Rule-based simulation of temperate bacteriophage infection: Restriction-modification as a limiter to infection in bacterial populations
Authored by R Gregory, J R Saunders, V A Saunders
Date Published: 2010
DOI: 10.1016/j.biosystems.2010.02.010
Sponsors:
Biotechnology and Biological Sciences Research Council
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Model Code URLs:
Model code not found
Abstract
An individual-based model (IbM) for bacterial adaptation and evolution, COSMIC-Rules, has been employed to simulate interactions of virtual
temperate bacteriophages (phages) and their bacterial hosts. Outcomes of
infection mimic those of a phage such as lambda, which can enter either
the lytic or lysogenic cycle, depending on the nutritional status of the
host. Infection of different hosts possessing differing restriction and
modification systems is also simulated. Phages restricted upon infection
of one restricting host can be adapted (by host-controlled modification
of the phage genome) and subsequently propagate with full efficiency on
this host. However, such ability is lost if the progeny phages are
passaged through a new host with a different restriction and
modification system before attempted re-infection of the original
restrictive host. The simulations show that adaptation and re-adaptation
to a particular host-controlled restriction and modification system
result in lower efficiency and delayed lysis of bacterial cells compared
with infection of non-restricting host bacteria.
Such biologically realistic simulations validate the use of the IbM
approach to predicting behaviour of bacteriophages in bacterial
populations. The applicability of the model for more complex scenarios
aimed at predictive modelling of bacterial evolution in a changing
environment and the implications for the spread of viruses in a wider
context are discussed. (C) 2010 Elsevier Ireland Ltd. All rights
reserved.
Tags
Evolution
ecology
Escherichia-coli
Dna
Cultures
Host-controlled modification
Phage-lambda
Microbial
interactions
Specificity
Lysogens