Abstract
An ancient evolutionary regenerative mechanism of injured myocardium in vertebrates has been conserved in zebrafish, urodeles (salamander, newt, and axolotl) and neonatal mice. This innate regenerative mechanism is characterized by extensive migration of pro-regenerative macrophages into the injured myocardium and non-immune activation of parts of the complement system. Loss of regenerative activity in neonatal mice within a few days after birth implies that it is suppressed and replaced by fibrotic repair and scar formation. Fibrosis prevents ventricular wall rupture following myocardial infarction (MI), but it compromises contractility and can lead to heart failure and premature death. Reactivation of the suppressed regenerative mechanism in post-MI adult mice may be feasible by localized immune activation of the complement system, resulting in extensive recruitment of pro-regenerative macrophages into the injured myocardium, recapitulating neonatal mechanisms. Localized complement activation can be achieved by a new method of harnessing the natural anti-Gal antibody, which constitutes ~1% of human immunoglobulins and binds the carbohydrate antigen "α-gal epitope". α-Gal nanoparticles (small liposomes presenting multiple α-gal epitopes) bind anti-Gal when administered into reperfused myocardium post-MI in anti-Gal-producing mice, thereby inducing localized complement activation. In this novel approach, macrophages recruited into the ischemic myocardium by complement cleavage chemotactic peptides, and binding anti-Gal-coated α-gal nanoparticles, polarize to become pro-regenerative macrophages that produce pro-regenerative cytokines and recruit stem cells. This process results in near-complete regeneration of the injured myocardium within 14 days. Future evaluation of this novel approach in larger animal models will help in determining whether trans-endocardial delivery by catheter of α-gal nanoparticles into ischemic myocardium warrants clinical application in acute MI.