Mu Xianfu, Liu Kongjun, Yang Jinghan, Liu Juan, Du Fengpei, Hao Gefei, Wang Peiyi
State Key Laboratory of Green Pesticide, Key Laboratory of Green Pesticide and Agricultural Bioengineering, Ministry of Education, Center for Research and Development of Fine Chemicals of Guizhou University, Guiyang, 550025, China.
Key Laboratory of Basic Pharmacology of Ministry of Education and Joint International Research Laboratory of Ethnomedicine of Ministry of Education, Zunyi Medical University, Zunyi, 563006, China.
Adv Sci (Weinh). 2025 Mar 27:e2410878. doi: 10.1002/advs.202410878.
Conventional antimicrobials typically exhibit suboptimal deposition on rice leaves, resulting in poor efficacy, further impaired by biofilms and Type III Secretion Systems (T3SS). Herein, this study presents a supramolecular strategy to fabricate BtP27@β-CD, a sunflower-like material engineered through host-guest recognition between de novo designed molecule BtP27 and β-cyclodextrin. BtP27@β-CD manifests enhanced foliar affinity and in vivo efficiency, demonstrating superior protective (62.67%) and curative (51.16%) activities against bacterial leaf blight at a low-dose of 200 µg mL compared to commercial thiodiazole-copper (37.78%/38.13%) without compromising safety. This multifunctional material, structurally derived from dufulin, inherit progenitor's systemic and conductive properties, alongside the capacity to activate salicylic acid-mediated plant defense pathways. Moreover, it is endowed with the anticipated abilities to disorganize biofilm barriers, annihilate encased pathogens, and inhibit T3SS. This constitutes the inaugural report of a supramolecular-based biofilm/T3SS dual inhibitor. An expanded investigation into substrate and indication screening identified additional molecules that self-assemble with β-cyclodextrin to form supramolecular materials, exhibiting superior potency against other rice diseases, with protective potency ranging from 63.53% to 73.30% and curative efficacy spanning 42.18% to 60.41% at 200 µg mL. In brief, this work establishes a paradigm for designing guest molecules from scratch to construct supramolecular materials with tailored characteristics.
传统抗菌剂通常在水稻叶片上的沉积效果欠佳,导致疗效不佳,而生物膜和III型分泌系统(T3SS)会进一步削弱其效果。在此,本研究提出了一种超分子策略来制备BtP27@β-CD,这是一种通过从头设计的分子BtP27与β-环糊精之间的主客体识别构建的向日葵状材料。BtP27@β-CD表现出增强的叶面亲和力和体内效率,在200μg/mL的低剂量下,对水稻白叶枯病表现出优异的保护活性(62.67%)和治疗活性(51.16%),相比之下,市售的噻森铜的保护活性和治疗活性分别为37.78%/38.13%,且不影响安全性。这种多功能材料在结构上源自毒氟磷,继承了母体的内吸传导特性,同时具有激活水杨酸介导的植物防御途径的能力。此外,它还具有破坏生物膜屏障、消灭被包裹的病原体以及抑制III型分泌系统的预期能力。这构成了基于超分子的生物膜/III型分泌系统双重抑制剂的首次报道。对底物和适应症筛选的进一步研究确定了其他能与β-环糊精自组装形成超分子材料的分子,这些材料对其他水稻病害表现出优异的效力,在2μg/mL时保护效力为63.53%至73.30%,治疗效果为42.18%至60.41%。简而言之,这项工作建立了一个从无到有设计客体分子以构建具有定制特性的超分子材料的范例。
