Background: The pathophysiology of atrial fibrillation (AF) has been characterized by changes in the cellular concentration of Ca2+ and related processes leading to the initiation and maintenance of the condition. Inositol trisphosphate-receptors (IP3Rs) are ligand-gated calcium channels for which overexpression in AF has been linked to cardiac remodeling. microRNA (miR, miRNA)s, small non-coding RNAs, are around 22 nucleotides in length and regulate gene expression by mRNA destabilization or inhibition of its translation. A growing body of evidence has emerged about miRNA's role in the pathophysiology of cardiac disorders, including AF-induced adverse remodeling. Objective: Our laboratory has shown that nuclear IP3R1 level is upregulated in the dog AF model, producing increased nuclear calcium loading. Hence, this study aims to investigate the role of miRNAs in the regulation of IP3R1 initiating and/or perpetuating AF in atrial cardiomyocytes of the dog AF model. Methods: We used AF dog model established by atrial-tachypacing for 600 bpm × one week; Langendorff-perfused hearts to isolate atrial cardiomyocytes for molecular experiments; screening miRs that target ITPR1 gene, encoding IP3R1, using online databases; RT-qPCR to measure ITPR1 mRNA expression and confirm the expression level of the screened miRNAs; western blot analysis to evaluate the protein level of IP3R1; dual-luciferase reporter assay, overexpression and knockdown of miRNAs in primary culture of isolated cardiomyocytes or appropriate cell lines; and Fluo-4 AM calcium fluorescence imaging to assess the potential role of the miRNA on Ca2+ handling. For miRNA manipulation experiments, cells were transfected with 1) non-coding miRNA (miR-NC, control group), 2) miRNA mimic, and 3) inhibitor of the miRNA (AMO). Statistical significance is calculated with Student's t-test or one-way analysis of variance (ANOVA) followed by Tukey's multiple comparisons test using GraphPad Prism software version 6.00. Results: Our data indicated a rise in IP3R1 protein level with no apparent change in ITPR1 gene expression in left atrial cardiomyocytes from our dog AF model. Based on the computational analysis, miR-26a was predicted to target the ITPR1 mRNA. AF significantly downregulated miR-26a in left atrial cardiomyocytes. The dual-luciferase reporter assay in H9C2 cells showed that miR-26a directly acted on the 3′ untranslated region (3′UTR) of ITPR1 mRNA. In addition, miR-26a overexpression reduced the IP3R1 protein level and decreased the diastolic [Ca2+] in both nucleus and cytosol of the electrically-stimulated Ca2+ -transients, dog cardiomyocytes, while miR-26a knockdown reversed these effects. ITPR1 mRNA expression remained unaltered in isolated dog cardiomyocytes after transfection with the miRNA mimic and inhibitor. Conclusion: IP3R1 upregulation in AF is due to translation inhibition by miR-26a, which is downregulated in the atrial cardiomyocytes of the dog AF model. This change is associated with altered Ca2+ handling, reflected as enhanced nuclear diastolic Ca2+ levels. Our results suggest that miR-26a downregulation enhances the IP3R1 expression, contributing to pro-arrhythmic remodeling in AF.