Add to ORKGMany cells can sense and respond to time-varying stimuli, selectively triggering changes in cell fate only in response to inputs of a particular duration or frequency. A common motif in dynamically controlled cells is a dual-timescale regulatory network: although long-term fate decisions are ultimately controlled by a slow-timescale switch (e.g., gene expression), input signals are first processed by a fast-timescale signaling layer, which is hypothesized to filter what dynamic information is efficiently relayed downstream. Directly testing the design principles of how dual-timescale circuits control dynamic sensing, however, has been challenging, because most synthetic biology methods have focused solely on rewiring transcriptional circuit...
Gene networks and signaling pathways display complex topologies and, as a result, complex nonlinear ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
How can cells shape and utilize dynamic gene regulation to enable complex cellular behaviors? I stud...
Cells can sense temporal changes of molecular signals, allowing them to predict environmental variat...
The ability to self-regulate in feedback is what allows cells to operate robustly despite the uncert...
Cells are dynamic, adaptive structures--able to sense their environment and change their behavior ac...
To program cells in a dynamic manner, synthetic biologists require precise control over the threshol...
Eukaryotic genes are regulated by multivalent transcription factor complexes. Through cooperative se...
Cells reside in highly dynamic environments to which they must adapt. Throughout its lifetime, an in...
Abstract Gene networks and signaling pathways display complex topologies and, as a result, complex ...
Genetically-encodable optical reporters, such as Green Fluorescent Protein, have revolutionized the ...
Highlights Live single-cell quantification of light-activated transcriptional bursts in yeast A ...
Cellular systems have evolved numerous mechanisms to adapt to environmental stimuli, underpinned by ...
Gene networks and signaling pathways display complex topologies and, as a result, complex nonlinear ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...
Biological circuits are responsible for transitions between cellular states in a timely fashion. For...
How can cells shape and utilize dynamic gene regulation to enable complex cellular behaviors? I stud...
Cells can sense temporal changes of molecular signals, allowing them to predict environmental variat...
The ability to self-regulate in feedback is what allows cells to operate robustly despite the uncert...
Cells are dynamic, adaptive structures--able to sense their environment and change their behavior ac...
To program cells in a dynamic manner, synthetic biologists require precise control over the threshol...
Eukaryotic genes are regulated by multivalent transcription factor complexes. Through cooperative se...
Cells reside in highly dynamic environments to which they must adapt. Throughout its lifetime, an in...
Abstract Gene networks and signaling pathways display complex topologies and, as a result, complex ...
Genetically-encodable optical reporters, such as Green Fluorescent Protein, have revolutionized the ...
Highlights Live single-cell quantification of light-activated transcriptional bursts in yeast A ...
Cellular systems have evolved numerous mechanisms to adapt to environmental stimuli, underpinned by ...
Gene networks and signaling pathways display complex topologies and, as a result, complex nonlinear ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...
Recent studies have shown that many cell-signaling networks contain interactions and feedback loops ...