Ancient DNA and paleoproteomic analysis on Roman Imperial-era individuals from Histria, Romania

Ancient DNA and paleoproteomic analysis on Roman Imperial-era individuals from Histria, Romania
Romania
2024


Ancient biomolecules have become an increasingly important part of archaeological investigations interested in understanding population movements and health. Despite their ability to elucidate historically-attested contexts of human mobility and interaction between different cultural groups, biomolecular techniques are still underutilized in certain historical and archaeological contexts. One such context is the Roman Imperial limes, or border zone, along the lower reaches of the Danube, which saw more than five hundred years of migration, conflict, and accommodation among a wide range of populations, from Mediterranean settlers to steppe pastoralists. In this region, more than a century of archaeological investigation has unearthed the remains of tens of thousands of Roman-era individuals. However, only a limited number of contexts have undergone biomolecular analyses. While these deceased humans may offer an untapped reservoir of biomolecular information, many were collected during a period when the standard precautions and protocols for ancient biomolecular research were not yet established. Because contamination is a major barrier for successfully recovering ancient DNA and proteins, conducting a pilot study to assess bimolecular preservation of a small representative dataset of human remains before embarking on a more extensive research program may prevent unnecessary sampling. This study applies ancient DNA and paleoproteomic techniques to human remains from a Roman-period cemetery at Histria, a site located just south of the Danube at the edge of the Roman province of Moesia Inferior. The individuals from whom we sampled dentin and dental calculus were excavated between the 1940s and 1980s and were housed at the Francisc J. Rainer Institute since. Our results suggest that both microbial and human ancient DNA is preserved in the dental calculus and dentin samples. We also successfully recovered sex-specific amelogenin peptides in tooth enamel from three individuals, including a juvenile. In conclusion, our results are encouraging, signifying the feasibility of future aDNA and paleoproteomic research for this skeletal collection. Our analyses also showcase how sex estimation with genomic and proteomic methods may contradict traditional osteological approaches. These findings not only offer deeper insights into the lives of these individuals but also show promise for the investigation of broader anthropological questions, such as the impact of Roman annexation in this region.