Host contact and shedding patterns clarify variation in pathogen exposure and transmission in threatened tortoise<i>Gopherus agassizii</i>: implications for disease modelling and management

Aiello, Christina M.; Nussear, Kenneth E.; Esque, Todd C.; Emblidge, Patrick G.; Sah, Pratha; Bansal, Shweta; Hudson, Peter J.

doi:10.1111/1365-2656.12511

Cited by 46 publications

(70 citation statements)

References 49 publications

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“…First, because the impact of edge weights on disease transmission can be context dependent, depending on the type of interaction, transmission mode of pathogen, and the relative time‐scale of network collection and pathogen spread, we have chosen to not include edge weights while performing our computational disease experiments. Future meta‐analytic studies can leverage a growing number of transmission studies to explicitly incorporate the role of contact intensity on disease transmission (Aiello et al., ; Manlove, Cassirer, Plowright, Cross, & Hudson, ). Second, we assume that social contacts do not covary with pathogen characteristics and remain unaltered after an infection is introduced into a population.…”

Section: Discussionmentioning

confidence: 99%

Disease implications of animal social network structure: A synthesis across social systems

Sah

Mann

Bansal

2018

Journal of Animal Ecology

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112

137

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The disease costs of sociality have largely been understood through the link between group size and transmission. However, infectious disease spread is driven primarily by the social organization of interactions in a group and not its size. We used statistical models to review the social network organization of 47 species, including mammals, birds, reptiles, fish and insects by categorizing each species into one of three social systems, relatively solitary, gregarious and socially hierarchical. Additionally, using computational experiments of infection spread, we determined the disease costs of each social system. We find that relatively solitary species have large variation in number of social partners, that socially hierarchical species are the least clustered in their interactions, and that social networks of gregarious species tend to be the most fragmented. However, these structural differences are primarily driven by weak connections, which suggest that different social systems have evolved unique strategies to organize weak ties. Our synthetic disease experiments reveal that social network organization can mitigate the disease costs of group living for socially hierarchical species when the pathogen is highly transmissible. In contrast, highly transmissible pathogens cause frequent and prolonged epidemic outbreaks in gregarious species. We evaluate the implications of network organization across social systems despite methodological challenges, and our findings offer new perspective on the debate about the disease costs of group living. Additionally, our study demonstrates the potential of meta-analytic methods in social network analysis to test ecological and evolutionary hypotheses on cooperation, group living, communication and resilience to extrinsic pressures.

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Section: Discussionmentioning

confidence: 99%

Disease implications of animal social network structure: A synthesis across social systems

Sah

Mann

Bansal

2018

Journal of Animal Ecology

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112

137

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“…Some host–parasite systems can, however, be used in this context: in a recent study Aiello et al . [51] undertook experiments with desert tortoises ( Gopherus agassizii ) and showed transmission likelihood was a function of time an infected and susceptible host spent together (usually in a burrow) and were able to estimate transmission patterns from data collected from proximity loggers. Notably the teleost-gyrodactylid systems where the metazoan parasites behave as if they were microparasites, can also be used in this context, where stage 5, the dose acquired, can be observed in vivo under a dissecting microscope using anaesthesia to immobilize the host [57,58].…”

Section: Empirical Measurement and The Deconstructed βmentioning

confidence: 99%

Breaking beta: deconstructing the parasite transmission function

McCallum

Fenton

Hudson

et al. 2017

Phil. Trans. R. Soc. B

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105

149

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Transmission is a fundamental step in the life cycle of every parasite but it is also one of the most challenging processes to model and quantify. In most host–parasite models, the transmission process is encapsulated by a single parameter β. Many different biological processes and interactions, acting on both hosts and infectious organisms, are subsumed in this single term. There are, however, at least two undesirable consequences of this high level of abstraction. First, nonlinearities and heterogeneities that can be critical to the dynamic behaviour of infections are poorly represented; second, estimating the transmission coefficient β from field data is often very difficult. In this paper, we present a conceptual model, which breaks the transmission process into its component parts. This deconstruction enables us to identify circumstances that generate nonlinearities in transmission, with potential implications for emergent transmission behaviour at individual and population scales. Such behaviour cannot be explained by the traditional linear transmission frameworks. The deconstruction also provides a clearer link to the empirical estimation of key components of transmission and enables the construction of flexible models that produce a unified understanding of the spread of both micro- and macro-parasite infectious disease agents.This article is part of the themed issue ‘Opening the black box: re-examining the ecology and evolution of parasite transmission’.

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“…Social interactions between individuals influence infectious disease dynamics at the population level (Aiello et al., ; Clay, Lehmer, Previtali, St. Jeor, & Dearing, ; Grear, Perkins, & Hudson, ), so understanding factors affecting these interactions and how they change in the presence of disease will facilitate more accurate predictions of how diseases spread (Aiello et al., ; Hawley, Etienne, Ezenwa, & Jolles, ; Lloyd‐Smith, Schreiber, Kopp, & Getz, ; Paull et al., ; VanderWaal & Ezenwa, ). Social animals associating with infected conspecifics likely increase their risk of infection, particularly with directly transmitted disease‐causing organisms, and there is evidence from multiple taxa that they avoid doing so (Behringer, Butler, & Shields, ; Croft et al., ; Goodall, ; Kavaliers, Fudge, Colwell, & Choleris, ; Kiesecker, Skelly, Beard, & Preisser, ; Poirotte et al., ; Schaller, ).…”

Section: Introductionmentioning

confidence: 99%

“…Historically, models have assumed homogeneous population mixing and transmission risk, that is mean field estimates of β c and β p , but this typically leads to overestimated transmission rates (Keeling & Grenfell, ). More recent work has demonstrated that incorporating empirical estimates of heterogeneity in both β c and β p improves model fit to natural disease dynamics (see Aiello et al., and references therein), but that β c and β p may themselves covary has been largely ignored. However, this covariation has potentially powerful implications for disease dynamics.…”

Section: Introductionmentioning

confidence: 99%

Transmission risk predicts avoidance of infected conspecifics in Trinidadian guppies

Stephenson

Perkins

Cable

2018

Journal of Animal Ecology

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Associating with conspecifics afflicted with infectious diseases increases the risk of becoming infected, but engaging in avoidance behaviour incurs the cost of lost social benefits. Across systems, infected individuals vary in the transmission risk they pose, so natural selection should favour risk-sensitive avoidance behaviour that optimally balances the costs and benefits of sociality. Here, we use the guppy Poecilia reticulata-Gyrodactylus turnbulli host-parasite system to test the prediction that individuals avoid infected conspecifics in proportion to the transmission risk they pose. In dichotomous choice tests, uninfected fish avoided both the chemical and visual cues, presented separately, of infected conspecifics only in the later stages of infection. A transmission experiment indicated that this avoidance behaviour accurately tracked transmission risk (quantified as both the speed at which transmission occurs and the number of parasites transmitting) through the course of infection. Together, these findings reveal that uninfected hosts can use redundant cues across sensory systems to inform dynamic risk-sensitive avoidance behaviour. This correlation between the transmission risk posed by infected individuals and the avoidance response they elicit has implications for the evolutionary ecology of infectious disease, and its explicit inclusion may improve the ability of epidemic models to predict disease spread.

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Host contact and shedding patterns clarify variation in pathogen exposure and transmission in threatened tortoiseGopherus agassizii: implications for disease modelling and management

Cited by 46 publications

References 49 publications

Disease implications of animal social network structure: A synthesis across social systems

Disease implications of animal social network structure: A synthesis across social systems

Breaking beta: deconstructing the parasite transmission function

Transmission risk predicts avoidance of infected conspecifics in Trinidadian guppies

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