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Distinct functional and molecular profiles between physiological and pathological atrial enlargement offer potential new therapeutic opportunities for atrial fibrillation

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posted on 2024-09-20, 01:47 authored by Yi-Ching ChenYi-Ching Chen, Seka Wijekoon, Aya Matsumoto, Jieting Luo, Helen Kiriazis, Emma Masterman, Gunes Yildiz, Jonathon Cross, Adam ParslowAdam Parslow, Roger Chooi, Junichi Sadoshima, David GreeningDavid Greening, Kate Weeks, Julie McMullenJulie McMullen

Atrial fibrillation (AF) remains challenging to prevent and treat. A key feature of AF is . However, not all atrial enlargement progresses to AF. Atrial enlargement in response to physiological stimuli such as exercise is typically benign and reversible. Understanding the differences in atrial function and molecular profile underpinning pathological and physiological atrial remodelling will be critical for identifying new strategies for AF. The discovery of molecular mechanisms responsible for pathological and physiological ventricular hypertrophy has uncovered new drug targets for heart failure. Studies in the atria have been limited in comparison. Here, we characterised mouse atria from (1) a pathological model (cardiomyocyte-specific transgenic (Tg) that develops dilated cardiomyopathy [DCM] and AF due to reduced protective signalling [PI3K]; DCM-dnPI3K), and (2) a physiological model (cardiomyocyte-specific Tg with an enlarged heart due to increased insulin-like growth factor 1 receptor; IGF1R). Both models presented with an increase in atrial mass, but displayed distinct functional, cellular, histological and molecular phenotypes. Atrial enlargement in the DCM-dnPI3K Tg, but not IGF1R Tg, was associated with atrial dysfunction, fibrosis and a heart failure gene expression pattern. Atrial proteomics identified protein networks related to cardiac contractility, sarcomere assembly, metabolism, mitochondria, and extracellular matrix which were differentially regulated in the models; many co-identified in atrial proteomics data sets from human AF. In summary, physiological and pathological atrial enlargement are associated with distinct features, and the proteomic dataset provides a resource to study potential new regulators of atrial biology and function, drug targets and biomarkers for AF.

Funding

This work was supported by grants from the National Heart Foundation of Australia (Vanguard) [grant numbers 105720 (to J.R.M.) and 105072 (to D.W.G.)]; National Health and Medical Research Council (Ideas) [grant number 2029334 (to J.R.M. and Y.C.C.)], and in part by the Victorian Government’s Operational Infrastructure Support Program. D.W.G. is supported by the Amelia Hains Foundation, and National Health and Medical Research Council funding (Ideas/MRFF schemes). K.L.W. is supported by Future Leader Fellowships from the National Heart Foundation of Australia [grant number 102539 (to K.L.W.)]. J.R.M. was supported by a National Health and Medical Research Council Senior Research Fellowship [grant number 1078985] and Baker Fellowship (The Baker Foundation, Australia).

History

Publication Date

2024-07-30

Journal

Clinical Science

Volume

138

Issue

15

Pagination

941 - 962

Publisher

Portland Press

ISSN

0143-5221

Rights Statement

© 2024 The Author(s). This is an open access article published by Portland Press Limited on behalf of the Biochemical Society and distributed under the Creative Commons Attribution License 4.0 (CC BY).