Abstract
The language of gene expression displays topological symmetry. An important step during gene expression is the binding of transcriptional proteins to DNA promoters adjacent to a gene. Some proteins bind to many promoters in a genome, defining a regulon of genes wherein each promoter might vary in DNA sequence relative to the average consensus. Here we examine the linguistic organization of gene promoter networks, wherein each node in the network represents a promoter and links between nodes represent the extent of base pair-sharing. Prior work revealed a fractal nucleus in several σ-factor regulons from Escherichia coli. We extend these findings to show fractal nuclei in gene promoter networks from three bacterial species, E. coli, Bacillus subtilis, and Pseudomonas aeruginosa. We surveyed several non-σ transcription factors from these species and found that many contain a nucleus that is both visually and numerically fractal. Promoter footprint size scaled as a negative power-law with both information entropy and fractal dimension, while the latter two parameters scaled positively and linearly. The fractal dimension of the diffuse networks (dB = ~1.7) was close to that expected of a diffusion limited aggregation process, confirming prior predictions as to a possible mechanism for development of this structure.
Highlights
Genomes display symmetry on several levels of organization
We address the following: (a) Do other regulons contain fractal nuclei in their Gene Promoter Networks (GPNs)? (b) Do other species contain fractal nuclei in their GPNs? (c) Is there a quantitative relationship between information entropy of the promoter signals in a regulon and the fractal dimension of a GPN nucleus? Do these factors co-vary with promoter footprint size? (d) In addition to addressing these questions, we offer greater detail in the methods used to study GPNs in this fashion
Our findings demonstrate that a fractal symmetry is present in the nucleus of GPNs of bacteria including but not limited to E. coli
Summary
Genomes display symmetry on several levels of organization. On the most basic level, the DNA double helix is symmetric about its central axis [1]. Several studies show a fractal organization of chromatin [8,9,10] and fractal folding and compaction of whole genomes [11]. The fractal dimension of nuclear chromatin has been examined for the prognosis of cancer [12,13,14]. While many of these examples of symmetry derive from studies of structural genomics, others draw from functional genomics–cases in which genome behavior is symmetric as revealed by Gene
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