Human Bone Proteomes Before and After Decomposition: Investigating the Effects of Biological Variation and Taphonomic Alteration on Bone Protein Profiles and the Implications for Forensic Proteomics

Overview

Journal J Proteome Res

Publisher American Chemical Society

Specialty Biochemistry

Date 2021 Mar 8

PMID 33683123

Citations 15

Authors

Hayley L Mickleburgh

Edward C Schwalbe

Andrea Bonicelli

Haruka Mizukami

Federica Sellitto

Sefora Starace

Daniel J Wescott

David O Carter

Noemi Procopio

Affiliations

Soon will be listed here.

Abstract

Bone proteomic studies using animal proxies and skeletonized human remains have delivered encouraging results in the search for potential biomarkers for precise and accurate post-mortem interval (PMI) and the age-at-death (AAD) estimation in medico-legal investigations. The development of forensic proteomics for PMI and AAD estimation is in critical need of research on human remains throughout decomposition, as currently the effects of both inter-individual biological differences and taphonomic alteration on the survival of human bone protein profiles are unclear. This study investigated the human bone proteome in four human body donors studied throughout decomposition outdoors. The effects of ageing phenomena ( and post-mortem) and intrinsic and extrinsic variables on the variety and abundancy of the bone proteome were assessed. Results indicate that taphonomic and biological variables play a significant role in the survival of proteins in bone. Our findings suggest that inter-individual and inter-skeletal differences in bone mineral density (BMD) are important variables affecting the survival of proteins. Specific proteins survive better within the mineral matrix due to their mineral-binding properties. The mineral matrix likely also protects these proteins by restricting the movement of decomposer microbes. New potential biomarkers for PMI estimation and AAD estimation were identified. Future development of forensic bone proteomics should include standard measurement of BMD and target a combination of different biomarkers.

Citing Articles

Human Decomposition and Time Since Death: Persistent Challenges and Future Directions of Postmortem Interval Estimation in Forensic Anthropology.

Weisensee K, Atwell M Am J Biol Anthropol. 2025; 186 Suppl 78:e70011.

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"Omics" and Postmortem Interval Estimation: A Systematic Review.

Secco L, Palumbi S, Padalino P, Grosso E, Perilli M, Casonato M Int J Mol Sci. 2025; 26(3).

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Enhancing late postmortem interval prediction: a pilot study integrating proteomics and machine learning to distinguish human bone remains over 15 years.

Garces-Parra C, Saldivia P, Hernandez M, Uribe E, Roman J, Torrejon M Biol Res. 2024; 57(1):75.

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Bone Proteomics Method Optimization for Forensic Investigations.

Gent L, Chiappetta M, Hesketh S, Palmowski P, Porter A, Bonicelli A J Proteome Res. 2024; 23(5):1844-1858.

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Volabolomic Fingerprinting for Post-Mortem Interval Estimation: A Novel Physiological Approach.

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