When transcription regulatory networks are compared among distantly related eukaryotes, a number of striking similarities are observed: a larger-than-expected number of genes, extensive overlapping connections, and an apparently high degree of functional redundancy. It is often assumed that the complexity of these networks represents optimized solutions, precisely sculpted by natural selection; their common features are often asserted to be adaptive. Here, we discuss support for an alternative hypothesis: the common structural features of transcription networks arise from evolutionary trajectories of "least resistance"--that is, the relative ease with which certain types of network structures are formed during their evolution
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
AbstractThe modulation of promoter activity by DNA-binding transcription regulators forms a bipartit...
Gene regulatory networks (GRNs) play key roles in development, phenotype plasticity, and evolution. ...
When transcription regulatory networks are compared among distantly related eukaryotes, a number of ...
Transcription networks have an unusual structure. In both prokaryotes and eukaryotes, the number of ...
Transcriptional regulatory networks take part in the regulation of essentially every aspect of an or...
peer reviewedGene expression is a result of the interplay between the structure, type, kinetics, and...
<div><p>The evolution of transcriptional regulatory networks has thus far mostly been studied at the...
The mystery of how diverse life forms evolved has captivated scientists for over 150 years. It has b...
DNA evolution models made invaluable contributions to comparative genomics, although it seemed formi...
dynamics of these networks across organisms, which would reveal Of the several steps at which the fl...
<p>The top-left network shows the structure of the giant component of the transcription factor inter...
We present a first attempt to evaluate the generic topological principles underlying the mammalian t...
A proof is presented that gene regulatory networks (GRNs) based solely on transcription factors can-...
Networks in molecular evolution properties of the RNA map were derived: "For sequence spaces of ch...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
AbstractThe modulation of promoter activity by DNA-binding transcription regulators forms a bipartit...
Gene regulatory networks (GRNs) play key roles in development, phenotype plasticity, and evolution. ...
When transcription regulatory networks are compared among distantly related eukaryotes, a number of ...
Transcription networks have an unusual structure. In both prokaryotes and eukaryotes, the number of ...
Transcriptional regulatory networks take part in the regulation of essentially every aspect of an or...
peer reviewedGene expression is a result of the interplay between the structure, type, kinetics, and...
<div><p>The evolution of transcriptional regulatory networks has thus far mostly been studied at the...
The mystery of how diverse life forms evolved has captivated scientists for over 150 years. It has b...
DNA evolution models made invaluable contributions to comparative genomics, although it seemed formi...
dynamics of these networks across organisms, which would reveal Of the several steps at which the fl...
<p>The top-left network shows the structure of the giant component of the transcription factor inter...
We present a first attempt to evaluate the generic topological principles underlying the mammalian t...
A proof is presented that gene regulatory networks (GRNs) based solely on transcription factors can-...
Networks in molecular evolution properties of the RNA map were derived: "For sequence spaces of ch...
The topology of cellular circuits (the who-interacts-with-whom) is key to understand their robustnes...
AbstractThe modulation of promoter activity by DNA-binding transcription regulators forms a bipartit...
Gene regulatory networks (GRNs) play key roles in development, phenotype plasticity, and evolution. ...