Incorporating habitat distribution in wildlife disease models: conservation implications for the threat of squirrelpox on the <scp>I</scp>sle of <scp>A</scp>rran

Macpherson, Morag F.; Davidson, Ross S.; Duncan, Dugald B.; Lurz, Peter W. W.; Jarrott, Andrew; White, Andrew

doi:10.1111/acv.12219

Cited by 10 publications

(11 citation statements)

References 51 publications

(76 reference statements)

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“…Biological invasions have emerged as a major component of human‐induced global change and are one of the five major pressures driving biodiversity loss, and ultimately the extinction of native species (Lövei, ; Brook, Sodhi & Bradshaw, ; Roy et al ., ). Alien species may affect the invaded ecosystems to varying degrees (Hobbs et al ., ), some resulting in substantial economic and health costs to human societies (Pejchar & Mooney, ), along with causing the progressive substitution and elimination of native species through predation, hybridization, the introduction of disease, habitat alteration and competition for resources or space (Gurevitch & Padilla, ; Kumschick et al ., ; Macpherson et al ., ). Known examples of these negative impacts are, among others, the zebra mussel Dreissena polymorpha , which have invaded fresh waters in North America (Ricciardi, ), and amphibian chytrid fungus Batrachochytrium dendrobatidis , which are responsible for the recent worldwide outbreaks of amphibian chytridiomycosis (Fisher, Garner & Walker, ).…”

Section: Introductionmentioning

confidence: 97%

“…In this respect, although alien species are the second most common threat associated with native species extinction (Bellard, Cassey & Blackburn, ), large‐scale studies with which to explicitly guide decisions relating to the management of alien species risk assessments are not frequent (but see Rodríguez et al ., ; Guisan et al ., ; Thalmann et al ., ). This is, however, not exclusive to invasion biology, since <1% of the currently published papers that employ a macro‐ecological perspective are specifically targeted toward conservation decisions (Guisan et al ., ; Acevedo et al ., ; Macpherson et al ., ). In this scenario, it is necessary to disentangle the aspects which drive alien species distribution patterns that can be attributed to different factors (namely, native species richness, human activity and abiotic characteristics) in order to establish solid and efficient alien species management plans.…”

Section: Introductionmentioning

confidence: 97%

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An assessment of conflict areas between alien and native species richness of terrestrial vertebrates on a macro‐ecological scale in a Mediterranean hotspot

Carpio

Barasona

Guerrero-Casado

et al. 2017

Animal Conservation

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Understanding how the diversity of invasive species is geographically distributed and identifying the major drivers of that pattern is a relevant challenge as regards invasion biology. The aim of this paper was, therefore, to identify and characterize those areas colonized by a high number of alien species as a means to provide directional indications that can be used to minimize the potential negative effects that the alien species may have on host ecosystems. This is done by applying spatially explicit predictive modeling in order to explain the diversity of vertebrate alien species in Spain. The relative importance of the different factors was assessed using variation partitioning. Our results showed that the main factor as regards predicting the distribution of alien species was the anthropogenic variable, and that this was followed by abiotic variables. The other significant predictor of alien species was the number of native species, which had a positive relationship with the number of alien species. This accord with the 'the rich get richer' acceptance hypothesis, which predicts a higher number of alien species in areas with high native species diversity. In this study, we detected actual conflict areas (ACAs), which have high-medium values for the number of both native and alien species.

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Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 97%

An assessment of conflict areas between alien and native species richness of terrestrial vertebrates on a macro‐ecological scale in a Mediterranean hotspot

Carpio

Barasona

Guerrero-Casado

et al. 2017

Animal Conservation

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“…Where SQPV is present, the grey squirrel replaces red squirrels up to 25 times faster than in areas without the infection, where only competition for resources occurs (Rushton et al ., ). SQPV in the UK appears thus as a crucial driver in the interaction between the alien and the native species and collecting data on its presence is fundamental in order to plan adequate management and conservation strategies (Gurnell et al ., ; Schuchert et al ., ; Macpherson et al ., ; Bertolino et al ., ; White et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Disease, invasions and conservation: no evidence of squirrelpox virus in grey squirrels introduced to Italy

Romeo

McInnes

Dale

et al. 2018

Animal Conservation

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Native red squirrels Sciurus vulgaris in Great Britain and Ireland are threatened by alien grey squirrels S. carolinensis through exploitation competition and spillover of squirrelpox virus (SQPV). By accelerating the replacement of red squirrels by the invader, SQPV represents a fundamental factor to consider when planning management and conservation strategies. In mainland Europe, grey squirrels introduced to Italy threaten the survival of the whole continental red squirrel population, but no extensive surveys for SQPV presence have been carried out in the region. We therefore investigated SQPV infection in north Italian grey squirrel populations through a combination of serological and molecular methods. Firstly, we analysed sera from 285 individuals through an enzyme-linked immunosorbent assay (ELISA) to detect antibodies against SQPV. Secondly, a PCR designed to amplify a segment of the G8R SQPV gene was carried out on DNA extracted from swabs and skin tissue samples from a second set of 66 grey squirrels. ELISA tests identified four reactors (1.4%), but the subsequent PCR survey did not detect any SQPV DNA. Based on the low prevalence observed and on PCR results, we believe that the four suspected positives were the result of an ELISA cross-reaction following exposure to another pox virus. Considering sample size and performances of the two methods, confidence of freedom from SQPV resulted above 99.9%. However, because of the severe impact of SQPV on red squirrels, we recommend the implementation of a passive surveillance plan for the early detection of an SQPV emergence in continental Europe.

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“…Deeper, dynamic insights into disease-host interactions and the spread of epidemics for better incursion preparedness could be gained through epidemiological simulation models (Ostfeld et al 2005;Riley 2007;Milne et al 2008). Our data on patch and matrix connectivity could be integrated to realistically constrain pathways of spread or the extent of epidemiologically connected zones (Cowled & Garner 2008;Rees et al 2013, Macpherson et al 2016. Epidemiological models could also elucidate the relationship between connectivity and disease transmission or persistence in wildlife hosts.…”

Section: Implications For Disease Managementmentioning

confidence: 99%

“…We focused on understanding habitat connectivity for the wildlife host, as such knowledge gaps have impeded epidemiological models and disease management in Australia and elsewhere (Ostfeld et al 2005;Cowled & Garner 2008;Rees et al 2013;Macpherson et al 2016). …”

Section: Introductionmentioning

confidence: 99%

Modelling seasonal habitat suitability and connectivity for feral pigs in northern Australia: towards risk-based management of infectious animal diseases with wildlife hosts

Froese¹

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Infectious animal diseases are a major biosecurity threat in an increasingly connected world.Wildlife hosts are a well-recognized risk factor for disease introduction, establishment and spread.Northern Australia is vulnerable to disease incursions from neighbouring countries, and widespread invasive feral pigs (Sus scrofa) can seriously complicate post-border disease management. The aim of this thesis was to generate new regional-scale spatial knowledge of feral pig populations in northern Australia to inform risk-based management of directly transmitted infectious animal diseases for which feral pigs are a host.Due to environmental variability and empirical knowledge gaps across this vast region, I adopted a resource-based modelling approach, based on expert knowledge but rooted in landscape ecological theory, to answer three research questions at multiple levels of biological organisation.Specifically, I conceptualized feral pigs in northern Australia as a metapopulation and the landscape as displaying a patch-corridor-matrix structure. At the level of individual feral pig breeding herds, I explored the selection of supplementary and complementary resources within home ranges. At the level of local subpopulations, consisting of several herds with adjacent or overlapping home ranges, I used a habitat suitability modelling approach to investigate the distribution of potential patches of breeding habitat emerging from the interactions between resources and home range movements. At the metapopulation level, I examined potential dispersal pathways between many such patches using a habitat connectivity modelling approach. As feral pig movements and distributional patterns vary with conditions, I applied models to two seasonal scenarios (wet and dry) corresponding to northern Australia's annual rainfall cycle.This thesis contributed methodological advances and new ecological insights. I developed a novel combined methodology, spatial pattern suitability analysis, for capturing feral pigs' resourceseeking home range movements based on expert-elicited response-to-pattern curves and spatial moving window analysis. Based on landscape ecological principles, this methodology improves the application of resource-based Bayesian networks models to mobile animals. I found that habitat suitability for persistent feral pig breeding in northern Australia is dependent on spatial interactions between four key habitat requirements: water and food resources as well as protection from heat and from disturbance. Through scenario analysis and empirical validation I showed that habitat suitability at the regional scale is most reliably modelled as a function of distance to supplementary and complementary resource patches. When applied to a wet season and a dry season scenario, mapped model results indicated that the spatial distribution of feral pig habitat patches varied markedly. Importantly, empirically validated findings suggest that dry season conditions restrict overall habitat suitability for feral pig breeding in northern...

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Incorporating habitat distribution in wildlife disease models: conservation implications for the threat of squirrelpox on the Isle of Arran

Cited by 10 publications

References 51 publications

An assessment of conflict areas between alien and native species richness of terrestrial vertebrates on a macro‐ecological scale in a Mediterranean hotspot

An assessment of conflict areas between alien and native species richness of terrestrial vertebrates on a macro‐ecological scale in a Mediterranean hotspot

Disease, invasions and conservation: no evidence of squirrelpox virus in grey squirrels introduced to Italy

Modelling seasonal habitat suitability and connectivity for feral pigs in northern Australia: towards risk-based management of infectious animal diseases with wildlife hosts

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