Recent advances in ancient DNA research and their implications for archaeobotany

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Recent advances in ancient DNA research and their implications for archaeobotany. / Brown, Terence A.; Cappellini, Enrico; Kistler, Logan; Lister, Diane L.; Oliveira, Hugo R.; Wales, Nathan; Schlumbaum, Angela.

In: Vegetation History and Archaeobotany, Vol. 24, No. 1, 2015, p. 207-214.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Brown, TA, Cappellini, E, Kistler, L, Lister, DL, Oliveira, HR, Wales, N & Schlumbaum, A 2015, 'Recent advances in ancient DNA research and their implications for archaeobotany', Vegetation History and Archaeobotany, vol. 24, no. 1, pp. 207-214. https://doi.org/10.1007/s00334-014-0489-4

APA

Brown, T. A., Cappellini, E., Kistler, L., Lister, D. L., Oliveira, H. R., Wales, N., & Schlumbaum, A. (2015). Recent advances in ancient DNA research and their implications for archaeobotany. Vegetation History and Archaeobotany, 24(1), 207-214. https://doi.org/10.1007/s00334-014-0489-4

Vancouver

Brown TA, Cappellini E, Kistler L, Lister DL, Oliveira HR, Wales N et al. Recent advances in ancient DNA research and their implications for archaeobotany. Vegetation History and Archaeobotany. 2015;24(1):207-214. https://doi.org/10.1007/s00334-014-0489-4

Author

Brown, Terence A. ; Cappellini, Enrico ; Kistler, Logan ; Lister, Diane L. ; Oliveira, Hugo R. ; Wales, Nathan ; Schlumbaum, Angela. / Recent advances in ancient DNA research and their implications for archaeobotany. In: Vegetation History and Archaeobotany. 2015 ; Vol. 24, No. 1. pp. 207-214.

Bibtex

@article{c90d565af053453d843dc56f36cfac40,
title = "Recent advances in ancient DNA research and their implications for archaeobotany",
abstract = "The scope and ambition of biomolecular archaeology is undergoing rapid change due to the development of new {\textquoteleft}next generation{\textquoteright} sequencing (NGS) methods for analysis of ancient DNA in archaeological specimens. These methods have not yet been applied extensively to archaeobotanical material but their utility has been demonstrated with desiccated, waterlogged and charred remains. The future use of NGS is likely to open up new areas of investigation that have been difficult or impossible with the traditional approach to aDNA sequencing. Species identification should become more routine with archaeobotanical explants, not just with charred grain but with most if not all species likely to be encountered in an archaeobotanical setting. Distinctions between different subspecies groups such as cereal landraces will also be possible in the near future. Phenotypic characterization, in which aDNA sequencing is used to infer the biological characteristics of an archaeological specimen, will become possible, improving our understanding of traits such as flowering behaviour of cereals, and when combined with studies of preserved RNA and protein will enable complex phenotypes such as environmental tolerance and nutritional quality to be assessed. The sequencing of entire ancient plant genomes is also likely to have significant impact. As with past studies of ancient plant DNA, realization of the new potential provided by NGS will require productive collaboration between archaeologists and geneticists within the archaeobotanical research community.",
keywords = "Ancient DNA, Charred plant remains, Desiccated plant remains, Genomes, Next generation DNA sequencing, Phenotype characterization, Species identification, Waterlogged plant remains",
author = "Brown, {Terence A.} and Enrico Cappellini and Logan Kistler and Lister, {Diane L.} and Oliveira, {Hugo R.} and Nathan Wales and Angela Schlumbaum",
year = "2015",
doi = "10.1007/s00334-014-0489-4",
language = "English",
volume = "24",
pages = "207--214",
journal = "Vegetation History and Archaeobotany",
issn = "0939-6314",
publisher = "Springer",
number = "1",

}

RIS

TY - JOUR

T1 - Recent advances in ancient DNA research and their implications for archaeobotany

AU - Brown, Terence A.

AU - Cappellini, Enrico

AU - Kistler, Logan

AU - Lister, Diane L.

AU - Oliveira, Hugo R.

AU - Wales, Nathan

AU - Schlumbaum, Angela

PY - 2015

Y1 - 2015

N2 - The scope and ambition of biomolecular archaeology is undergoing rapid change due to the development of new ‘next generation’ sequencing (NGS) methods for analysis of ancient DNA in archaeological specimens. These methods have not yet been applied extensively to archaeobotanical material but their utility has been demonstrated with desiccated, waterlogged and charred remains. The future use of NGS is likely to open up new areas of investigation that have been difficult or impossible with the traditional approach to aDNA sequencing. Species identification should become more routine with archaeobotanical explants, not just with charred grain but with most if not all species likely to be encountered in an archaeobotanical setting. Distinctions between different subspecies groups such as cereal landraces will also be possible in the near future. Phenotypic characterization, in which aDNA sequencing is used to infer the biological characteristics of an archaeological specimen, will become possible, improving our understanding of traits such as flowering behaviour of cereals, and when combined with studies of preserved RNA and protein will enable complex phenotypes such as environmental tolerance and nutritional quality to be assessed. The sequencing of entire ancient plant genomes is also likely to have significant impact. As with past studies of ancient plant DNA, realization of the new potential provided by NGS will require productive collaboration between archaeologists and geneticists within the archaeobotanical research community.

AB - The scope and ambition of biomolecular archaeology is undergoing rapid change due to the development of new ‘next generation’ sequencing (NGS) methods for analysis of ancient DNA in archaeological specimens. These methods have not yet been applied extensively to archaeobotanical material but their utility has been demonstrated with desiccated, waterlogged and charred remains. The future use of NGS is likely to open up new areas of investigation that have been difficult or impossible with the traditional approach to aDNA sequencing. Species identification should become more routine with archaeobotanical explants, not just with charred grain but with most if not all species likely to be encountered in an archaeobotanical setting. Distinctions between different subspecies groups such as cereal landraces will also be possible in the near future. Phenotypic characterization, in which aDNA sequencing is used to infer the biological characteristics of an archaeological specimen, will become possible, improving our understanding of traits such as flowering behaviour of cereals, and when combined with studies of preserved RNA and protein will enable complex phenotypes such as environmental tolerance and nutritional quality to be assessed. The sequencing of entire ancient plant genomes is also likely to have significant impact. As with past studies of ancient plant DNA, realization of the new potential provided by NGS will require productive collaboration between archaeologists and geneticists within the archaeobotanical research community.

KW - Ancient DNA

KW - Charred plant remains

KW - Desiccated plant remains

KW - Genomes

KW - Next generation DNA sequencing

KW - Phenotype characterization

KW - Species identification

KW - Waterlogged plant remains

U2 - 10.1007/s00334-014-0489-4

DO - 10.1007/s00334-014-0489-4

M3 - Journal article

VL - 24

SP - 207

EP - 214

JO - Vegetation History and Archaeobotany

JF - Vegetation History and Archaeobotany

SN - 0939-6314

IS - 1

ER -

ID: 127261312