根际微生物组组装与植物健康

土壤微生物拥有高度多样化的群落结构,其通过与植物发生复杂的相互作用影响植物健康,也被称为植物的第二基因组。最近研究表明植物能通过改变根际分泌物的组成影响根际微生物群落的组装,反之,根际微生物群落组成的改变能够通过影响植物营养吸收和抵御生物及非生物胁迫的能力影响植物健康。除此之外,农艺管理也是影响土壤微生物群落组装方式的重要因素。但到目前为止,根际微生物与宿主植物及土壤微生物之间互作机制的研究尚不清楚。本文将从农艺管理和宿主植物对微生物群落组装的影响及根际微生物组对植物健康的影响进行总结,为增加作物产量提供机会。     

Maize seed endophytes

Maize is a vital global crop, and each seed (kernel) hosts an ecosystem of microbes living inside it. However, we know very little about these endophytes and what their role is in plant production and physiology. In this Microreview, I summarize the major questions around maize seed endophytes, including what organisms are present, how they get there, whether and how they transmit across generations, and how they and the plant affect each other. Although several studies touch on each of these areas, ultimately there are far more questions than answers. Future priorities for research on maize seed endophytes should include understanding what adaptations allow microbes to be seed endophytes, how the host genetics and the environment affect these communities, and how maize seed endophytes ultimately contribute to the next generation of plants.     

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.     

Microbial effects on plant phenology and fitness

Plant development and the timing of developmental events (phenology) are tightly coupled with plant fitness. A variety of internal and external factors determine the timing and fitness consequences of these life-history transitions. Microbes interact with plants throughout their life history and impact host phenology. This review summarizes current mechanistic and theoretical knowledge surrounding microbe-driven changes in plant phenology. Overall, there are examples of microbes impacting every phenological transition. While most studies have focused on flowering time, microbial effects remain important for host survival and fitness across all phenological phases. Microbe-mediated changes in nutrient acquisition and phytohormone signaling can release plants from stressful conditions and alter plant stress responses inducing shifts in developmental events. The frequency and direction of phenological effects appear to be partly determined by the lifestyle and the underlying nature of a plant–microbe interaction (i.e., mutualistic or pathogenic), in addition to the taxonomic group of the microbe (fungi vs. bacteria). Finally, we highlight biases, gaps in knowledge, and future directions. This biotic source of plasticity for plant adaptation will serve an important role in sustaining plant biodiversity and managing agriculture under the pressures of climate change.     

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.     

Focus: Microbiome: Unraveling the Dynamics of the Human Vaginal Microbiome

Four Lactobacillus species, namely L. crispatus, L. iners, L. gasseri, and L. jensenii, commonly dominate the vaginal communities of most reproductive-age women. It is unclear why these particular species, and not others, are so prevalent. Historically, estrogen-induced glycogen production by the vaginal epithelium has been proffered as being key to supporting the proliferation of vaginal lactobacilli. However, the ‘fly in the ointment’ (that has been largely ignored) is that the species of Lactobacillus commonly found in the human vagina cannot directly metabolize glycogen. It would appear that this riddle has been solved as studies have demonstrated that vaginal lactobacilli can metabolize the products of glycogen depolymerization by α-amylase, and fortunately, amylase activity is found in vaginal secretions. These amylases are presumed to be host-derived, but we suggest that other bacterial populations in vaginal communities could also be sources of amylase in addition to (or instead of) the host. Here we briefly review what is known about human vaginal bacterial communities and discuss how glycogen-derived resources and resource competition might shape the composition and structure of these communities.     

Overview of the rules of the microbial engagement in the gut microbiome: a step towards microbiome therapeutics

Human gut microbiome is a diversified, resilient, immuno-stabilized, metabolically active and physiologically essential component of the human body. Scientific explorations have been made to seek in-depth information about human gut microbiome establishment, microbiome functioning, microbiome succession, factors influencing microbial community dynamics and the role of gut microbiome in health and diseases. Extensive investigations have proposed the microbiome therapeutics as a futuristic medicine for various physiological and metabolic disorders. A comprehensive outlook of microbial colonization, host–microbe interactions, microbial adaptation, commensal selection and immuno-survivability is still required to catalogue the essential genetic and physiological features for the commensal engagement. Evolution of a structured human gut microbiome relies on the microbial flexibility towards genetic, immunological and physiological adaptation in the human gut. Key features for commensalism could be utilized in developing tailor-made microbiome-based therapy to overcome various physiological and metabolic disorders. This review describes the key genetics and physiological traits required for host–microbe interaction and successful commensalism to institute a human gut microbiome.     

马铃薯全生育期内根际微生物组变化规律

[目的]陆生植物根际环境与土壤中的微生物菌群关系密切,其根际微生物群落动态极可能直接影响着植物健康及养分高效利用。虽然根际益生菌已被证实可用于提高作物生产力,但由于缺乏对这些菌群组成动态变化规律的认识了解,它们的开发受到限制。研究马铃薯全生育期根际菌群的动态变化规律,探讨根际菌群变化与马铃薯发育时期的相关性,为针对马铃薯不同生长时期开发专用生物益生菌肥奠定理论基础。[方法]本研究着眼于马铃薯田间全生命周期微生物组动态变化,通过Illumina MiSeq高通量测序技术对不同时间点马铃薯根际细菌16S rRNA基因V3-V4区和真菌ITS区测序并对操作分类单位(OTU)进行聚类,分析样品间微生物群落的多样性特征,并通过机器学习的方法建立模型,将根际菌群与田间马铃薯发育时间相关联。[结果]根际菌群在马铃薯各个发育阶段随时间变化明显,营养生长阶段的微生物群落结构发生了显著变化,随着结薯期的开始逐渐稳定,直到块茎成熟后期根际菌群再次出现较大变化,且在不同施肥处理间呈现较大差异。进一步基于模型挖掘了与马铃薯发育时间相关联的22个特征细菌类群和16个特征真菌类群,其中苗期和结薯末期的特征类群分别为梭菌(Clostridium)和放线菌(Actinobacteria)。[结论]马铃薯的生长发育时期是影响根际微生物群落组成的主要因素,益生菌肥的添加主要影响马铃薯结薯末期的细菌微生物菌群结构。     

玉米根际土壤中铜形态的动态变化

采用根垫法研究玉米根际土壤形态动态变化。结果表明：玉米生长过程中根际土壤铜形态发生显著变化。植物生长前期交换态和碳酸盐结合态铜含量逐渐增加,随后增加量减少。植物生长后期根际交换态和碳酸盐结合态铜含量低于非根际土壤。这种变化主要由根际环境变化与植物吸收引起。与根限土壤中铜形态变化,特别是交换态铜含量变化关系密切的因素包括土壤溶解性有机碳、pH和土壤微生物。随着植物生物量的增加,对铜的吸收速率不断增加,导致根限土壤中有效态铜的先增后减。     

高效降解生活污水中COD的根际微生物的分离筛选

采用平板划线法从人工湿地的芦苇、美人蕉的根际土壤中分离出若干细菌、真菌、放线菌菌株,在实验室条件下检测了这些菌株对灭菌生活污水和自然生活污水COD的去除效果,结果表明4株细菌、1株放线菌、1株真菌对灭菌生活污水和自然生活污水COD均具有较高的去除率。4株细菌在降解灭菌生活污水COD的去除率在48 h后依次为75.4%、78.7%、83.5%、69.8%;其在降解未灭菌生活污水COD的去除率在48 h后依次为43.4%、47.8%、50.7%、36.8%;真菌对灭菌和未灭菌生活污水COD的去除率在48 h后分别为60.2%、41.3%;放线菌对灭菌和自然生活污水COD 48 h后的去除率分别为57.8%、46.4%。这几株高效降解COD的湿地根际微生物具有潜在的应用价值。     

Actinomycetes in the Rhizosphere of Barley Grown on Acid Soddy Podzolic Soil

The study of various factors (soil acidity, the variety of barley, and their developmental phases) on the rhizosphere actinomycete complex showed that it is soil acidity that substantially influences the population of rhizosphere actinomycetes. The effect of soil acidity was most likely due to the different tolerance of rhizosphere actinomycetes to high concentrations of the aluminum and hydrogen ions. The developmental phases of barley correlated with the population indices of only one genus of actinomycetes, Micromonospora.     

Microbiome resilience of Amazonian forests: Agroforest divergence to bacteria and secondary forest succession convergence to fungi

An alarming and increasing deforestation rate threatens Amazon tropical ecosystems and subsequent degradation due to frequent fires. Agroforestry systems (AFS) may offer a sustainable alternative, reportedly mimicking the plant–soil interactions of the natural mature forest (MF). However, the role of microbial community in tropical AFS remains largely unknown. This knowledge is crucial for evaluating the sustainability of AFS and practices given the key role of microbes in the aboveground–belowground interactions. The current study, by comparing different AFS and successions of secondary and MFs, showed that AFS fostered distinct groups of bacterial community, diverging from the MFs, likely a result of management practices while secondary forests converged to the same soil microbiome found in the MF, by favoring the same groups of fungi. Model simulations reveal that AFS would require profound changes in aboveground biomass and in soil factors to reach the same microbiome found in MFs. In summary, AFS practices did not result in ecosystems mimicking natural forest plant–soil interactions but rather reshaped the ecosystem to a completely different relation between aboveground biomass, soil abiotic properties, and the soil microbiome.     

活性污泥微生物组：去除污浊，只留清淡

活性污泥法诞生一百多年来,在污水处理特别是城市污水处理中发挥了不可替代的作用。活性污泥微生物是去除污染物包括新型有机和无机污染物的关键角色,活性污泥微生物组为微生物分离培养、功能鉴定和生态互作等方面的研究带来新的活力。     

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。     

Spatial Ecology of the Human Tongue Dorsum Microbiome

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