The research, led by scientists at Harvard University, the Max Planck Institute for Evolutionary Biology (MPI-EVA), and the European Synchrotron Radiation Facility (ESRF), is detailed in the Proceedings of the National Academy of Sciences.
“Teeth are remarkable time recorders, capturing each day of growth much like rings in trees reveal yearly progress,” says Tanya M. Smith, assistant professor of human evolutionary biology at Harvard. “Even more impressive is the fact that our first molars contain a tiny ‘birth certificate,’ and finding this birth line allows scientists to calculate exactly how old a juvenile was when it died.”
Compared to even early humans, other primates have shorter gestation, faster childhood maturation, younger age at first reproduction, and a shorter overall lifespan. It’s been unclear exactly when, in the 6 to 7 million years since our evolutionary split from non-human primates, the life course shifted.
Smith and her colleagues found that young Neanderthals’ teeth growth — a proxy for overall development — was significantly faster than in our own species, including some of the earliest groups of modern humans to leave Africa some 90,000 to 100,000 years ago. This indicates that the elongation of childhood has been a relatively recent development.
Such studies add to the growing body of evidence that subtle developmental differences exist between us and our Neanderthal cousins. The recent sequencing of the Neanderthal genome has provided tantalizing genetic clues pointing to differences in cranial and skeletal development between Neanderthals and modern humans.
The current study involves some of the most famous Neanderthal children ever discovered, including the first hominin fossil, discovered in Belgium in the winter of 1829-30. This individual was previously thought, based on comparisons with modern humans, to have been four to five years old at the time of death. Now, powerful synchrotron X-rays and biological rhythms inside teeth have revealed the child was only three years old.
While counting lines in teeth isn’t a new method, Smith says, doing it “virtually” using synchrotron micro-computed tomography is.
“These new methods present a unique opportunity to assess the origins of a fundamentally human condition: the costly yet advantageous shift from a primitive ‘live fast and die young’ strategy to the ‘live slow and grow old’ strategy that has helped to make humans one of the most successful organisms on the planet,” Smith says. Humans’ extended maturation may have facilitated additional learning and complex cognition, possibly giving early Homo sapiens an advantage over their Neanderthal cousins.
Smith’s co-authors are Paul Tafforeau of ESRF; Donald J. Reid of Newcastle University; Joane Pouech of MPI-EVA and ESRF; Vincent Lazzari of MPI-EVA, ESRF, and the International Institute of Paleoprimatology and Human Paleontology; John P. Zermeno of Harvard; Debbie Guatelli-Steinberg of Ohio State University; Anthony J. Olejniczak of MPI-EVA and the Centro Nacional de Investigación sobre la Evolución Humana; Almut Hoffman of the Museum für Vor- und Frühgeschichte; Jakov Radovčić of the Croatian Natural History Museum; Masrour Makaremi of University Bordeaux II; Michel Toussaint of Service Publique de Wallonie; Chris Stringer of the British Natural History Museum; and Jean-Jacques Hublin of MPI-EVA.
The work was funded by the Max Planck Society, ESRF, and Harvard.
Provided by Harvard University. Original written by Steve Bradt, Harvard Staff Writer.
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