Abstract
BackgroundIt is widely accepted that genetic regulatory systems are 'modular', in that the whole system is made up of smaller 'subsystems' corresponding to specific biological functions. Most attempts to identify modules in genetic regulatory systems have relied on the topology of the underlying network. However, it is the temporal activity (dynamics) of genes and proteins that corresponds to biological functions, and hence it is dynamics that we focus on here for identifying subsystems.ResultsUsing Boolean network models as an exemplar, we present a new technique to identify subsystems, based on their dynamical properties. The main part of the method depends only on the stable dynamics (attractors) of the system, thus requiring no prior knowledge of the underlying network. However, knowledge of the logical relationships between the network components can be used to describe how each subsystem is regulated. To demonstrate its applicability to genetic regulatory systems, we apply the method to a model of the Drosophila segment polarity network, providing a detailed breakdown of the system.ConclusionWe have designed a technique for decomposing any set of discrete-state, discrete-time attractors into subsystems. Having a suitable mathematical model also allows us to describe how each subsystem is regulated and how robust each subsystem is against perturbations. However, since the subsystems are found directly from the attractors, a mathematical model or underlying network topology is not necessarily required to identify them, potentially allowing the method to be applied directly to experimental expression data.
Highlights
It is widely accepted that genetic regulatory systems are 'modular', in that the whole system is made up of smaller 'subsystems' corresponding to specific biological functions
Rather than being a protein complex or group of co-expressed genes, such a module can be viewed as the temporal activity of a group of genes/ proteins that controls a specific function in different environmental conditions, cell types and/or tissues
We present a method for identifying subsystems ('dynamical modules'), given a set of discrete state, discrete time attractors
Summary
It is widely accepted that genetic regulatory systems are 'modular', in that the whole system is made up of smaller 'subsystems' corresponding to specific biological functions. Most attempts to identify modules in genetic regulatory systems have relied on the topology of the underlying network. It is the temporal activity (dynamics) of genes and proteins that corresponds to biological functions, and it is dynamics that we focus on here for identifying subsystems. Genetic regulatory systems are assumed to be 'modular', with specific combinations of genes and proteins responsible for different biological functions. Rather than being a protein complex or group of co-expressed genes, such a module can be viewed as the temporal activity (dynamics) of a group of genes/ proteins that controls a specific function in different environmental conditions, cell types and/or tissues. The topology of the underlying interaction network is just a description of the interactions associated with the activity profiles
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