for National Geographic News
Paleontologists are used to drab brown and gray fossils. Sediments that seep in to cast the shape of ancient organisms in stone, determine the color. Instead, long-gone beasts and the ancient worlds they inhabited, spring to life in the depths of these scientists' imaginations.
Now under exceptional circumstances, scientists have uncovered and explained a 50-million-year-old beetle fossil that still retains the bright blue metallic hue it sported in life. This beetle and others from the same site, are very rare examples of fossils that retain any original color, and are the oldest colored fossils ever found.
The specimen is a "paleontological Rosetta stone" said Andrew Parker, lead researcher behind the find, and evolutionary biologist at the University of Oxford in England. The fossil beetle may be the key to analyzing and predicting the color of other well-preserved invertebrate fossils, fish scales and even bird and dinosaur feathers, that have not retained any original coloration, he said.
The beetle specimen was found in 50-million-year-old oil shale deposits from the Messel Quarry near Frankfurt, Germany. Messel, a World Heritage site, is unique because its fossils are so well preserved. Bats and crocodiles for example, not only retain skeletal parts, but outlines of their entire bodies. The beetles are unusual in that they still contain the original materialchitinthat formed their exoskeleton in life.
Messel fossil hunters had previously turned up beetles, which retained bright colors lost on drying, but those researchers had paid little heed to color before. "Plenty of people are working on color in animals today, but few have thought of looking at colors in the past," said Parker.
Parker, and physicist colleague David McKenzie of the University of Sydney, are the first to detail these colored beetles and explain why they have retained their decoration over so many millennia. The pair describe the remarkable find in a recent online edition of the journal Biology Letters.
Coloration is one of the very many speculations that researchers, filmmakers and alike, have to make when reconstructing prehistoric plants and animals. When organisms become fossilized, the original material of their body is usually completely replaced. "In this process, chemicals are destroyed and pigments are not retained," said Parker.
World of Color
However there are ways, other than chemical pigmentation, in which organisms can produce color. One way is using a structure, such as wafer thin stacks of thin translucent organic material, to interfere with and reflect light (in a similar way to a prism splitting white light into colored beams). These films, made of chitin for example, can reflect and amplify light of one wavelength (or color). This is how most iridescent or metallic animal colors are produced, such as those striking hues found to adorn shiny butterfly wings, the feathers of hummingbirds and peacocks, and an entire rainbow of beetles.
Microscopic analysis revealed that the exoskeleton of the beetle found at Messel did indeed retain a type of structure known as a multi-layer reflector in its chitin exoskeleton, thus explaining its color.
"There is an incredible level of preservation in these [beetle] fossils," commented Chris Lawrence senior scientist studying the physics of biological color and its application, at research and development company QinetiQ in Hampshire, England. Finding colored fossils is unheard of, he said.
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