Tick-borne infectious agents in nature: Simulated effects of changes in host density on spatial-temporal prevalence of infected ticks
Authored by Hsiao-Hsuan Wang, W E Grant, P D Teel, S A Hamer
Date Published: 2016
DOI: 10.1016/j.ecolmodel.2015.11.021
Sponsors:
Air Force Research Laboratories (AFRL)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Ticks (Ixodidae) are important vectors of infectious agents that affect
human and animal health, and the spatial-temporal dynamics of
tick-host-pathogen-landscape interactions are difficult to understand
based on empirical observations alone. We used a spatially explicit
simulation model to examine the effects of changes in host density on
the prevalence of a hypothetical transstadially transmitted infectious
agent in a population of a prototypical three-host tick under ecological
conditions representative of the predominantly forested areas of the
south-central United States. The model was parameterized such that
baseline conditions yielded a landscape-level nymphal infection
prevalence (NIP) fluctuating seasonally around a threshold of 0.1
(indicative of pathogen endemicity in some disease systems) roughly
paralleling seasonal fluctuations in wildlife host densities, with
seasonal highs in late summer and early fall and seasonal lows in winter
and spring. In simulated scenarios of both small-sized and medium-sized
host reduction, the densities of both uninfected and infected off-host
nymphs decreased markedly from year-to-year. The number of habitat
patches in which NIP >0.1, however, increased when small-sized hosts
were removed, yet decreased when medium-sized hosts were removed.
Simulation of the reduction in density of large-sized hosts resulted in
trends similar to those produced by reducing density of small sized
hosts, but trends were less pronounced. Under the conditions simulated, both NIP and off-host nymph densities (DON) were particularly sensitive
to changes in the proportion of larvae obtaining their blood meal from
medium-sized hosts. Variation in simulated NIP values can be explained
by the fact that larval, nymphal, and adult tick loads were distributed
differently among the different-sized hosts, each with their distinct
range of movement and degree of variation in population size. Simulation
results of this hypothetical case study offer insight into the complex
landscape-level interactions of a prototypical 3-host tick and suggest
that medium-sized hosts could play a key role in sustaining and
dispersing a tick-borne infectious agent in nature. (C) 2016 Elsevier
B.V. All rights reserved.
Tags
Amblyomma-americanum acari
Ixodidae population-dynamics
Lone star
tick
Ehrlichia-chaffeensis rickettsiales
Parasite-landscape
interactions
Boophilus spp. infestations
Basic reproductive number
Vector ixodes-scapularis
Lyme-disease spirochete
Reservoir competence