Within‐Host Disease Ecology in the Sea Fan Gorgonia ventalina: Modeling the Spatial Immunodynamics of a Coral‐Pathogen Interaction
- 1 December 2007
- journal article
- research article
- Published by University of Chicago Press in The American Naturalist
- Vol. 170 (6), E143-E161
- https://doi.org/10.1086/522841
Abstract
We develop a spatially explicit model for the within-host interactions between a fungal pathogen and the immune response by its coral host. The model is parameterized for the recent epizootic of Aspergillus sydowii in the sea fan Gorgonia ventalina, but its struc- ture is adaptable to many other diseases attacking corals worldwide, fungal infections in other invertebrates and plants, and opportunistic fungal infections in vertebrates. Model processes include pathogen growth and spread through consumption of host tissue, chemotactic attraction of undifferentiated host amoebocytes to infections, and amoebocyte differentiation into various cell types that attack the pathogen. Sensitivity analysis shows that the spread rate of a single localized infection is determined primarily by the pathogen's poten- tial rate of host tissue consumption and by the host's ability to replenish the pool of undifferentiated amoebocytes and sustain a long-term response. The spatial localization of immune responses creates potentially strong indirect interactions between distant le- sions, allowing new infections to grow rapidly while host resources are concentrated at older, larger infections. These findings provide possible mechanistic explanations for effects of environmental stress- ors (e.g., ocean warming, nutrient enrichment) on aspergillosis prev- alence and severity and for the observed high spatial and between- host variability in disease impacts.Keywords
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