Abstract P2005: Mechanosensitive Piezo-1 Channel Aggravates Ischemia Induced Adverse Cardiac Remodeling And Dysfunction

Abstract only Background: Mechanotransduction is a physiological process through which mechanical forces are sensed and converted to biological responses. It is fundamental for morphogenesis during early development and organ functions during adult life. An injured heart undergoes dynamic phases of...

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Published in:Circulation research 2023-08, Vol.133 (Suppl_1)
Main Authors: Umbarkar, Prachi, Ruiz Ramirez, Sulivette, Ejantkar, Suma, Tousif, Sultan, Toro Cora, Angelica, Galindo, Cristi L, Zhang, Qinkun, Lal, Hind
Format: Article
Language:English
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Summary:Abstract only Background: Mechanotransduction is a physiological process through which mechanical forces are sensed and converted to biological responses. It is fundamental for morphogenesis during early development and organ functions during adult life. An injured heart undergoes dynamic phases of structural and functional remodeling, exposing cardiac cells to the fluctuating mechanical environment. Piezo-1 (PZO1) is a recently discovered mechanosensitive ion channel with widespread physiological importance. However, its role in the pathophysiology of heart disease is not fully understood. Methods and Results: The qPCR analysis confirmed that PZO-1 expression increases in cardiomyocytes (CM) post-MI. To evaluate the role of CM-PZO1 in MI-induced adverse cardiac remodeling, conditional CM-specific PZO1 KO mice were generated using tamoxifen-inducible α-MHC promoter driven MerCreMer transgene. At 12 weeks of age, mice were subjected to a well-established tamoxifen diet protocol followed by MI surgery. Cardiac function was monitored by serial echocardiography. In the control group, EF and FS declined from 2 weeks post-MI, indicating systolic dysfunction. These changes were associated with the development of structural remodeling as reflected by a significant increase in LVIDs, HW/TL ratio, CM CSA, and hypertrophy markers (ANP, BNP). Interestingly, all these parameters were essentially normalized in CM-PZO1 KO mice, confirming that CM-specific PZO1 deletion prevents the progression of pathological hypertrophy and systolic dysfunction in MI heart. Moreover, CM-PZO1 KO displayed significant alterations in gene expression of ECM proteins such as connective tissue growth factor (CTGF), latent TGF-β binding protein 2 (LTBP2), cartilage oligomeric matrix protein (COMP), cartilage intermediate layer protein (CILP) while collagen and fibronectin levels were comparable between control and KO groups. These observations indicate a potential role of CM-PZO1 in modulating cardiac ECM and scar properties under pathological conditions. Conclusion: Our findings suggest that PZO1 serves as a key cardiac mechanotransducer under pathological condition and represent a novel therapeutic target for treating heart diseases.
ISSN:0009-7330
1524-4571
DOI:10.1161/res.133.suppl_1.P2005