Preservation and Taphonomy of Fossil Insects from the Earliest Eocene of Denmark.

Miriam Heingård,Peter Sjövall,Bo P Schultz,Johan Lindgren,René L Sylvestersen

doi:10.3390/biology11030395

Miriam Heingård, Peter Sjövall + Show 3 more

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https://doi.org/10.3390/biology11030395

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Abstract

Simple SummaryInsect fossils dating 55 million-years-old from the Stolleklint Clay and Fur Formation of Denmark are known to preserve both fine morphological details and color patterns. To enhance our understanding on how such fragile animals are retained in the fossil record, we examined a pair of beetle elytra, a wasp and a damselfly using sensitive analytical techniques. In our paper, we demonstrate that all three insect fossils are composed of cuticular remains (that is, traces of the exoskeleton) that, in turn, are dominated by the natural pigment eumelanin. In addition, the beetle elytra show evidence of a delicate lamellar structure comparable to multilayered reflectors that produce metallic hues in modern insects. Our results contribute to improved knowledge on the process of fossilization of insect body fossils in marine environments.Marine sediments of the lowermost Eocene Stolleklint Clay and Fur Formation of north-western Denmark have yielded abundant well-preserved insects. However, despite a long history of research, in-depth information pertaining to preservational modes and taphonomic pathways of these exceptional animal fossils remains scarce. In this paper, we use a combination of scanning electron microscopy coupled with energy-dispersive X-ray spectroscopy (SEM-EDX), transmission electron microscopy (TEM) and time-of-flight secondary ion mass spectrometry (ToF-SIMS) to assess the ultrastructural and molecular composition of three insect fossils: a wasp (Hymenoptera), a damselfly (Odonata) and a pair of beetle elytra (Coleoptera). Our analyses show that all specimens are preserved as organic remnants that originate from the exoskeleton, with the elytra displaying a greater level of morphological fidelity than the other fossils. TEM analysis of the elytra revealed minute features, including a multilayered epicuticle comparable to those nanostructures that generate metallic colors in modern insects. Additionally, ToF-SIMS analyses provided spectral evidence for chemical residues of the pigment eumelanin as part of the cuticular remains. To the best of our knowledge, this is the first occasion where both structural colors and chemical traces of an endogenous pigment have been documented in a single fossil specimen. Overall, our results provide novel insights into the nature of insect body fossils and additionally shed light on exceptionally preserved terrestrial insect faunas found in marine paleoenvironments.

Highlights

This article is an open access articleLowermost Eocene deposits of the Limfjord Region, Northwestern Jutland, Denmark, have yielded diverse biotas of exceptionally preserved plant and animal body fossils that frequently retain soft parts, such as feathers and skin [1,2]
Three insect fossils from the Stolleklint Clay and Fur Formation showing various states of preservation were selected for this study: (1) a pair of isolated but three-dimensional beetle elytra (Coleoptera; FUM-N-17627) collected from a calcium carbonate concretion near ash layer +15 in the Fur Formation; (2) a flattened yet fully articulated wasp (Hy-Biology 2022, 11, 395 menoptera, Ichneumonidae; FUM-N-11263) preserved in a calcium carbonate concretion, collected from the Fur Formation on the Island of Mors; and (3) a compressed but largely articulated damselfly (Odonata, Zygoptera; FUM-N-10904) found in hardened clays of the Stolleklint Clay
To gain a better understanding of the retention of insect body fossils in the rock record, we investigated three exceptionally preserved specimens from the lowermost Eocene

Summary

Introduction

This article is an open access articleLowermost Eocene deposits of the Limfjord Region, Northwestern Jutland, Denmark, have yielded diverse biotas of exceptionally preserved plant and animal body fossils that frequently retain soft parts, such as feathers and skin [1,2]. Insects are currently one of the most ubiquitous and numerically abundant groups of animals on Earth, and they have a fossil record that dates back to the Early Devonian [6,7]. Preserved biotas, such as those from the Limfjord Region, act as important “windows” into the evolutionary history of this clade, but are crucial for understanding taphonomic pathways that may contribute to the retention of delicate anatomical features in the rock record. Previous work on insects from the Stolleklint Clay and Fur Formation has touched upon taphonomic and biostratinomic processes [20–23], most studies have focused on other aspects of the assemblage (e.g., [24–28])

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