Dynamic species distribution models from categorical survey data

Mieszkowska, Nova; Milligan, G. C.; Burrows, Michael T.; Freckleton, Robert P.; Spencer, Matthew

doi:10.1111/1365-2656.12100

Cited by 34 publications

(36 citation statements)

References 42 publications

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“…Our synthesis can lead to joint inference on spatiotemporal data, yielding parameterized population models that can be used for forecasts outside the range of observed scenarios. While sharing with other recent work (Mieszkowska et al 2013) the motivation of confronting spatiotemporal dynamics with data empirically, our model's mechanistic component is greater and more expandable. Further, rather than requiring geo-referenced data on growth (in the form of spatial layers for survival and fecundity, e.g., Aldridge and Boyce [2008], DeCesare et al [2014]), we fit to nonspatial population time series, such as those available from long-term monitoring studies (e.g., Saether 1997, Gaillard et al 1998, Brook et al 2000, Parmesan and Yohe 2003, Stuart et al 2004, Strayer et al 2006.…”

Section: Discussionmentioning

confidence: 78%

“…While many ecological questions on species distribution are motivated by population dynamics (e.g., viability of fragmented populations, spatial management of pests, species range shifts), an explicit connection between observed distributions and dynamics is rarely pursued (Railsback et al 2003, Guisan and Thuiller 2005, Zurell et al 2009, Gaillard et al 2010, McLoughlin et al 2010, Mieszkowska et al 2013. This, and other broadly recognized issues with SDMs have thus far been investigated with literature reviews, or comparative studies between existing frameworks that, in their majority, make the assumption that populations are at a state of equilibrium (Guisan and Zimmermann 2000, Arau´jo and Guisan 2006, Randin et al 2006, Elith and Graham 2009, Elith and Leathwick 2009, Zurell et al 2009, Hoffman et al 2010, Matthiopoulos and Aarts 2010.…”

Section: Discussionmentioning

confidence: 99%

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Establishing the link between habitat selection and animal population dynamics

Matthiopoulos

Fieberg

Aarts³

et al. 2015

Ecological Monographs

128

200

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Abstract. Although classical ecological theory (e.g., on ideal free consumers) recognizes the potential effect of population density on the spatial distribution of animals, empirical species distribution models assume that species-habitat relationships remain unchanged across a range of population sizes. Conversely, even though ecological models and experiments have demonstrated the importance of spatial heterogeneity for the rate of population change, we still have no practical method for making the connection between the makeup of real environments, the expected distribution and fitness of their occupants, and the long-term implications of fitness for population growth. Here, we synthesize several conceptual advances into a mathematical framework using a measure of fitness to link habitat availability/selection to (density-dependent) population growth in mobile animal species. A key feature of this approach is that it distinguishes between apparent habitat suitability and the true, underlying contribution of a habitat to fitness, allowing the statistical coefficients of both to be estimated from multiple observation instances of the species in different environments and stages of numerical growth. Hence, it leverages data from both historical population time series and snapshots of species distribution to predict population performance under environmental change. We propose this framework as a foundation for building more realistic connections between a population's use of space and its subsequent dynamics (and hence a contribution to the ongoing efforts to estimate a species' critical habitat and fundamental niche). We therefore detail its associated definitions and simplifying assumptions, because they point to the framework's future extensions. We show how the model can be fit to data on species distributions and population dynamics, using standard statistical methods, and we illustrate its application with an individual-based simulation. When contrasted with nonspatial population models, our approach is better at fitting and predicting population growth rates and carrying capacities. Our approach can be generalized to include a diverse range of biological considerations. We discuss these possible extensions and applications to real data.

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Section: Discussionmentioning

confidence: 78%

Section: Discussionmentioning

confidence: 99%

Establishing the link between habitat selection and animal population dynamics

Matthiopoulos

Fieberg

Aarts³

et al. 2015

Ecological Monographs

128

200

View full text Add to dashboard Cite

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“…It is difficult to say whether this increase and new colonization is a direct result of warming temperatures, but the pattern is certainly in line with observations for a range of other intertidal and fish species in the region (e.g., Mieszkowska et al. 2006, 2013; Hiddink and ter Hofstede 2008; Firth et al. 2009; Hawkins et al.…”

Section: Discussionmentioning

confidence: 99%

“…2009, 2013a; Mieszkowska et al. 2013). For example, the extremely cold winter of 1962/1963 had a dramatic effect on marine organisms in Britain with widespread population decreases and localized extinctions (Crisp 1964).…”

Section: Introductionmentioning

confidence: 99%

Historical comparisons reveal multiple drivers of decadal change of an ecosystem engineer at the range edge

Firth

Mieszkowska

Grant

et al. 2015

Ecology and Evolution

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Biogenic reefs are important for habitat provision and coastal protection. Long-term datasets on the distribution and abundance of Sabellaria alveolata (L.) are available from Britain. The aim of this study was to combine historical records and contemporary data to (1) describe spatiotemporal variation in winter temperatures, (2) document short-term and long-term changes in the distribution and abundance of S. alveolata and discuss these changes in relation to extreme weather events and recent warming, and (3) assess the potential for artificial coastal defense structures to function as habitat for S. alveolata. A semi-quantitative abundance scale (ACFOR) was used to compare broadscale, long-term and interannual abundance of S. alveolata near its range edge in NW Britain. S. alveolata disappeared from the North Wales and Wirral coastlines where it had been abundant prior to the cold winter of 1962/1963. Population declines were also observed following the recent cold winters of 2009/2010 and 2010/2011. Extensive surveys in 2004 and 2012 revealed that S. alveolata had recolonized locations from which it had previously disappeared. Furthermore, it had increased in abundance at many locations, possibly in response to recent warming. S. alveolata was recorded on the majority of artificial coastal defense structures surveyed, suggesting that the proliferation of artificial coastal defense structures along this stretch of coastline may have enabled S. alveolata to spread across stretches of unsuitable natural habitat. Long-term and broadscale contextual monitoring is essential for monitoring responses of organisms to climate change. Historical data and gray literature can be invaluable sources of information. Our results support the theory that Lusitanian species are responding positively to climate warming but also that short-term extreme weather events can have potentially devastating widespread and lasting effects on organisms. Furthermore, the proliferation of coastal defense structures has implications for phylogeography, population genetics, and connectivity of coastal populations.

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“…Although this study examines average climatic conditions, extreme events may be driving some are temporally biased and the median difference between observations is 11 years, which means we cannot replicate analyses such as those relying on year on-year transitional models (Mieszkowska et al 2013). Methodological advances are required in order to extract the full potential from these data.…”

Section: Methodsmentioning

confidence: 99%

Large brown seaweeds of the British Isles: Evidence of changes in abundance over four decades

Yesson

Bush

Davies

et al. 2015

Estuarine, Coastal and Shelf Science

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The large brown seaweeds (macroalgae) are keystone species in intertidal and shallow subtidal marine ecosystems and are harvested for food and other products. Recently, there have been sporadic, often anecdotal, reports of local abundance declines around the British Isles, but regional surveys have rarely revisited sites to determine possible changes. An assessment of changes in the abundance of large brown seaweeds around the British Isles using historical survey data, and determination of whether any changes were linked with climate change was undertaken. Data were analysed from multiple surveys for 14 habitat-forming and commercially important species of Phaeophyceae, covering orders Laminariales, Fucales and Tilopteridales. Changes in abundance were assessed for sites over the period 1974-2010. Trends in distribution were compared to summer and winter sea surface temperatures (SST). Results revealed regional patterns of both increase and decrease in abundance for multiple species, with significant declines in the south for kelp species and increases in northern and central areas for some kelp and wracks. Abundance patterns of 10 of the 14 species showed a significant association with SSTs, but there was a mixture of positive and negative responses. This is the first UK-wide observation of declining abundance of large brown seaweeds. Historical surveys provide useful data to examine trends in abundance, but the ad hoc nature of these studies limit the conclusions that can be drawn. Although the British Isles remains a stronghold for large brown algae, it is imperative that systematic surveys are undertaken to monitor changes.

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Dynamic species distribution models from categorical survey data

Cited by 34 publications

References 42 publications

Establishing the link between habitat selection and animal population dynamics

Establishing the link between habitat selection and animal population dynamics

Historical comparisons reveal multiple drivers of decadal change of an ecosystem engineer at the range edge

Large brown seaweeds of the British Isles: Evidence of changes in abundance over four decades

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