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Main Authors: Zhao, Wan-Qian, Zhao, Li-Juan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.04427
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author Zhao, Wan-Qian
Zhao, Li-Juan
author_facet Zhao, Wan-Qian
Zhao, Li-Juan
contents Deamination has historically been important for authenticating ancient biomolecules. However, expanding paleogenomic datasets indicate that damage patterns are more influenced by burial hydrology and microstructural context than by molecular age or ancestry. Fossils interact with their environments differently: some form closed, water-restricted compartments that preserve minimally damaged endogenous biomolecules, whereas others serve as open molecular reservoirs in which infiltrated environmental biomolecules undergo extensive deamination from repeated water exposure. Reliance on deamination alone can therefore suppress endogenous signals and complicate the interpretation of exogenous sequences. By introducing the molecular sedimentation model for fossil biomolecules, this Perspective outlines a source tracing framework that integrates fossil microstructure, ecological reference sets, and species-specific fragments to enable more reliable molecular inference across diverse depositional environments.
format Preprint
id arxiv_https___arxiv_org_abs_2512_04427
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sedimentary models of fossil biomolecules, principles and methodological improvements
Zhao, Wan-Qian
Zhao, Li-Juan
Populations and Evolution
Deamination has historically been important for authenticating ancient biomolecules. However, expanding paleogenomic datasets indicate that damage patterns are more influenced by burial hydrology and microstructural context than by molecular age or ancestry. Fossils interact with their environments differently: some form closed, water-restricted compartments that preserve minimally damaged endogenous biomolecules, whereas others serve as open molecular reservoirs in which infiltrated environmental biomolecules undergo extensive deamination from repeated water exposure. Reliance on deamination alone can therefore suppress endogenous signals and complicate the interpretation of exogenous sequences. By introducing the molecular sedimentation model for fossil biomolecules, this Perspective outlines a source tracing framework that integrates fossil microstructure, ecological reference sets, and species-specific fragments to enable more reliable molecular inference across diverse depositional environments.
title Sedimentary models of fossil biomolecules, principles and methodological improvements
topic Populations and Evolution
url https://arxiv.org/abs/2512.04427