Host-seeking efficiency can explain population dynamics of the tsetse fly Glossina morsitans morsitans in response to host density decline
Authored by Jennifer S Lord, Zinhle Mthombothi, Vitalis K Lagat, Fatumah Atuhaire, John W Hargrove
Date Published: 2017
DOI: 10.1371/journal.pntd.0005730
Sponsors:
European Union
United States National Institutes of Health (NIH)
Platforms:
NetLogo
Model Documentation:
Other Narrative
Model Code URLs:
https://github.com/jenniesuz/nagupande
Abstract
Females of all blood-feeding arthropod vectors must find and feed on a
host in order to produce offspring. For tsetse D vectors of the
trypanosomes that cause human and animal African trypanosomiasis D the
problem is more extreme, since both sexes feed solely on blood. Host
location is thus essential both for survival and reproduction. Host
population density should therefore be an important driver of population
dynamics for haematophagous insects, and particularly for tsetse, but
the role of host density is poorly understood. We investigate the issue
using data on changes in numbers of tsetse (Glossina morsitans morsitans
Westwood) caught during a host elimination experiment in Zimbabwe in the
1960s. During the experiment, numbers of flies caught declined by 95\%.
We aimed to assess whether models including starvation-dependent
mortality could explain observed changes in tsetse numbers as host
density declined. An ordinary differential equation model, including
starvation-dependent mortality, captured the initial dynamics of the
observed tsetse population. However, whereas small numbers of tsetse
were caught throughout the host elimination exercise, the modelled
population went extinct. Results of a spatially explicit agent-based
model suggest that this discrepancy could be explained by immigration of
tsetse into the experimental plot. Variation in host density, as a
result of natural and anthropogenic factors, may influence tsetse
population dynamics in space and time. This has implications for
Trypanosoma brucei rhodesiense transmission. Increased tsetse mortality
as a consequence of low host density may decrease trypanosome
transmission, but hungrier flies may be more inclined to bite humans,
thereby increasing the risk of transmission to humans. Our model
provides a way of exploring the role of host density on tsetse
population dynamics and could be incorporated into models of trypanosome
transmission dynamics to better understand how spatio-temporal variation
in host density impacts trypanosome prevalence in mammalian hosts.
Tags
behavior
Diptera
Hunger
Flies glossina
Pallidipes
Westwood
Baits