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The Horse Cardiac Transcriptome: Moving Towards a Molecular Understanding of Atrial Fibrillation
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  • Simon Haugaard,
  • Sarah Nissen,
  • Mélodie Schneider,
  • Jesper Bratz Birk,
  • Helena Carstensen,
  • Charlotte Hopster-Iversen,
  • Ali Altıntaş,
  • Romain Barrès,
  • Rasmus Kjøbsted,
  • Jørgen F.P. Wojtaszewski,
  • Kate M. Herum,
  • Thomas Jespersen,
  • Rikke Buhl
Simon Haugaard
University of Copenhagen

Corresponding Author:simon.haugaard@sund.ku.dk

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Sarah Nissen
University of Copenhagen
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Mélodie Schneider
University of Copenhagen
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Jesper Bratz Birk
August Krogh Section for Human and Molecular Physiology
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Helena Carstensen
University of Copenhagen
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Charlotte Hopster-Iversen
University of Copenhagen
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Ali Altıntaş
Kobenhavns Universitet Novo Nordisk Fondens Center for Grundlaeggende Metabolisk Forskning
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Romain Barrès
Kobenhavns Universitet Novo Nordisk Fondens Center for Grundlaeggende Metabolisk Forskning
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Rasmus Kjøbsted
August Krogh Section for Human and Molecular Physiology
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Jørgen F.P. Wojtaszewski
August Krogh Section for Human and Molecular Physiology
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Kate M. Herum
Novo Nordisk A/S Global Research
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Thomas Jespersen
University of Copenhagen
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Rikke Buhl
University of Copenhagen
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Abstract

Background: Treatment of atrial fibrillation (AF) in horses is challenged by high recurrence rates, potentially driven by underlying myocardial changes or remodelling caused by AF itself. Understanding the molecular mechanisms behind these changes is crucial for developing new targeted therapies and improving treatment outcomes. Objectives: To characterize the cardiac transcriptome of healthy horses and explore the transcriptional changes associated with persistent AF. Study design: Case-control study. Methods: RNA-sequencing was performed on samples from all four heart chambers collected from six horses with naturally occurring persistent AF (lasting 2–12 weeks) and six healthy controls. Differential gene expression and pathway enrichment analyses were conducted to identify chamber specific differences and molecular pathways associated with AF. Findings were integrated with proteomic data and compared to transcriptional changes observed in tachypacing-induced AF. Atrial metabolic remodelling was further investigated by evaluating AMP-activated protein kinase (AMPK) activity and local glycogen content. Results: The transcriptomes of the four heart chambers had distinct molecular identities. Expression of ion channels and genes encoding calcium handling proteins were largely similar to humans, despite important differences in the ventricular expression of repolarizing potassium channels. Persistent AF was associated with minimal ion channel changes but significant upregulation of metabolic, fibrotic, and myofibrillar pathways. Metabolic remodelling included transcriptional upregulation of glycolytic pathways, increased glycogen content in the left atrium, and preserved AMPK activity in the right atrium. The transcriptomic profiles of persistent AF correlated well with those of tachypacing-induced AF. Main limitations: The study cannot distinguish changes predisposing to AF from those caused by it. Functional validation of ion channel currents was not performed. Conclusion: Persistent AF was associated with changes in metabolic and fibrotic pathways in the atria, with minimal ion channel remodelling. Targeting these pathways, rather than focusing solely on the electrical disturbance, may improve treatment outcomes in equine AF.
18 Dec 2024Submitted to Equine Veterinary Journal
18 Dec 2024Submission Checks Completed
18 Dec 2024Assigned to Editor
18 Dec 2024Review(s) Completed, Editorial Evaluation Pending
18 Dec 2024Reviewer(s) Assigned