<p>Transcriptomic profiling of peripheral blood offers a promising, non-invasive approach for disease diagnosis and monitoring. However, its clinical translation is hindered by limited knowledge of the natural temporal variation. Here, we present a comprehensive reference map of longitudinal transcriptomic variability, based on RNA-sequencing of 333 healthy individuals sampled at three time points over six months. We find that 85% of genes and 99% of transcripts exhibit greater intra-individual than inter-individual variation, primarily driven by dynamic regulation of housekeeping pathways. In contrast, immune-related transcripts –particularly those linked to T and B cell activity– are strikingly stable over time. Gene expression levels drive inter-individual differences, while splicing variation contributes more to intra-individual fluctuation. In an independent twin cohort (148 monozygotic, 166 dizygotic), genes with high inter-individual variability show greater heritability, suggesting genetic control of steady-state expression. By integrating extensive clinical and environmental data, we trace temporal expression changes to genetic, compositional, and external factors, and identify robust seasonal and sex-specific signatures. These findings were validated in a third, cross-sectional cohort of 3,480 individuals. The observed temporal variation patterns have important implications for cohort-based transcriptomic analyses, as they may limit discovery and reproducibility of expression quantitative trait loci and increase the risk of spurious associations in cross-sectional studies. This resource provides a critical baseline for distinguishing disease-associated transcriptomic changes from normal physiological variation, advancing the reliability of blood-based biomarkers in clinical practice.</p>

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Large-scale analysis of temporal gene expression variation in peripheral blood

  • Neha Mishra,
  • Franziska Kimmig,
  • Doris Vandeputte,
  • Valentina Talevi,
  • Lindsey De Commer,
  • Chloe Verspecht,
  • Arnau Vich Vila,
  • Julia S. El-Sayed Moustafa,
  • Lukasz Kreft,
  • Alexander Botzki,
  • Youssef El Darzi,
  • Sebastian Proost,
  • Lindsay Devolder,
  • Dongmeng Wang,
  • Joana P. Bernardes,
  • N. Ahmad Aziz,
  • Konrad Aden,
  • Vibeke Andersen,
  • Aggelos Banos,
  • George Bertsias,
  • Marc Beyer,
  • Johanna I. Blase,
  • Dimitrios Boumpas,
  • Paraskevi Christofidou,
  • Axel Finckh,
  • Gilles Gasparoni,
  • Michel Georges,
  • Wei Gu,
  • Robert Häsler,
  • Stephan Huthmacher,
  • Mohamad Jawhara,
  • Amy Kenyon,
  • Christina Kratsch,
  • Roland Krause,
  • Gordan Lauc,
  • Paul A. Lyons,
  • Massimo Mangino,
  • Eoin F. McKinney,
  • Gioacchino Natoli,
  • Karl Nordström,
  • Marek Ostaszewski,
  • Silja H. Overgaard,
  • Marija Pezer,
  • Souad Rahmouni,
  • Benedikt Reiz,
  • Elisa Rosati,
  • Despina Sanoudou,
  • Venkata Satagopam,
  • Reinhard Schneider,
  • Jonas Schulte-Schrepping,
  • Prodromos Sidiropoulos,
  • Kenneth G. C. Smith,
  • Signe B. Sørensen,
  • Timothy Spector,
  • Aleksandar Vojta,
  • Jörn Walter,
  • Stefanie Warnat-Herresthal,
  • Vlatka Zoldoš,
  • Andre Franke,
  • Stefan Schreiber,
  • Emmanouil T. Dermitzakis,
  • Sara Vieira-Silva,
  • Gwen Falony,
  • Kerrin S. Small,
  • Monique M. B. Breteler,
  • Joachim L. Schultze,
  • Jeroen Raes,
  • Philip Rosenstiel

摘要

Transcriptomic profiling of peripheral blood offers a promising, non-invasive approach for disease diagnosis and monitoring. However, its clinical translation is hindered by limited knowledge of the natural temporal variation. Here, we present a comprehensive reference map of longitudinal transcriptomic variability, based on RNA-sequencing of 333 healthy individuals sampled at three time points over six months. We find that 85% of genes and 99% of transcripts exhibit greater intra-individual than inter-individual variation, primarily driven by dynamic regulation of housekeeping pathways. In contrast, immune-related transcripts –particularly those linked to T and B cell activity– are strikingly stable over time. Gene expression levels drive inter-individual differences, while splicing variation contributes more to intra-individual fluctuation. In an independent twin cohort (148 monozygotic, 166 dizygotic), genes with high inter-individual variability show greater heritability, suggesting genetic control of steady-state expression. By integrating extensive clinical and environmental data, we trace temporal expression changes to genetic, compositional, and external factors, and identify robust seasonal and sex-specific signatures. These findings were validated in a third, cross-sectional cohort of 3,480 individuals. The observed temporal variation patterns have important implications for cohort-based transcriptomic analyses, as they may limit discovery and reproducibility of expression quantitative trait loci and increase the risk of spurious associations in cross-sectional studies. This resource provides a critical baseline for distinguishing disease-associated transcriptomic changes from normal physiological variation, advancing the reliability of blood-based biomarkers in clinical practice.