Age Estimation Based on Different Molecular Clocks in Several Tissues and a Multivariate Approach: an Explorative Study

Overview

Journal Int J Legal Med

Specialty Forensic Sciences

Date 2019 Apr 13

PMID 30976985

Citations 6

Authors

Julia Becker

Nina Sophia Mahlke

A Reckert

S B Eickhoff

S Ritz-Timme

Affiliations

Soon will be listed here.

Abstract

Several molecular modifications accumulate in the human organism with increasing age. Some of these "molecular clocks" in DNA and in proteins open up promising approaches for the development of methods for forensic age estimation. A natural limitation of these methods arises from the fact that the chronological age is determined only indirectly by analyzing defined molecular changes that occur during aging. These changes are not linked exclusively to the expired life span but may be influenced significantly by intrinsic and extrinsic factors in the complex process of individual aging. We tested the hypothesis that a combined use of different molecular clocks in different tissues results in more precise age estimates because this approach addresses the complex aging processes in a more comprehensive way. Two molecular clocks (accumulation of D-aspartic acid (D-Asp), accumulation of pentosidine (PEN)) in two different tissues (annulus fibrosus of intervertebral discs and elastic cartilage of the epiglottis) were analyzed in 95 cases, and uni- and multivariate models for age estimation were generated. The more parameters were included in the models for age estimation, the smaller the mean absolute errors (MAE) became. While the MAEs were 7.5-11.0 years in univariate models, a multivariate model based on the two protein clocks in the two tissues resulted in a MAE of 4.0 years. These results support our hypothesis. The tested approach of a combined analysis of different molecular clocks analyzed in different tissues opens up new possibilities in postmortem age estimation. In a next step, we will add the epigenetic clock (DNA methylation) to our protein clocks (PEN, D-Asp) and expand our set of tissues.

Citing Articles

Molecular age prediction using skull bone samples from individuals with and without signs of decomposition: a multivariate approach combining analysis of posttranslational protein modifications and DNA methylation.

Becker J, Buhren V, Schmelzer L, Reckert A, Eickhoff S, Ritz S Int J Legal Med. 2024; 139(1):157-174.

PMID: 39256256 PMC: 11732915. DOI: 10.1007/s00414-024-03314-z.

Molecular age estimation based on posttranslational protein modifications in bone: why the type of bone matters.

Konig L, Becker J, Reckert A, Ritz-Timme S Int J Legal Med. 2023; 137(2):437-443.

PMID: 36648544 PMC: 9902325. DOI: 10.1007/s00414-023-02948-9.

Analysis of C, C and Aspartic Acid Racemization in Teeth and Bones to Facilitate Identification of Unknown Human Remains: Outcomes of Practical Casework.

Teglind R, Dawidson I, Balkefors J, Alkass K Biomolecules. 2021; 11(11).

PMID: 34827653 PMC: 8615977. DOI: 10.3390/biom11111655.

Molecular clocks in ancient proteins: Do they reflect the age at death even after millennia?.

Mahlke N, Renhart S, Talaa D, Reckert A, Ritz-Timme S Int J Legal Med. 2021; 135(4):1225-1233.

PMID: 33595689 PMC: 8205898. DOI: 10.1007/s00414-021-02522-1.

Postmortem age estimation via DNA methylation analysis in buccal swabs from corpses in different stages of decomposition-a "proof of principle" study.

Koop B, Mayer F, Gunduz T, Blum J, Becker J, Schaffrath J Int J Legal Med. 2020; 135(1):167-173.

PMID: 32632799 PMC: 7782454. DOI: 10.1007/s00414-020-02360-7.

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