The incidence of plant bacterial diseases has been rising annually alongside the development of facility agriculture,which can seriously affect the yield and quality of crops,and cause significant losses to agricultur...The incidence of plant bacterial diseases has been rising annually alongside the development of facility agriculture,which can seriously affect the yield and quality of crops,and cause significant losses to agricultural production globally.Thus,the development of highly effective prevention and control agents targeting plant pathogenic bacteria are urgently needed.The Type III secretion system(T3SS)is a complex molecular apparatus exist in many Gram-negative pathogenic bacteria,which plays a crucial role in the pathogenic process of bacteria.In recent years,T3SS has become an important target for the development of novel antibacterial agents.Here,we highlight the recent findings on a plant defense compound targeting T3SS for plant bacterial diseases by Lei and his colleagues.展开更多
Self-assembled films(SAFs)have been proposed to be a promising candidate for molecularly thin lubricants.However,the frictional performance of SAFs is sensitively dependent on their molecular structures that are susce...Self-assembled films(SAFs)have been proposed to be a promising candidate for molecularly thin lubricants.However,the frictional performance of SAFs is sensitively dependent on their molecular structures that are susceptible to external environments.Taking erucamide,a fatty amide widely used as a macroscale slip additive,as an example,we demonstrate that SAFs can be readily formed on various substrates,including silicon oxide,sapphire,copper,and graphite.Through high-resolution topography and friction measurements,two types of erucamide SAFs are identified.The first type is atomically flat and exhibits clear atomic stick–slip friction behavior and ultra-low frictional dissipation;while the second type has a stripe-like nanoscale pattern and shows much higher(8 times higher)frictional dissipation.The sharp contrast between these two types of SAFs is attributed to their distinct molecular structures originating from different interactions between erucamide molecules and substrates.We further demonstrate that,by proper surface functionalization,we can actively and reliably control the molecular structures of SAFs through guided self-assembling,achieving rational friction tuning with patterning capability.展开更多
基金supported by the Key R&D Project of Hubei Province(2023BBB176)Wuhan Knowledge Innovation Special Project‘Dawning Program’(2023020201020433)the authors also gratefully acknowledge the partial support from Hubei Agricultural Science Innovation Center(2024-620-000-001-023).
文摘The incidence of plant bacterial diseases has been rising annually alongside the development of facility agriculture,which can seriously affect the yield and quality of crops,and cause significant losses to agricultural production globally.Thus,the development of highly effective prevention and control agents targeting plant pathogenic bacteria are urgently needed.The Type III secretion system(T3SS)is a complex molecular apparatus exist in many Gram-negative pathogenic bacteria,which plays a crucial role in the pathogenic process of bacteria.In recent years,T3SS has become an important target for the development of novel antibacterial agents.Here,we highlight the recent findings on a plant defense compound targeting T3SS for plant bacterial diseases by Lei and his colleagues.
基金supported by the National Natural Science Foundation of China(Grants 11772169,12025203,11921002,and 11890671)the National Science and Technology Major Project(Grant 2017-VI-OOO3-OO73)the Initiative Program of State Key Laboratory of Tribology(Grant SKLT2019B02).
文摘Self-assembled films(SAFs)have been proposed to be a promising candidate for molecularly thin lubricants.However,the frictional performance of SAFs is sensitively dependent on their molecular structures that are susceptible to external environments.Taking erucamide,a fatty amide widely used as a macroscale slip additive,as an example,we demonstrate that SAFs can be readily formed on various substrates,including silicon oxide,sapphire,copper,and graphite.Through high-resolution topography and friction measurements,two types of erucamide SAFs are identified.The first type is atomically flat and exhibits clear atomic stick–slip friction behavior and ultra-low frictional dissipation;while the second type has a stripe-like nanoscale pattern and shows much higher(8 times higher)frictional dissipation.The sharp contrast between these two types of SAFs is attributed to their distinct molecular structures originating from different interactions between erucamide molecules and substrates.We further demonstrate that,by proper surface functionalization,we can actively and reliably control the molecular structures of SAFs through guided self-assembling,achieving rational friction tuning with patterning capability.
