命活动和代谢对土壤影响最直接、最强烈的区域,其物理、化学和生物性质不同于土体土壤。在这个区域里,与植物发生相互作用的大量微生物,被称为根际微生物。根际微生物在植物的生长发育和植物病虫害的生物防治等方面都具有十分重要的意义。本文总结了根际微生物群落构建的研究现状,介绍了根际微生物的经典和最新的研究方法,包括根箱法、同位素技术以及高通量测序、菌群定量分析、高通量分离培养等方法在根际微生物研究中的应用,讨论了植物根系分泌物(碳水化物、氨基酸、黄酮类、酚类、激素及其信号物质)和土壤物理化学性质对根际微生物群落的影响,概述了根际微生物-植物的互作机制,以及根际微生物群落对植物的促生作用、提高植物抗逆性和抑制作用,并对根际微生物群落研究中存在的问题和未来发展方向进行了展望。     

Application of ecological and evolutionary theory to microbiome community dynamics across systems

A fundamental aim of microbiome research is to understand the factors that influence the assembly and stability of host-associated microbiomes, and their impact on host phenotype, ecology and evolution. However, ecological and evolutionary theories applied to predict microbiome community dynamics are largely based on macroorganisms and lack microbiome-centric hypotheses that account for unique features of the microbiome. This special feature sets out to drive advancements in the application of eco-evolutionary theory to microbiome community dynamics through the development of microbiome-specific theoretical and conceptual frameworks across plant, human and non-human animal systems. The feature comprises 11 research and review articles that address: (i) the effects of the microbiome on host phenotype, ecology and evolution; (ii) the application and development of ecological and evolutionary theories to investigate microbiome assembly, diversity and stability across broad taxonomic scales; and (iii) general principles that underlie microbiome diversity and dynamics. This cross-disciplinary synthesis of theoretical, conceptual, methodological and analytical approaches to characterizing host–microbiome ecology and evolution across systems addresses key research gaps in the field of microbiome research and highlights future research priorities.     

Changes in the Composition and Microbial Community of the Pepper Rhizosphere in Field with Bacterial Wilt Disease

Bacterial wilt caused by Ralstonia solanacearum is considered one of the most harmful diseases of pepper plants. Recently, research on plant disease control through the rhizosphere microbiome has been actively conducted. In this study, the relationship with disease occurrence between the neighboring plant confirmed by analyzing the physicochemical properties of the rhizosphere soil and changes in the microbial community. The results confirmed that the microbial community changes significantly depending on the organic matters, P₂O₅, and clay in the soil. Despite significant differences in microbial communities according to soil composition, Actinobacteriota at the phylum level was higher in healthy plant rhizosphere (mean of relative abundance, D: 8.05 ± 1.13; H: 10.06 ± 1.59). These results suggest that Actinobacteriota may be associated with bacterial wilt disease. In this study, we present basic information for constructing of healthy soil in the future by presenting the major microbial groups that can suppress bacterial wilt.     

Contrasting Strategies: Human Eukaryotic Versus Bacterial Microbiome Research

Most discussions of human microbiome research have focused on bacterial investigations and findings. Our target is to understand how human eukaryotic microbiome research is developing, its potential distinctiveness, and how problems can be addressed. We start with an overview of the entire eukaryotic microbiome literature (578 papers), show tendencies in the human‐based microbiome literature, and then compare the eukaryotic field to more developed human bacterial microbiome research. We are particularly concerned with problems of interpretation that are already apparent in human bacterial microbiome research (e.g. disease causality, probiotic interventions, evolutionary claims). We show where each field converges and diverges, and what this might mean for progress in human eukaryotic microbiome research. Our analysis then makes constructive suggestions for the future of the field.