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

White, Lauren A.; Forester, James D.; Craft, Meggan E.

doi:10.1111/1365-2656.12761

Cited by 64 publications

(62 citation statements)

References 278 publications

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“…Mechanistic portrayals of how animals form and maintain territories remain rare, and to our knowledge, have not been integrated with a disease modeling framework. This work provides a key interface between the disciplines of movement and disease ecology [4,5,13] by exploring how mechanistic movement driven by an individual's social landscape affects disease dynamics. These results indicate an interesting threshold at higher host densities where stigmergy-driven movement behavior can still support pathogen persistence.…”

Section: Discussionmentioning

confidence: 99%

“…In contrast, mechanistic portrayals of how animals form and maintain territories remain rare [9] (but see: [10][11][12]). Disease ecology faces similar barriers to incorporating contact behavior that explicitly reflects individual movement patterns [4,5,13]. Models in disease ecology are often specific to a given-host pathogen system or emphasize the risk of contact rather than ongoing transmission dynamics [5].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A mechanistic, stigmergy model of territory formation in asocial animals: Territorial behavior can dampen disease prevalence but increase persistence

White

VandeWoude

Craft

2019

Preprint

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Mechanistic portrayals of how animals form and maintain territories remain rare, and as a discipline, collective movement ecology has tended to focus on synergistic (e.g., migration, shoaling) rather than agonistic or territorial interactions. Here we ask how dynamic territory formation and maintenance might contribute to disease dynamics in an asocial territorial animal for an indirectly transmitted pathogen. We developed a mechanistic individual-based model where stigmergy-the deposition of signals into the environment (e.g., scent marking, scraping)-dictates not only local movement choices and long-term territory formation, but also the risk of pathogen transmission. Based on a variable importance analysis, the length of the infectious period was the single most important variable in predicting outbreak success, maximum prevalence, and outbreak duration. Population size and rate of pathogen decay were also key predictors. We found that territoriality best reduced maximum prevalence in conditions where we would otherwise expect outbreaks to be most successful: slower recovery rates (i.e., longer infectious periods) and higher conspecific densities. However, at high enough densities, outbreak duration became considerably more variable. Our findings therefore support a limited version of the "territoriality benefits" hypothesis-where reduced home range overlap leads to reduced opportunities for pathogen transmission, but with the caveat that reduction in outbreak severity may increase the likelihood of pathogen persistence. For longer infectious periods and higher host densities, key trade-offs emerged between the strength of pathogen load, strength of the stigmergy cue, and the rate at which those two quantities decayed; this finding raises interesting questions about the evolutionary nature of these competing processes and the role of possible feedbacks between parasitism and territoriality. This work also highlights the importance of considering social cues as part of the movement landscape in order to improve our understanding of the consequences of individual behaviors on population level outcomes. 2 Author summaryMaking decisions about conservation and disease management relies on our understanding of what allows animal populations to be successful. However, movement ecology, as a field, tends to focus on how animals respond to their abiotic environment. Similarly, disease ecology often focuses on the social behavior of animals without accounting for their individual movement patterns. We developed a simulation model that bridges these two fields by allowing hosts to inform their movement based on the past trajectories of other hosts. As hosts navigate their environment, they leave behind a scent trail while avoiding the scent trails of other individuals. We wanted to know if this means of territory formation could heighten or dampen disease spread when infectious hosts leave pathogens in their wake. We found that territoriality could inhibit disease spread under conditions that we would normally expect ...

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A mechanistic, stigmergy model of territory formation in asocial animals: Territorial behavior can dampen disease prevalence but increase persistence

White

VandeWoude

Craft

2019

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“… Jenni McDonald and colleagues’ (2018) Synthesis on host‐pathogen systems of a naturally infected badger population (McDonald, Robertson, and Silk, ). Kristine Grayson's (2018) Synthesis of the population dynamics and invasion biology of gypsy moths in the US (Grayson and Johnson ). Lauren White and colleagues’ (2018) Review of spatial models of parasite transmission in wildlife (White, Forester, and Craft ). Quinn Webber's (2018) Review integrating the ecological and evolutionary implications of individual social and spatial behaviour (Webber and Vander Wal ). Ben Weinstein's (2018) Review of a computer vision for animal ecology (Weinstein ). Pratha Sah's () Review on disease implications of animal social network structure (Sah, Mann, & Bansal, 2018). …”

Section: Shortlisted Papersmentioning

confidence: 99%

“…Grayson's (2018) Synthesis of the population dynamics and invasion biology of gypsy moths in the US (Grayson and Johnson 2018). ' (2018) Review of spatial models of parasite transmission in wildlife (White, Forester, and Craft 2018). Webber's (2018) Review integrating the ecological and evolutionary implications of individual social and spatial behaviour (Webber and Vander Wal 2018).…”

Section: S Hortlis Ted Paper Smentioning

confidence: 99%

And the winner of the inaugural Sidnie Manton Award is…

Wilson

Sheldon

Gaillard

et al. 2018

Journal of Animal Ecology

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“…The application of network approaches (Silk et al, 2017a,b;White et al, 2017) and movement ecology (Dougherty et al, 2018;White et al, 2018) has become integral to understanding the impact of individual behaviour in disease ecology. Both approaches have exploited the increasing availability of high resolution bio-logging technology to quantify how variation in host behaviour contributes to heterogeneity in pathogen transmission opportunities (Krause et al, 2013;White et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Quantifying direct and indirect contacts for the potential transmission of infection between species using a multilayer contact network

Silk

Drewe

Delahay

et al. 2018

Behav.

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Detecting opportunities for between-species transmission of pathogens can be challenging, particularly if rare behaviours or environmental transmission are involved. We present a multilayer network framework to quantify transmission potential in multi-host systems, incorporating environmental transmission, by using empirical data on direct and indirect contacts between European badgers Meles meles and domestic cattle. We identify that indirect contacts via the environment at badger latrines on pasture are likely to be important for transmission within badger populations and between badgers and cattle. We also find a positive correlation between the role of individual badgers within the badger social network, and their role in the overall badger-cattle-environment network, suggesting that the same behavioural traits contribute to the role of individual badgers in within-and between-species transmission. These findings have implications for disease management interventions in this system, and our novel network approach can provide general insights into transmission in other multi-host disease systems.

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

Cited by 64 publications

References 278 publications

A mechanistic, stigmergy model of territory formation in asocial animals: Territorial behavior can dampen disease prevalence but increase persistence

A mechanistic, stigmergy model of territory formation in asocial animals: Territorial behavior can dampen disease prevalence but increase persistence

And the winner of the inaugural Sidnie Manton Award is…

Quantifying direct and indirect contacts for the potential transmission of infection between species using a multilayer contact network

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