New Amber Fossils Indicate That Larvae of Dermestidae Had Longer Defensive Structures in the Past

New Amber Fossils Indicate That Larvae of Dermestidae Had Longer Defensive Structures in the Past

Representatives of Dermestidae (skin, larder, and carpet beetles) play a crucial role as decomposers in global ecosystems, facilitating the recycling of animal and plant biomass to sustain nutrient cycling. Despite their widespread ecological presence and functional importance, the fossil record of...

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Main Authors: Jéhan Le Cadre, Joshua Gauweiler, Joachim T. Haug, Sofía I. Arce, Viktor Baranov, Jörg U. Hammel, Carolin Haug, Uwe Kaulfuss, Christine Kiesmüller, Ryan C. McKellar, Patrick Müller, Marie K. Hörnig, Ana Zippel
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Insects
Subjects:
Amber
Skin beetles
Carpet beetles
Larder beetles
Morphological diversity
hastisetae
Online Access:https://www.mdpi.com/2075-4450/16/7/710
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Summary:Representatives of Dermestidae (skin, larder, and carpet beetles) play a crucial role as decomposers in global ecosystems, facilitating the recycling of animal and plant biomass to sustain nutrient cycling. Despite their widespread ecological presence and functional importance, the fossil record of their larval stages has remained sparse, with previous documentation limited to occasional discoveries. This study significantly expands the larval fossil record by identifying 36 amber-preserved specimens from the Cretaceous, Eocene, and Miocene time slices, obtained from deposits distributed globally. By challenging the historical view of larval fossil rarity, we reveal morphological changes in defensive setae over geological time, demonstrating that Cretaceous and later fossil larvae possess significantly longer absolute and relative setal lengths compared to their extant counterparts. These findings, bolstered by quantitative comparisons of setal and body dimensions across fossil and extant representatives, indicate evolutionary adaptations in defensive structures dating back at least 100 million years. Our results offer new insights into the paleobiology of the group Dermestidae, highlighting how the morphology of larvae potentially reflects historical ecological pressures and resources availability. This study emphasizes the importance of integrating fossil evidence with comparative morphology to elucidate the evolutionary trajectories and functional roles of larvae in ancient terrestrial ecosystems.
ISSN:2075-4450

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