Abstract
After being considered as a nuisance to be filtered out, it became recently clear that biochemical noise plays a complex role, often fully functional, for a biomolecular network. The influence of intrinsic and extrinsic noises on biomolecular networks has intensively been investigated in last ten years, though contributions on the co-presence of both are sparse. Extrinsic noise is usually modeled as an unbounded white or colored gaussian stochastic process, even though realistic stochastic perturbations are clearly bounded. In this paper we consider Gillespie-like stochastic models of nonlinear networks, i.e. the intrinsic noise, where the model jump rates are affected by colored bounded extrinsic noises synthesized by a suitable biochemical state-dependent Langevin system. These systems are described by a master equation, and a simulation algorithm to analyze them is derived. This new modeling paradigm should enlarge the class of systems amenable at modeling. We investigated the influence of both amplitude and autocorrelation time of a extrinsic Sine-Wiener noise on: the Michaelis-Menten approximation of noisy enzymatic reactions, which we show to be applicable also in co-presence of both intrinsic and extrinsic noise, a model of enzymatic futile cycle and a genetic toggle switch. In and we show that the presence of a bounded extrinsic noise induces qualitative modifications in the probability densities of the involved chemicals, where new modes emerge, thus suggesting the possible functional role of bounded noises.
Highlights
Cellular functions and decisions are implemented through the coordinate interactions of a very large number of molecular species
We propose the extension of the above structure to more general networks than those ruled by the rigourous massaction law via a stochastic Quasi Steady State approximation (QSSA)
In this paper we investigated the effects of joint extrinsic and intrinsic randomness in nonlinear genetic and other biomolecular networks, under the assumption of non-Gaussian bounded external perturbations
Summary
Cellular functions and decisions are implemented through the coordinate interactions of a very large number of molecular species Central unit of these processes is the DNA, a polymer that is in part segmented in subunits, called genes, which control the production of the key cellular molecules: the proteins, via the mechanism of the transcription. Given the above rough outlook of the intracellular machineries it is not surprising that two modeling tools, born in other applicative domains, revealed to be of the utmost relevance in molecular biology They are the inter-related concepts of feedback [1,2] and of network [3,4,5,6], with their mathematical backbones: the dynamical systems theory and the graph theory, respectively. From the interplay and integration of these two theories with molecular biology, a new scientific field has appeared: Systems Biology [3,4,5]
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