Selective atrial profibrotic signalling in mice and man.

Although oral anticoagulation can prevent the majority of strokes in patients with atrial fibrillation (AF) if used as recommended in treatment guidelines, patients with AF receiving optimal therapy still die prematurely, and are frequently hospitalized. Hence, weneed a deeperunderstanding of the mechanisms behind AF in patients to develop better treatment. Most of the currently used treatments for AF were initially developed to treat ventricular heart disease, e.g. angiotensin-converting enzyme inhibitors, digitalis, beta-adrenoceptor blockers, spironolactone, andmostantiarrhythmicdrugs.Understandingelectrophysiological differences between the atria and ventricles have allowed the recent development of atrial antiarrhythmic drugs (dronedarone, vernakalant), with others undergoing clinical development. Catheter ablation of AF also illustrates how the understanding of an atrial arrhythmia mechanism, i.e. focal firing in and around the pulmonary veins, helped develop a specific AF treatment. In this issue of Cardiovascular Research, Rahmutula et al. characterize a molecular pathway leading to selective atrial fibrosis. By analysing human atrial and ventricular tissues, they identified an atrial preponderance of transforming growth factor-b (TGF-b) expression, and higher atrial TGF-b levels in patients who developed post-operative AF. They further studied the effects of increased TGF-b expression using a murine model of enhanced TGFb expression under the control of the a-MHC promoter that is prone to inducible AF. In this model, TGF-b expression is increased to a similar level in both ventricular and atrial cardiomyocytes as measured in young adults, but only the atria respond to this TGF-b expression by increased interstitial fibrosis. Why does the same level of TGF-b overexpression cause fibrosis in the atria, but not in the ventricles? Published experiments provide ample room for speculation: TGF-b is an important activator of chemokines and attracts monocytes into the heart. Micro-RNAs, plasminogen activator-inhibitor 1, or non-canonical, SMAD-independent activation of junction kinase can alter the response of cardiac and vascular tissue toTGF-b. Ofnote,TGF-b alsoalters left-rightdifferentiation of embryonal mesoderm. Rahmutula et al. provide insights from gene array and gene expression analyses and protein chemistry in atrial and ventricular tissue in TGF-b transgenic and wild-type mice suggesting enhanced receptor binding, enhanced phosphorylation of receptor regulated (R-)SMAD2/3, reduced expression of the inhibitory SMAD7 in atria vs. ventricles. Hence, it appears that ‘canonical’ TGF-b signalling is the most likely mediator of selective atrial fibrosis in response to TGF-b (Figure 1). A similar signalling pattern has been described in patients with aortic aneurysm and mutations in the TGF-b receptor. The study has limitations: the number of human atrial samples acquired during open heart surgery was limited (n 1⁄4 17), and even fewer patients had AF, only n 1⁄4 2 spontaneous AF and n 1⁄4 4 postoperative AF. Concerning the overexpression model, it may be relevant to consider that the a-MHC promoter is activated earlier in the atria than in the ventricles, possibly increasing atrial vulnerability. Noncanonical TGF-b signalling cannot be fully excluded. Bone morphogenic protein-10 (BMP-10), the ‘right atrial mirror marker’ of the left atrial gene Pitx2 is a target of TGF-b signalling and seems reduced in the gene array presented by Ramuhtula et al. We will need to carefully differentiate left and right atrial changes in future studies to better understand selective signalling pathways. While these limitations call for replication of the findings in other models and cohorts, their hypothesis is supported by the translational approach ‘from mice to men’, by demonstration of enhanced TGF-b expression and activity in human atrial compared with the ventricular myocardium, and by attenuation of the fibrotic response to TGF-b by inhibiting the TGF-b receptor kinase support. Also, in a coincident clinical study, increased expression of connective tissue growth factor and TGF-b in patients with chronic AF (n 1⁄4 28) is seen compared with others in sinus rhythm (n 1⁄4 12). Furthermore, dogs treated with the TGF-b inhibitor tranilast develop less AF in response to rapid pacing. The study reported here may provide a molecular explanation for these findings. In summary, the results of this translational study suggest that inhibitingTGF-b signallingmayhelpprevent atrial fibrosis moreeffectively than inhibiting the renin–angiotensin system. Further studies are needed to identify the best therapeutic target and to understand the relevance of fibrosis and fibroblast activation for AF, but the data suggest that the development of atrial-specific antifibrotic therapy is feasible.