Bacterial pathogens produced resistance against the existing antimicrobial applications. Scientist trending towards the potent novel eco-friendly and cost effective antimicrobial approaches and fabricating bio-based n...Bacterial pathogens produced resistance against the existing antimicrobial applications. Scientist trending towards the potent novel eco-friendly and cost effective antimicrobial approaches and fabricating bio-based nano-particles. In this regard, several bio-materials have been investigated, such as, bacteria, fungi, algae, lichens and green plants. Lichens are introduced as an emerging source to synthesis bio-based nano-particles. The lichen-based metal nano-materials, especially fabricated by applying green chemistry strategies, have resulted significant alternates to traditional antimicrobial applications. Several studies break out and revealed that lichen-based nano-particle showed strong antimicrobial efficacy, as the lichens are biologically compatible. Current review summarizes an overview of lichen-based nano-materials, their fabrication, their applications, and their molecular action mechanism. As it emerged a broad spectrum antimicrobial agent for pharmaceutical and agricultural applications.展开更多
Chordotonal neurons are responsible for sound sensation in Drosophila.However,little is known about how they respond to sound with high sensitivity.Using genetic labeling,we found one of the Drosophila axonemal dynein...Chordotonal neurons are responsible for sound sensation in Drosophila.However,little is known about how they respond to sound with high sensitivity.Using genetic labeling,we found one of the Drosophila axonemal dynein heavy chains,CG9492(DNAH5),was specifically expressed in larval chordotonal neurons and showed a distribution restricted to proximal cilia.While DNAH5 mutation did not affect the cilium morphology or the trafficking of Inactive,a candidate auditory transduction channel,larvae with DNAH5 mutation had reduced startle responses to sound at low and medium intensities.Calcium imaging confirmed that DNAH5 functioned autonomously in chordotonal neurons for larval sound sensation.Furthermore,disrupting DNAH5 resulted in a decrease of spike firing responses to low-level sound in chordotonal neurons.Intriguingly,DNAH5 mutant larvae displayed an altered frequency tuning curve of the auditory organs.All together,our findings support a critical role of DNAH5 in tuning the frequency selectivity and the sound sensitivity of larval auditory neurons.展开更多
文摘Bacterial pathogens produced resistance against the existing antimicrobial applications. Scientist trending towards the potent novel eco-friendly and cost effective antimicrobial approaches and fabricating bio-based nano-particles. In this regard, several bio-materials have been investigated, such as, bacteria, fungi, algae, lichens and green plants. Lichens are introduced as an emerging source to synthesis bio-based nano-particles. The lichen-based metal nano-materials, especially fabricated by applying green chemistry strategies, have resulted significant alternates to traditional antimicrobial applications. Several studies break out and revealed that lichen-based nano-particle showed strong antimicrobial efficacy, as the lichens are biologically compatible. Current review summarizes an overview of lichen-based nano-materials, their fabrication, their applications, and their molecular action mechanism. As it emerged a broad spectrum antimicrobial agent for pharmaceutical and agricultural applications.
基金the National Key R&D Program of China Project(2017YFA0103900 and 2016YFA0502800)the National Natural Science Foundation of China(31571083 and 31970931)+2 种基金the Program for Professor of Special Appointment(Eastern Scholar of Shanghai,TP2014008)the Shanghai Municipal Science and Technology Major Project(2017SHZDZX01 and 2018SHZDZX01)ZJLab,and the Shanghai Rising-Star Program(14QA1400800)。
文摘Chordotonal neurons are responsible for sound sensation in Drosophila.However,little is known about how they respond to sound with high sensitivity.Using genetic labeling,we found one of the Drosophila axonemal dynein heavy chains,CG9492(DNAH5),was specifically expressed in larval chordotonal neurons and showed a distribution restricted to proximal cilia.While DNAH5 mutation did not affect the cilium morphology or the trafficking of Inactive,a candidate auditory transduction channel,larvae with DNAH5 mutation had reduced startle responses to sound at low and medium intensities.Calcium imaging confirmed that DNAH5 functioned autonomously in chordotonal neurons for larval sound sensation.Furthermore,disrupting DNAH5 resulted in a decrease of spike firing responses to low-level sound in chordotonal neurons.Intriguingly,DNAH5 mutant larvae displayed an altered frequency tuning curve of the auditory organs.All together,our findings support a critical role of DNAH5 in tuning the frequency selectivity and the sound sensitivity of larval auditory neurons.