Rhizosphere carbon flow measurement and implications: from isotopes to reporter genes

Despite the fundamental importance of rhizosphere C-flow in managed and natural systems, reliable measurement/resolution of C-flow and assessment of its consequences have largely remained elusive to soil biologists. Techniques involving both radioactive (¹⁴C) and stable (¹³C) isotopes of carbon have made some progress in terms of studying rhizosphere C-flow. Pulse-chase techniques have been used effectively to study dynamics of C-transfer to the rhizosphere and rhizosphere microbial biomass. The information obtained through pulse-chase is strongly dependent on the chase period following the labelling event. Continuous labelling is primarily used to determine plant inputs to soil over an extended time period and includes all kinds of C input – from root turnover, root respiration, root exudation, production of mucilage, etc. One of the main constraints to both approaches is that distinguishing root from microbial respiration is difficult, if not impossible. ¹³C techniques have gone some way towards resolving this difficulty, although ¹³C signatures in the plant–soil system are not easy to interpret and detailed resolution of carbon flow through different components of the rhizosphere biomass is unlikely to be achieved in such an inherently `noisy' system. Recent developments in molecular biology now provide a new opportunity to resolve rhizosphere C-flow and its implications. Reporter gene systems where, for example, rhizobacteria are marked with lux and unstable gfp reporters, overcome the difficulty of distinguishing root and microbial C fluxes and complement the isotopic and more traditional approaches. Reporter systems have now begun to resolve the competitive C sink strengths of different components of the rhizosphere microbial community and assess how a rhizobacterial inoculum may change C-flow in applications such as disease control and rhizoremediation of contaminated land. Fusion of reporter genes to nutrient (N and P) starvation genes in rhizobacteria has also enabled in situ characterisation of nutrient depletion around the root and assessment of the impact of changes in C-flow (such as those induced by climate change) on nutrient depletion dynamics. The availability of an integrated approach involving isotopic, molecular biological and other techniques now offers an exciting new era where reliable measurement and resolution of rhizosphere C-flow (and its consequences) can contribute to our understanding of ecosystem function and to management of crop-microbe interactions.     

污染物在根-土界面的化学行为与生态效应

根-土界面是污染物进入植物体内的主要通道和导致一系列生态安全问题的特殊微生态区,本文提出污染物在根-土界面上的化学行为和生态效应包括根际化学行为与生态效应,根系化学行为与生态效应两个方面的具体内容,并从理论上根据最新的研究进展对这两方面内容进行了探讨,指出根际化学行为与生态效应包括根际pH环境与吸附行为、根际氧化-还原行为、根际化学致毒效应、根际微生物效应及根际生物酶反应等;根系化学行为与生态效应包括根系分泌物、根系酶系统的影响、干扰正常生理过程、改变细胞结构与功能、干扰生物大分子的结构和功能等,并阐述根-土界面上的化学行为和生态效应在污染生态学中的重要性以及研究中存在的问题。     

Root Caps and Rhizosphere

In this paper we discuss recent work on the physiological, molecular, and mechanical mechanisms that underlie the capacity of root caps to modulate the properties of the rhizosphere and thereby foster plant growth and development. The root cap initially defines the rhizosphere by its direction of growth, which in turn occurs in response to gradients in soil conditions and gravity. The ability of the root cap to modulate its environment is largely a result of the release of exudates and border cells, and so provides a potential method to engineer the rhizosphere. Factors affecting the release of border cells from the outer surface of the root cap, and function of these cells and their exudates in the rhizosphere, are considered in detail. Release of border cells into the rhizosphere depends on soil matric potential and mechanical impedance, in addition to a host of other environmental conditions. There is good evidence of unidentified feedback signals between border cells and the root cap meristem, and some potential mechanisms are discussed. Root border cells play a significant mechanical role in decreasing frictional resistance to root penetration, and a conceptual model for this function is discussed. Root and border cell exudates influence specific interactions between plant hosts and soil organisms, including pathogenic fungi. The area of exudates and border cell function in soil is an exciting and developing one that awaits the production of appropriate mutant and transgenic lines for further study in the soil environment.     

Root Caps and Rhizosphere

In this paper we discuss recent work on the physiological, molecular, and mechanical mechanisms that underlie the capacity of root caps to modulate the properties of the rhizosphere and thereby foster plant growth and development. The root cap initially defines the rhizosphere by its direction of growth, which in turn occurs in response to gradients in soil conditions and gravity. The ability of the root cap to modulate its environment is largely a result of the release of exudates and border cells, and so provides a potential method to engineer the rhizosphere. Factors affecting the release of border cells from the outer surface of the root cap, and function of these cells and their exudates in the rhizosphere, are considered in detail. Release of border cells into the rhizosphere depends on soil matric potential and mechanical impedance, in addition to a host of other environmental conditions. There is good evidence of unidentified feedback signals between border cells and the root cap meristem, and some potential mechanisms are discussed. Root border cells play a significant mechanical role in decreasing frictional resistance to root penetration, and a conceptual model for this function is discussed. Root and border cell exudates influence specific interactions between plant hosts and soil organisms, including pathogenic fungi. The area of exudates and border cell function in soil is an exciting and developing one that awaits the production of appropriate mutant and transgenic lines for further study in the soil environment.     

Periodic carbon flushing to roots of Quercus rubra saplings affects soil respiration and rhizosphere microbial biomass

Patterns of root/shoot carbon allocation within plants have been studied at length. The extent, however, to which patterns of carbon allocation from shoots to roots affect the timing and quantity of organic carbon release from roots to soil is not known. We employed a novel approach to study how natural short-term variation in the allocation of carbon to roots may affect rhizosphere soil biology. Taking advantage of the semi-determinate phenology of young northern red oak (Quercus rubra L.), we examined how pulsed delivery of carbon from shoots to roots affected dynamics of soil respiration as well as microbial biomass and net nitrogen mineralization in the rhizosphere. Young Q. rubra exhibit (1) clear switches in the amount of carbon allocated below-ground that are non-destructively detected simply by observing pulsed shoot growth above-ground, and (2) multiple switches in internal carbon allocation during a single growing season, ensuring our ability to detect short-term effects of plant carbon allocation on rhizosphere biology separate from longer-term seasonal effects. In both potted oaks and oaks rooted in soil, soil respiration varied inversely with shoot flush stage through several oak shoot flushes. In addition, upon destructive harvest of potted oaks, microbial biomass in the rhizosphere of saplings with actively flushing shoots was lower than microbial biomass in the rhizosphere of saplings with shoots that were not flushing. Given that plants have evolved with their roots in contact with soil microbes, known species-specific carbon allocation patterns within plants may provide insight into interactions among roots, symbionts, and free-living microbes in the dynamic soil arena.     

Mycorrhizosphere interactions to improve plant fitness and soil quality

Arbuscular mycorrhizal fungi are key components of soil microbiota and obviously interact with other microorganisms in the rhizosphere, i.e. the zone of influence of plant roots on microbial populations and other soil constituents. Mycorrhiza formation changes several aspects of plant physiology and some nutritional and physical properties of the rhizospheric soil. These effects modify the colonization patterns of the root or mycorrhizas (mycorrhizosphere) by soil microorganisms. The rhizosphere of mycorrhizal plants, in practice a mycorrhizosphere, harbors a great array of microbial activities responsible for several key ecosystem processes. This paper summarizes the main conceptual principles and accepted statements on the microbial interactions between mycorrhizal fungi and other members of rhizosphere microbiota and discusses current developments and future trends concerning the following topics: (i) effect of soil microorganisms on mycorrhiza formation; (ii) mycorrhizosphere establishment; (iii) interactions involved in nutrient cycling and plant growth; (iv) interactions involved in the biological control of plant pathogens; and (v) interactions to improve soil quality. The main conclusion is that microbial interactions in the rhizosphere of mycorrhizal plants improve plant fitness and soil quality, critical issues for a sustainable agricultural development and ecosystem functioning. This revised version was published online in August 2006 with corrections to the Cover Date.     

The interconnected rhizosphere: High network complexity dominates rhizosphere assemblages

While interactions between roots and microorganisms have been intensively studied, we know little about interactions among root‐associated microbes. We used random matrix theory‐based network analysis of 16S rRNA genes to identify bacterial networks associated with wild oat (Avena fatua) over two seasons in greenhouse microcosms. Rhizosphere networks were substantially more complex than those in surrounding soils, indicating the rhizosphere has a greater potential for interactions and niche‐sharing. Network complexity increased as plants grew, even as diversity decreased, highlighting that community organisation is not captured by univariate diversity. Covariations were predominantly positive (> 80%), suggesting that extensive mutualistic interactions may occur among rhizosphere bacteria; we identified quorum‐based signalling as one potential strategy. Putative keystone taxa often had low relative abundances, suggesting low‐abundance taxa may significantly contribute to rhizosphere function. Network complexity, a previously undescribed property of the rhizosphere microbiome, appears to be a defining characteristic of this habitat.     

基于高通量测序的杨树人工林根际土壤真菌群落结构

研究不同根序细根根际土壤微生物群落组成结构对深入了解根系-微生物互作关系具有重要意义.本研究采用Illumina MiSeq测序平台,对杨树人工林非根际土壤和不同根序细根根际土壤的真菌群落结构进行分析.物种注释结果显示: 杨树1～2级根(R1)、3级根(R2)和4～5级(R3)根际及非根际土壤(NR)中分别包含128、124、130和101个真菌属,表明杨树根际存在对真菌群落构建的选择性机制.不同根序根际土壤中相对丰度>1%的真菌属有7个,木霉属在1～2级根根际土壤中丰度较高,毛孢子菌属和曲霉属分别是3级根和4～5级根根际土壤中丰度最高的真菌属.α多样性指数表明: 根际土壤真菌的多样性在不同根序间存在显著差异,低级根显著高于高级根(P<0.05).β多样性指数表明: 真菌群落随着序级的升高差异性不断上升,相似性不断降低.不同根序细根根际真菌群落的趋异化组成和结构与细根功能具有密切关系.     

PREFACE

This highlight section of the Annals of Botany contains a collectionof articles that focus on the structure and function of rootsof flowering plants. Most of the papers presented are basedon talks given at a symposium on root structure and functionat the XVII International Botanical Congress, Vienna, Austria,July 2005. Many of the articles, briefly capsulated below, examinethe interactions between plants and the rhizosphere—thebelow-ground environment that immediately surrounds the root.The rhizosphere is far more complex physically, chemically andbiologically than the above-ground environment of the shootbecause (1) rapid, long-distance movement of energy or matteris limited through     

植物根系分泌物主要生态功能研究进展

根系分泌物在植物根系-土壤-微生物互作过程及其生态反馈机制中发挥重要作用。在植物根际复杂网络互作过程中, 根系分泌物被认为是“根际对话”的媒介, 其在调控植物适应微生境、缓解根际养分竞争及构建根际微生物群落结构方面意义重大。该文结合国内外该领域主要研究成果, 综述了根系分泌物对植物生长、土壤微生物特性及土壤养分循环的影响, 并展望了未来根系分泌物的研究方向。     

Research Advances in the Main Ecological Functions of Root Exudates

根系分泌物在植物根系-土壤-微生物互作过程及其生态反馈机制中发挥重要作用。在植物根际复杂网络互作过程中, 根系分泌物被认为是“根际对话”的媒介, 其在调控植物适应微生境、缓解根际养分竞争及构建根际微生物群落结构方面意义重大。该文结合国内外该领域主要研究成果, 综述了根系分泌物对植物生长、土壤微生物特性及土壤养分循环的影响, 并展望了未来根系分泌物的研究方向。     

The role of ABC transporters in kin recognition in Arabidopsis thaliana

The ability to sense and respond to the surrounding rhizosphere including communications with neighboring plants and microbes is essential for plant survival. Recently, it has been established that several plant species including Arabidopsis thaliana have the ability to recognize rhizospheric neighbors based or their genetic identity. This study investigated the role of ABC transporters in kin recognition in A. thaliana based on previous evidence that root secretions are involved in the kin recognition response and that ABC transporters are responsible for secretion of a number of compounds. Three genes, AtPGP1, AtATH1 and AtATH10, are all implicated to be partially involved in the complex kin recognition response in A. thaliana based on this report. These findings highlight the importance of ABC transporters in understanding root secretions and plant-plant community interactions.Key words: root biology, rhizosphere, kin recognition, root secretions, Arabidopsis     

Rhizosphere engineering for sustainable crop production: entropy-based insights

There is a growing interest in exploring interactions at root–soil interface in natural and agricultural ecosystems, but an entropy-based understanding of these dynamic rhizosphere processes is lacking. We have developed a new conceptual model of rhizosphere regulation by localized nutrient supply using thermodynamic entropy. Increased nutrient-use efficiency is achieved by rhizosphere management based on self-organization and minimized entropy via equilibrium attractors comprising (i) optimized root strategies for nutrient acquisition and (ii) improved information exchange related to root–soil–microbe interactions. The cascading effects through different hierarchical levels amplify the underlying processes in plant–soil system. We propose a strategy for manipulating rhizosphere dynamics and improving nutrient-use efficiency by localized nutrient supply with minimization of entropy to underpin sustainable food/feed/fiber production.     

Beneficial and deleterious effects of HCN-producing pseudomonads on rhizosphere interactions

Rhizobacteria live around roots but also inside the cortical root tissues by utilizing organic substances released from root cells into the intercellular spaces and the root environment. The effects of metabolites of these rhizosphere-inhabiting bacteria on root physiology and plant development have hardly been studied. However, recent studies indicate that, depending on environmental factors and plant species, certain strains of rhizosphere Pseudomonas spp. and some of their metabolites such as HCN may inhibit or enhance plant establishment or inhibit development of plant disease. Cultural practices such as cropping frequency, no tillage, and soilless cultivation, as well as edaphic factors seem to determine these rhizosphere interactions.     

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。     

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。     

Perception and modification of plant flavonoid signals by rhizosphere microorganisms

Flavonoids are a diverse class of polyphenolic compounds that are produced as a result of plant secondary metabolism. They are known to play a multifunctional role in rhizospheric plant-microbe and plant-plant communication. Most familiar is their function as a signal in initiation of the legume-rhizobia symbiosis, but, flavonoids may also be signals in the establishment of arbuscular mycorrhizal symbiosis and are known agents in plant defence and in allelopathic interactions. Flavonoid perception by, and impact on, their microbial targets (e.g. rhizobia, plant pathogens) is relatively well characterized. However, potential impacts on 'non-target' rhizosphere inhabitants ('non-target' is used to distinguish those microorganisms not conventionally known as targets) have not been thoroughly investigated. Thus, this review first summarizes the conventional roles of flavonoids as nod gene inducers, phytoalexins and allelochemicals before exploring questions concerning 'non-target' impacts. We hypothesize that flavonoids act to shape rhizosphere microbial community structure because they represent a potential source of carbon and toxicity and that they impact on rhizosphere function, for example, by accelerating the biodegradation of xenobiotics. We also examine the reverse question, 'how do rhizosphere microbial communities impact on flavonoid signals?' The presence of microorganisms undoubtedly influences the quality and quantity of flavonoids present in the rhizosphere, both through modification of root exudation patterns and microbial catabolism of exudates. Microbial alteration and attenuation of flavonoid signals may have ecological consequences for below-ground plant-microbe and plant-plant interaction. We have a lack of knowledge concerning the composition, concentration and bioavailability of flavonoids actually experienced by microbes in an intact rhizosphere, but this may be addressed through advances in microspectroscopic and biosensor techniques. Through the use of plant mutants defective in flavonoid biosynthesis, we may also start to address the question of the significance of flavonoids in shaping rhizosphere community structure and function.     

Is rhizosphere remediation sufficient for sustainable revegetation of mine tailings?

Background

Revegetation of mine tailings (fine-grained waste material) starts with the reconstruction of root zones, consisting of a rhizosphere horizon (mostly topsoil and/or amended tailings) and the support horizon beneath (i.e. equivalent to subsoil – mostly tailings), which must be physically and hydro-geochemically stable. This review aims to discuss key processes involved in the development of functional root zones within the context of direct revegetation of tailings and introduces a conceptual process of rehabilitating structure and function in the root zones based on a state transition model.

Scope

Field studies on the revegetation of tailings (from processing base metal ore and bauxite residues) are reviewed. Particular focus is given to tailings'' properties that limit remediation effectiveness. Aspects of root zone reconstruction and vegetation responses are also discussed.

Conclusions

When reconstructing a root zone system, it is critical to restore physical structure and hydraulic functions across the whole root zone system. Only effective and holistically restored systems can control hydro-geochemical mobility of acutely and chronically toxic factors from the underlying horizon and maintain hydro-geochemical stability in the rhizosphere. Thereafter, soil biological capacity and ecological linkages (i.e. carbon and nutrient cycling) may be rehabilitated to integrate the root zones with revegetated plant communities into sustainable plant ecosystems. A conceptual framework of system transitions between the critical states of root zone development has been proposed. This will illustrate the rehabilitation process in root zone reconstruction and development for direct revegetation with sustainable plant communities. Sustainable phytostabilization of tailings requires the systematic consideration of hydro-geochemical interactions between the rhizosphere and the underlying supporting horizon. It further requires effective remediation strategies to develop hydro-geochemically stable and biologically functional root zones, which can facilitate the recovery of the microbial community and ecological linkages with revegetated plant communities.     

Glyphosate affects micro-organisms in rhizospheres of glyphosate-resistant soybeans

Aims: Glyphosate‐resistant (GR) soybean production increases each year because of the efficacy of glyphosate for weed management. A new or ‘second’ generation of GR soybean (GR2) is now commercially available for farmers that is being promoted as higher yielding relative to the previous, ‘first generation’ (GR1) cultivars. Recent reports show that glyphosate affects the biology and ecology of rhizosphere micro‐organisms in GR soybean that affect yield. The objective of this research was to evaluate the microbiological interactions in the rhizospheres of GR2 and GR1 soybean and the performance of the cultivars with different rates of glyphosate applied at different growth stages. Methods and Results: A greenhouse study was conducted using GR1 and GR2 soybean cultivars grown in a silt loam soil. Glyphosate was applied at V2, V4 and V6 growth stages at three rates. Plants harvested at R1 growth stage had high root colonization by Fusarium spp.; reduced rhizosphere fluorescent pseudomonads, Mn‐reducing bacteria, and indoleacetic acid–producing rhizobacteria; and reduced shoot and root biomass. Conclusions: Glyphosate applied to GR soybean, regardless of cultivar, negatively impacts the complex interactions of microbial groups, biochemical activity and root growth that can have subsequent detrimental effects on plant growth and productivity. Significance and Impact of the Study: The information presented here will be crucial in developing strategies to overcome the potential detrimental effects of glyphosate in GR cropping systems.     

Increased killing of Bacillus subtilis on the hair roots of transgenic T4 lysozyme-producing potatoes

Transgenic potato plants expressing the phage T4 lysozyme gene which are resistant to the plant-pathogenic enterobacterium Erwinia carotovora subsp. carotovora have been constructed. The agricultural growth of these potatoes might have harmful effects on soil microbiota as a result of T4 lysozyme release into the rhizosphere. To assess the bactericidal effect of roots, we have developed a novel method to associate the cells of Bacillus subtilis with hair roots of plants and to quantify the survival of cells directly on the root surface by appropriate staining and fluorescence microscopy. With this technique, we found that the roots of potato plants (Désirée and transgenic control lines) without T4 lysozyme gene display measurable killing activity on root-adsorbed B. subtilis cells. Killing was largely independent of the plant age and growth of plants in greenhouse or field plots. Roots from potato lines expressing the T4 lysozyme gene always showed significantly (1.5- to 3.5-fold) higher killing. It is concluded that T4 lysozyme is released from the root epidermis cells and is active in the fluid film on the root surface. We discuss why strong negative effects of T4 lysozyme-producing potatoes on soil bacteria in field trials may not be observed. We propose that the novel method presented here to study interactions of bacteria with roots can be applied not only to bacterial killing but also to interactions leading to growth-sustaining effects of plants on bacteria.