Hostname: page-component-78c5997874-8bhkd Total loading time: 0 Render date: 2024-11-05T10:42:14.656Z Has data issue: false hasContentIssue false

Correction to Redfern et al. (2017) ‘Written in Bone’: New Discoveries about the Lives of Roman Londoners, Britannia 48, 253–77

Published online by Cambridge University Press:  28 September 2023

Rebecca Redfern
Affiliation:
Museum of London/University of Newcastle upon Tyne [email protected]
Kyriaki Anastasiadou
Affiliation:
Marina Soares Da Silva
Affiliation:
Rights & Permissions [Opens in a new window]

Abstract

In 2017, ancient DNA analysis of the Harper Road burial from Southwark (London) found that the individual had male chromosomes. Now analysis has discovered that the individual had female chromosomes, data which match the osteological estimation of sex and the interpretation of the grave-goods.

Type
Shorter Contributions
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Society for the Promotion of Roman Studies

INTRODUCTION

The Harper Road burial (HR79) is one of the few very early Roman inhumations from London (a.d. 50–70), and is unique in the area for the range of local and imported grave-goods accompanying the burial, including a British torc and Claudio-Neronian pottery.Footnote 1 In 2017, Redfern and colleagues undertook analysis of the individual and grave-goods, and part of that work involved ancient DNA (aDNA) analysis of the human remains using a permanent molar tooth.Footnote 2 The osteological analysis estimated the skeleton's sex to be female, and examination of the grave-goods also suggested that many of the objects were more likely to belong to the burial of a woman. In contrast, the aDNA analysis concluded that the person's chromosomes were male (XY), and the burial was interpreted to be that of a person who identified as a woman. More recently, using those published data, Power (Reference Power2020) has used it to explore how intersex and non-binary burials are identified and interpreted in the Roman world. As part of wider work for a new museum display about prehistoric London, we undertook further aDNA extraction, and used the most current bioinformatic methods to research the individual's genomic information.Footnote 3

MATERIALS AND METHODS

Ninety milligrams of bone powder were drilled from the petrous portion of the left temporal bone of the Harper Road skeleton following the minimally invasive method of Sirak et al. (Reference Sirak, Fernandes, Cheronet, Novak, Gamarra, Balassa, Bernert, Cséki, Dani, Zsolt Gallina, Kocsis-Buruzs, Kővári, László, Pap, Patay, Petkes, Szenthe, Szeniczey, Hajdu and Pinhasi2017). Established ancient DNA techniquesFootnote 4 were applied to the bone powder for the preparation of sequencing libraries in the specialised ancient DNA cleanroom facility at The Francis Crick Institute. DNA extraction and single stranded library preparation was performed on automated Agilent Bravo Workstations following standard protocols.Footnote 5 The libraries were amplified with unique double index combinations and screened for endogenous DNA on the HiSeq4000 platform.

Downstream analysis was carried out through the nf-core/eager v.2.3 pipeline.Footnote 6 Mainly, a 35bp cutoff was set before alignment against the hs37d5 assembly in BWA.Footnote 7 Duplicates were removed via DedupFootnote 8 and DNA damage was estimated with DamageProfiler.Footnote 9 Genetic (karyotypic) sex was estimated using a previously published approach, restricting to sequences with a mapping quality of at least 30.Footnote 10

RESULTS

Results of shallow sequencing of the Harper Road aDNA library are presented in table 1, with the number of sequences generated which aligned to the human genome being 127,000, which exceeds the 100,000 suggested by Skoglund and colleaguesFootnote 11 needed for a robust identification. Endogenous content (percentage of sequences aligning to the human genome rather than environmental contaminants) was moderate (21.81 per cent). A high proportion of human sequences (25.70 per cent) showed patterns of C to T damage characteristic of ancient DNA, consistent with authentic ancient DNA.

TABLE 1 results of a shallow next generation shotgun sequencing run of the harper road (hr79) ancient dna library.

Genetic (karyotypic) sex was estimated based on ratios of DNA reads aligning to the X and Y sex chromosomes. Assessments of the sequencing data indicated that the Harper Road skeleton carried two X-chromosomes and was therefore from a female (fig. 1). In the shallow screening data 4,773 sequencing reads aligned to the X-chromosome and just 3 to the Y-chromosome. Given that degradation in the form of cytosine deamination was observed, it is hard to imagine this result being due to female contamination of a male individual, but to confirm this further we restricted to sequences with clear evidence of cytosine deamination and a PMD score of at least 1Footnote 12 and observed 1,426 alignments to chromosome X but none to chromosome Y. The presence of a Y chromosome can therefore be excluded.

FIG. 1. Results of genetic (karyotypic) sex estimation for ancient individuals analysed in the Ancient Genomics Laboratory at the Francis Crick Institute, including the Harper Road burial (HR 79).

DISCUSSION AND CONCLUSIONS

Our analysis of DNA from the Harper Road skeleton conflicts with the result presented by Redfern and colleagues,Footnote 13 whose DNA analysis suggested that the skeleton came from a male (XY karyotype) individual. We used different methods and there could be various reasons why our results differ. The method of sex estimation employed by Redfern and colleaguesFootnote 14 used targeted DNA hybridisation enrichment to retrieve sequences of particular genes on the Y-chromosome, whereas our approach was more comprehensive in examining reads aligning to all parts of the X or Y-chromosomes,Footnote 15 allowing for correction for the small number of spurious alignments to the Y chromosome that are often observed. The approach we use here is well established and is the standard method of estimating genetic sex in ancient samples. Therefore, the female sex estimate given here is more robust and should supersede the male estimate previously published.Footnote 16 The sequencing data from this individual is freely available at the European Nucleotide Archive: ENA Accession: PRJEB65282 (Sample number ERS16280561).

ACKNOWLEDGEMENTS

We would like to thank the Museum of London for approving sampling of the Harper Road skeleton. As the sampling took place in 2020 during Covid-19 restrictions, we are grateful to Luisa Duarte for helping us access and replace the human remains in their display case, and to other MoL colleagues who organised our visit to London Wall. We are also grateful to help from the Advanced Sequencing STP of the Francis Crick Institute, and to the Poinar Lab (McMaster University, Canada) for their support and goodwill.

Footnotes

3 This was wide ranging and included, amongst others, appearance (e.g. hair colour) and genetic population group (haplotype). This work is ongoing and will be published elsewhere (Booth and Redfern pers. comm. 2023).

References

BIBLIOGRAPHY

Cotton, J. 2008: ‘Harper Road, Southwark: an early Roman burial revisited’, in Clark, J., Cotton, J., Hall, J., Sherris, R. and Swain, H. (eds), Londinium and Beyond. Essays on Roman London and its Hinterland for Harvey Sheldon, Council for British Archaeology Research Report 156, York, 151–61.Google Scholar
Gansauge, M.T., Aximu-Petri, A., Nagel, S., and Meyer, M. 2020: ‘Manual and automated preparation of single-stranded DNA libraries for the sequencing of DNA from ancient biological remains and other sources of highly degraded DNA’, Nature Protocols 15.8, 2279–300.CrossRefGoogle ScholarPubMed
Li, H., and Durbin, R. 2009: ‘Fast and accurate short read alignment with Burrows–Wheeler transform’, Bioinformatics 25.14, 1754–60.CrossRefGoogle ScholarPubMed
Neukamm, J., Peltzer, A., and Nieselt, K. 2021: ‘DamageProfiler: fast damage pattern calculation for ancient DNA’, Bioinformatics 37, 3652–3.CrossRefGoogle ScholarPubMed
Peltzer, A., Jäger, G., Herbig, A., Seitz, A., Kniep, C., Krause, J., and Nieselt, K. 2016: ‘EAGER: efficient ancient genome reconstruction’, Genome Biology 17, 60.CrossRefGoogle ScholarPubMed
Power, M. 2020: ‘Non-binary and intersex visibility and erasure in Roman archaeology’, Theoretical Roman Archaeology Journal 3.1, 11.CrossRefGoogle Scholar
Redfern, R.C., Marshall, M., Booth, T., Silva, M., Anastasiadou, K., Gilardet, A., Kyriacou, M., and Skoglund, P. 2021: ‘Powerful Women in Late Iron Age London: The Harper Road burial’, Museum of London Discovery blog. https://www.museumoflondon.org.uk/discover/powerful-women-late-iron-age-london-harper-road-burial [accessed 2 February 2023].Google Scholar
Redfern, R.C., Marshall, M., Eaton, C., and Poinar, H.N. 2017: ‘“Written in Bone”: new discoveries about the lives of Roman Londoners’, Britannia 48, 253–77.CrossRefGoogle Scholar
Rohland, N., Glocke, I., Aximu-Petri, A., and Meyer, M. 2018: ‘Extraction of highly degraded DNA from ancient bones, teeth and sediments for high-throughput sequencing’, Nature Protocols 13.11, 2447–61.CrossRefGoogle ScholarPubMed
Sirak, K.A., Fernandes, D.M., Cheronet, O., Novak, M., Gamarra, B., Balassa, T., Bernert, Z., Cséki, A., Dani, J., Zsolt Gallina, J., Kocsis-Buruzs, G., Kővári, I., László, O., Pap, I., Patay, R., Petkes, Z., Szenthe, G., Szeniczey, T., Hajdu, T., and Pinhasi, R. 2017: ‘A minimally-invasive method for sampling human petrous bones from the cranial base for ancient DNA analysis’, BioTechniques 62.6, 283–9.CrossRefGoogle ScholarPubMed
Skoglund, P., Storå, J., Götherström, A., and Jakobsson, M. 2013: ‘Accurate sex identification of ancient human remains using DNA shotgun sequencing’, Journal of Archaeological Science 40.12, 4477–82.CrossRefGoogle Scholar
Yates, J.A.F., Lamnidis, T.C., Borry, M., Andrades Valtueña, A., Fagernäs, Z., Clayton, S., Garcia, M.U., Neukamm, J. and Peltzer, A. 2021: ‘Reproducible, portable, and efficient ancient genome reconstruction with nf-core/eager’, PeerJ 9, e10947, https://doi.org/10.7717/peerj.10947Google Scholar
Figure 0

TABLE 1 results of a shallow next generation shotgun sequencing run of the harper road (hr79) ancient dna library.

Figure 1

FIG. 1. Results of genetic (karyotypic) sex estimation for ancient individuals analysed in the Ancient Genomics Laboratory at the Francis Crick Institute, including the Harper Road burial (HR 79).