Loss of conserved long non-coding RNA MIR503HG leads to altered NOTCH pathway signalling and left ventricular non-compaction cardiomyopathy

Abstract

Aims The highly conserved long non-coding RNA (lncRNA) MIR505HG has been primarily recognized as a precursor for microRNAs (miR)-424 and miR-503. However, studies have since demonstrated that MIR503HG has distinct functions from its associated miRNAs, playing important roles in cell proliferation, invasion, apoptosis, and differentiation. While these miRNAs are known to influence cardiomyocyte differentiation, the specific role of MIR503HG in heart development remains unexplored. We seek to determine how MIR503HG deletion impacts ventricular chamber development and to identify underlying molecular mechanisms. Methods and results To study the role of the lncRNA in vivo, we generated a functional MIR503HG knockout mouse model (MIR503HG−/−) using a synthetic polyadenylation signal to terminate MIR503HG transcription without affecting miR-424/503 expression. We performed morphological analyses on embryonic and adult hearts using microCT along with cardiac functional analysis via transthoracic echocardiography. We further apply single-nuclei RNA sequencing (snRNA-seq) on adult hearts to identify potential molecular mechanisms underlying the observed phenotypes. Functional deletion of MIR503HG alone was associated with reduced compact myocardium thickness and increased trabecular myocardium in the left ventricle (LV) at embryonic day 17.5 compared to wild-type mice, indicating a LV non-compaction (LVNC) phenotype. Moreover, adult MIR503HG−/− mutant hearts showed increased trabecular complexity, impaired LV relaxation, and mitral valve regurgitation. SnRNA-seq further revealed altered expression of several genes associated with cardiomyocyte function and LVNC, including Actc1, Mib1, Mybpc3, and Myh7. Lastly, Notch1 activity was also significantly increased in mutant hearts which has been previously associated with LVNC. Conclusion MIR503HG plays a role in ventricular chamber development, and its deletion leads to an LVNC phenotype independent of the miRNA cluster within its locus, highlighting its importance in cardiac development and disease. We further suggest that abnormal Notch1 activity may underpin the LVNC phenotype presented.