Design and implementation of robust network modules is essential for construction of complex biological systems through hierarchical assembly of 'parts' and 'devices'. The robustness of gene regulatory networks (GRNs) is ascribed chiefly to the underlying topology. The automatic designing capability of GRN topology that can exhibit robust behavior can dramatically change the current practice in synthetic biology. A recent study shows that Darwinian evolution can gradually develop higher topological robustness. Subsequently, this work presents an evolutionary algorithm that simulates natural evolution in silico, for identifying network topologies that are robust to perturbations. We present a Monte Carlo based method for quantifying topologi...
Large and complex biological networks are thought to be built from small functional modules called m...
A common gene regulatory network model is the threshold Boolean network, used for example to model t...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
<div><p>Design and implementation of robust network modules is essential for construction of complex...
Design and implementation of robust network modules is essential for construction of com-plex biolog...
Gene regulatory networks (GRNs) are complex systems in which many genes regulate mutually to adapt t...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
Synthetic biology has yielded many successful basic modules inspired by electronic devices over the ...
Network robustness is an important principle in biology and engineering. Previous studies of global ...
We investigate how scale-free (SF) and Erdős–Rényi (ER) topologies affect the interplay between evol...
We investigate how scale-free (SF) and Erdos-Renyi (ER) topologies affect the interplay between evol...
Network motifs have been identified as building blocks of regulatory networks, including gene regula...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Abstract Background Reconstructing gene regulatory networks (GRNs) from expression data is one of th...
Robust stabilization and environmental disturbance attenuation are ubiquitous systematic properties ...
Large and complex biological networks are thought to be built from small functional modules called m...
A common gene regulatory network model is the threshold Boolean network, used for example to model t...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
<div><p>Design and implementation of robust network modules is essential for construction of complex...
Design and implementation of robust network modules is essential for construction of com-plex biolog...
Gene regulatory networks (GRNs) are complex systems in which many genes regulate mutually to adapt t...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
Synthetic biology has yielded many successful basic modules inspired by electronic devices over the ...
Network robustness is an important principle in biology and engineering. Previous studies of global ...
We investigate how scale-free (SF) and Erdős–Rényi (ER) topologies affect the interplay between evol...
We investigate how scale-free (SF) and Erdos-Renyi (ER) topologies affect the interplay between evol...
Network motifs have been identified as building blocks of regulatory networks, including gene regula...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Abstract Background Reconstructing gene regulatory networks (GRNs) from expression data is one of th...
Robust stabilization and environmental disturbance attenuation are ubiquitous systematic properties ...
Large and complex biological networks are thought to be built from small functional modules called m...
A common gene regulatory network model is the threshold Boolean network, used for example to model t...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...