Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases

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Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases. / Fagernäs, Zandra; Troché, Gaudry; Olsen, Jesper V.; Welker, Frido.

In: Journal of Proteomics, Vol. 298, 105143, 2024.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Fagernäs, Z, Troché, G, Olsen, JV & Welker, F 2024, 'Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases', Journal of Proteomics, vol. 298, 105143. https://doi.org/10.1016/j.jprot.2024.105143

APA

Fagernäs, Z., Troché, G., Olsen, J. V., & Welker, F. (2024). Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases. Journal of Proteomics, 298, [105143]. https://doi.org/10.1016/j.jprot.2024.105143

Vancouver

Fagernäs Z, Troché G, Olsen JV, Welker F. Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases. Journal of Proteomics. 2024;298. 105143. https://doi.org/10.1016/j.jprot.2024.105143

Author

Fagernäs, Zandra ; Troché, Gaudry ; Olsen, Jesper V. ; Welker, Frido. / Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases. In: Journal of Proteomics. 2024 ; Vol. 298.

Bibtex

@article{5bf503b533a14980a4517118aa95b5c2,
title = "Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases",
abstract = "An increasing number of studies utilise the recovery of ancient skeletal proteomes for phylogenetic and evolutionary analysis. Although these studies manage to extract and analyse ancient peptides, the recovered proteomes are generally small in size and with low protein sequence coverage. We expand on previous observations which have shown that the parallel digestion and analysis of Pleistocene skeletal proteomes increases overall proteome size and protein sequence coverage. Furthermore, we demonstrate that the consecutive digestion of a skeletal proteome using two proteases, particularly the combination of Glu-C or chymotrypsin followed by trypsin digestion, enables the recovery of alternative proteome components not reachable through trypsin digestion alone. The proteomes preserved in Pleistocene skeletal specimens are larger than previously anticipated, but unlocking this protein sequence information requires adaptation of extraction and protein digestion protocols. The sequential utilisation of several proteases is, in this regard, a promising avenue for the study of highly degraded but unique hominin proteomes for phylogenetic purposes. SIGNIFICANCE: Palaeoproteomic analysis of archaeological materials, such as hominin skeletal elements, show great promise in studying past organisms and evolutionary relationships. However, as most proteomic methods are inherently destructive, it is essential to aim to recover as much information as possible from every sample. Currently, digestion with trypsin is the standard approach in most palaeoproteomic studies. We find that parallel or consecutive digestion with multiple proteases can improve proteome size and coverage for both Holocene and Pleistocene bone specimens. This allows for recovery of more proteomic data from a sample and maximises the chance of recovering phylogenetically relevant information.",
author = "Zandra Fagern{\"a}s and Gaudry Troch{\'e} and Olsen, {Jesper V.} and Frido Welker",
note = "Copyright {\textcopyright} 2023. Published by Elsevier B.V.",
year = "2024",
doi = "10.1016/j.jprot.2024.105143",
language = "English",
volume = "298",
journal = "Journal of Proteomics",
issn = "1874-3919",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Digging deeper into ancient skeletal proteomes through consecutive digestion with multiple proteases

AU - Fagernäs, Zandra

AU - Troché, Gaudry

AU - Olsen, Jesper V.

AU - Welker, Frido

N1 - Copyright © 2023. Published by Elsevier B.V.

PY - 2024

Y1 - 2024

N2 - An increasing number of studies utilise the recovery of ancient skeletal proteomes for phylogenetic and evolutionary analysis. Although these studies manage to extract and analyse ancient peptides, the recovered proteomes are generally small in size and with low protein sequence coverage. We expand on previous observations which have shown that the parallel digestion and analysis of Pleistocene skeletal proteomes increases overall proteome size and protein sequence coverage. Furthermore, we demonstrate that the consecutive digestion of a skeletal proteome using two proteases, particularly the combination of Glu-C or chymotrypsin followed by trypsin digestion, enables the recovery of alternative proteome components not reachable through trypsin digestion alone. The proteomes preserved in Pleistocene skeletal specimens are larger than previously anticipated, but unlocking this protein sequence information requires adaptation of extraction and protein digestion protocols. The sequential utilisation of several proteases is, in this regard, a promising avenue for the study of highly degraded but unique hominin proteomes for phylogenetic purposes. SIGNIFICANCE: Palaeoproteomic analysis of archaeological materials, such as hominin skeletal elements, show great promise in studying past organisms and evolutionary relationships. However, as most proteomic methods are inherently destructive, it is essential to aim to recover as much information as possible from every sample. Currently, digestion with trypsin is the standard approach in most palaeoproteomic studies. We find that parallel or consecutive digestion with multiple proteases can improve proteome size and coverage for both Holocene and Pleistocene bone specimens. This allows for recovery of more proteomic data from a sample and maximises the chance of recovering phylogenetically relevant information.

AB - An increasing number of studies utilise the recovery of ancient skeletal proteomes for phylogenetic and evolutionary analysis. Although these studies manage to extract and analyse ancient peptides, the recovered proteomes are generally small in size and with low protein sequence coverage. We expand on previous observations which have shown that the parallel digestion and analysis of Pleistocene skeletal proteomes increases overall proteome size and protein sequence coverage. Furthermore, we demonstrate that the consecutive digestion of a skeletal proteome using two proteases, particularly the combination of Glu-C or chymotrypsin followed by trypsin digestion, enables the recovery of alternative proteome components not reachable through trypsin digestion alone. The proteomes preserved in Pleistocene skeletal specimens are larger than previously anticipated, but unlocking this protein sequence information requires adaptation of extraction and protein digestion protocols. The sequential utilisation of several proteases is, in this regard, a promising avenue for the study of highly degraded but unique hominin proteomes for phylogenetic purposes. SIGNIFICANCE: Palaeoproteomic analysis of archaeological materials, such as hominin skeletal elements, show great promise in studying past organisms and evolutionary relationships. However, as most proteomic methods are inherently destructive, it is essential to aim to recover as much information as possible from every sample. Currently, digestion with trypsin is the standard approach in most palaeoproteomic studies. We find that parallel or consecutive digestion with multiple proteases can improve proteome size and coverage for both Holocene and Pleistocene bone specimens. This allows for recovery of more proteomic data from a sample and maximises the chance of recovering phylogenetically relevant information.

U2 - 10.1016/j.jprot.2024.105143

DO - 10.1016/j.jprot.2024.105143

M3 - Journal article

C2 - 38423353

VL - 298

JO - Journal of Proteomics

JF - Journal of Proteomics

SN - 1874-3919

M1 - 105143

ER -

ID: 384485678