Signaling networks that convert graded stimuli into binary, all-or-none cellular responses are critical in processes ranging from cell-cycle control to lineage commitment. To exhaustively enumerate topologies that exhibit this switch-like behavior, we simulated all possible two- and three-component networks on random parameter sets, and assessed the resulting response profiles for both steepness (ultrasensitivity) and extent of memory (bistability). Simulations were used to study purely enzymatic networks, purely transcriptional networks, and hybrid enzymatic/transcriptional networks, and the topologies in each class were rank ordered by parametric robustness (i.e., the percentage of applied parameter sets exhibiting ultrasensitivity or bis...
The ability to engineer an all-or-none cellular response to a given signaling ligand is important in...
SummaryMany signaling systems show adaptation—the ability to reset themselves after responding to a ...
The problem of understanding the connection between network topology and dynamical output represents...
Signaling networks that convert graded stimuli into binary, all-or-none cellular responses are criti...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
Cellular networks are highly dynamic in their function, yet evolutionarily conserved in their core n...
Design and implementation of robust network modules is essential for construction of complex biologi...
Cellular networks are highly dynamic in their function, yet evolutionarily conserved in their core n...
Conventionally, biological signal transduction networks are analysed using experimental and theoreti...
<div><p>Design and implementation of robust network modules is essential for construction of complex...
Cellular signaling networks have evolved an astonishing ability to function reliably and with high f...
Many signaling systems show adaptation-the ability to reset themselves after responding to a stimulu...
We investigate how scale-free (SF) and Erdos-Renyi (ER) topologies affect the interplay between evol...
Synthetic biology promise to provide solutions to many challenges in energy, agriculture, and health...
We investigate how scale-free (SF) and Erdős–Rényi (ER) topologies affect the interplay between evol...
The ability to engineer an all-or-none cellular response to a given signaling ligand is important in...
SummaryMany signaling systems show adaptation—the ability to reset themselves after responding to a ...
The problem of understanding the connection between network topology and dynamical output represents...
Signaling networks that convert graded stimuli into binary, all-or-none cellular responses are criti...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
Cellular networks are highly dynamic in their function, yet evolutionarily conserved in their core n...
Design and implementation of robust network modules is essential for construction of complex biologi...
Cellular networks are highly dynamic in their function, yet evolutionarily conserved in their core n...
Conventionally, biological signal transduction networks are analysed using experimental and theoreti...
<div><p>Design and implementation of robust network modules is essential for construction of complex...
Cellular signaling networks have evolved an astonishing ability to function reliably and with high f...
Many signaling systems show adaptation-the ability to reset themselves after responding to a stimulu...
We investigate how scale-free (SF) and Erdos-Renyi (ER) topologies affect the interplay between evol...
Synthetic biology promise to provide solutions to many challenges in energy, agriculture, and health...
We investigate how scale-free (SF) and Erdős–Rényi (ER) topologies affect the interplay between evol...
The ability to engineer an all-or-none cellular response to a given signaling ligand is important in...
SummaryMany signaling systems show adaptation—the ability to reset themselves after responding to a ...
The problem of understanding the connection between network topology and dynamical output represents...