Host behaviour–parasite feedback: an essential link between animal behaviour and disease ecology

Ezenwa, Vanessa O.; Archie, Elizabeth A.; Craft, Meggan E.; Hawley, Dana M.; Martin, Lynn B.; Moore, Janice; White, Lauren A.

doi:10.1098/rspb.2015.3078

Cited by 129 publications

(122 citation statements)

References 81 publications

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“…Waning immunity from maternal antibodies or prior exposure to an infectious agent may also contribute to temporal lags in the availability of susceptible individuals on different host patches depending on the local history of exposure (Fouchet et al., ; Garnier, Gandon, Harding, & Boulinier, ; Garnier et al., ; Plowright et al., ). Importantly, behavioural and physiological processes may be linked through host–parasite feedbacks (Ezenwa et al., ; Gudelj & White, ; VanderWaal & Ezenwa, ). An important next step for spatial, individual‐based models might be to incorporate feedbacks between behaviour and physiology, such as sickness‐induced behavioural changes or variable transmission efficiency between populations (Croft et al., ; Ezenwa et al., ; Quevillon, Hanks, Bansal, Hughes, & Gordon, ; Wilson et al., ).…”

Section: Future Directions: Addressing Global Challengesmentioning

confidence: 99%

“…Importantly, behavioural and physiological processes may be linked through host–parasite feedbacks (Ezenwa et al., ; Gudelj & White, ; VanderWaal & Ezenwa, ). An important next step for spatial, individual‐based models might be to incorporate feedbacks between behaviour and physiology, such as sickness‐induced behavioural changes or variable transmission efficiency between populations (Croft et al., ; Ezenwa et al., ; Quevillon, Hanks, Bansal, Hughes, & Gordon, ; Wilson et al., ). Advances in the field of ecoimmunology are making the data needed for such analyses ever more accessible (Adelman, Moyers, & Hawley, ).…”

Section: Future Directions: Addressing Global Challengesmentioning

confidence: 99%

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Dynamic, spatial models of parasite transmission in wildlife: Their structure, applications and remaining challenges

White

Forester

Craft

2017

Journal of Animal Ecology

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Individual differences in contact rate can arise from host, group and landscape heterogeneity and can result in different patterns of spatial spread for diseases in wildlife populations with concomitant implications for disease control in wildlife of conservation concern, livestock and humans. While dynamic disease models can provide a better understanding of the drivers of spatial spread, the effects of landscape heterogeneity have only been modelled in a few well-studied wildlife systems such as rabies and bovine tuberculosis. Such spatial models tend to be either purely theoretical with intrinsic limiting assumptions or individual-based models that are often highly species- and system-specific, limiting the breadth of their utility. Our goal was to review studies that have utilized dynamic, spatial models to answer questions about pathogen transmission in wildlife and identify key gaps in the literature. We begin by providing an overview of the main types of dynamic, spatial models (e.g., metapopulation, network, lattice, cellular automata, individual-based and continuous-space) and their relation to each other. We investigate different types of ecological questions that these models have been used to explore: pathogen invasion dynamics and range expansion, spatial heterogeneity and pathogen persistence, the implications of management and intervention strategies and the role of evolution in host-pathogen dynamics. We reviewed 168 studies that consider pathogen transmission in free-ranging wildlife and classify them by the model type employed, the focal host-pathogen system, and their overall research themes and motivation. We observed a significant focus on mammalian hosts, a few well-studied or purely theoretical pathogen systems, and a lack of studies occurring at the wildlife-public health or wildlife-livestock interfaces. Finally, we discuss challenges and future directions in the context of unprecedented human-mediated environmental change. Spatial models may provide new insights into understanding, for example, how global warming and habitat disturbance contribute to disease maintenance and emergence. Moving forward, better integration of dynamic, spatial disease models with approaches from movement ecology, landscape genetics/genomics and ecoimmunology may provide new avenues for investigation and aid in the control of zoonotic and emerging infectious diseases.

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Section: Future Directions: Addressing Global Challengesmentioning

confidence: 99%

Section: Future Directions: Addressing Global Challengesmentioning

confidence: 99%

Dynamic, spatial models of parasite transmission in wildlife: Their structure, applications and remaining challenges

White

Forester

Craft

2017

Journal of Animal Ecology

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“…It may also be important to consider networks as dynamic, rather than static, structures, with changes affecting transmission over longer time‐scales, particularly in endemic diseases (Funk, Salathé & Jansen ; Ezenwa et al . ; Silk et al . ).…”

Section: Introductionmentioning

confidence: 99%

The application of statistical network models in disease research

et al. 2017

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Summary1. Host social structure is fundamental to how infections spread and persist, and so the statistical modelling of static and dynamic social networks provides an invaluable tool to parameterise realistic epidemiological models. 2. We present a practical guide to the application of network modelling frameworks for hypothesis testing related to social interactions and epidemiology, illustrating some approaches with worked examples using data from a population of wild European badgers Meles meles naturally infected with bovine tuberculosis. 3. Different empirical network datasets generate particular statistical issues related to non-independence and sampling constraints. We therefore discuss the strengths and weaknesses of modelling approaches for different types of network data and for answering different questions relating to disease transmission. 4. We argue that statistical modelling frameworks designed specifically for network analysis offer great potential in directly relating network structure to infection. They have the potential to be powerful tools in analysing empirical contact data used in epidemiological studies, but remain untested for use in networks of spatio-temporal associations. 5. As a result, we argue that developments in the statistical analysis of empirical contact data are critical given the ready availability of dynamic network data from bio-logging studies. Furthermore, we encourage improved integration of statistical network approaches into epidemiological research to facilitate the generation of novel modelling frameworks and help extend our understanding of disease transmission in natural populations.

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“…Changes in behaviour following experimental infections have been shown in many animals (Ezenwa et al, 2016;Barber et al, 2000) and might reflect 'sickness behaviours' including lethargy, depression and a reduction in maintenance behaviours, such as grooming (Hart, 1988). During its pre-infective early growth phase within its fish host, S. solidus presence does not induce a host leucocyte immune response (Scharsack et al, 2004) and is associated with decreased monocyte proliferation (Scharsack et al, 2007).…”

Section: The Host Immune Response Hypothesismentioning

confidence: 99%

Can the behaviour of threespine stickleback parasitized with Schistocephalus solidus be replicated by manipulating host physiology?

Hébert

Berger

Barber

et al. 2016

Journal of Experimental Biology

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Sticklebacks infected by the parasitic flatworm Schistocephalus solidus show dramatic changes in phenotype, including a loss of species-typical behavioural responses to predators. The timing of host behaviour change coincides with the development of infectivity of the parasite to the final host (a piscivorous bird), making it an ideal model for studying the mechanisms of infection-induced behavioural modification. However, whether the loss of host anti-predator behaviour results from direct manipulation by the parasite, or is a by-product (e.g. host immune response) or side effect of infection (e.g. energetic loss), remains controversial. To understand the physiological mechanisms that generate these behavioural changes, we quantified the behavioural profiles of experimentally infected fish and attempted to replicate these in non-parasitized fish by exposing them to treatments including immunity activation and fasting, or by pharmacologically inhibiting the stress axis. All fish were screened for the following behaviours: activity, water depth preference, sociability, phototaxis, anti-predator response and latency to feed. We were able to change individual behaviours with certain treatments. Our results suggest that the impact of S. solidus on the stickleback might be of a multifactorial nature. The behaviour changes observed in infected fish might result from the combined effects of modifying the serotonergic axis, lack of energy and activation of the immune system.

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Host behaviour–parasite feedback: an essential link between animal behaviour and disease ecology

Cited by 129 publications

References 81 publications

Dynamic, spatial models of parasite transmission in wildlife: Their structure, applications and remaining challenges

Dynamic, spatial models of parasite transmission in wildlife: Their structure, applications and remaining challenges

The application of statistical network models in disease research

Can the behaviour of threespine stickleback parasitized with Schistocephalus solidus be replicated by manipulating host physiology?

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