Abstract
A transcriptional regulatory network (TRN) constitutes the collection of regulatory rules that link environmental cues to the transcription state of a cell's genome. We recently proposed a matrix formalism that quantitatively represents a system of such rules (a transcriptional regulatory system [TRS]) and allows systemic characterization of TRS properties. The matrix formalism not only allows the computation of the transcription state of the genome but also the fundamental characterization of the input-output mapping that it represents. Furthermore, a key advantage of this “pseudo-stoichiometric” matrix formalism is its ability to easily integrate with existing stoichiometric matrix representations of signaling and metabolic networks. Here we demonstrate for the first time how this matrix formalism is extendable to large-scale systems by applying it to the genome-scale Escherichia coli TRS. We analyze the fundamental subspaces of the regulatory network matrix (R) to describe intrinsic properties of the TRS. We further use Monte Carlo sampling to evaluate the E. coli transcription state across a subset of all possible environments, comparing our results to published gene expression data as validation. Finally, we present novel in silico findings for the E. coli TRS, including (1) a gene expression correlation matrix delineating functional motifs; (2) sets of gene ontologies for which regulatory rules governing gene transcription are poorly understood and which may direct further experimental characterization; and (3) the appearance of a distributed TRN structure, which is in stark contrast to the more hierarchical organization of metabolic networks.
Highlights
Complex regulatory networks control the transcription state of a genome and the functional activity of a cell [1]
The work that we present here represents the first R matrix-based model of a genome-scale transcriptional regulatory system (TRS), and this work has enabled us to gain important insights into the behavior of the R matrix at a larger scale, challenges associated with the scale-up, as well as the underlying biology of E. coli transcriptional regulation
We performed singular value decomposition (SVD) to characterize the fundamental subspaces of multiple R* matrices for the E. coli TRS, and we summarize the results below
Summary
Complex regulatory networks control the transcription state of a genome and the functional activity of a cell [1]. To effectively describe the interconnected functions of the regulated genes and associated regulatory proteins within a given TRN, we recently developed a formalism involving a regulatory network matrix called R [7]. The R matrix represents the components (extracellular cues, metabolites, genes, and proteins, including regulatory activators and repressors) and reactions (regulatory rules) within a transcriptional regulatory system (TRS). By using the fundamental properties of linear algebra, this matrix formalism allows characterization of TRS properties and facilitates in silico prediction of the transcription state of the genome under any specified set of environmental conditions
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