Data from: Silk properties and overwinter survival in gregarious butterfly larvae
Data files
Sep 10, 2019 version files 361.10 MB
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Bombyx.zip
729.09 KB
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InhibitionArea-Silk-Oct2017.xlsx
32.67 KB
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MCINX.zip
1.40 MB
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PostDiapause-EM-Silk-Images.zip
319.86 MB
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PostDiapause-silkDensity.xlsx
17.76 KB
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Pre-diapause-SilkDensity.xlsx
13.84 KB
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PreDiapause-EM-Silk-Images.zip
39.04 MB
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README_for_InhibitionArea-Silk-Oct2017.rtf
1.25 KB
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README_for_MCINX.rtf
14.88 KB
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README_for_PostDiapause-silkDensity.rtf
3.64 KB
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README_for_Pre-diapause-SilkDensity.rtf
2.03 KB
Abstract
All organisms are challenged by encounters with parasites, which strongly select for efficient escape strategies in the host. The threat is especially high for gregarious species entering immobile periods, such as diapause. Larvae of the Glanville fritillary butterfly, Melitaea cinxia, spend the winter in diapause in groups of conspecifics each sheltered in a silk-nest. Despite intensive monitoring of the population, we have little understanding of the ecological factors influencing larval survival over the winter in the field. We tested whether qualitative and quantitative properties of the silk-nest contribute to larval survival over diapause. We used comparative proteomics, metabarcoding analyses, microscopic imaging, and in-vitro experiments to compare protein composition of the silk, community composition of the silk-associated microbiota, and silk density from both wild-collected and laboratory-reared families, which survived or died in the field. Although most traits assessed varied across families, only silk density correlated with over-winter survival in the field. The silk nest spun by gregarious larvae before the winter acts as an efficient breathable physical shield that positively affects larval survival during diapause. Such benefit may explain how this costly trait is conserved across populations of this butterfly species, and potentially across other silk-spinning insect species.