Rule-based computing system for microbial interactions and communications: Evolution in virtual bacterial populations
Authored by R Gregory, J R Saunders, V A Saunders
Date Published: 2008
DOI: 10.1016/j.biosystems.2007.09.002
Sponsors:
Biotechnology and Biological Sciences Research Council (BBSRC)
Platforms:
No platforms listed
Model Documentation:
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Abstract
We have developed a novel rule-based computing system of microbial
interactions and communications, referred to as COSMIC-Rules, for
simulating evolutionary processes within populations of virtual
bacteria. The model incorporates three levels: the bacterial genome, the
bacterial cell and an environment inhabited by such cells. The virtual
environment in COSMIC-Rules can contain multiple substances, whose
relative toxicity or nutrient status is specified by the genome of the
bacterium. Each substance may be distributed uniformly or in a
user-defined manner. The organisms in COSMIC-Rules possess
individually-defined physical locations, size, cell division status and
genomes. Genes and/or gene systems are represented by abstractions that
may summate sometimes complex phenotypes. Central to COSMIC-Rules is a
simplified representation of bacterial species, each containing a
functional genome including, where desired, extrachromosomal elements
such as plasmids and/or bacteriophages. A widely applicable computer
representation of biological recognition systems based on bit string
matching is essential to the model. This representation permits, for
example, the modelling of protein-protein interactions, receptor-ligand
interactions and DNA-DNA transactions. COSMIC-Rules is intended to
inform studies on bacterial adaptation and evolution, and to predict
behaviour of populations of pathogenic bacteria and their viruses. The
framework is constructed for parallel execution across a large number of
machines and efficiently utilises a 64 processor development cluster. It
will run on any Grid system and has successfully tested simulations with
millions of bacteria, of multiple species and utilising multiple
substrates. The model may be used for large-scale simulations where a
genealogical record for individual organisms is required. (C) 2007
Elsevier Ireland Ltd. All rights reserved.
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