Add to ORKGWe study the robustness and stability of the yeast cell regulatory network by using a general inhomogeneous discrete model. We find that inhomogeneity, on average, enhances the stability of the biggest attractor of the dynamics and that the large size of the basin of attraction is robust against changes in the parameters of inhomogeneity. We find that the most frequent orbit, which represents the cell-cycle pathway, has a better biological meaning than the one exhibited by the homogeneous model
In this dissertation, we study the control network that governs the cell division cycle of budding y...
Dynamic behaviors of protein-protein and protein-DNA interactions in living cells are investigated u...
Complex biological systems, such as the cell cycle control network, are shown to be robust against v...
We study the robustness and stability of the yeast cell regulatory network by using a general inhomo...
Biological functions in living cells are controlled by protein interaction and genetic networks. The...
To understand the molecular mechanisms that regulate cell cycle progression in eukaryotes, a variety...
Studying the cell cycle process is crucial for understanding cell growth, proliferation, development...
Introduction: The cell cycle network is responsible of control, growth and proliferation of cells. T...
The eukaryotic cell cycle is robustly designed, with interacting molecules organized within a defini...
J. Theoretical Biology 292 (2012), 103-115International audienceMotivated by experimental and theore...
We study the dynamics of gene activities in relatively small size biological networks (up to a few t...
The eukaryotic cell cycle is robustly designed, with interacting molecules organized within a defini...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
AbstractWe study the origin of robustness of yeast cell cycle cellular network through uncovering it...
In this dissertation, we study the control network that governs the cell division cycle of budding y...
Dynamic behaviors of protein-protein and protein-DNA interactions in living cells are investigated u...
Complex biological systems, such as the cell cycle control network, are shown to be robust against v...
We study the robustness and stability of the yeast cell regulatory network by using a general inhomo...
Biological functions in living cells are controlled by protein interaction and genetic networks. The...
To understand the molecular mechanisms that regulate cell cycle progression in eukaryotes, a variety...
Studying the cell cycle process is crucial for understanding cell growth, proliferation, development...
Introduction: The cell cycle network is responsible of control, growth and proliferation of cells. T...
The eukaryotic cell cycle is robustly designed, with interacting molecules organized within a defini...
J. Theoretical Biology 292 (2012), 103-115International audienceMotivated by experimental and theore...
We study the dynamics of gene activities in relatively small size biological networks (up to a few t...
The eukaryotic cell cycle is robustly designed, with interacting molecules organized within a defini...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
AbstractWe study the origin of robustness of yeast cell cycle cellular network through uncovering it...
In this dissertation, we study the control network that governs the cell division cycle of budding y...
Dynamic behaviors of protein-protein and protein-DNA interactions in living cells are investigated u...
Complex biological systems, such as the cell cycle control network, are shown to be robust against v...