Abstract
The Chemical Master Equation is a standard approach to model biochemical reaction networks. It consists of a system of linear differential equations, in which each state corresponds to a possible configuration of the reaction system, and the solution describes a time-dependent probability distribution over all configurations. The Stochastic Simulation Algorithm (SSA) is a method to simulate sample paths from this stochastic process. Both approaches are only applicable for small systems, characterized by few reactions and small numbers of molecules. For larger systems, the CME is computationally intractable due to a large number of possible configurations, and the SSA suffers from large reaction propensities. In our study, we focus on catalytic reaction systems, in which substrates are converted by catalytic molecules. We present an alternative description of these systems, called SiCaSMA, in which the full system is subdivided into smaller subsystems with one catalyst molecule each. These single catalyst subsystems can be analyzed individually, and their solutions are concatenated to give the solution of the full system. We show the validity of our approach by applying it to two test-bed reaction systems, a reversible switch of a molecule and methyltransferase-mediated DNA methylation.
Highlights
Different approaches exist to modelchemical reaction networks
We focus on catalytic reaction systems, in which substrates are converted by catalytic molecules
We show on different example systems, including a simple conversion reaction and a model for methyltransferase-mediated DNA methylation, that Single Catalyst Stochastic Modeling Approach (SiCaSMA) is equivalent to the standard Chemical Master Equation (CME) description of the full system
Summary
Different approaches exist to model (bio)chemical reaction networks. On one end of the spectrum, quantum-theoretical approaches provide insights into the dynamics of few-atom systems using nearly no approximations of the underlying physics. Force-field driven particle simulations approximate the positions and velocities of atoms or molecules deterministically and are capable of simulating significantly larger systems. The only time-dependent system state is characterized by the number of molecules of each chemical species at a given time. An established method to describe the behavior of such a system is the Chemical Master Equation (CME). It is a system of coupled linear ordinary differential equations whose solution describes a time-dependent probability distribution over the set of possible states of the system (see, e.g., Higham [1], Wilkinson [2], Schnoerr et al [3] for reviews on stochastic modeling approaches for chemical reactions)
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