地下-地上植物-微生物相互作用:关注大豆、根际细菌和菌根真菌。

Q3 Immunology and Microbiology Open Microbiology Journal Pub Date : 2018-07-31 DOI:10.2174/1874285801812010261
Nicholas O Igiehon, Olubukola O Babalola
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引用次数: 70

摘要

简介:生物体很少单独存在,通常与几种宿主相互作用,这些相互作用与土壤的物理化学参数一起影响植物的生长和发育。对地下和地上微生物群落的研究揭示了根际内无数有趣的相互作用,其中许多相互作用是由植物根系分泌的分泌物促进的。这些相互作用可以在农业中得到有益的利用,以提高作物生产力,特别是在半干旱和干旱环境中。根际:根际是指土壤中靠近植物根部的区域,植物根部含有大量不同的生物。在根际发现的候选微生物的例子包括丛枝菌根真菌(AMF)和根际细菌。这些根际微生物利用植物根系分泌物,如粘液和类黄酮,这些分泌物能够影响它们的多样性和功能,并增强它们在植物根系定植的潜力。微生物和植物之间的自然相互作用:在自然环境中,植物与不同的微生物相互作用,这些微生物在根际地下和叶层地上生长。一些植物与微生物的相互作用(可以是拮抗、闭经、寄生和共生的形式)保护宿主植物免受有害的微生物和非微生物入侵者的侵害,并为植物提供营养,而另一些则对植物产生负面影响。这些相互作用可以影响地上植物的生物量发展,从而在维持植物生长方面发挥重要作用。因此,了解根际和叶际微生物的相互作用对于减少对传统化肥的依赖的农业实践至关重要,因为传统化肥对环境有已知的负面影响。地下根际细菌的相互作用缓解了干旱胁迫:干旱胁迫是影响全球农业生产力的主要因素之一,而且可能会进一步增加。地下根际细菌的相互作用可能在缓解植物干旱胁迫方面发挥重要作用。这些有益的根际细菌定殖在植物根际,并通过上调或下调干旱反应基因,如抗坏血酸过氧化物酶、S-腺苷甲硫氨酸合成酶和热休克蛋白,赋予植物耐旱性。通过经济学研究深入了解地下和地上微生物的相互作用:调查环境中复杂的微生物群落是一个巨大的挑战。因此,对根际微生物的组学研究很重要,因为根际是大多数植物与微生物相互作用发生的地方。这篇综述的目的之一不是详细介绍目前的所有组学技术,而是强调目前的组学技术可能导致在根际检测新基因及其各自的蛋白质,这可能对提高作物(如大豆)生产力具有重要意义,特别是在半干旱和干旱环境中。未来前景和结论:植物与微生物的相互作用尚不完全清楚,因此,有必要对这些相互作用进行进一步研究,以获得更多对可持续农业发展有用的见解。随着组学技术的出现,现在可以有效地监测根际微生物群落的转化及其对植物发育的影响。这可能为科学家发现能够与植物有效相互作用的新微生物物种铺平道路。这些微生物物种可以用作生物肥料和/或生物农药,以提高作物产量并加强全球粮食安全。
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Below-ground-above-ground Plant-microbial Interactions: Focusing on Soybean, Rhizobacteria and Mycorrhizal Fungi.

Introduction: Organisms seldom exist in isolation and are usually involved in interactions with several hosts and these interactions in conjunction with the physicochemical parameters of the soil affect plant growth and development. Researches into below and aboveground microbial community are unveiling a myriad of intriguing interactions within the rhizosphere, and many of the interactions are facilitated by exudates that are secreted by plants roots. These interactions can be harnessed for beneficial use in agriculture to enhance crop productivity especially in semi-arid and arid environments.

The rhizosphere: The rhizosphere is the region of soil close to plants roots that contain large number of diverse organisms. Examples of microbial candidates that are found in the rhizosphere include the Arbuscular Mycorrhizal Fungi (AMF) and rhizobacteria. These rhizosphere microorganisms use plant root secretions such as mucilage and flavonoids which are able to influence their diversity and function and also enhance their potential to colonize plants root.

Natural interactions between microorganisms and plant: In the natural environments, plants live in interactions with different microorganisms, which thrive belowground in the rhizosphere and aboveground in the phyllosphere. Some of the plant-microbial interactions (which can be in the form of antagonism, amensalism, parasitism and symbiosis) protect the host plants against detrimental microbial and non-microbial invaders and provide nutrients for plants while others negatively affect plants. These interactions can influence below-ground-above-ground plants' biomass development thereby playing significant role in sustaining plants. Therefore, understanding microbial interactions within the rhizosphere and phyllosphere is urgent towards farming practices that are less dependent on conventional chemical fertilizers, which have known negative impacts on the environments.

Below ground rhizobacteria interactions alleviate drought stress: Drought stress is one of the major factors militating against agricultural productivity globally and is likely to further increase. Belowground rhizobacteria interactions could play important role in alleviating drought stress in plants. These beneficial rhizobacterial colonize the rhizosphere of plants and impart drought tolerance by up regulation or down regulation of drought responsive genes such as ascorbate peroxidase, S-adenosyl-methionine synthetase, and heat shock protein.

Insights into below and above the ground microbial interactions via omic studies: Investigating complex microbial community in the environment is a big challenge. Therefore, omic studies of microorganisms that inhabit the rhizosphere are important since this is where most plant-microbial interactions occur. One of the aims of this review is not to give detailed account of all the present omic techniques, but instead to highlight the current omic techniques that can possibly lead to detection of novel genes and their respective proteins within the rhizosphere which may be of significance in enhancing crop plants (such as soybean) productivity especially in semi-arid and arid environments.

Future prospects and conclusions: Plant-microbial interactions are not totally understood, and there is, therefore, the need for further studies on these interactions in order to get more insights that may be useful in sustainable agricultural development. With the emergence of omic techniques, it is now possible to effectively monitor transformations in rhizosphere microbial community together with their effects on plant development. This may pave way for scientists to discover new microbial species that will interact effectively with plants. Such microbial species can be used as biofertilizers and/or bio-pesticides to increase crop yield and enhance global food security.

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来源期刊
Open Microbiology Journal
Open Microbiology Journal Immunology and Microbiology-Immunology and Microbiology (all)
CiteScore
1.80
自引率
0.00%
发文量
24
期刊介绍: The Open Microbiology Journal is a peer-reviewed open access journal which publishes research articles, reviews/mini-reviews, case studies, guest edited thematic issues and short communications/letters covering theoretical and practical aspects of Microbial systematics, evolutionary microbiology, immunology, virology, parasitology , bacteriology, mycology, phycology, protozoology, microbial ecology, molecular biology, microbial physiology, biochemistry, microbial pathogenesis, host-microbe interaction, systems microbiology, synthetic microbiology, bioinformatics. The Open Microbiology Journal , a peer-reviewed journal, is an important and reliable source of current information on developments in the field. The emphasis will be on publishing quality papers rapidly and freely available to researchers worldwide.
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