A little over a year ago, we reported on a large area at the foot of the Asperillo cliff, on the coast of the Donana Natural Area in Huelva, Spain. There, along with numerous animal footprints, other footprints had been found – those of hominids.
Until then, the only time reference that allowed the age of the site to be established was the dating of one of the dunes that covered the surface to around 106,000 years ago (Upper Pleistocene). As with most of the hominid footprints found worldwide, we dated them in line with the environment in which they were found. For this reason, our first hypothesis when trying to attribute the newfound footprints was that they belonged to Neanderthals, who lived in the Upper Pleistocene.
However, in the course of the investigation, we sampled the surface where the footprints were found, which had never been dated before, and the dunes above. It turned out to be about 295,800 years old (Middle Pleistocene): this is to say, much earlier than previously thought.
Drastic climate change
The new dating placed the footprints in a new geographical and environmental context. The European continent was about to undergo drastic climate change 300,000 years ago. Relatively warm conditions were changing to much colder conditions, a precursor to an ice age. At that time, the sea level on the European continent was on average about 60 meters below its present level, which implies that the Huelva coastline would be 20 to 25 kilometers offshore from its present position.
In other words, the coastal plain was very extensive and probably created by the delta of the river. It was probably covered by water during the wet seasons and totally or partially exposed during the dry seasons.
Over this shallow and saline lake environment, made of polygonal ground and microbial covers, that hominids and other fauna trampled. Today, the same kind of polygonal covers are found in extensive areas of marshland in both hot desert and tropical climates.
More or less extensive vegetated areas would be found in the non-flooded areas of this wide coastal plain. Around them, there would be a significant development of dune systems that would move landward from the coast.
New suspects?
The environmental context and the landscape have changed in relation to the initial interpretation. The question, therefore, became whether our understanding of who produced these footprints should also change. The answer is to be found in the palaeontological record.
Hominid fossils belonging to the Middle Pleistocene are thought to be from the Neanderthal lineage: Homo neanderthalensis and Homo heidelbergensis. However, their remains are still very scarce, fragmentary and geographically dispersed. Worse still, footprints are even scarcer than skeletal remains. In the entire European Middle Pleistocene, only four sites have provided traces from this period: Terra Amata, in France (380,000 years old), Roccamonfina, in Italy (345,000 years old, attributed to Homo heidelbergensis), Biache-Vaast, in France (236,000 years old, Homo neanderthalensis) and Theopetra, in Greece (130,000 years old, Homo neanderthalensis).
On the other hand, it must be considered that the formal characteristics of the footprint are not only the result of the anatomy of the foot, but also of other factors such as biomechanical characteristics, the type of substrate and the processes that gave rise to the fossil. Therefore, the footprints studied must be well preserved and reflect several anatomical features (arch impression of the toes), which is rarely the case in places like this site in Huelva.
To confirm which hominid group the footprints belong to, we would need to compare their anatomical characteristics with the known skeletal record for the Middle Pleistocene.
Almost all the foot fossils known for this period come from the Sima de Los Huesos site (Atapuerca, Spain) and are associated with individuals related to Neanderthals. Making a more precise attribution would be difficult, as there are many debates about the evolution of this lineage, but also about the taxonomic definition of Homo heidelbergensis.
Different models for the evolution of the Neanderthal lineage have been proposed, but this question is still far from being resolved, given the paucity of the fossil record and the new and more complicated evolutionary picture provided by the latest ancient DNA studies. Moreover, not all anatomical traits evolved at the same rate and polymorphisms probably occurred in different traits at different rates of occurrence.
Despite these uncertainties, the Donana site proves to be a crucial record for understanding human occupations in Europe during the Pleistocene. Our recent dating opens up a broader horizon of possibilities. For example, we may be looking at the remains of very early Neanderthal hominids or their more directly related ancestors, Homo heidelbergensis.
Authors: Eduardo Mayoral Alfaro, Catedratico de Paleontologia, Universidad de Huelva; Ana Santos, Assistant lecturer, Universidad de Oviedo; Antonio Rodriguez Ramirez, profesor titular del departamento de Geodinamica y Paleontologia, Universidad de Huelva; Asier Gomez-Olivencia, Paleontologist. Ramon y Cajal Research Fellow at the Department of Geology, Universidad del Pais Vasco / Euskal Herriko Unibertsitatea; Ignacio Diaz-Martinez, Instituto de Investigacion en Paleobiologia y Geologia, Universidad Nacional de Rio Negro; Jeremy Duveau, Chercheur associe, Museum national d’histoire naturelle (MNHN); Jorge Rivera Silva, Doctor en Ciencias Fisicas. Tecnico del Servicio de Radioisotopos, Centro de Investigacion CITIUS, Universidad de Sevilla; Juan Antonio Morales, Catedratico de Estratigrafia, Universidad de Huelva, and Ricardo Diaz-Delgado, Laboratorio de SIG y Teledeteccion (LAST-EBD), Estacion Biologica de Donana (EBD-CSIC)
This article is republished from The Conversation under a Creative Commons license. Read the original article.
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