Forecasting range shifts of a cold‐adapted species under climate change: are genomic and ecological diversity within species crucial for future resilience?

Theodoridis, Spyros; Patsiou, Theofania; Randin, Christophe F.; Conti, Elena

doi:10.1111/ecog.03346

Cited by 33 publications

(27 citation statements)

References 99 publications

(181 reference statements)

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“…Although we do not have information on the genetic diversity of these species, the correlation between increased genetic diversity and increased range size allows us to hypothesize that these two circumpolar species may have increased genetic diversity. High levels of genetic diversity within a species have been correlated with wider ecological breadth, and consequently, these species are thought to be able to cope with a broader range of climatic changes (Theodoridis, Patsiou, Randin, & Conti, ). In spite of the fact that these species are predicted to maintain large geographic areas despite changing climate, it is notable that less than half of the current habitat for both species overlaps with predicted future habitat (Table ).…”

Section: Discussionmentioning

confidence: 99%

The future of cold‐adapted plants in changing climates: Micranthes (Saxifragaceae) as a case study

Stubbs

Soltis

Cellinese

2018

Ecology and Evolution

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Research has shown species undergoing range contractions and/or northward and higher elevational movements as a result of changing climates. Here, we evaluate how the distribution of a group of cold‐adapted plant species with similar evolutionary histories changes in response to warming climates. We selected 29 species of Micranthes (Saxifragaceae) representing the mountain and Arctic biomes of the Northern Hemisphere. For this analysis, 24,755 data points were input into ecological niche models to assess both present fundamental niches and predicted future ranges under climate change scenarios. Comparisons were made across the Northern Hemisphere between all cold‐adapted Micranthes, including Arctic species, montane species, and species defined as narrow endemics. Under future climate change models, 72% of the species would occupy smaller geographical areas than at present. This loss of habitat is most pronounced in Arctic species in general, but is also prevalent in species restricted to higher elevations in mountains. Additionally, narrowly endemic species restricted to high elevations were more susceptible to habitat loss than those species found at lower elevations. Using a large dataset and modeling habitat suitability at a global scale, our results empirically model the threats to cold‐adapted species as a result of warming climates. Although Arctic and alpine biomes share many underlying climate similarities, such as cold and short growing seasons, our results confirm that species in these climates have varied responses to climate change and that key abiotic variables differ between these two habitats.

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Section: Discussionmentioning

confidence: 99%

The future of cold‐adapted plants in changing climates: Micranthes (Saxifragaceae) as a case study

Stubbs

Soltis

Cellinese

2018

Ecology and Evolution

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“…Our sampling design aimed at representing most genetic and ecogeographic variation within P. farinosa (Albert et al, ; Gotelli & Stanton‐Geddes, ). For its European distribution, we used 57 populations reported previously (Theodoridis et al, , ) and selected one to three individuals per population based on the size of the available genomic data (i.e., maximizing the total number of sequencing reads per individual). For its Asian distribution, we sampled 14 populations for the first time (two individuals per population) across Mongolia.…”

Section: Methodsmentioning

confidence: 99%

“…We first calculated niche overlap between genetic groups using Schoener's D similarity index (Schoener, ), a metric that ranges from 0 (completely discordant niches) to 1 (identical niches). We then defined a background extent for each genetic group using a 20 km buffer zone around the sampling localities (Theodoridis et al, ) and tested whether the ecological niches of the groups tend to be more similar to each other than would be expected by chance using background (or niche) similarity tests (Broennimann et al, ; Warren, Glor, & Turelli, ). These tests randomly shift the density of occurrences in one range and calculate similarity (Schoener's D ) using the observed niche from the other range.…”

Section: Methodsmentioning

confidence: 99%

“…Regarding its conservation status, P. farinosa has gone extinct or is facing extinction mainly caused by human‐driven changes in its wetland microhabitats and is included in the IUCN Red Lists of several European countries (Croatia: Topić & Stančić, ; Ukraine: Didukh, ; Hungary: Salamon‐Albert & Morschhauser, ; Poland: Gajewski, Sitek, Stolarczyk, Nowak, & Kapała, ; Denmark: Sørensen, Larsen, Orabi, & ørgaard, ; United K ingdom: Cheffings et al, ; Slovakia: Turis et al, ; Romania: Coldea, Stoica, Puşcaş, Ursu, & Oprea, ). Additionally, the species is predicted to suffer a dramatic reduction in its climatically suitable habitats in certain regions across its European range (Theodoridis, Patsiou, Randin, & Conti, ).…”

Section: Introductionmentioning

confidence: 99%

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The role of cryptic diversity and its environmental correlates in global conservation status assessments: Insights from the threatened bird's‐eye primrose (Primula farinosa L.)

Bravo

Conti

2019

Diversity and Distributions

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Aim: Most of the fundamental questions in conservation biogeography require the description of species geographic boundaries and the identification of discrete biological units within these boundaries. International conservation efforts and institutions rely mainly on traditional taxonomic approaches for defining these boundaries, resulting in significant cryptic diversity going undetected and often extinct. Here, we combine high-throughput genomic data with publicly available environmental data to identify cryptic diversity in the threatened bird's-eye primrose (Primula farinosa).We aim to characterize evolutionary lineages and test whether they co-occur with changes in environmental conditions. These lineages can be used as intraspecific units for conservation to enhance assessments regarding the status of threatened species.Location: Europe and temperate Asia (latitude, 40-65°N; longitude, 10°E-115°W). Methods:We genotyped 93 individuals from 71 populations at 1,220 loci (4,089 SNPs) across the Eurasian distribution of P. farinosa. We used phylogenomic and population structure approaches to identify intraspecific lineages. We further extracted statistically derived and remotely sensed environmental information, that is land cover, climate and soil characteristics, to define the biotic and abiotic environment inhabited by each lineage and test for niche similarities among lineages. Additionally, we tested for isolation by distance among populations and applied linear and polynomial regressions to identify lineage-environment associations.Results: Analyses of genomic data revealed six major lineages within P. farinosa corresponding to distinct geographic areas. Niche similarity tests indicated that lineages occupy distinct abiotic and biotic space. Isolation by distance indicated that geography alone cannot explain genetic divergence within P. farinosa, while lineage-environment associations suggested potential adaptation to different abiotic conditions across lineages. However, relationships with the land cover classes, a proxy for habitat, were weaker.

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“…Local models are built separately for each partition and their predictions are combined across the entire range of the species (D'Amen, Zimmermann, & Pearman, 2013;Ikeda et al, 2017;Pearman, D'Amen, Graham, Thuiller, & Zimmermann, 2010). These studies indicate that such local approaches can significantly alter model outcomes (Smith et al, 2019;Theodoridis, Patsiou, Randin, & Conti, 2018). However, detailed information on relevant intraspecific differentiation is available for few species only.…”

Section: Introductionmentioning

confidence: 99%

A novel tool to assess the effect of intraspecific spatial niche variation on species distribution shifts under climate change

Martin

Dyck

Legendre

et al. 2019

Global Ecol Biogeogr

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Aim: Niche-based models often ignore spatial variation in the climatic niche of a species across its occupied range and the related variation in the response to changing climate conditions. This assumption may lead to inaccurate predictions of species distribution shifts under climate change. Models have been developed to address this issue, but most of them depend upon prior knowledge on evolutionary lineages, phenotypic traits or ecological processes underlying local adaptation or adaptive plasticity. As such information is often lacking, these models are not frequently used to predict distribution shifts for many species. This limits our ability to explore general patterns of change across species.Innovation: Here, we propose a modelling framework that can be applied across a large sample of species to assess their distribution shifts under future climate while exploring the effect of intraspecific spatial variation in the response to climate conditions. The proposed approach does not require a detailed understanding of the processes underlying such variation. The geographical distribution of a species is split into spatial subsets along the gradient of occupied climate conditions. These subsets are considered as proxies for intraspecific spatial niche variation. Local models are built with each subset and their predictions are assembled across the study area | 591 MARTIN eT Al.

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Forecasting range shifts of a cold‐adapted species under climate change: are genomic and ecological diversity within species crucial for future resilience?

Cited by 33 publications

References 99 publications

The future of cold‐adapted plants in changing climates: Micranthes (Saxifragaceae) as a case study

The future of cold‐adapted plants in changing climates: Micranthes (Saxifragaceae) as a case study

The role of cryptic diversity and its environmental correlates in global conservation status assessments: Insights from the threatened bird's‐eye primrose (Primula farinosa L.)

A novel tool to assess the effect of intraspecific spatial niche variation on species distribution shifts under climate change

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