Signal transduction in biological cells is effected by signaling pathways that typically include multiple feedback loops. Here we analyze information transfer through a prototypical signaling module with biochemical feedback. The module switches stochastically between an inactive and active state; the input to the module governs the activation rate while the output (i.e., the product concentration) perturbs the inactivation rate. Using a novel perturbative approach, we compute the rate with which information about the input is gained from observation of the output. We obtain an explicit analytical result valid to first order in feedback strength and to second order in the strength of input. The total information gained during an extended ti...
Molecular noise restricts the ability of an individual cell to resolve input signals of different st...
The mammalian signal transduction network relays detailed information about the presence and concent...
Stochasticity inherent to biochemical reactions (intrinsic noise) and variability in cellular states...
AbstractA conceptual framework is developed for the quantitative analysis of signal transfer through...
This dissertation analyzes the dynamics of the individual components in two specific biological netw...
Signal transduction is a process required to conduct information from a receptor to the nucleus. Thi...
AbstractWe perform a systematic analysis of mechanisms of feedback regulation that underlie short-te...
Cells must sense extracellular signals and transfer the information contained about their environmen...
Cells live in changing, dynamic environments. To understand cellular decision-making, we must theref...
Feedback modules, which appear ubiquitously in biological regulations, are often subject to disturba...
Cells leverage signaling molecules to carry information about the cellular state to receptors that r...
Feedback modules, which appear ubiquitously in biological regulations, are often subject to disturba...
In biology, signal transduction is the process by which an extracellular signaling molecule activate...
Biological signaling networks comprised of cellular components including signaling proteins and smal...
Cell signal transduction is a non-equilibrium process characterized by the reaction cascade. This st...
Molecular noise restricts the ability of an individual cell to resolve input signals of different st...
The mammalian signal transduction network relays detailed information about the presence and concent...
Stochasticity inherent to biochemical reactions (intrinsic noise) and variability in cellular states...
AbstractA conceptual framework is developed for the quantitative analysis of signal transfer through...
This dissertation analyzes the dynamics of the individual components in two specific biological netw...
Signal transduction is a process required to conduct information from a receptor to the nucleus. Thi...
AbstractWe perform a systematic analysis of mechanisms of feedback regulation that underlie short-te...
Cells must sense extracellular signals and transfer the information contained about their environmen...
Cells live in changing, dynamic environments. To understand cellular decision-making, we must theref...
Feedback modules, which appear ubiquitously in biological regulations, are often subject to disturba...
Cells leverage signaling molecules to carry information about the cellular state to receptors that r...
Feedback modules, which appear ubiquitously in biological regulations, are often subject to disturba...
In biology, signal transduction is the process by which an extracellular signaling molecule activate...
Biological signaling networks comprised of cellular components including signaling proteins and smal...
Cell signal transduction is a non-equilibrium process characterized by the reaction cascade. This st...
Molecular noise restricts the ability of an individual cell to resolve input signals of different st...
The mammalian signal transduction network relays detailed information about the presence and concent...
Stochasticity inherent to biochemical reactions (intrinsic noise) and variability in cellular states...