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解析茄科作物多面根际生物防治剂MC2和NBG的抗菌活性

Deciphering the antimicrobial activity of multifaceted rhizospheric biocontrol agents of solanaceous crops , MC2, and NBG.

作者信息

Rahman Mehjebin, Borah Sapna Mayuri, Borah Pradip Kr, Bora Popy, Sarmah Bidyut Kumar, Lal Milan Kumar, Tiwari Rahul Kumar, Kumar Ravinder

机构信息

Department of Plant Pathology, Assam Agricultural University, Jorhat, Assam, India.

Department of Plant Pathology, Regional Agricultural Research Station, Jorhat, Assam, India.

出版信息

Front Plant Sci. 2023 Mar 3;14:1141506. doi: 10.3389/fpls.2023.1141506. eCollection 2023.

DOI:10.3389/fpls.2023.1141506
PMID:36938007
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10020943/
Abstract

The family is generally known to be the third most economically important plant taxon, but also harbors a host of plant pathogens. Diseases like wilt and fruit rot of solanaceous crops cause huge yield losses in the field as well as in storage. In the present study, eight isolates of spp. were obtained from rhizospheric micro-flora of three solanaceous crops: tomato, brinjal, and chili plants, and were subsequently screened for pre-eminent biocontrol activity against three fungal ( f. sp. , , and ) and one bacterial () pathogen. Morphological, ITS, and marker-based molecular identification revealed eight isolates were different strains of . Seven isolates were distinguished as while one was identified as . antagonistic and biochemical assays indicated significant biocontrol activity governed by all eight isolates. Two fungal isolates, MC2 and NBG were further evaluated to decipher their best biological control activity. Preliminary insights into the secondary metabolic profile of both isolates were retrieved by liquid chromatography-mass spectrometry (LC-MS). Further, a field experiment was conducted with the isolates MC2 and NBG which successfully resulted in suppression of bacterial wilt disease in tomato. Which possibly confer biocontrol properties to the identified isolates. The efficacy of these two strains in suppressing bacterial wilt and promoting plant growth in the tomato crop was also tested in the field. The disease incidence was significantly reduced by 47.50% and yield incremented by 54.49% in plants treated in combination with both the bioagents. The results of scanning electron microscopy were also in consensus with the results. The results altogether prove that MC2 and NBG are promising microbes for their prospective use in agricultural biopesticide formulations.

摘要

一般认为该属是经济上第三重要的植物分类群,但也藏有许多植物病原体。茄科作物的枯萎病和果腐病等病害在田间和储存过程中都会造成巨大的产量损失。在本研究中,从三种茄科作物(番茄、茄子和辣椒植株)的根际微生物区系中获得了8株 spp. 分离株,随后对其针对三种真菌( f. sp. 、 、 和 )和一种细菌( )病原体的卓越生物防治活性进行了筛选。基于形态学、ITS和 标记的分子鉴定表明,8株分离株是 的不同菌株。7株分离株被鉴定为 ,而1株被鉴定为 。 拮抗和生化分析表明,所有8株分离株均具有显著的生物防治活性。进一步评估了两株真菌分离株MC2和NBG,以确定它们的最佳生物防治活性。通过液相色谱 - 质谱联用(LC - MS)对两株分离株的次生代谢产物谱进行了初步分析。此外,对分离株MC2和NBG进行了田间试验,成功抑制了番茄的青枯病。这可能赋予了已鉴定分离株生物防治特性。还在田间测试了这两种菌株在抑制番茄青枯病和促进番茄作物生长方面的功效。在同时使用这两种生物制剂处理的植株中,发病率显著降低了47.50%,产量提高了54.49%。扫描电子显微镜的结果也与 结果一致。这些结果共同证明,MC2和NBG是有望用于农业生物农药制剂的微生物。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6599/10020943/f407b0b9fa12/fpls-14-1141506-g012.jpg
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