Evaluation of the biocontrol activity of Frateuria defendens-derived metabolites against mollicutes

IF 2.8 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Plant Signaling & Behavior Pub Date : 2022-04-29 DOI:10.1080/15592324.2022.2070355

Alaa Naama-Amar, Y. Gerchman, Lilach Iasur Kruh, V. Naor

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引用次数: 1

Abstract

ABSTRACT Frateuria defendens is a candidate biocontrol agent that has been shown to reduce phytoplasma-related disease symptoms in grapevines and periwinkle plants. While a crude filtrate prepared from F. defendens can inhibit mollicute growth, the specific growth parameters for this bacterium, necessary to enhance this protective inhibitory response, remain unknown. Moreover, the separation of filtrate preparations from bacterial cells via centrifugation and filtration is laborious and time-consuming. As such, the present study was conducted to define the optimal growth conditions associated with maximal inhibitory activity of F. defendens and to establish a better approach to separating these bacterial cells from their secreted metabolites. To conduct these analyses, F. defendens was cultured in a range of media types, while associated inhibitory effects were tested in vitro using Spiroplasma melliferum as a model mollicute bacterium, and in planta using phytoplasma-infected periwinkle plantlets. These analyses revealed F. defendens growth patterns change based upon media composition, with filtrates prepared from a specific rich medium (S-medium) exhibiting beneficial activities, including the inhibition of S. melliferum and enhanced plant growth. When F. defendens cells were grown within semi-permeable, membrane-coated Small Bioreactor Platform (SBP) capsules, they could be more readily separated from the secreted metabolite fraction, obviating the need for filtration and/or centrifugation. This study is the first to have reported the use of SBP capsules to separate bacterial cells from their secreted metabolites under sterile conditions while retaining the ability of these metabolites to inhibit S. melliferum growth and to benefit the host plant. The results highlight promising new approaches to the effective biocontrol of phytoplasma-driven diseases in grapevines and other economically important plant species.

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防御菌衍生代谢物对分子物的生物防治活性评价

Frateuria defenens是一种候选生物防治剂，已被证明可以减少葡萄和长春花植物的植物原体相关疾病症状。虽然从F. defenens制备的粗滤液可以抑制mollicate的生长，但这种细菌的特定生长参数，增强这种保护性抑制反应所必需的，仍然未知。此外，通过离心和过滤从细菌细胞中分离滤液制剂是费力和耗时的。因此，本研究旨在确定与F. defenens最大抑制活性相关的最佳生长条件，并建立一种更好的方法来分离这些细菌细胞及其分泌的代谢物。为了进行这些分析，在一系列培养基类型中培养了F. defenens，同时在体外以melliferum螺原体作为模型mollicute细菌测试了相关的抑制效果，在植物中使用植物原体感染的长春花植株测试了相关的抑制效果。这些分析表明，F. defends的生长模式会根据培养基组成而变化，从特定的富培养基(S-medium)制备的滤液显示出有益的活性，包括抑制S. melliferum和促进植物生长。当F. defens细胞生长在半透性、膜包被的小生物反应器平台(SBP)胶囊中时，它们可以更容易地从分泌的代谢物部分中分离出来，从而避免了过滤和/或离心的需要。这项研究首次报道了使用SBP胶囊在无菌条件下将细菌细胞与其分泌的代谢物分离，同时保留这些代谢物抑制甜葡萄球菌生长并使寄主植物受益的能力。该研究结果强调了在葡萄和其他重要的经济植物物种中有效生物防治植物原体驱动疾病的新方法。

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来源期刊

Plant Signaling & Behavior Agricultural and Biological Sciences-Plant Science

CiteScore

6.00

自引率

3.40%

发文量

111

期刊介绍： Plant Signaling & Behavior, a multidisciplinary peer-reviewed journal published monthly online, publishes original research articles and reviews covering the latest aspects of signal perception and transduction, integrative plant physiology, and information acquisition and processing.