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- Publisher
- Wiley
- Copyright
- Copyright © 2006 Wiley Subscription Services, Inc., A Wiley Company
- ISSN
- 0305-0270
- eISSN
- 1365-2699
- DOI
- 10.1111/j.1365-2699.2006.01466.x
- Publisher site
- See Article on Publisher Site
Abstract
Aim To assess the geographical transferability of niche‐based species distribution models fitted with two modelling techniques. Location Two distinct geographical study areas in Switzerland and Austria, in the subalpine and alpine belts. Methods Generalized linear and generalized additive models (GLM and GAM) with a binomial probability distribution and a logit link were fitted for 54 plant species, based on topoclimatic predictor variables. These models were then evaluated quantitatively and used for spatially explicit predictions within (internal evaluation and prediction) and between (external evaluation and prediction) the two regions. Comparisons of evaluations and spatial predictions between regions and models were conducted in order to test if species and methods meet the criteria of full transferability. By full transferability, we mean that: (1) the internal evaluation of models fitted in region A and B must be similar; (2) a model fitted in region A must at least retain a comparable external evaluation when projected into region B, and vice‐versa; and (3) internal and external spatial predictions have to match within both regions. Results The measures of model fit are, on average, 24% higher for GAMs than for GLMs in both regions. However, the differences between internal and external evaluations (AUC coefficient) are also higher for GAMs than for GLMs (a difference of 30% for models fitted in Switzerland and 54% for models fitted in Austria). Transferability, as measured with the AUC evaluation, fails for 68% of the species in Switzerland and 55% in Austria for GLMs (respectively for 67% and 53% of the species for GAMs). For both GAMs and GLMs, the agreement between internal and external predictions is rather weak on average (Kulczynski's coefficient in the range 0.3–0.4), but varies widely among individual species. The dominant pattern is an asymmetrical transferability between the two study regions (a mean decrease of 20% for the AUC coefficient when the models are transferred from Switzerland and 13% when they are transferred from Austria). Main conclusions The large inter‐specific variability observed among the 54 study species underlines the need to consider more than a few species to test properly the transferability of species distribution models. The pronounced asymmetry in transferability between the two study regions may be due to peculiarities of these regions, such as differences in the ranges of environmental predictors or the varied impact of land‐use history, or to species‐specific reasons like differential phenotypic plasticity, existence of ecotypes or varied dependence on biotic interactions that are not properly incorporated into niche‐based models. The lower variation between internal and external evaluation of GLMs compared to GAMs further suggests that overfitting may reduce transferability. Overall, a limited geographical transferability calls for caution when projecting niche‐based models for assessing the fate of species in future environments.
Journal
Journal of Biogeography – Wiley
Published: Oct 1, 2006
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References
-
Maximum likelihood identification of Gaussian autoregressive moving average modelsAkaike, Akaike
-
Validation of species–climate impact models under climate changeAraújo, Araújo; Pearson, Pearson; Thuiller, Thuiller; Erhard, Erhard
-
Reducing uncertainty in projections of extinction risk from climate changeAraújo, Araújo; Whittaker, Whittaker; Ladle, Ladle; Erhard, Erhard
-
Climate warming and the decline of amphibians and reptiles in EuropeAraújo, Araújo; Thuiller, Thuiller; Pearson, Pearson
-
Searching for a model for use in vegetation analysisAustin, Austin
-
Continuum concept, ordination methods, and niche theoryAustin, Austin
-
Spatial prediction of species distribution: an interface between ecological theory and statistical modellingAustin, Austin
-
A new model for the continuum conceptAustin, Austin; Smith, Smith
-
New approaches to direct gradient analysis using environmental scalars and statistical curve‐fitting proceduresAustin, Austin; Cunningham, Cunningham; Fleming, Fleming
-
Assessing effects of forecasted climate change on the diversity and distribution of European higher plants for 2050Bakkenes, Bakkenes; Alkemade, Alkemade; Ihle, Ihle; Leemans, Leemans; Latour, Latour
-
Evaluating resource selection functionsBoyce, Boyce; Vernier, Vernier; Nielsen, Nielsen; Schmiegelow, Schmiegelow
-
Spatial variation in abundanceBrown, Brown; Mehlman, Mehlman; Stevens, Stevens
-
The use of GIS to identify sites that will become suitable for a rare orchid, Himantoglossum hircinum L., in future changed climateCarey, Carey; Brown, Brown
-
Soil nutritional factors improve plant species distribution models: an illustration with Acer campestre (L.) in FranceCoudun, Coudun; Gegout, Gegout
-
Sources and sinks in population biologyDias, Dias
-
Habitat distribution models, spatial autocorrelation, functional traits and dispersal capacity of alpine plant speciesDirnböck, Dirnböck; Dullinger, Dullinger
-
A regional impact assessment of climate and land‐use change on alpine vegetationDirnböck, Dirnböck; Dullinger, Dullinger; Grabherr, Grabherr
-
An improved approach for predicting the distribution of rare and endangered species from occurrence and pseudo‐absence dataEngler, Engler; Guisan, Guisan; Rechsteiner, Rechsteiner
-
A review of methods for the assessment of prediction errors in conservation presence–absence modelsFielding, Fielding; Bell, Bell
-
Testing the generality of bird‐habitat modelsFielding, Fielding; Haworth, Haworth
-
Predictive vegetation mapping: geographic modelling of biospatial patterns in relation to environmental gradientsFranklin, Franklin
-
Transferability of habitat suitability criteria for fishes in warmwater streamsFreeman, Freeman; Bowen, Bowen; Crance, Crance
-
Transferability of habitat suitability curves for a benthic minnow, Rhinichthys cataractaeGlozier, Glozier; Culp, Culp; Scrimgeour, Scrimgeour
-
Preliminary distributional analysis of US endangered bird speciesGodown, Godown; Peterson, Peterson
-
Prediction of vegetation patterns at the limits of plant life: a new view of the alpine‐nival ecotoneGottfried, Gottfried; Pauli, Pauli; Grabherr, Grabherr
-
Allee effects limit population viability of an annual plantGroom, Groom
-
Equilibrium modeling of alpine plant distribution: how far can we go?Guisan, Guisan; Theurillat, Theurillat
-
Assessing alpine plant vulnerability to climate change: a modeling perspectiveGuisan, Guisan; Theurillat, Theurillat
-
Predicting species distribution: offering more than simple habitat models?Guisan, Guisan; Thuiller, Thuiller
-
Predictive habitat distribution models in ecologyGuisan, Guisan; Zimmermann, Zimmermann
-
Predicting the potential distribution of plant species in an Alpine environmentGuisan, Guisan; Theurillat, Theurillat; Kienast, Kienast
-
Generalized linear and generalized additive models in studies of species distributions: setting the sceneGuisan, Guisan; Edwards, Edwards; Hastie, Hastie
-
Spatially distributed hydrotope‐based modelling of evapotranspiration and runoff in mountainous basinsGurtz, Gurtz; Baltensweiler, Baltensweiler; Lang, Lang
-
A comparative study in modelling runoff and its components in two mountainous catchmentsGurtz, Gurtz; Zappa, Zappa; Jasper, Jasper; Lang, Lang; Verbunt, Verbunt; Badoux, Badoux; Vitvar, Vitvar
-
Bioclimate envelope models: what they detect and what they hideHampe, Hampe
-
Generalized additive modelsHastie, Hastie; Tibshirani, Tibshirani
-
Extending Ellenberg's indicator values to a new area: an algorithmic approachHill, Hill; Roy, Roy; Mountford, Mountford; Bunce, Bunce
-
Predictive value of statistical modelsVan Houwelingen, Van Houwelingen; Le Cessie, Le Cessie
-
Plant species response to climate change – implications for the conservation of European birdsHuntley, Huntley
-
Temperature and the biogeographical distributions of speciesJeffree, Jeffree; Jeffree, Jeffree
-
Local adaptation enhances performance of common plant speciesJoshi, Joshi; Schmid, Schmid; Caldeira, Caldeira; Dimitrakopoulos, Dimitrakopoulos; Good, Good; Harris, Harris; Hector, Hector; Huss‐Danell, Huss‐Danell; Jumpponen, Jumpponen; Minns, Minns; Mulder, Mulder; Pereira, Pereira; Prinz, Prinz; Scherer‐Lorenzen, Scherer‐Lorenzen; Siamantziouras, Siamantziouras; Terry, Terry; Troumbis, Troumbis; Lawton, Lawton
-
Allee effects, invasion pinning, and species’ bordersKeitt, Keitt; Lewis, Lewis; Holt, Holt
-
Validation of plant functional types across two contrasting landscapesKleyer, Kleyer
-
Modelling topographic variation in solar radiation in a GIS environmentKumar, Kumar; Skidmore, Skidmore; Knowles, Knowles
-
Measurement of observer agreement for categorical dataLandis, Landis; Koch, Koch
-
Regression models for spatial prediction: their role for biodiversity and conservationLehmann, Lehmann; Overton, Overton; Austin, Austin
-
Improving generalized regression analysis for spatial predictions of forest communitiesMaggini, Maggini; Lehmann, Lehmann; Zimmermann, Zimmermann; Guisan, Guisan
-
Transferability of habitat suitability criteria of juvenile Atlantic salmon ( Salmo salar )Mäki‐Petäys, Mäki‐Petäys; Huusko, Huusko; Erkinaro, Erkinaro; Muotka, Muotka
-
The effects of species’ range sizes on the accuracy of distribution models: ecological phenomenon or statistical artefact?McPherson, McPherson; Jetz, Jetz; Rogers, Rogers
-
Predicting rare plant‐distribution patterns in the southern Appalachians of the southeastern USAMiller, Miller
-
Comparing five modelling techniques for predicting forest characteristicsMoisen, Moisen; Frescino, Frescino
-
Coexistence in metacommunities: the regional similarity hypothesisMouquet, Mouquet; Loreau, Loreau
-
Community patterns in source–sink metacommunitiesMouquet, Mouquet; Loreau, Loreau
-
The altitudinal gradient of vascular plant richness in Aurland, western NorwayOdland, Odland; Birks, Birks
-
A spatial habitat model for the marsh‐breeding red‐winged blackbird ( Agelaius phoeniceus L.) in coastal Lake Erie wetlandsOzesmi, Ozesmi; Mitsch, Mitsch
-
SPECIES: a spatial evaluation of climate impact on the envelope of speciesPearson, Pearson; Dawson, Dawson; Berry, Berry; Harrison, Harrison
-
Model‐based uncertainty in species range predictionPearson, Pearson; Thuiller, Thuiller; Araújo, Araújo; Martinez‐Meyer, Martinez‐Meyer; Brotons, Brotons; McClean, McClean; Miles, Miles; Segurado, Segurado; Dawson, Dawson; Lees, Lees
-
Geographic analysis of conservation priority: endemic birds and mammals in Veracruz, MexicoPeterson, Peterson; Egbert, Egbert; Sanchez‐Cordero, Sanchez‐Cordero; Price, Price
-
Future projections for Mexican faunas under global climate change scenariosPeterson, Peterson; Ortega‐Huerta, Ortega‐Huerta; Bartley, Bartley; Sanchez‐Cordero, Sanchez‐Cordero; Soberon, Soberon; Buddemeier, Buddemeier; Stockwell, Stockwell
-
Predicting the potential invasive distributions of four alien plant species in North AmericaPeterson, Peterson; Papes, Papes; Kluza, Kluza
-
Geographic variability of ecological niches of plant species: are competition and stress relevant?Prinzing, Prinzing; Durka, Durka; Klotz, Klotz; Brandl, Brandl
-
On the relationship between niche and distributionPulliam, Pulliam
-
Are habitat models transferable in space and time?Schröder, Schröder; Richter, Richter
-
Measuring the accuracy of diagnostic systemsSwets, Swets
-
Boreal forest futures – modeling the controls on tree species range limits and transient responses to climate changeSykes, Sykes; Prentice, Prentice
-
Application and testing of a procedure to evaluate transferability of habitat suitability criteriaThomas, Thomas; Bovee, Bovee
-
Ellenberg numbers revisitedThompson, Thompson; Hodgson, Hodgson; Grime, Grime; Rorison, Rorison; Band, Band; Spencer, Spencer
-
Patterns and uncertainties of species’ range shifts under climate changeThuiller, Thuiller
-
Biodiversity conservation – uncertainty in predictions of extinction riskThuiller, Thuiller; Araújo, Araújo; Pearson, Pearson; Whittaker, Whittaker; Brotons, Brotons; Lavorel, Lavorel
-
Climate change threats to plant diversity in EuropeThuiller, Thuiller; Lavorel, Lavorel; Araújo, Araújo; Sykes, Sykes; Prentice, Prentice
-
Current and potential ranges of three exotic goldenrods ( Solidago ) in EuropeWeber, Weber
-
Predictive mapping of alpine grasslands in Switzerland: species versus community approachZimmermann, Zimmermann; Kienast, Kienast
-
The relative role of species pools in determining plant species richness: an alternative explanation of species coexistenceZobel, Zobel
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