The isolated <i>Erebia pandrose</i> Apennine population is genetically unique and endangered by climate change

Sistri, Ginevra; Menchetti, Mattia; Santini, Luca; Pasquali, Lorenzo; Sapienti, Sofia; Cini, Alessandro; Platania, Leonardo; Balletto, Emilio; Bonelli, Simona; Casacci, Luca Pietro; Dincă, Vlad; Vila, Roger; Mantoni, Cristina; Fattorini, Simone; Dapporto, Leonardo

doi:10.1111/icad.12538

Cited by 19 publications

(30 citation statements)

References 76 publications

(98 reference statements)

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“…Many butterfly species inhabiting relatively cold habitats were presumably more widely distributed during the last glacial maximum and in the current interglacial they shifted towards high latitudes and/or to scattered mountain areas. Examples among Holarctic butterflies are included in the genera Erebia (De Groot et al 2009;Hinojosa et al 2018;Minter et al 2020;Sistri et al 2022) and Parnassius (Ashton et al 2009;Todisco et al 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Indeed, the possibility to shift towards higher elevations is clearly limited for populations inhabiting mountains, since the area of the habitats rapidly decreases with altitude (Habel et al 2011). In addition to ecological consequences of population extinction, the loss of intra-specificgenetic diversity is an important aspect to consider, since many relict populations are markedly genetically distinct from the other lineages, as a result of their protracted isolation (Schmitt et al 2005;Konvička et al 2014;Minter et al 2020;Sistri et al 2022). A high extinction risk has been predicted for several species with disjunct populations in the Apennines, such as Erebia gorge (Hübner, [1804]) (Piazzini and Favilli 2020) and Erebia pandrose (Borkhausen, 1788) (Sistri et al 2022), the latter represented by a genetically differentiated population on these mountains.…”

Section: Introductionmentioning

confidence: 99%

“…In Italy, the distribution of L. petropolitana is similar to that of other butterfly species such as Polyommatus eros (Ochsenheimer, 1808), Boloria pales ([Denis & Schiffermüller], 1775), Erebia pandrose and E. pluto (Prunner, 1798), which are widely distributed in the Alps and restricted to a few mountain areas in the Apennines. These isolated populations often represent endemic lineages responsible for a strong genetic distinctiveness between the communities of the Apennines and the Alps (Ehl et al 2020;Menchetti et al 2021;Schmitt et al 2021;Sistri et al 2022). In the Apennines, L. petropolitana only occurs in a few sites in three neighbouring massifs: Monti della Laga, Gran Sasso and Monti Marsicani (Balletto et al 2007).…”

Section: Introductionmentioning

confidence: 99%

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Climate change may cause the extinction of the butterfly Lasiommata petropolitana in the Apennines

et al. 2022

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Climate change represents a threat to narrow-ranged mountain species living in low-altitude massifs. We studied the disjunct Apennine population of Lasiommata petropolitana (Lepidoptera, Nymphalidae) in the Gran Sasso and Monti della Laga National Park. We quantified the altitudinal shifts undergone in the last decades (1964–2021) in the Alps and Apennines and estimated the local extinction risk due to climate change. We also sequenced the COI mitochondrial marker of seven Apennine specimens, comparing them with those available across the Palearctic. We projected the probability of presence for the species under a future climatic scenario using an ensemble forecasting approach. We found that, despite geographical isolation, the Apennine population of L. petropolitana displays a single widespread COI haplotype also occurring in most European populations. In the Alps and Apennines, this species has shifted uphill an average of 6.3 m per year since 1964. Accordingly, our model predicted a likely extinction in the Apennines by about 2060, due to a reduction of the climatic suitability in this region. Implications for insect conservation Implications for insect conservation Despite its potential loss in the Apennines would not erode mitochondrial diversity, L. petropolitana characterises the butterfly community of the Gran Sasso massif as an alpine enclave. The loss of the Apennine population, together with those of other orophilous butterflies, could trigger a homogenization of alpha and beta diversity and induce a loss of functional diversity in the impoverished high-altitude biotas. As habitat heterogeneity is a key aspect for populations to endure climate change, the maintenance of varied microhabitats, mainly through grazing management, could address the decline of this population.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Climate change may cause the extinction of the butterfly Lasiommata petropolitana in the Apennines

et al. 2022

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“…Anselmo, 2019; Urbani et al, 2017), and Lepidoptera (e.g. Batalden et al, 2014; Sistri et al, 2021). The basic idea of climate‐related HSMs is that of inferring the climatic niche of a species from climatic predictors occurring in its range; then, based on this relationship, future values of climatic variables can be used to predict possible future changes in species' available areas (Bellard et al, 2012; Thuiller et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Conservation biogeography of high‐altitude longhorn beetles under climate change

Poloni

Iannella

Fusco

et al. 2022

Insect Conserv Diversity

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High‐altitude insects are expected to be strongly affected by climate change because of their limited range. Phytophagous species will be subject to further threats because of their dependence on host plants. We investigated the impact of climate change on the distribution of Italian high‐altitude longhorn beetles (Cerambycidae) using a maximum entropy approach based on bioclimatic variables. We used 510 presence records for 15 species distributed throughout the Italian Alps and Apennines. Then, we combined climate‐based predictions with vegetation data to predict the future changes in the extent of suitable areas. All species but two will move uphill to track suitable climates and will face a range contraction (with an average loss of 44%) under both climatic change scenarios considered. Suitable vegetation covers, on average, only 56% of the estimated current species ranges, which means that the future distribution will be even more limited. Given the importance of Italian mountains as hubs of diversity in the Mediterranean hotspot, these results are particularly alarming. Conservation actions that can mitigate the effects of climate change on high‐altitude cerambycids should be focused on contrasting habitat loss and degradation through land preservation and the adoption of appropriate forest management practices.

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“…To disentangle the roles of behavioural responses and physical differences in thermoregulation, we studied adult Erebia (Nymphalidae, Satyrinae) butterflies occurring in sympatry in alpine environments. In the mountains, microclimatic conditions experienced by butterflies are changing rapidly (Stuhldreher & Fartmann, 2018) and alpine species including Erebia are endangered by climate warming (Konvicka et al, 2021; Sistri et al, 2022). Erebia butterflies have low mobility (Polic et al, 2014; Slamova et al, 2013), which probably leads to slower uphill shifts in response to climate warming compared to mobile generalist species (Rödder et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Body size, not species identity, drives body heating in alpineErebiabutterflies

Klečková

Okrouhlík

Svozil

et al. 2022

Preprint

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Efficient thermoregulation is crucial for animals living under changing climatic and weather conditions. We used a thermal camera to measure thermoregulation of six co-occurring species of Erebia (Lepidoptera: Nymphalidae) mountain butterflies in a laboratory experiment with artificial light and heating source. We studied wild individuals to test whether physical characteristics (body size, wing loading) are responsible for the interspecific differences in thermoregulation detected previously under natural conditions in European Alps. We revealed that physical characteristics had a small effect on explaining interspecific differences compared to distinct thermoregulatory differences recorded in the field. Our results show that larger butterflies, with higher weight and wing loading, heated up more slowly but reached the same asymptotic body temperature as smaller butterflies. Altogether, our results suggest that differences in body temperatures among Erebia species observed in the field are likely caused mainly by species-specific differences in microhabitat use and confirm the role of active thermoregulation in adult butterflies.

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The isolated Erebia pandrose Apennine population is genetically unique and endangered by climate change

Cited by 19 publications

References 76 publications

Climate change may cause the extinction of the butterfly Lasiommata petropolitana in the Apennines

Climate change may cause the extinction of the butterfly Lasiommata petropolitana in the Apennines

Conservation biogeography of high‐altitude longhorn beetles under climate change

Body size, not species identity, drives body heating in alpineErebiabutterflies

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