Abstract
BackgroundMetabolism and its regulation constitute a large fraction of the molecular activity within cells. The control of cellular metabolic state is mediated by numerous molecular mechanisms, which in effect position the metabolic network flux state at specific locations within a mathematically-definable steady-state flux space. Post-translational regulation constitutes a large class of these mechanisms, and decades of research indicate that achieving a network flux state through post-translational metabolic regulation is both a complex and complicated regulatory problem. No analysis method for the objective, top-down assessment of such regulation problems in large biochemical networks has been presented and demonstrated.ResultsWe show that the use of Monte Carlo sampling of the steady-state flux space of a cell-scale metabolic system in conjunction with Principal Component Analysis and eigenvector rotation results in a low-dimensional and biochemically interpretable decomposition of the steady flux states of the system. This decomposition comes in the form of a low number of small reaction sets whose flux variability accounts for nearly all of the flux variability in the entire system. This result indicates an underlying simplicity and implies that the regulation of a relatively low number of reaction sets can essentially determine the flux state of the entire network in the given growth environment.ConclusionWe demonstrate how our top-down analysis of networks can be used to determine key regulatory requirements independent of specific parameters and mechanisms. Our approach complements the reductionist approach to elucidation of regulatory mechanisms and facilitates the development of our understanding of global regulatory strategies in biological networks.
Highlights
Metabolism and its regulation constitute a large fraction of the molecular activity within cells
Metabolic network reconstructions[1] have been used as a basis for a number of analyses[2] that have provided insights into the topology [3,4,5], modularity[6,7], robustness[8], and dynamics[9] of large biochemical networks
In the constraint-based framework, the regulatory challenge for genome-scale metabolic networks has been described as a two-level process[10,11]: first, regulatory mechanisms associated with transcription and translation geometrically delimit the steady-state flux space by determining which reactions can potentially carry flux; and second, regulation of gene product activity by posttranslational mechanisms determines the flux state as a point location within the flux space
Summary
Metabolism and its regulation constitute a large fraction of the molecular activity within cells. BMC Systems Biology 2009, 3:30 http://www.biomedcentral.com/1752-0509/3/30 dimensionality of the second level has yet to be assessed. We approach this problem of cell-scale post-translational regulation in the context of presenting a method for the decomposition of the range of functional capabilities of large biochemical reaction systems. We describe this decomposition procedure and demonstrate how it can elucidate a low number of reaction sets that account for most of the range of behaviors in a cell-scale system
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