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通过体外和计算机模拟研究鉴定几丁寡糖防治水稻细菌性条斑病的机制

Identification of a Chitooligosaccharide Mechanism against Bacterial Leaf Blight on Rice by In Vitro and In Silico Studies.

机构信息

School of Crop Production Technology, Institute of Agricultural Technology, Suranaree University of Technology, Nakhon Ratchasima 30000, Thailand.

Synchrotron Light Research Institute (Public Organization), Nakhon Ratchasima 30000, Thailand.

出版信息

Int J Mol Sci. 2021 Jul 27;22(15):7990. doi: 10.3390/ijms22157990.

DOI:10.3390/ijms22157990
PMID:34360756
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8347687/
Abstract

This study focuses on a commercial plant elicitor based on chitooligosaccharides (BIG), which aids in rice plant growth and disease resistance to bacterial leaf blight (BLB). When the pathogen () vigorously attacks rice that has suffered yield losses, it can cause damage in up to 20% of the plant. Furthermore, is a seed-borne pathogen that can survive in rice seeds for an extended period. In this study, when rice seeds were soaked and sprayed with BIG, there was a significant increase in shoot and root length, as well as plant biomass. Furthermore, BIG-treated rice plants showed a significant reduction in BLB severity of more than 33%. Synchrotron radiation-based Fourier transform infrared (SR-FTIR) analysis was used to characterize BIG's mechanism in the chemical structure of rice leaves. The SR-FTIR results at 1650, 1735, and 1114 cm indicated changes in biochemical components such as pectins, lignins, proteins, and celluloses. These findings demonstrated that commercial BIG not only increased rice growth but also induced resistance to BLB. The drug's target enzyme, 1075 from (PDB ID: 5CY8), was analyzed for its interactions with polymer ingredients, specifically chitooligosaccharides, to gain molecular insights down to the atomic level. The results are intriguing, with a strong binding of the chitooligosaccharide polymer with the drug target, revealing 10 hydrogen bonds between the protein and polymer. Overall, the computational analysis supported the experimentally demonstrated strong binding of chitooligosaccharides to the drug target.

摘要

本研究聚焦于一种基于壳寡糖(BIG)的商业植物激发子,它有助于水稻生长并提高对细菌性条斑病(BLB)的抗性。当病原菌()强烈攻击已减产的水稻时,它可导致高达 20%的植物受损。此外,()是一种种子带菌病原体,可在水稻种子中存活很长时间。在这项研究中,当用 BIG 浸泡和喷洒水稻种子时,茎和根的长度以及植物生物量显著增加。此外,BIG 处理的水稻植株 BLB 严重度显著降低了 33%以上。基于同步辐射的傅里叶变换红外(SR-FTIR)分析用于表征 BIG 在水稻叶片化学结构中的作用机制。SR-FTIR 在 1650、1735 和 1114 cm 处的结果表明果胶、木质素、蛋白质和纤维素等生化成分发生了变化。这些发现表明,商业 BIG 不仅促进了水稻生长,还诱导了对 BLB 的抗性。药物的靶酶,来自(PDB ID:5CY8)的 1075,与聚合物成分(特别是壳寡糖)的相互作用进行了分析,以从原子水平获得分子见解。结果令人着迷,壳寡糖聚合物与药物靶标具有很强的结合力,在蛋白质和聚合物之间发现了 10 个氢键。总的来说,计算分析支持了实验证明的壳寡糖与药物靶标的强结合。

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