Niches, models, and climate change: Assessing the assumptions and uncertainties

Wiens, John A.; Stralberg, Diana; Jongsomjit, Dennis; Howell, Christine A.; Snyder, Mark A.

doi:10.1073/pnas.0901639106

Cited by 769 publications

(678 citation statements)

References 72 publications

(67 reference statements)

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“…Understanding and predicting these responses is one of the most pressing issues currently facing humanity. For this reason, in the past quarter century, there has been considerable interest in developing ways to understand how the natural world will be affected by environmental change (Ives 1995;Bossdorf et al 2008;Gilbert and Epel 2009;Wiens et al 2009;Lavergne et al 2010;Dawson et al 2011;Hoffmann and Sgrò 2011). We introduce a new general approach combining insights from structured population modeling and evolutionary genetics that allows us to examine how adaptive evolution and plasticity contribute to the way that populations-and, consequently, the ecosystems in which they are embedded-respond to environmental change.…”

Section: Introductionmentioning

confidence: 99%

Modeling Adaptive and Nonadaptive Responses of Populations to Environmental Change

Coulson

Kendall

Barthold

et al. 2017

The American Naturalist

113

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General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. abstract: Understanding how the natural world will be impacted by environmental change over the coming decades is one of the most pressing challenges facing humanity. Addressing this challenge is difficult because environmental change can generate both populationlevel plastic and evolutionary responses, with plastic responses being either adaptive or nonadaptive. We develop an approach that links quantitative genetic theory with data-driven structured models to allow prediction of population responses to environmental change via plasticity and adaptive evolution. After introducing general new theory, we construct a number of example models to demonstrate that evolutionary responses to environmental change over the short-term will be considerably slower than plastic responses and that the rate of adaptive evolution to a new environment depends on whether plastic responses are adaptive or nonadaptive. Parameterization of the models we develop requires information on genetic and phenotypic variation and demography that will not always be available, meaning that simpler models will often be required to predict responses to environmental change. We consequently develop a method to examine whether the full machinery of the evolutionarily explicit models we develop will be needed to predict responses to environmental change or whether simpler nonevolutionary models that are now widely constructed may be sufficient.

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Section: Introductionmentioning

confidence: 99%

Modeling Adaptive and Nonadaptive Responses of Populations to Environmental Change

Coulson

Kendall

Barthold

et al. 2017

The American Naturalist

113

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“…However, the future conditions which were used as inputs into our distribution models do not represent novel conditions for the tidal marsh bird species we studied. Species distribution models also rely upon other assumptions that are frequently violated (Wiens et al 2009). For example, the tolerances of species are assumed to be represented by their spatial distributions and these tolerances are also assumed to remain unchanged into the future.…”

Section: Discussionmentioning

confidence: 99%

Modeling climate change impacts on tidal marsh birds: Restoration and conservation planning in the face of uncertainty

et al. 2013

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Abstract. The large uncertainty surrounding the future effects of sea-level rise and other aspects of climate change on tidal marsh ecosystems exacerbates the difficulty in planning effective conservation and restoration actions. We addressed these difficulties in the context of large-scale wetland restoration activities underway in the San Francisco Estuary (Suisun, San Pablo and San Francisco Bays). We used a boosted regression tree approach to project the future distribution and abundance of five marsh bird species (through 2110) in response to changes in habitat availability and suitability as a result of projected sea-level rise, salinity, and sediment availability in the Estuary. To bracket the uncertainty, we considered four future scenarios based on two sediment availability scenarios (high or low), which varied regionally, and two rates of sea-level rise (0.52 or 1.65 m/100 yr). We evaluated three approaches for using model results to inform the selection of potential restoration projects: (1) Use current conditions only to prioritize restoration. (2) Use a single future scenario (among the four referred to above) in combination with current conditions to select priority restoration projects. (3) Combine current conditions with all four future scenarios, while incorporating uncertainty among future scenarios into the selection of restoration projects. We found that simply using current conditions resulted in the poorest performing restoration projects selected in terms of providing habitat for tidal marsh birds in light of possible future scenarios. The most robust method for selecting restoration projects, the ''combined'' strategy, used projections from all future scenarios with a discounting of areas with high levels of variability among future scenarios. We show that uncertainty about future conditions can be incorporated in site prioritization algorithms and should motivate the selection of adaptation measures that are robust to uncertain future conditions. These results and data have been made available via an interactive decision support tool at www.prbo.org/sfbayslr.

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“…For modelling, the potential niche or habitat idoneity is understood as the n-dimensional area where the species encounters the conditions that allow its survival and reproduction (Wiens et al 2009). A total, 19 variables correspond to bioclimatic parameters associated with the baseline annual temperature and precipitation characteristics (Hijmans et al 2005) were selected.…”

Section: Selection and Preparation Of Modelling Variablesmentioning

confidence: 99%

Orchids distribution and bioclimatic niches as a strategy to climate change in areas of tropical dry forest in Colombia

Reina-Rodriguez

Mejía²,

Llanos³

et al. 2017

Lankesteriana

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AbstrACt. Climate change projections in Colombia predict an average increase in temperature of 2.6°C and in precipitation of 20% by the end of the century. These changes would directly affect the tropical dry forest (TDF) and its biodiversity. Epiphytic orchids, more exposed to the atmosphere than the terrestrial biota, remain dependent on climatic variables, making them particularly susceptible to climate change. We studied the spatial and temporal changes of a focal group of 12 orchid species typical of the TDF in Colombia, and the future conservation areas to this ecosystem. The algorithm used by MaxEnt was employed for modelling. A total of 439 records: direct observations (276); herbaria collections (159) Other variables analysed, such as distance thresholds of pollinators (Euglossini), availability of phorophytes, and distances to TDF cover and protected areas, all suggest an improving connectivity between the lowland and mid-mountain areas. Consequently, bioclimatic niches (BN) are proposed as a new landscape management unit. Throughout the country, 69 of these BN were located as an adaptation-conservation strategy against climate change in the TDF in Colombia.resumen. Las proyecciones del cambio climático en Colombia, indican en promedio un incremento en 2.6°C de temperatura y 20% de la precipitación para el fin del siglo. Estos cambios afectarán directamente al bosque seco tropical (Bs-T) y su biodiversidad. Las orquídeas epífitas, más expuestas a la atmósfera que la biota terrestre mantienen dependencia de variables ligadas al clima. Esta condición las hace particularmente susceptibles al cambio climático. Nosotros estudiamos los cambios espacio-temporales de un grupo focal de 12 especies de orquídeas típicas del Bs-T en Colombia y las futuras áreas de conservación de este ecosistema. El algoritmo usado por MaxEnt fue empleado para el modelamiento. Un total de 439 registros: observaciones directas (276); registros de herbario (159) y fuentes bibliográficas (4), colectadas desde septiembre de 2009 hasta abril 2015 fueron consideradas para entrenar el modelo. El nicho potencial actual fue comparado con el escenario de emisiones de cambio climático SRES 8.5 para dos periodos: 2020-2049 (2030) y 2040-2069 (2050). Los resultados indican un desplazamiento altitudinal respecto al presente, condicionado por variables como: temperatura, accesibilidad, y precipitación. Las áreas de montaña media (1300-1700 m) incrementarán su idoneidad en los modelos de nicho potencial futuro (2030 y 2050) en detrimento de las tierras bajas (0-1000 m). Otras variables analizadas como umbrales de distancia en polinizadores (Euglossini), disponibilidad de forófitos, distancias a coberturas de Bs-T y áreas protegidas, sugieren mejorar la conectividad entre tierras bajas y áreas de montaña media. En consecuencia, los nichos bioclimáticos (BN) son propuestos como nueva unidad 18 LANKESTERIANA de manejo del paisaje. En todo el país, 69 de ellos fueron localizados como estrategia de adaptación-conservación frente al cambio climático ...

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Niches, models, and climate change: Assessing the assumptions and uncertainties

Cited by 769 publications

References 72 publications

Modeling Adaptive and Nonadaptive Responses of Populations to Environmental Change

Modeling Adaptive and Nonadaptive Responses of Populations to Environmental Change

Modeling climate change impacts on tidal marsh birds: Restoration and conservation planning in the face of uncertainty

Orchids distribution and bioclimatic niches as a strategy to climate change in areas of tropical dry forest in Colombia

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