Add to ORKGGenetic devices that directly detect and respond to intracellular concentrations of proteins are important synthetic biology tools, supporting the design of biological systems that target, respond to or alter specific cellular states. Here, we develop ribozyme-based devices that respond to protein ligands in two eukaryotic hosts, yeast and mammalian cells, to regulate the expression of a gene of interest. Our devices allow for both gene-ON and gene-OFF response upon sensing the protein ligand. As part of our design process, we describe an in vitro characterization pipeline for prescreening device designs to identify promising candidates for in vivo testing. The in vivo gene-regulatory activities in the two types of eukaryotic cells correlat...
Artificial riboswitches based on ribozymes serve as versatile tools for ligand-dependent gene expres...
The engineering of biological systems is anticipated to provide effective solutions to challenges th...
The driving force of synthetic biology is the desire to build programmable cellular systems de novo ...
Genetic devices that directly detect and respond to intracellular concentrations of proteins are imp...
Synthetic RNA control devices that use ribozymes as gene-regulatory components have been applied to ...
Engineered biological systems hold promise in addressing pressing human needs in chemical processing...
Engineered ribozymes are powerful tools for manipulating gene expression in living cells. However, i...
Living systems rely on the precise control of gene expression to affect appropriate phenotypic respo...
Synthetic biological systems promise to combine the spectacular diversity of biological functionalit...
Recent advances have demonstrated the use of RNA-based control devices to program sophisticated cell...
Ribozymes are RNA sequences capable of catalysing chemical reactions. For some ribozymes their catal...
Self-cleaving ribozymes engineered to be activated or inhibited by a small molecule binding to an RN...
During the main research study we wanted to demonstrate that it is possible to control the amino aci...
Systems for conditional gene expression are powerful tools in basic research as well as in biotechno...
A series of allosteric ribozymes that respond to the bacterial second messenger cyclic diguanosyl-5′...
Artificial riboswitches based on ribozymes serve as versatile tools for ligand-dependent gene expres...
The engineering of biological systems is anticipated to provide effective solutions to challenges th...
The driving force of synthetic biology is the desire to build programmable cellular systems de novo ...
Genetic devices that directly detect and respond to intracellular concentrations of proteins are imp...
Synthetic RNA control devices that use ribozymes as gene-regulatory components have been applied to ...
Engineered biological systems hold promise in addressing pressing human needs in chemical processing...
Engineered ribozymes are powerful tools for manipulating gene expression in living cells. However, i...
Living systems rely on the precise control of gene expression to affect appropriate phenotypic respo...
Synthetic biological systems promise to combine the spectacular diversity of biological functionalit...
Recent advances have demonstrated the use of RNA-based control devices to program sophisticated cell...
Ribozymes are RNA sequences capable of catalysing chemical reactions. For some ribozymes their catal...
Self-cleaving ribozymes engineered to be activated or inhibited by a small molecule binding to an RN...
During the main research study we wanted to demonstrate that it is possible to control the amino aci...
Systems for conditional gene expression are powerful tools in basic research as well as in biotechno...
A series of allosteric ribozymes that respond to the bacterial second messenger cyclic diguanosyl-5′...
Artificial riboswitches based on ribozymes serve as versatile tools for ligand-dependent gene expres...
The engineering of biological systems is anticipated to provide effective solutions to challenges th...
The driving force of synthetic biology is the desire to build programmable cellular systems de novo ...