Epigenomic Modifications in Modern and Ancient Genomes

Niiranen, Laura; Leciej, Dawid; Edlund, Hanna; Bernhardsson, Carolina; Fraser, Magdalena; Sánchez-Quinto, Federico; Herzig, Karl‐Heinz; Jakobsson, Mattias; Walkowiak, Jarosław; Thalmann, Olaf

doi:10.3390/genes13020178

Cited by 12 publications

(8 citation statements)

References 140 publications

(195 reference statements)

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“…Thus, in all cohorts, except Baqah_BA the number of CpG positions whose coverage allows for reliable reconstruction of aDNA methylation is larger than in these popular commercial arrays. A recent study claims that even shotgun coverage as low as 10x might suffice to reconstruct DNA methylation, using windows of up to 50 consecutive CpG positions ( 38 ). Using this estimate, we get that 75% of Caribbean_CER windows are amendable to reconstruction, and 1% of Baqah_BA ( Supplementary Table S2 ).…”

Section: Resultsmentioning

confidence: 99%

Reconstructing DNA methylation maps of ancient populations

Barouch,

Mathov,

Meshorer

et al. 2024

Nucleic Acids Research

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Studying premortem DNA methylation from ancient DNA (aDNA) provides a proxy for ancient gene activity patterns, and hence valuable information on evolutionary changes in gene regulation. Due to statistical limitations, current methods to reconstruct aDNA methylation maps are constrained to high-coverage shotgun samples, which comprise a small minority of available ancient samples. Most samples are sequenced using in-situ hybridization capture sequencing which targets a predefined set of genomic positions. Here, we develop methods to reconstruct aDNA methylation maps of samples that were not sequenced using high-coverage shotgun sequencing, by way of pooling together individuals to obtain a DNA methylation map that is characteristic of a population. We show that the resulting DNA methylation maps capture meaningful biological information and allow for the detection of differential methylation across populations. We offer guidelines on how to carry out comparative studies involving ancient populations, and how to control the rate of falsely discovered differentially methylated regions. The ability to reconstruct DNA methylation maps of past populations allows for the development of a whole new frontier in paleoepigenetic research, tracing DNA methylation changes throughout human history, using data from thousands of ancient samples.

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Section: Resultsmentioning

confidence: 99%

Reconstructing DNA methylation maps of ancient populations

Barouch,

Mathov,

Meshorer

et al. 2024

Nucleic Acids Research

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“…Isolation of ancient chromatin (a complex of DNA and proteins forming chromosomes) from preserved nervous tissues might enable investigation of epigenetic patterns of aDNA methylation [ 98 ]. These heritable changes in gene expression are phylogenetically informative molecular targets that elucidate evolutionary trajectories [ 99 ] and ecological adaptations [ 100 ] at the population level, as well as permitting the study of phenotype (e.g. age at death [ 101 ] and morphological characters [ 102 ]) of ancient individuals.…”

Section: Discussionmentioning

confidence: 99%

Human brains preserve in diverse environments for at least 12 000 years

Morton-Hayward,

Anderson,

Saupe

et al. 2024

Proc. R. Soc. B.

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The brain is thought to be among the first human organs to decompose after death. The discovery of brains preserved in the archaeological record is therefore regarded as unusual. Although mechanisms such as dehydration, freezing, saponification, and tanning are known to allow for the preservation of the brain on short time scales in association with other soft tissues (≲4000 years), discoveries of older brains, especially in the absence of other soft tissues, are rare. Here, we collated an archive of more than 4400 human brains preserved in the archaeological record across approximately 12 000 years, more than 1300 of which constitute the only soft tissue preserved amongst otherwise skeletonized remains. We found that brains of this type persist on time scales exceeding those preserved by other means, which suggests an unknown mechanism may be responsible for preservation particular to the central nervous system. The untapped archive of preserved ancient brains represents an opportunity for bioarchaeological studies of human evolution, health and disease.

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“…These analyses could be coupled with direct reconstruction of gene expression profiles from natural history specimens (e.g., Marmol‐Sanchez et al., 2023), which is now possible, thanks to the development of protocols for extracting RNA from preserved specimens (e.g., Speer et al., 2022). DNA methylation patterns have already been investigated in ancient and historical specimens (e.g., Gokhman et al., 2014; Gokhman et al., 2016; Hahn et al., 2020; Niiranen et al., 2022; Orlando et al., 2015; Pedersen et al., 2014; Rubi et al., 2020; Smith et al., 2014), indicating that this approach holds promise for unravelling the role of heritable epigenetic modifications in facilitating rapid adaptation to environmental shifts. However, the effects of sample age, preservation method, contamination and the sensitivity of epigenetic marks to the environment mean their feasibility will be dependent on the specimen type and preservation method (Hahn et al., 2020; Raxworthy & Smith, 2021).…”

Section: Applications Of Temporal Data In Invasion Biologymentioning

confidence: 99%

Temporal collections to study invasion biology

Kim,

Kreiner,

Hernández

et al. 2023

Molecular Ecology

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Biological invasions represent an extraordinary opportunity to study evolution. This is because accidental or deliberate species introductions have taken place for centuries across large geographical scales, frequently prompting rapid evolutionary transitions in invasive populations. Until recently, however, the utility of invasions as evolutionary experiments has been hampered by limited information on the makeup of populations that were part of earlier invasion stages. Now, developments in ancient and historical DNA technologies, as well as the quickening pace of digitization for millions of specimens that are housed in herbaria and museums globally, promise to help overcome this obstacle. In this review, we first introduce the types of temporal data that can be used to study invasions, highlighting the timescale captured by each approach and their respective limitations. We then discuss how ancient and historical specimens as well as data available from prior invasion studies can be used to answer questions on mechanisms of (mal)adaptation, rates of evolution, or community‐level changes during invasions. By bridging the gap between contemporary and historical invasive populations, temporal data can help us connect pattern to process in invasion science. These data will become increasingly important if invasions are to achieve their full potential as experiments of evolution in nature.

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Epigenomic Modifications in Modern and Ancient Genomes

Cited by 12 publications

References 140 publications

Reconstructing DNA methylation maps of ancient populations

Reconstructing DNA methylation maps of ancient populations

Human brains preserve in diverse environments for at least 12 000 years

Temporal collections to study invasion biology

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