<div><p>Synthetic constructs in biotechnology, biocomputing, and modern gene therapy interventions are often based on plasmids or transfected circuits which implement some form of “on-off” switch. For example, the expression of a protein used for therapeutic purposes might be triggered by the recognition of a specific combination of inducers (e.g., antigens), and memory of this event should be maintained across a cell population until a specific stimulus commands a coordinated shut-off. The robustness of such a design is hampered by molecular (“intrinsic”) or environmental (“extrinsic”) noise, which may lead to spontaneous changes of state in a subset of the population and is reflected in the bimodality of protein expression, as measured fo...
<div><p>Populations of cells often switch states as a group to cope with environmental changes such ...
Synthetic biology has recently provided functional single-cell oscillators. With a few exceptions, h...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Engineering artificial networks from modular components is a major challenge in synthetic biology. I...
It is well known that white noise can induce switch behaviors in bistable systems. However, recent e...
The use of in silico simulations as a basis for designing artificial biological systems (and experim...
We have developed a mathematical framework to analyze the cooperative control of cell population hom...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
International audienceGenetic positive feedback loops are essential for cell differentiation process...
Synthetically engineered genetic circuits can perform a wide variety of tasks but are generally less...
Synthetic biology aims to develop new biological systems and devices, from the modification of exist...
Despite stochastic fluctuations, some genetic switches are able to retain their expression states th...
Turning genes on and off is a mechanism by which cells and tissues make phenotypic decisions. Gene n...
The engineering of genetic circuits with predictive functionality in living cells represents a defin...
<div><p>Complex gene regulation requires responses that depend not only on the current levels of inp...
<div><p>Populations of cells often switch states as a group to cope with environmental changes such ...
Synthetic biology has recently provided functional single-cell oscillators. With a few exceptions, h...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...
Engineering artificial networks from modular components is a major challenge in synthetic biology. I...
It is well known that white noise can induce switch behaviors in bistable systems. However, recent e...
The use of in silico simulations as a basis for designing artificial biological systems (and experim...
We have developed a mathematical framework to analyze the cooperative control of cell population hom...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
International audienceGenetic positive feedback loops are essential for cell differentiation process...
Synthetically engineered genetic circuits can perform a wide variety of tasks but are generally less...
Synthetic biology aims to develop new biological systems and devices, from the modification of exist...
Despite stochastic fluctuations, some genetic switches are able to retain their expression states th...
Turning genes on and off is a mechanism by which cells and tissues make phenotypic decisions. Gene n...
The engineering of genetic circuits with predictive functionality in living cells represents a defin...
<div><p>Complex gene regulation requires responses that depend not only on the current levels of inp...
<div><p>Populations of cells often switch states as a group to cope with environmental changes such ...
Synthetic biology has recently provided functional single-cell oscillators. With a few exceptions, h...
Diverse biochemical rhythms are generated by thousands of cellular oscillators that somehow manage t...