This paper investigates empirically the influence of regulation logic on the dynamics of two computational models of genetic regulatory network motifs. The gene regulatory network motifs considered in this work consist of three genes with both positive and negative feedback loops. Two forms of fuzzy logic, namely, the Zadeh operators and the probabilistic operators, as well as the summation logic have been investigated. We show that the easiness of evolving sustained oscillation, and the stability of the evolved oscillation depend both on the regulation logic and on the consistency of the regulation on the target gene
Interactions between genes and gene products give rise to complex circuits that enable cells to proc...
A future quantitative genetics theory should link genetic variation to phenotypic variation in a cau...
AbstractA future quantitative genetics theory should link genetic variation to phenotypic variation ...
Jin Y, Meng Y, Sendhoff B. Influence of regulation logic on the easiness of evolving sustained oscil...
Jin Y, Sendhoff B. Fuzzy Logic in Evolving in silico Oscillatory Dynamics for Gene Regulatory Networ...
Jin Y, Meng Y. Emergence of robust regulatory motifs from in silico evolution of sustained oscillati...
In this paper, we review the qualitative tools developed by our group for the analysis of regulatory...
We analyse a suite of Boolean networks which have been evolved to exhibit limit cycle-type dynamics ...
Abstract Background Genetic regulatory networks (GRN) can be described by differential equations wit...
Steiner T, Schramm L, Jin Y, Sendhoff B. Emergence of feedback in artificial gene regulatory network...
Network motifs have been identified as building blocks of regulatory networks, including gene regula...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Gene-on-gene regulations are key components of every living organism. Dynamical abstract models of g...
Genes are the fundamental units of biological organisms. Genes encode proteins which carryout variou...
Interactions between genes and gene products give rise to complex circuits that enable cells to proc...
A future quantitative genetics theory should link genetic variation to phenotypic variation in a cau...
AbstractA future quantitative genetics theory should link genetic variation to phenotypic variation ...
Jin Y, Meng Y, Sendhoff B. Influence of regulation logic on the easiness of evolving sustained oscil...
Jin Y, Sendhoff B. Fuzzy Logic in Evolving in silico Oscillatory Dynamics for Gene Regulatory Networ...
Jin Y, Meng Y. Emergence of robust regulatory motifs from in silico evolution of sustained oscillati...
In this paper, we review the qualitative tools developed by our group for the analysis of regulatory...
We analyse a suite of Boolean networks which have been evolved to exhibit limit cycle-type dynamics ...
Abstract Background Genetic regulatory networks (GRN) can be described by differential equations wit...
Steiner T, Schramm L, Jin Y, Sendhoff B. Emergence of feedback in artificial gene regulatory network...
Network motifs have been identified as building blocks of regulatory networks, including gene regula...
In this chapter, we describe the use of evolutionary methods for the in silico generation of artific...
Living organisms are remarkably robust despite fluctuating concentrations of functional molecules in...
Gene-on-gene regulations are key components of every living organism. Dynamical abstract models of g...
Genes are the fundamental units of biological organisms. Genes encode proteins which carryout variou...
Interactions between genes and gene products give rise to complex circuits that enable cells to proc...
A future quantitative genetics theory should link genetic variation to phenotypic variation in a cau...
AbstractA future quantitative genetics theory should link genetic variation to phenotypic variation ...