Exploring the Genome-wide Expression Level of the Bacterial Strain Belonging to Bacillus safensis (MM19) Against Phomopsis viticola.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-14 DOI:10.1007/s00284-024-03908-1

Ragıp Soner Silme, Ömür Baysal, Ahmet Can, Yiğit Kürüm, Ahmet Korkut, Kevser Kübra Kırboğa, Agit Çetinkaya

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Abstract

Rhizobacteria have the ability to compete with pathogenic microorganisms and contribute to plant immunity and defense mechanisms. Their growth and survival in the rhizosphere ensure a biological balance in favor of the host plant. The differential gene expression profiles of B. safensis (MM19) revealed significantly increased expression of prominent genes related to thiamine biosynthesis involving various metabolites and enzymes that participate in the suppression of mycelium growth and pathogen inhibition. Correspondingly, the expression of three major genes (HOG1, FUS3, SGI) involved in the virulence of P. viticola was assessed using qPCR analysis. HOG1 was the highest expressed gene in the pathogen when it was co-cultivated with MM19. Based on these findings, we performed molecular docking and dynamics analysis to explore the interaction between HOG1 and thiamine, as well as expression network analysis constructed using Cytoscape. The functional genomic data related to thiamine biosynthesis and the corresponding pathways ensure a priming role in the antagonistic behavior of B. safensis (MM19) against P. viticola as a support for plant immunity.

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探索枯草芽孢杆菌（MM19）菌株抗拟南芥的全基因组表达水平

根瘤菌具有与病原微生物竞争的能力，有助于植物免疫和防御机制。它们在根圈中的生长和存活确保了有利于寄主植物的生物平衡。B. safensis（MM19）的差异基因表达谱显示，与硫胺素生物合成有关的主要基因表达量显著增加，这些基因涉及参与抑制菌丝生长和病原体抑制的各种代谢物和酶。相应地，利用 qPCR 分析评估了涉及葡萄孢菌毒力的三个主要基因（HOG1、FUS3 和 SGI）的表达情况。当病原体与 MM19 共培养时，HOG1 是表达量最高的基因。基于这些发现，我们进行了分子对接和动力学分析，以探索 HOG1 与硫胺素之间的相互作用，并利用 Cytoscape 构建了表达网络分析。与硫胺素生物合成相关的功能基因组数据以及相应的途径确保了 B. safensis（MM19）对葡萄孢的拮抗作用，从而为植物免疫提供了支持。

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