Introduction: From fine mapping the gene locus on chromosome 20 found in the SAPPHIRe study, multiple SNP of RRBP1 was identified to be highly associated with hypertension and insulin resistant in human. The present study aims to investigate the roles of RRBP1 in regulating cardiovascular function. Material and Method: To clarify the role of RRBP1 in cardiovascular diseases, rrbp1-/- mouse embryonic stem cell (ESC) was generated and the cardiovascular cells derived from ESC were used to identify the mechanism contributed to the different functional properties between wild type (wt) and rrbp1-/- cells. Fura2AM was used as intracellular calcium indicator, and DAF as nitric oxide indicator. Lentivirus vectors were used to deliver human RRBP1 gene (hRRBP1) into rrbp1-/- myocytes. Real-time qPCR was performed to determine transcriptional alterations of NOSs. Results: We demonstrated different calcium handling properties in rrbp1-/- myocytes, including the elevated basal calcium levels, the slowed rates of both SR calcium release and cytosolic calcium return to baseline in calcium transients of cardiac cells, and diastolic SR Ca2+ leak. We further observed that the NO level was high in rrbp1-/- cells and calcium handling properties were restored in the presence of NOSs inhibitors (L-NAME and 1400W). Real-time RT-PCR demonstrated that the transcriptional levels of eNOS, iNOS and nNOS were both higher in rrbp1-/- myocytes. KN93, a Ca/calmodulin dependent kinase (CAMKII) inhibitor, could only restore SR calcium releasing velocity, but not in calcium decay rate and intracellular NO level. Overexpression of hRRBP1 in rrbp1-/- myocytes could also restore all intracellular calcium handling properties. Conclusion: Taken together, rrbp1 deficiency could increase the expression of iNOS, eNOS and nNOS to produce more intracellular NO, which may result in the post-translational modification on cardiac RyR2 and SERCA2 to lead to the slowed rates of SR calcium release and cytosolic calcium return to basal level, the diastolic SR calcium leak as well as the increase of diastolic calcium levels. The elevated diastolic calcium level could further activate CAMKII to cause the abnormality of cardiac RyR2 in regulating calcium release.