Warming threatens habitat suitability and breeding occupancy of rear‐edge alpine bird specialists

Hernando, Miguel de Gabriel; Fernández-Gil, Juan; Roa, Isabel; Juan, Jara; Ortega, F. Javier; Calzada, Francisco de la; Revilla, Eloy

doi:10.1111/ecog.05593

Cited by 28 publications

(23 citation statements)

References 93 publications

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“…This often results also in patchily distributions of species that are strictly connected to very specific elevation ranges, and also in high endemism levels ( Ruggiero & Hawkins, 2008 ; Cadena et al, 2012 ). Mountain ecosystems are consequently extremely valuable in terms of biodiversity and conservation ( Myers et al, 2000 ; Körner & Ohsawa, 2006 ; Boyle & Martin, 2015 ), but species specialist of those ecosystems are highly threatened by climate change ( e.g ., Goodenough & Hart, 2013 ; Brambilla et al, 2017 ; De Gabriel Hernando et al, 2021 ), because of their adaptation to local conditions ( Cheviron & Brumfield, 2012 ). Among birds, species distribution/abundance along elevational gradients have been investigated in several studies ( e.g ., Chamberlain et al, 2016 ; Frey, Hadley & Betts, 2016 ; Elsen et al, 2017 ; Jähnig et al, 2020 ), considering factors such as local climate, vegetation characteristics and topography as explanatory variables.…”

Section: Introductionmentioning

confidence: 99%

Disentangling direct and indirect effects of local temperature on abundance of mountain birds and implications for understanding global change impacts

Ceresa¹,

Kranebitter²,

Monrós

et al. 2021

PeerJ

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Unravelling the environmental factors driving species distribution and abundance is crucial in ecology and conservation. Both climatic and land cover factors are often used to describe species distribution/abundance, but their interrelations have been scarcely investigated. Climatic factors may indeed affect species both directly and indirectly, e.g., by influencing vegetation structure and composition. We aimed to disentangle the direct and indirect effects (via vegetation) of local temperature on bird abundance across a wide elevational gradient in the European Alps, ranging from montane forests to high-elevation open areas. In 2018, we surveyed birds by using point counts and collected fine-scale land cover and temperature data from 109 sampling points. We used structural equation modelling to estimate direct and indirect effects of local climate on bird abundance. We obtained a sufficient sample for 15 species, characterized by a broad variety of ecological requirements. For all species we found a significant indirect effect of local temperatures via vegetation on bird abundance. Direct effects of temperature were less common and were observed in seven woodland/shrubland species, including only mountain generalists; in these cases, local temperatures showed a positive effect, suggesting that on average our study area is likely colder than the thermal optimum of those species. The generalized occurrence of indirect temperature effects within our species set demonstrates the importance of considering both climate and land cover changes to obtain more reliable predictions of future species distribution/abundance. In fact, many species may be largely tracking suitable habitat rather than thermal niches, especially among homeotherm organisms like birds.

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Section: Introductionmentioning

confidence: 99%

Disentangling direct and indirect effects of local temperature on abundance of mountain birds and implications for understanding global change impacts

Ceresa¹,

Kranebitter²,

Monrós

et al. 2021

PeerJ

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“…There is striking evidence that white‐winged snowfinches are strictly associated with cold alpine environments, in terms of their distribution (Brambilla et al 2017a, 2020, Brambilla and Delgado 2020, BirdLife International 2021, de Gabriel Hernando et al 2021), foraging areas (Antor et al 1995, Brambilla et al 2017b, 2018), social behaviour (Delgado et al 2021), survival rates (Strinella et al 2020) and habitat and nest‐site selection (Heiniger 1991a, b1991b, Brambilla et al 2017b, Bettega et al 2020, Niffenegger 2021). The dependence of this species on cold environments is particularly strong during the breeding season (Brambilla et al 2019, 2017a, Resano‐Mayor et al 2019, Schano et al 2021, Alessandrini et al 2022, de Gabriel Hernando et al 2022): the breeding distribution of the species in European mountains is associated with low values of annual average temperature (Brambilla et al 2017a, 2020, 2017a, de Gabriel Hernando et al 2021), suggesting a thermal niche much narrower than that suggested by Cobos et al (2021). Similarly, during winter the species appears almost invariably tied to mountain sites above the treeline (Heiniger 1991a, Bettega et al 2020, Resano‐Mayor et al 2020, Delgado et al 2021, de Gabriel Hernando et al 2021; see also the wintering distribution according to BirdLife International 2021), with season‐specific distribution models showing how suitable areas during the cold season extend only partly to lower mountain ranges (de Gabriel Hernando et al 2021).…”

Section: A Worked Example: the Thermal Niche Of The White‐winged Snow...mentioning

confidence: 99%

“…The dependence of this species on cold environments is particularly strong during the breeding season (Brambilla et al 2019, 2017a, Resano‐Mayor et al 2019, Schano et al 2021, Alessandrini et al 2022, de Gabriel Hernando et al 2022): the breeding distribution of the species in European mountains is associated with low values of annual average temperature (Brambilla et al 2017a, 2020, 2017a, de Gabriel Hernando et al 2021), suggesting a thermal niche much narrower than that suggested by Cobos et al (2021). Similarly, during winter the species appears almost invariably tied to mountain sites above the treeline (Heiniger 1991a, Bettega et al 2020, Resano‐Mayor et al 2020, Delgado et al 2021, de Gabriel Hernando et al 2021; see also the wintering distribution according to BirdLife International 2021), with season‐specific distribution models showing how suitable areas during the cold season extend only partly to lower mountain ranges (de Gabriel Hernando et al 2021). In fact, unlike other typical alpine species like wheatears, water pipits and alpine choughs, observations in warmer areas at low elevation are extremely rare despite the potential suitability of habitat (Knaus et al 2018) and are more likely to occur in the case of prolonged, exceptionally cold or snowy periods and mostly linked to food shortage at higher elevation (Cramp and Perrins 1994, Glutz von Blotzheim and Bauer 1997).…”

Section: A Worked Example: the Thermal Niche Of The White‐winged Snow...mentioning

confidence: 99%

Insufficient considerations of seasonality, data selection and validation lead to biased species–climate relationships in mountain birds

Brambilla

Bettega

Delgado

et al. 2022

Journal of Avian Biology

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“…The increase of anthropogenic and environmental pressures, both being intimately bound, represents an unprecedented threat for vulnerable species. In particular, populations from species of high‐mountain ecosystems might not be able to move upward rapidly enough to keep within their thermal tolerances and might be doomed on their “sky islands” (see McCormack et al, 2009, e.g., De Gabriel Hernando et al, 2021, Kidane et al, 2019). Thus, species endemic to specific mountain ranges represent a major conservation issue, if only for their heritage interest.…”

Section: Introductionmentioning

confidence: 99%

Little hope for the polyploid endemic Pyrenean Larkspur (Delphinium montanum): Evidences from population genomics and Ecological Niche Modeling

Salvado

Boixader²,

Parera³

et al. 2022

Ecology and Evolution

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Species endemic to restricted geographical ranges represent a particular conservation issue, be it for their heritage interest. In a context of global change, this is particularly the case for plants which belong to high‐mountain ecosystems and, because of their ecological requirements, are doomed to survive or disappear on their “sky islands”. The Pyrenean Larkspur (Delphinium montanum, Ranunculaceae) is endemic to the Eastern part of the Pyrenees (France and Spain). It is now only observable at a dozen of localities and some populations show signs of decline, such as a recurrent lack of flowering. Implementing population genomics approach (e.g., RAD‐seq like) is particularly useful to understand genomic patterns of diversity and differentiation in order to provide recommendations in term of conservation. However, it remains challenging for species such as D. montanum that are autotetraploid with a large genome size (1C‐value >10 pg) as most methods currently available were developed for diploid species. A Bayesian framework able to call genotypes with uncertainty allowed us to assess genetic diversity and population structure in this system. Our results show evidence for inbreeding (mean GIS = 0.361) within all the populations and substantial population structure (mean GST = 0.403) at the metapopulation level. In addition to a lack of connectivity between populations, spatial projections of Ecological Niche Modeling (ENM) analyses under different climatic scenarios predict a dramatic decrease of suitable habitat for D. montanum in the future. Based on these results, we discuss the relevance and feasibility of different conservation measures.

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Warming threatens habitat suitability and breeding occupancy of rear‐edge alpine bird specialists

Cited by 28 publications

References 93 publications

Disentangling direct and indirect effects of local temperature on abundance of mountain birds and implications for understanding global change impacts

Disentangling direct and indirect effects of local temperature on abundance of mountain birds and implications for understanding global change impacts

Insufficient considerations of seasonality, data selection and validation lead to biased species–climate relationships in mountain birds

Little hope for the polyploid endemic Pyrenean Larkspur (Delphinium montanum): Evidences from population genomics and Ecological Niche Modeling

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