Abstract

Myocardial fibrosis is a major life-limiting problem in chronic kidney disease (CKD). Despite this, the molecular phenotype and metabolism of collagen fibrillogenesis in fibrotic hearts of patients with advanced CKD have been largely unstudied. We analyzed explanted human left ventricular (LV) heart tissues in a 3-arm cross-sectional cohort study of deceased donor patients on hemodialysis (HD, n=18), hypertension with preserved renal function (HTN, n=8), and healthy controls (CON, n=17), ex vivo. RNA-seq and protein analysis was performed on human donor hearts and cardiac fibroblasts treated with mineral stressors (high phosphate and high calcium). Further mechanistic studies were performed using primary cardiac fibroblasts, in vitro treated with mineral stressors, pro-inflammatory and pro-fibrotic cytokines. Of the 43 donor participants, there was no difference in age (P>0.2), sex (P>0.8), or body mass index (P>0.1) between the groups. Hearts from the HD group had extensive fibrosis (P<0.01). All LV tissues expressed only the trimeric form of collagen type I. HD hearts expressed increased collagen type I (P<0.03), elevated collagen type I:III ratio (P<0.05), and decreased MMP1 (P<0.05) and MMP2 (P<0.05). RNA-seq revealed no significant differential gene expression of extracellular matrix proteins of interest in HD hearts, but there was significant upregulation of LH2, periostin, α-SMA, and TGF-β1 gene expression in mineral stressor-treated cardiac fibroblasts. Both mineral stressors (P<0.009) and cytokines (P<0.03) increased collagen type I:III ratio. Mineral stressors induced trimeric collagen type I, but cytokine treatment induced only dimeric collagen type I in cardiac fibroblasts. Mineral stressors downregulated fibronectin (P<0.03) and MMP2 zymogen (P<0.01) but did not significantly affect expression of periostin, MMP1, or cross-linking enzymes. TGF-β upregulated fibronectin (P<0.01) and periostin (P<0.02) only. Myocardial fibrosis in advanced CKD hearts is characterized by increased trimeric collagen type I and dysregulated collagen metabolism, and is differentially regulated by components of uremia.

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