Add to ORKGProtein engineering of microbial rhodopsins has been successful in generating variants with improved properties for applications in optogenetics. Members of this membrane protein family can act as both actuators and sensors of neuronal activity. Chimeragenesis, structure-guided mutagenesis, and directed evolution have proven effective strategies for tuning absorption wavelength, altering ion specificity and increasing fluorescence. These approaches facilitate the development of useful optogenetic tools and, in some cases, have yielded insights into rhodopsin structure–function relationships
Microbial rhodopsins are photosensitive pigments implemented in the growth and adaptat...
Optogenetics is the use of genetically encoded light-activated proteins to manipulate cells in a min...
The capture and utilization of light is an exquisitely evolved process. The single-component microbi...
Protein engineering of microbial rhodopsins has been successful in generating variants with improved...
Microbial rhodopsins, a photoactive membrane protein family, serve as fundamental tools for optogene...
Microbial rhodopsins, which are photoreceptive membrane proteins consisting of seven α-helical struc...
Optogenetic tools have become indispensable in neuroscience to stimulate or inhibit excitable cells ...
Light-driven proton and chloride pumps were discovered as proteins used by halophilic archaea to pro...
In life science research, methods to control biological activities with stimuli such as light, heat,...
The overarching goal of my PhD research has been engineering proteins capable of controlling and rea...
Over the past 15 years, optogenetic methods have revolutionized neuroscientific and cell biological ...
Membrane proteins assume key roles in environmental sensing, metabolite uptake, and product efflux. ...
Microbial rhodopsins comprise one of the most diverse clades of light-harvesting proteins. At the be...
The proteins can be divided into the two major types in terms of the cell localization: membrane pro...
The capture and utilization of light is an exquisitely evolved process. The single-component microbi...
Microbial rhodopsins are photosensitive pigments implemented in the growth and adaptat...
Optogenetics is the use of genetically encoded light-activated proteins to manipulate cells in a min...
The capture and utilization of light is an exquisitely evolved process. The single-component microbi...
Protein engineering of microbial rhodopsins has been successful in generating variants with improved...
Microbial rhodopsins, a photoactive membrane protein family, serve as fundamental tools for optogene...
Microbial rhodopsins, which are photoreceptive membrane proteins consisting of seven α-helical struc...
Optogenetic tools have become indispensable in neuroscience to stimulate or inhibit excitable cells ...
Light-driven proton and chloride pumps were discovered as proteins used by halophilic archaea to pro...
In life science research, methods to control biological activities with stimuli such as light, heat,...
The overarching goal of my PhD research has been engineering proteins capable of controlling and rea...
Over the past 15 years, optogenetic methods have revolutionized neuroscientific and cell biological ...
Membrane proteins assume key roles in environmental sensing, metabolite uptake, and product efflux. ...
Microbial rhodopsins comprise one of the most diverse clades of light-harvesting proteins. At the be...
The proteins can be divided into the two major types in terms of the cell localization: membrane pro...
The capture and utilization of light is an exquisitely evolved process. The single-component microbi...
Microbial rhodopsins are photosensitive pigments implemented in the growth and adaptat...
Optogenetics is the use of genetically encoded light-activated proteins to manipulate cells in a min...
The capture and utilization of light is an exquisitely evolved process. The single-component microbi...