Competence of hosts and complex foraging behavior are two cornerstones in the dynamics of trophically transmitted parasites.
Fiche publication
Date publication
mai 2016
Journal
Journal of theoretical biology
Auteurs
Membres identifiés du Cancéropôle Est :
Dr PERASSO Antoine
Tous les auteurs :
Baudrot V, Perasso A, Fritsch C, Raoul F
Lien Pubmed
Résumé
Multi-host trophically transmitted parasite (TTP) is a common life cycle where prey and predators are respectively intermediate and definitive hosts of the parasite. In these systems, the foraging response of the predator toward variations in prey community composition underlies the dynamic of the parasite. Therefore, modeling epidemiological dynamic of infectious diseases considering ecological predator-prey interactions is essential to understand the spreading of parasites in ecosystems. However, two important weaknesses of previous TTP models including feeding interaction can be pointed out: (i) the choice of a linear density-dependent contact rate is faintly realistic as it supposes an unlimited ingestion rate with an increase of prey density and (ii) considering only one host prey species prevents the study of host biodiversity effect due to change in the prey community composition where species have different competences to be infected and to transmit the parasite. This article attempts to address the dynamics of parasite in a context of multiple intermediate hosts differentiated by their competences and of complex foraging behavior of the predator. We present and analyze a deterministic one predator-two prey model, which is then used to explore the transmission cycle of the cestode Echinococcus multilocularis. This study examines the foraging condition for the co-existence of the prey, and then, based on the computation of the threshold measure of disease risk, R0, we show that the pattern of feeding interactions changes the relationship between disease risk and prey community composition. Finally, we disentangle the mechanism leading to the counter-intuitive observation of a decrease of disease risk while the population density of intermediate hosts increases.
Mots clés
Algorithms, Animals, Echinococcus multilocularis, pathogenicity, Ecosystem, Feeding Behavior, physiology, Host-Parasite Interactions, Humans, Models, Biological, Parasites, pathogenicity, Parasitic Diseases, parasitology, Population Density, Population Dynamics, Predatory Behavior, physiology, Risk Factors, Virulence, Zoonoses, parasitology
Référence
J. Theor. Biol.. 2016 May 21;397:158-68