Canadian butterfly climate debt is significant and correlated with range size

Lewthwaite, Jayme M. M.; Angert, Amy L.; Kembel, Steven W.; Goring, Simon; Davies, T. Jonathan; Mooers, Arne Ø.; Sperling, Felix A. H.; Vamosi, Steven M.; Vamosi, Jana C.; Kerr, Jeremy T.

doi:10.1111/ecog.03534

Cited by 25 publications

(34 citation statements)

References 73 publications

(79 reference statements)

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“…The direct effects of climate change on our tested butterflies followed expectations that HS in lower latitudes would decline and in high latitudes would gain. We again caution against attributing the gains observed as fact because other studies have identified that species typically lag behind poleward shifts in climate (Kerr et al, 2015; Lewthwaite et al, 2018; Menéndez et al, 2007; Parmesan et al, 1999). The maps of predicted future suitability for butterfly species are also averages across all GCMs, and thus are neglecting nuances associated with specific climatic patterns, such as drier conditions projecting declines in P. smintheus and P. occidentalis .…”

Section: Discussionmentioning

confidence: 80%

“…Although the direct effects of climate on P. smintheus are well understood, the indirect effects are unknown. Previous studies exploring the indirect effects of climate change on butterflies typically are missing the mechanism that drives the direct effects climate on the population dynamics of their target species (Lewthwaite et al, 2018; e.g. Menéndez et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Inclusion of trophic interactions increases the vulnerability of an alpine butterfly species to climate change

Filazzola

Matter

Roland

2020

Global Change Biology

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Climate change is expected to have significant and complex impacts on ecological communities. In addition to direct effects of climate on species, there can also be indirect effects through an intermediary species, such as in host-plant interactions.Indirect effects are expected to be more pronounced in alpine environments because these ecosystems are sensitive to temperature changes and there are limited areas for migration of both species (i.e. closed systems), and because of simpler trophic interactions. We tested the hypothesis that climate change will reduce the range of an alpine butterfly (Parnassius smintheus) because of indirect effects through its host plant (Sedum sp.). To test for direct and indirect effects, we used the simulations of climate change to assess the distribution of P. smintheus with and without Sedum sp. We also compared the projected ranges of P. smintheus to four other butterfly species that are found in the alpine, but that are generalists feeding on many plant genera. We found that P. smintheus gained distributional area in climate-only models, but these gains were significantly reduced with the inclusion of Sedum sp. and in dryclimate scenarios which resulted in a reduction in net area. When compared to the more generalist butterfly species, P. smintheus exhibited the largest loss in suitable habitat. Our findings support the importance of including indirect effects in modelling species distributions in response to climate change. We highlight the potentially large and still neglected impacts climate change can have on the trophic structure of communities, which can lead to significant losses of biodiversity. In the future, communities will continue to favour species that are generalists as climate change induces asynchronies in the migration of species. K E Y W O R D S alpine, biotic interactions, butterfly, global change, host-plant, maxent, species distribution modelling

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Section: Discussionmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 99%

Inclusion of trophic interactions increases the vulnerability of an alpine butterfly species to climate change

Filazzola

Matter

Roland

2020

Global Change Biology

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“…In environments where dispersal is not a limiting factor and there is no strong spatial correlation in habitat quality, such simple relationships can be reasonable approximations, but in fragmented landscapes where occupancy is a function of both colonizations and local population dynamics, we should not let this assumption stand untested. An extreme example are bioclimatic envelope models lacking any population dynamic component that are used to predict range shifts under climate change (Araújo et al 2005, Lewthwaite et al 2018, in spite of the availability dynamic alternatives (Keith et al 2008, Buckley et al 2010, Leroux et al 2013. These models, which are fit to records of presence and absence of the study species, often assume a simple relationship between carrying capacity and patch characteristic, such as area and habitat quality, and use this relationship as the basis of extinction probabilities.…”

Section: Introductionmentioning

confidence: 99%

“…Such deficiencies are most critical when predicting under novel environmental conditions and outside a species' current range. An extreme example are bioclimatic envelope models lacking any population dynamic component that are used to predict range shifts under climate change (Araújo et al 2005, Lewthwaite et al 2018, in spite of the availability dynamic alternatives (Keith et al 2008, Buckley et al 2010, Leroux et al 2013.…”

Section: Introductionmentioning

confidence: 99%

Long‐term demographic surveys reveal a consistent relationship between average occupancy and abundance within local populations of a butterfly metapopulation

2019

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Species distribution models are the tool of choice for large-scale population monitoring, environmental association studies and predictions of range shifts under future environmental conditions. Available data and familiarity of the tools rather than the underlying population dynamics often dictate the choice of specific methodespecially for the case of presence-absence data. Yet, for predictive purposes, the relationship between occupancy and abundance embodied in the models should reflect the actual population dynamics of the modelled species. To understand the relationship of occupancy and abundance in a heterogeneous landscape at the scale of local populations, we built a spatio-temporal regression model of populations of the Glanville fritillary butterfly Melitaea cinxia in a Baltic Sea archipelago. Our data comprised nineteen years of habitat surveys and snapshot data of land use in the region. We used variance partitioning to quantify relative contributions of land use, habitat quality and metapopulation covariates. The model revealed a consistent and positive, but noisy relationship between average occupancy and mean abundance in local populations. Patterns of abundance were highly variable across years, with large uncorrelated random variation and strong local population stochasticity. In contrast, the spatio-temporal random effect, habitat quality, population connectivity and patch size explained variation in occupancy, vindicating metapopulation theory as the basis for modelling occupancy patterns in fragmented landscapes. Previous abundance was an important predictor in the occupancy model, which points to a spillover of abundance into occupancy dynamics. While occupancy models can successfully model large-scale population structure and average occupancy, extinction probability estimates for local populations derived from occupancy-only models are overconfident, as extinction risk is dependent on actual, not average, abundance. Long-term demographic surveys reveal a consistent relationship between average occupancy and abundance within local populations of a butterfly metapopulation Torsti Schulz, Jarno Vanhatalo and Marjo Saastamoinen T. Schulz (https://orcid.org/0000-0001-8940-9483) ✉ (torsti.schulz@helsinki.fi), J. Vanhatalo (https://orcid.org/0000-0002-6831-0211) and M. Saastamoinen (https://orcid.org/0000-0001-7009-2527),

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“…Within Alberta and Saskatchewan, changes in mean annual temperature, growing degree‐days, and vegetation composition are expected to be most pronounced in central and southern regions, including the present‐day range of P. m. dodi (Barber, Nielsen, & Hamann, 2016; Schneider, 2013; Zhang, Nielsen, Stolar, Chen, & Thuiller, 2015). There is some evidence that vagile North American butterfly species may track their climatic niches poleward as temperatures warm; however, more often than not, these range expansions are not sufficient to offset contractions toward the equator (Lewthwaite et al., 2018). Indeed, there exist few opportunities for P. m. dodi to track its climatic niche northward as temperatures rise.…”

Section: Discussionmentioning

confidence: 99%

Gene flow and climate‐associated genetic variation in a vagile habitat specialist

et al. 2020

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Canadian butterfly climate debt is significant and correlated with range size

Cited by 25 publications

References 73 publications

Inclusion of trophic interactions increases the vulnerability of an alpine butterfly species to climate change

Inclusion of trophic interactions increases the vulnerability of an alpine butterfly species to climate change

Long‐term demographic surveys reveal a consistent relationship between average occupancy and abundance within local populations of a butterfly metapopulation

Gene flow and climate‐associated genetic variation in a vagile habitat specialist

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