Netrin-1 prevents ischemia/reperfusion-induced myocardial infarction via a DCC/ERK1/2/eNOSs1177/NO/DCC feed-forward mechanism

We have recently shown that a novel endothelial mitogen netrin-1 potently stimulates nitric oxide (NO) production via a DCC-ERK1/2 dependent mechanism. In view of the well-established cardioprotective role of NO, the present study investigated whether netrin-1 is cardioprotective via NO signaling in the heart. Netrin-1 receptor DCC was abundantly expressed in the C57BL/6J mouse hearts. Perfusion of heart with netrin-1 (100 ng/mL) using a Langendorff system significantly increased NO production. Under ischemia/reperfusion (I/R), netrin-1 induced a substantial reduction in infarct size (21.8 ± 4.9% from 42.5 ± 3.6% in the controls), which was accompanied by an augmented production of NO. Pre-perfusion with DCC-antibody, U0126 (MEK1/2 inhibitor), L-NAME or PTIO (NO scavenger) attenuated protective effects of netrin-1 on infarct size and NO production, indicating upstream roles of DCC and ERK1/2 in NO production, as well as an essential role of NO in cardioprotection. Netrin-1 induced reduction in infarct size was significantly attenuated in DCC+/− mice, confirming an intermediate role of DCC. In additional experiments we found netrin-1 increased ERK1/2 and eNOSs1177 phosphorylation, and DCC protein expression, which was diminished by I/R. Furthermore, netrin-1-induced DCC upregulation was NO and ERK1/2-dependent, implicating a feed-forward mechanism. DAF-AM staining revealed enhanced NO production in both cardiac endothelial cells (ECs) and myocytes. In primarily isolated cardiomyocytes, netrin-1 also increased NO production, DCC abundance and ERK1/2 phosphorylation. Of note, cardiac apoptosis was significantly attenuated by netrin-1, which was reversed by DCC-antibody, U0126, L-NAME or PTIO. In summary, our data clearly demonstrate that netrin-1 potently protects the heart from I/R injury by stimulating NO production from cardiac ECs and myocytes. This potent effect is mediated by a DCC/ERK1/2/eNOSs1177/NO/DCC feed-forward mechanism in both cell types.