We investigate the ability of artificial Genetic Regulatory Networks (GRNs) to evolve differentiation. The proposed GRN model supports non-linear interaction between regulating factors, thereby facilitating the realization of complex regulatory logics. As a proof of concept we evolve GRNs of this kind to follow different pathways, producing two kinds of periodic dynamics in response to minimal differences in external input. Furthermore we find that successive increases in environmental pressure for differentiation, allowing a lineage to adapt gradually, compared to an immediate requirement for a switch between behaviors, yields better results on average. Apart from better success there is also less variability in performance, the latter ind...
It is a well-known paradox that evolution in experiments or in the wild often proceeds orders of mag...
Gene expression is controlled by networks of regulatory proteins that interact specifically with ext...
Cellular phenotypes underpinned by regulatory networks need to respond to evolutionary pressures to ...
Genetic Regulatory Networks (GRNs) in biological organisms are primary engines for cells to enact th...
Despite spectacular progress in biophysics, molecular biology and biochemistry our ability to predic...
AbstractWe study a genetic regulatory network model developed to demonstrate that genetic robustness...
Dynamical interactions among sets of genes (and their products) regulate developmental processes and...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
NetworksInternational audienceGene regulatory networks are a central mechanism in the regulation of ...
In nature, gene regulatory networks are a key mediator between the information stored in the DNA of ...
The pattern of gene expression in the phenotype of an organism is determined in part by the dynamica...
This is the final version of the article. Available from Public Library of Science via the DOI in th...
A mathematical model is proposed which is able to describe the most important features of cell differ...
Cellular phenotypes underpinned by regulatory networks need to respond to evolutionary pressures to ...
Cell differentiation is a complex phenomenon whereby a stem cell becomes progressively more speciali...
It is a well-known paradox that evolution in experiments or in the wild often proceeds orders of mag...
Gene expression is controlled by networks of regulatory proteins that interact specifically with ext...
Cellular phenotypes underpinned by regulatory networks need to respond to evolutionary pressures to ...
Genetic Regulatory Networks (GRNs) in biological organisms are primary engines for cells to enact th...
Despite spectacular progress in biophysics, molecular biology and biochemistry our ability to predic...
AbstractWe study a genetic regulatory network model developed to demonstrate that genetic robustness...
Dynamical interactions among sets of genes (and their products) regulate developmental processes and...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
NetworksInternational audienceGene regulatory networks are a central mechanism in the regulation of ...
In nature, gene regulatory networks are a key mediator between the information stored in the DNA of ...
The pattern of gene expression in the phenotype of an organism is determined in part by the dynamica...
This is the final version of the article. Available from Public Library of Science via the DOI in th...
A mathematical model is proposed which is able to describe the most important features of cell differ...
Cellular phenotypes underpinned by regulatory networks need to respond to evolutionary pressures to ...
Cell differentiation is a complex phenomenon whereby a stem cell becomes progressively more speciali...
It is a well-known paradox that evolution in experiments or in the wild often proceeds orders of mag...
Gene expression is controlled by networks of regulatory proteins that interact specifically with ext...
Cellular phenotypes underpinned by regulatory networks need to respond to evolutionary pressures to ...