Human skeletal muscle-derived stem/progenitor cells modified with connexin-43 prevent arrhythmia in rat post-infarction hearts and influence gene expression in the myocardium.

Stem cell therapy in combination with genetic modification (e.g., transfection with the coding sequence for the connexion 43 gene, GJA1) may solve the problems associated with the occurrence of additional (secondary) stimulation in the post-infarcted heart (arrhythmia). Human skeletal muscle-derived stem/progenitor cells (SkMDS/PCs) were transfected with the pCiNeo-GJA1 plasmid at an efficiency of approximately 96%. Gene overexpression was assessed using qPCR, and subsequent analysis revealed that GJA1 expression increased more than 40-fold in SkMDS/PCs transfected with the appropriate coding sequence (SkMDS/PCsCX43) compared to that of the 'native' SkMDS/PCs control (SkMDS/PCsWT). Enhanced (4-fold) protein expression of connexin-43 was also confirmed by Western immunoblotting. Furthermore, using the arrhythmic score, we demonstrated the positive effects of SkMDS/PCsCX43 cell intervention in reducing additional secondary stimulations in rat post-infarcted hearts compared with that of wild-type cell delivery. Selected gene responses (Kcnq1, Cacna1c, Ncx1, Serca2a, and Tgfb1) showed significantly altered expression profiles in the rat myocardium upon intervention with SkMDS/PCsCX43. The genetic modification of human skeletal muscle-derived stem/progenitor cells with connexin-43 prevented the pro-arrhythmic effects of myogenic implanted stem cells on the host myocardium and positively influenced myocardial gene expression profiles in respect to myocardium conductivity.

Human myoblast transplantation in mice infarcted heart alters the expression profile of cardiac genes associated with left ventricle remodeling.

BACKGROUND: Myocardial infarction (MI) and left ventricle remodeling (LVR) are two of the most challenging disease entities in developed societies. Since conventional treatment cannot fully restore heart function new approaches were attempted to develop new strategies and technologies that could be used for myocardial regeneration. One of these strategies pursued was a cell therapy--particularly applying skeletal muscle stem cells (SkMCs). METHODS AND RESULTS: Using NOD-SCID murine model of MI and human skeletal myoblast transplantation we were able to show that SkMC administration significantly affected gene expression profile (p<0.05) (NPPB, CTGF, GATA4, SERCA2a, PLB) of the heart ventricular tissue and this change was beneficial for the heart function. We have also shown, that the level of heart biomarker, NT-proBNP, decreased in animals receiving implanted cells and that the NT-proBNP level negatively correlated with left ventricle area fraction change (LVFAC) index which makes NT-proBNP an attractive tool in assessing the efficacy of cell therapy both in the animal model and prospectively in clinical trials. CONCLUSIONS: The results obtained suggest that transplanted SkMCs exerted beneficial effect on heart regeneration and were able to inhibit LVR which was confirmed on the molecular level, giving hope for new ways of monitoring novel cellular therapies for MI.