Dysfunctional atrial fibroblast processing of filamin A in atrial fibrillation
Johnston AM., Yiu CHK., Moreira LA., Srivastava V., Sayeed R., Walcot NRH., Sastry P., Smart N., Reilly S.
Abstract Background/Introduction Atrial fibrillation (AF), the most common sustained cardiac arrhythmia, is associated with atrial structural remodelling, hallmarked by fibrosis. Atrial fibrosis is instigated by atrial fibroblasts (AFBs). It was previously uncovered the hormone calcitonin (CT) is produced in the heart and, via binding to the CT-receptors (CTR), inhibits atrial fibrogenesis and fibroblast profibrotic activity. [1] In AF, abnormally increased CTR internalisation causes loss of physiological surface CTR and prevents fibroblast activation by CT. The molecular mechanisms of this phenomenon in ACFs are unknown. Aim To explore the role of filamin A (FLNa), an actin cross-linking protein that was previously shown to interact with CTR, [2] in the regulation of CTR trafficking. Methods AFBs were enzymatically isolated from left atrial appendage biopsies collected from 30 patients in persistent AF or normal sinus rhythm (SR, controls) undergoing elective heart surgery. Immunostaining assessed the localisation of CTR and its overlap with the nucleus (stained with DAPI) and FLNa in AFBs. Co-localisation was quantified by the JACoP BIOP plugin for ImageJ. Target mRNA expression was assessed by RT-qPCR and protein levels by immunoblot. Immunoprecipitation (IP) then immunoblot (IB) validated protein-protein interactions. Calpain activity was assessed with a fluorescence-based assay. The effects of calpains on FLNa proteolytic processing was examined with calpain inhibitor calpeptin (10nM–100nM vs DMSO loading control). Results Immunostaining revealed aberrant, intracellular localisation of CTR in AF-AFBs (A) with increased nuclear localisation (p=0.03) and reduced co-localisation with FLNa (p=0.03). FLNa gene expression showed a trend towards reduction in AF (by 36%, p=0.06; B). Meanwhile, although full-length FLNa protein was unaltered in AF, there was a striking 67% reduction (p=0.02) in the expression of FLNa’s c-terminal fragment (FLNaCT), which contains the CTR binding domain (C). Co-immunoprecipitation confirmed a physical interaction between CTR and FLNaCT (D) in both SR and AF AFBs. FLNaCT is typically generated when FLNa is cleaved by the protease calpain 1, whose protein (F) but not mRNA (E), was significantly downregulated (71%, p<0.001) in AF. Puzzlingly, a ~70% loss of calpain 1 protein was associated with unchanged calpain activity (G) and FLNaCT levels in AFBs treated with calpain inhibitor calpeptin (H). Conclusions Persistent AF is associated with an aberrant CTR localisation and FLNa proteolytic processing, not attributable to altered calpain activity. Further characterisation of the molecular determinants of the altered CTR localisation may uncover novel and potentially druggable facets of structural remodelling in AF.