Confronting species distribution model predictions with species functional traits

Wittmann, Marion E.; Barnes, Matthew A.; Jerde, Christopher L.; Jones, Lisa; Lodge, David M.

doi:10.1002/ece3.1898

Cited by 47 publications

(64 citation statements)

References 39 publications

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“…However, heterogeneous change in climatic variables related to temperature and precipitation may cause some species to move in counterintuitive directions to track favorable climate (Crimmins, Dobrowski, Greenberg, Abatzoglou, & Mynsberge, ; Tingley et al., ; Wolf, Zimmerman, Anderegg, Busby, & Christensen, ). Species’ traits may be stronger predictors of range shifts when investigated in the context of niche tracking and environmental matching (Sol et al., ; Wittmann, Barnes, Jerde, Jones, & Lodge, ; Wogan, ). For example, temperature and water flow preference of invertebrates in New South Wales explained whether range shifts occurred at warm vs. wet range edges (Chessman, ).…”

Section: Discussionmentioning

confidence: 99%

Species’ traits as predictors of range shifts under contemporary climate change: A review and meta‐analysis

MacLean

Beissinger

2017

Global Change Biology

259

262

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A growing body of literature seeks to explain variation in range shifts using species' ecological and life-history traits, with expectations that shifts should be greater in species with greater dispersal ability, reproductive potential, and ecological generalization. Despite strong theoretical support for species' traits as predictors of range shifts, empirical evidence from contemporary range shift studies remains limited in extent and consensus. We conducted the first comprehensive review of species' traits as predictors of range shifts, collecting results from 51 studies across multiple taxa encompassing over 11,000 species' responses for 54 assemblages of taxonomically related species occurring together in space. We used studies of assemblages that directly compared geographic distributions sampled in the 20th century prior to climate change with resurveys of distributions after contemporary climate change and then tested whether species traits accounted for heterogeneity in range shifts. We performed a formal meta-analysis on study-level effects of body size, fecundity, diet breadth, habitat breadth, and historic range limit as predictors of range shifts for a subset of 21 studies of 26 assemblages with sufficient data. Range shifts were consistent with predictions based on habitat breadth and historic range limit. However, body size, fecundity, and diet breadth showed no significant effect on range shifts across studies, and multiple studies reported significant relationships that contradicted predictions. Current understanding of species' traits as predictors of range shifts is limited, and standardized study is needed for traits to be valid indicators of vulnerability in assessments of climate change impacts.

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Section: Discussionmentioning

confidence: 99%

Species’ traits as predictors of range shifts under contemporary climate change: A review and meta‐analysis

MacLean

Beissinger

2017

Global Change Biology

259

262

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“…; Wittmann et. al ), or assuming that dispersal is restricted, to either local extinction or local persistence through phenotypic plasticity or micro‐evolutionary adaptation (Bellard et al. ).…”

Section: Introductionmentioning

confidence: 99%

Phenotypic plasticity in life‐history traits of Daphnia galeata in response to temperature – a comparison across clonal lineages separated in time

Henning-Lucass

Cordellier

Streit

et al. 2016

Ecology and Evolution

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Climatic changes are projected to result in rapid adaptive events with considerable phenotypic shifts. In order to reconstruct the impact of increased mean water temperatures during past decades and to reveal possible thermal micro‐evolution, we applied a resurrection ecology approach using dormant eggs of the freshwater keystone species Daphnia galeata. To this end, we compared the adaptive response of D. galeata clones from Lake Constance of two different time periods, 1965–1974 (“historical”) versus 2000–2009 (“recent”), to experimentally increased temperature regimes. In order to distinguish between genetic versus environmentally induced effects, we performed a common garden experiment in a flow‐through system and measured variation in life‐history traits. Experimental thermal regimes were chosen according to natural temperature conditions during the reproductive period of D. galeata in Central European lakes, with one additional temperature regime exceeding the currently observable maximum (+2°C). Increased water temperatures were shown to significantly affect measured life‐history traits, and significant “temperature × clonal age” interactions were revealed. Compared to historical clones, recent clonal lineages exhibited a shorter time to first reproduction and a higher survival rate, which may suggest temperature‐driven micro‐evolution over time but does not allow an explicit conclusion on the adaptive nature of such responses.

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“…Whether SDM output is interpreted as a probability of occurrence or an index thereof, it describes only one dimension of potential response to environmental change. However, recent work demonstrates predictions from SDMs correlate with population‐level or physiological traits that directly relate to species’ persistence and roles within their communities (Michel et al., ; Wittmann et al., ). Hence, expanding the remit of ‘species’ distribution modeling to include functional and physiological traits opens promising avenues for forecasting responses to global change (Michel et al., ).…”

Section: Discussionmentioning

confidence: 99%

“…In this situation, the persistence of locally adapted populations could be threatened if they are unable to respond in situ to changing conditions through rapid selection (Shaw & Etterson, ), phenotypic plasticity (Jump & Peñuelas ), or dispersal. Thus, incorporating intraspecific phenotypic variation in climate vulnerability analyses is an important challenge in predicting population responses to global change (Wittmann, Barnes, Jerde, Jones & Lodge, ).…”

Section: Introductionmentioning

confidence: 99%

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Phenotypic distribution models corroborate species distribution models: A shift in the role and prevalence of a dominant prairie grass in response to climate change

Smith

Alsdurf

Knapp

et al. 2017

Global Change Biology

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Phenotypic distribution within species can vary widely across environmental gradients but forecasts of species' responses to environmental change often assume species respond homogenously across their ranges. We compared predictions from species and phenotype distribution models under future climate scenarios for Andropogon gerardii, a widely distributed, dominant grass found throughout the central United States. Phenotype data on aboveground biomass, height, leaf width, and chlorophyll content were obtained from 33 populations spanning a ~1000 km gradient that encompassed the majority of the species' environmental range. Species and phenotype distribution models were trained using current climate conditions and projected to future climate scenarios. We used permutation procedures to infer the most important variable for each model. The species-level response to climate was most sensitive to maximum temperature of the hottest month, but phenotypic variables were most sensitive to mean annual precipitation. The phenotype distribution models predict that A. gerardii could be largely functionally eliminated from where this species currently dominates, with biomass and height declining by up to ~60% and leaf width by ~20%. By the 2070s, the core area of highest suitability for A. gerardii is projected to shift up to ~700 km northeastward. Further, short-statured phenotypes found in the present-day short grass prairies on the western periphery of the species' range will become favored in the current core ~800 km eastward of their current location. Combined, species and phenotype models predict this currently dominant prairie grass will decline in prevalence and stature. Thus, sourcing plant material for grassland restoration and forage should consider changes in the phenotype that will be favored under future climate conditions. Phenotype distribution models account for the role of intraspecific variation in determining responses to anticipated climate change and thereby complement predictions from species distributions models in guiding climate adaptation strategies.

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Confronting species distribution model predictions with species functional traits

Cited by 47 publications

References 39 publications

Species’ traits as predictors of range shifts under contemporary climate change: A review and meta‐analysis

Species’ traits as predictors of range shifts under contemporary climate change: A review and meta‐analysis

Phenotypic plasticity in life‐history traits of Daphnia galeata in response to temperature – a comparison across clonal lineages separated in time

Phenotypic distribution models corroborate species distribution models: A shift in the role and prevalence of a dominant prairie grass in response to climate change

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