Abstract P2041: Identification Of The Nuclear Localization Signal In RBM20 And Its Function In The Pathogenesis Of Dilated Cardiomyopathy

Abstract

Human patients carrying genetic mutations in RNA binding motif 20 (RBM20) develop an aggressive and arrhythmogenic form of dilated cardiomyopathy (DCM). Five of over 900 genetic mutations in RBM20 have recently been validated in animal models. Four of these five mutations are located in the arginine/serine-rich (RS) domain with the fifth in the RNA recognition motif (RRM). Interestingly, only mutations in the RS domain cause severe DCM, which suggests that disruption of RS domain function is crucial for the pathogenesis of DCM. To test this hypothesis, we generated mice expressing RBM20 with an in-frame deletion of the RS domain ( Rbm20 ΔRS ). We show that Rbm20 ΔRS mice manifest DCM with RBM20 mis-localization and granule formation, similar to that in RS domain mutation knock-in (KI) animals. Conversely, mice expressing RBM20 lacking the RRM do not exhibit RBM20 nucleocytoplasmic transport or granule formation, and, similar to RRM mutation KI mice, do not develop DCM. These data suggest that the critical nuclear localization signal (NLS) in RBM20 is located within the RS domain and that disruption of this sequence leads to RBM20 mis-localization and granule formation. In vitro experiments employing sequence deletion plasmids and immunocytochemical staining revealed that the first nine amino acids in the RS domain constitute the core NLS in RBM20, which is further supported by the fact that all three validated DCM-causing mutations are located in this segment. Analysis of plasmids containing DCM-associated mutations in other regions of RBM20, as well as in the non-NLS RS domain sequence, further confirmed that only mutations in the NLS facilitate re-localization and granule formation. Phosphorylation of residues within the NLS has been shown play an important role in protein nucleocytoplasmic transport. To test this, we mutated all phosphorylatable serine residues in the NLS to unphosphorylatable alanine or phosphomimetic aspartate and provide evidence that phosphorylation is dispensable for nucleocytoplasmic transport. Collectively, our findings identify the critical NLS in RBM20 and demonstrate that mutations in this NLS cause severe DCM through disruption of RS domain-mediated nuclear localization and sarcoplasmic granule formation.