FN Archimer Export Format PT J TI Processes leading to the coexistence of a host and its parasitoid in homogeneous environments: The role of an infected dormant stage BT AF ARANCIO, Marc SOURISSEAU, Marc SOUISSI, Sami AS 1:1,2;2:1;3:2; FF 1:PDG-ODE-DYNECO-PELAGOS;2:PDG-ODE-DYNECO-PELAGOS;3:; C1 IFREMER Brest, Lab Dynam Environm Cotier, F-29280 Plouzane, France. Univ Lille 1 Sci & Technol, UMR CNRS LOG 8187, Stn Marine, F-62930 Wimereux, France. C2 IFREMER, FRANCE UNIV LILLE, FRANCE SI BREST SE PDG-ODE-DYNECO-PELAGOS IN WOS Ifremer jusqu'en 2018 copubli-france copubli-univ-france IF 2.321 TC 2 UR https://archimer.ifremer.fr/doc/00180/29119/27692.pdf LA English DT Article DE ;Individual-based model;Dinoflagellate;Parasitoid;Amoebophrya;Host-parasite interactions;Sources of coexistence AB Theoretical studies have usually been used to explain host–parasitoid persistence in conditions of spatial heterogeneity or in homogeneous environments with specific conditions. In shallow estuaries where spatial heterogeneity is prevented by tides and river input, a common host–parasitoid system (dinoflagellate-Amoebophrya spp.) is able to persist even in the absence of specific conditions described in the literature. Recent observations have revealed that the cyst stage (during which the dinoflagellate host can survive in difficult environmental conditions in a dormant stage) can be infected by the parasitoid. The encystment/excystment process is suspected to be the basis for the long-term persistence of the system. In this work, the coexistence of Amoebophrya spp. and their hosts in homogeneous environments has been tested with an individual-based model of host–parasitoid interactions. Three processes that enable the coexistence were introduced into our model: (1) modifications in infection parameters, (2) a tritrophic food web and (3) a host encystment–excystment process. The persistence of the system was obtained in mixed conditions in all cases; however, the conditions required to obtain persistence with the infection parameter modifications were unrealistic. The tritrophic food web scenario produced short, stable, 10-d-long cycles in which the control of the parasite population in the environment was difficult to observe. The excystment process appears to be responsible for the interannual persistence of the system. Durable cycles with periods of 50 d were produced despite the unstable conditions. Moreover, these cycles did not depend on the proportion of infected cysts as long as a portion of the cysts remained healthy. PY 2014 PD MAY SO Ecological Modelling SN 0304-3800 PU Elsevier Science Bv VL 279 UT 000334989500008 BP 78 EP 88 DI 10.1016/j.ecolmodel.2014.02.015 ID 29119 ER EF