Upwelling areas as climate change refugia for the distribution and genetic diversity of a marine macroalga

Lourenço, Carla R.; Zardi, Gerardo I.; McQuaid, Christopher D.; Serrão, Ester Á.; Pearson, Gareth A.; Jacinto, Rita; Nicastro, Katy R.

doi:10.1111/jbi.12744

Cited by 102 publications

(90 citation statements)

References 79 publications

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“…zebrina , was significantly different from populations inside the range of either species. In agreement with theoretical expectations the plastic, between‐site, phenotypic responses for the species at the leading edge of its range were gradient‐like or did not show significant differences, while the response of rear edge populations was site‐specific (Lourenco et al., ; Nicastro et al., ; Zardi et al., ). Together with the heterogeneous and extreme physical and chemical conditions, we documented in the intertidal and coastal zone around PLV (i.e.…”

Section: Discussionsupporting

confidence: 83%

Phenotypic plasticity at the edge: Contrasting population‐level responses at the overlap of the leading and rear edges of the geographical distribution of two Scurria limpets

Broitman

Aguilera

Lagos

et al. 2018

Journal of Biogeography

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Aim To examine the role of ocean temperature and chemistry as drivers of interpopulation differences in multiple phenotypic traits between rear and leading edge populations of two species of limpet. Location The coast of north‐central Chile, western South America. Taxon Mollusca, Gastropoda (Lottidae). Methods We used field and laboratory experiments to study the ecology and physiology of individuals from populations located at the overlap of the rear and leading edges of their respective geographical distributions. At the same time, we characterized local environmental regimes, measuring seawater physical and chemical properties. Results Towards the edge of their range, individuals from the leading edge species gradually reduced their shell length, metabolic rate and thermal response capacity, and increased carbonate content in their shells. Individuals of the rear edge species showed dissimilar responses between sites. Contrasting behavioural responses to experimental heating reconciled observations of an unintuitive higher maximal critical temperature and a smaller thermal safety margin for individuals of the rear edge populations. Physical–chemical characterization of seawater properties at the site located on the core of the upwelling centre showed extreme environmental conditions, with low oxygen concentration, high pCO2 and the episodic presence of corrosive seawater. These challenging environmental conditions were reflected in reduced growth for both species. Main conclusions We found different spatial patterns of phenotypic plasticity in two sister species around the leading and trailing edges of their distributions. Our results provide evidence that environmental conditions around large upwelling centres can maintain biogeographical breaks through metabolic constraints on the performance of calcifying organisms. Thus, local changes in seawater chemistry associated with coastal upwelling circulation emerge as a previously overlooked driver of marine range edges.

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Section: Discussionsupporting

confidence: 83%

Phenotypic plasticity at the edge: Contrasting population‐level responses at the overlap of the leading and rear edges of the geographical distribution of two Scurria limpets

Broitman

Aguilera

Lagos

et al. 2018

Journal of Biogeography

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show abstract

“…Although we have focused on representative species, equally valid approaches have identified refugia that cater to endemic or threatened species (Chitale et al 2014, Meng et al 2016, Stratmann et al 2016, capture a set of critical landscape characteristics (Molina-Venegas et al 2016, Sandberg et al 2016, or aim to protect genetic diversity (Havrdová et al 2015, Souto et al 2015, Lourenço et al 2016. Although we have focused on representative species, equally valid approaches have identified refugia that cater to endemic or threatened species (Chitale et al 2014, Meng et al 2016, Stratmann et al 2016, capture a set of critical landscape characteristics (Molina-Venegas et al 2016, Sandberg et al 2016, or aim to protect genetic diversity (Havrdová et al 2015, Souto et al 2015, Lourenço et al 2016.…”

Section: Discussionmentioning

confidence: 99%

Identifying in situ climate refugia for plant species

2018

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Identification of refugia from climate change is increasingly considered important for biodiversity conservation, but the distribution of putative refugia may vary across alternative climate scenarios, impeding conservation decision-making. Based on 117 plant species representative of ecoregions within south-eastern Australia, we provide a case study identifying in situ refugia across a spectrum of plausible future climates. We define in situ refugia as areas that currently contain populations of the target species, and are projected to remain climatically suitable in the future. Refugia were identified across scenarios describing futures that are, relative to 1990-2009, warmer and wetter, warmer/drier, hotter/wetter, and hotter with little precipitation change. Despite substantial variation in the spatial extent and longevity of climate refugia across species, ecoregions and climate scenarios, clear patterns emerged. By 2070, refugia for species in 1) deserts and xeric shrublands; 2) mediterranean forests, woodlands and shrublands; and 3) temperate and tropical grasslands are likely to be least extensive under a hotter/ wetter future. Conversely, wetter conditions may lead to broader refugia for species in temperate forests. We identified areas of congruence where high richness refugia (refugia for  50% of representative species) were projected to occur irrespective of the climate scenario. These regions therefore appear robust to uncertainty about climate change, presenting clear targets for conservation attention. Our approach provides valuable information for decision-makers, enabling them to identify and visualise the spatial arrangement of refugia under contrasting scenarios of environmental change. This reveals management options in the context of climate uncertainty and facilitates informed prioritisation of conservation resources.

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“…These range shifts pushed the current distribution to the northwestern Iberian Peninsula, and discontinuous occurrences along southwestern Portugal and western Morocco, but only in upwelling regions47. There, cold and nutrient-rich upwelled waters form climatic refugia that buffer the overall warming trend observed in Iberia-Morocco47. It has been suggested that throughout the world upwelling is becoming more persistent, longer and stronger48.…”

Section: Discussionmentioning

confidence: 99%

Major shifts at the range edge of marine forests: the combined effects of climate changes and limited dispersal

Assis

Berecibar

Claro

et al. 2017

Sci Rep

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Global climate change is likely to constrain low latitude range edges across many taxa and habitats. Such is the case for NE Atlantic marine macroalgal forests, important ecosystems whose main structuring species is the annual kelp Saccorhiza polyschides. We coupled ecological niche modelling with simulations of potential dispersal and delayed development stages to infer the major forces shaping range edges and to predict their dynamics. Models indicated that the southern limit is set by high winter temperatures above the physiological tolerance of overwintering microscopic stages and reduced upwelling during recruitment. The best range predictions were achieved assuming low spatial dispersal (5 km) and delayed stages up to two years (temporal dispersal). Reconstructing distributions through time indicated losses of ~30% from 1986 to 2014, restricting S. polyschides to upwelling regions at the southern edge. Future predictions further restrict populations to a unique refugium in northwestern Iberia. Losses were dependent on the emissions scenario, with the most drastic one shifting ~38% of the current distribution by 2100. Such distributional changes might not be rescued by dispersal in space or time (as shown for the recent past) and are expected to drive major biodiversity loss and changes in ecosystem functioning.

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Upwelling areas as climate change refugia for the distribution and genetic diversity of a marine macroalga

Cited by 102 publications

References 79 publications

Phenotypic plasticity at the edge: Contrasting population‐level responses at the overlap of the leading and rear edges of the geographical distribution of two Scurria limpets

Phenotypic plasticity at the edge: Contrasting population‐level responses at the overlap of the leading and rear edges of the geographical distribution of two Scurria limpets

Identifying in situ climate refugia for plant species

Major shifts at the range edge of marine forests: the combined effects of climate changes and limited dispersal

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