Abstract Biological systems often need to operate in complex environments where conditions can rapidly change. This is possible due to their inherent ability to sense changes and adapt their behavior in response. Here, we detail recent advances in the creation of synthetic genetic parts and circuits whose behaviors can be dynamically tuned through a variety of intra- and extra-cellular signals. We show how this capability lays the foundation for implementing control engineering schemes in living cells and allows for the creation of biological systems that are able to self-adapt, ensuring their functionality is maintained in the face of varying environmental and physiological conditions. We end by discussing some of the broader implications...
Gene regulatory networks lay at the foundation of biological function and are responsible for drivin...
The past several years have witnessed an increased presence of control theoretic concepts in synthet...
The ability to harness biomolecules as tools for systematic engineering is fundamental to future dev...
Abstract Biological systems often need to operate in complex environments where conditions can rapi...
One of the most remarkable features of biological systems is their ability to adapt to the constantl...
Abstract Synthetic genetic circuits allow us to modify the behavior of living cells. However, chang...
Significant advances have been made in synthetic biology to program information processing capabilit...
Living cells are exquisite systems. They are strongly regulated to perform in highly specific ways, ...
Microorganisms are able to respond effectively to diverse signals from their environment and interna...
Abstract The control of microbes and microbial consortia to achieve specific functions requires syn...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
Synthetic biology efforts have largely focused on small engineered gene networks, yet understanding ...
Chen, WilfredLiving systems of all scales must constantly adapt to changing conditions by surveying ...
Rapid advances in cellular engineering have positioned synthetic biology to address therapeutic and ...
Synthetic Biology enables the construction of new genetic circuits with the final goal of controllin...
Gene regulatory networks lay at the foundation of biological function and are responsible for drivin...
The past several years have witnessed an increased presence of control theoretic concepts in synthet...
The ability to harness biomolecules as tools for systematic engineering is fundamental to future dev...
Abstract Biological systems often need to operate in complex environments where conditions can rapi...
One of the most remarkable features of biological systems is their ability to adapt to the constantl...
Abstract Synthetic genetic circuits allow us to modify the behavior of living cells. However, chang...
Significant advances have been made in synthetic biology to program information processing capabilit...
Living cells are exquisite systems. They are strongly regulated to perform in highly specific ways, ...
Microorganisms are able to respond effectively to diverse signals from their environment and interna...
Abstract The control of microbes and microbial consortia to achieve specific functions requires syn...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
Synthetic biology efforts have largely focused on small engineered gene networks, yet understanding ...
Chen, WilfredLiving systems of all scales must constantly adapt to changing conditions by surveying ...
Rapid advances in cellular engineering have positioned synthetic biology to address therapeutic and ...
Synthetic Biology enables the construction of new genetic circuits with the final goal of controllin...
Gene regulatory networks lay at the foundation of biological function and are responsible for drivin...
The past several years have witnessed an increased presence of control theoretic concepts in synthet...
The ability to harness biomolecules as tools for systematic engineering is fundamental to future dev...