Evolution of searching and life history characteristics in individual-based models of host-parasitoid-microbe associations
Authored by P Schofield, M Chaplain, S Hubbard
Date Published: 2005
DOI: 10.1016/j.jtbi.2005.03.025
Sponsors:
Biotechnology and Biological Sciences Research Council (BBSRC)
Wellcome Trust
Scottish Higher Education Funding Council (SHEFC)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
In this paper we develop a novel discrete, individual-based mathematical
model of the evolution of life history, dispersal and other behavioural
characteristics in insect host-parasitoid-microbe associations, and use
it to investigate their evolutionary dynamics. For any individual
characteristic the model begins with an even, rectangular distribution
of characteristic values. Selection is then allowed to act, and the
change in the distribution of the characteristic values is observed.
Evolutionary change in the population variance of the characteristic
value is also observed, since we would expect this to decline under
selection in most cases. The paper, therefore, introduces a general
framework for modeling problems of evolution in stochastic, spatially
structured environments, where movement and dispersal are under
selection. The model then extends this approach to include the
sex-distorting bacterium Wolbachia in order to investigate aspects of
its horizontal and vertical transmission under different levels of
superparasitism by parasitoids. The model also includes a neutral
genetic marker, in order to be able to detect changes in phenotype
frequency caused by genetic drift, as well as a simplified simulation of
sexual reproduction so as to allow the possibility of recombination
between genotypes. Key results from the model simulations show that: (i)
the refractory time after oviposition affects the value of
superparasitism, with short refractory times favouring high rates of
superparasitism; (ii) variable levels of superparasitism do not affect
the stable proportion of the population of parasitoids infected with
Wolbachia, but this is achieved by different evolutionary pathways under
low and high superparasitism, respectively. In the case of low
superparasitism Wolbachia spreads mainly by vertical transmission, leading to population replacement, whereas when superparasitism rates
are high there is significant horizontal transfer. (c) 2005 Elsevier
Ltd. All rights reserved.
Tags
Dynamics
Mechanism
Populations
Wolbachia