For the first time, a Nobel Prize recognized the field of anthropology, the study of humanity. Svante Pääbo, a pioneer in the study of ancient DNA, or aDNA, was awarded the 2022 prize in physiology or medicine^[1] for his breathtaking achievements sequencing DNA extracted from ancient skeletal remains and reconstructing early humans’ genomes – that is, all the genetic information contained in one organism.

His accomplishment was once only the stuff of Jurassic Park-style science fiction. But Pääbo and many colleagues, working in large multidisciplinary teams, pieced together the genomes^[2] of our distant cousins, the famous Neanderthals and the more elusive Denisovans, whose existence was not even known until their DNA was sequenced^[3] from a tiny pinky bone of a child buried in a cave in Siberia^[4]. Thanks to interbreeding with and among^[5] these early humans, their genetic traces live on in many of us today^[6], shaping our bodies and our disease vulnerabilities – for example, to COVID-19^[7].

The world has learned a startling amount about our human origins^[8] in the last dozen years since Pääbo and teammates’ groundbreaking discoveries. And the field of paleogenomics has rapidly expanded. Scientists have now sequenced mammoths that lived a million years ago^[9]. Ancient DNA has addressed questions ranging from the origins of the first Americans^[10] to the domestication of horses^[11] and dogs^[12], the spread of livestock herding^[13] and our bodies’ adaptations – or lack thereof – to drinking milk^[14]. Ancient DNA can even shed light on social questions^[15] of marriage, kinship and mobility. Researchers can now sequence DNA not only from the remains of ancient humans, animals and plants, but even from their traces left in cave dirt^[16].

Alongside this growth in research, people have been grappling with concerns about the speed^[17] with which skeletal collections around the world have been sampled for aDNA, leading to broader conversations about how research should be done^[18]. Who should conduct it? Who may benefit from or be harmed by it, and who gives consent? And how can the field become more equitable? As an archaeologist^[19] who partners with geneticists to study ancient African history^[20], I see both challenges and opportunities ahead.

Building a better discipline

One positive sign: Interdisciplinary researchers are working to establish basic common guidelines^[21] for research design and conduct.

In North America, scholars have worked to address inequities by designing programs that train future generations of Indigenous geneticists^[22]. These are now expanding to other historically underrepresented communities in the world. In museums, best practices for sampling^[23] are being put into place. They aim to minimize destruction to ancestral remains, while gleaning the most new information possible.

But there is a long way to go to develop and enforce community consultation, ethical sampling and data sharing policies, especially in more resource-constrained parts of the world. The divide between the developing world and rich industrialized nations^[24] is especially stark when looking at where ancient DNA labs^[25], funding and research publications are concentrated. It leaves fewer opportunities for scholars from parts of Asia, Africa and the Americas to be trained in the field and lead research.

The field faces structural challenges, such as the relative lack of funding for archaeology and cultural heritage protection in lower income countries, worsened by a long history of extractive research practices^[26] and looming climate change and site destruction^[27]. These issues strengthen the regional bias in paleogenomics, which helps explain why some parts of the world – such as Europe – are so well-studied, while Africa – the cradle of humankind^[28] and the most genetically diverse continent^[29] – is relatively understudied, with shortfalls in archaeology^[30], genomics^[31] and ancient DNA^[32].

Making public education a priority

How paleogenomic findings are interpreted and communicated to the public raises other concerns^[33]. Consumers are regularly bombarded with advertisements for personal ancestry testing, implying that genetics and identity are synonymous^[34]. But lived experiences and decades of scholarship show that biological ancestry and socially defined identities do not map so easily onto one another^[35].

I’d argue that scholars studying aDNA have a responsibility to work with educational institutions, like schools and museums, to communicate the meaning of their research to the public. This is particularly important because people with political agendas – even elected officials^[36] – try to manipulate findings^[37].

For example, white supremacists have erroneously equated lactose tolerance with whiteness^[38]. It’s a falsehood that would be laughable to many livestock herders from Africa, one of the multiple centers of origin^[39] for genetic traits enabling people to digest milk.

References

1. ^{^} prize in physiology or medicine (www.nobelprize.org)
2. ^{^} pieced together the genomes (theconversation.com)
3. ^{^} DNA was sequenced (www.nytimes.com)
4. ^{^} buried in a cave in Siberia (theconversation.com)
5. ^{^} and among (theconversation.com)
6. ^{^} live on in many of us today (theconversation.com)
7. ^{^} COVID-19 (doi.org)
8. ^{^} our human origins (theconversation.com)
9. ^{^} mammoths that lived a million years ago (theconversation.com)
10. ^{^} first Americans (www.sapiens.org)
11. ^{^} horses (www.smithsonianmag.com)
12. ^{^} dogs (bigthink.com)
13. ^{^} livestock herding (theconversation.com)
14. ^{^} drinking milk (www.newscientist.com)
15. ^{^} social questions (doi.org)
16. ^{^} traces left in cave dirt (theconversation.com)
17. ^{^} concerns about the speed (theconversation.com)
18. ^{^} how research should be done (theconversation.com)
19. ^{^} archaeologist (scholar.google.com)
20. ^{^} ancient African history (theconversation.com)
21. ^{^} basic common guidelines (theconversation.com)
22. ^{^} train future generations of Indigenous geneticists (www.singconsortium.org)
23. ^{^} best practices for sampling (doi.org)
24. ^{^} between the developing world and rich industrialized nations (doi.org)
25. ^{^} ancient DNA labs (www.google.com)
26. ^{^} long history of extractive research practices (theconversation.com)
27. ^{^} climate change and site destruction (doi.org)
28. ^{^} cradle of humankind (theconversation.com)
29. ^{^} most genetically diverse continent (genomebiology.biomedcentral.com)
30. ^{^} archaeology (www.theguardian.com)
31. ^{^} genomics (www.nature.com)
32. ^{^} ancient DNA (www.discovermagazine.com)
33. ^{^} raises other concerns (www.nature.com)
34. ^{^} implying that genetics and identity are synonymous (blogs.ancestry.com)
35. ^{^} do not map so easily onto one another (theconversation.com)
36. ^{^} even elected officials (www.smithsonianmag.com)
37. ^{^} try to manipulate findings (theconversation.com)
38. ^{^} erroneously equated lactose tolerance with whiteness (www.nytimes.com)
39. ^{^} centers of origin (www.the-scientist.com)
40. ^{^} CC BY-ND (creativecommons.org)
41. ^{^} specialists in different disciplines should work together (theconversation.com)
42. ^{^} backlash (www.nature.com)
43. ^{^} where ancestral skeletal collections come from and should rest (www.sapiens.org)