BACKGROUND: The myocardial infarct size can be reduced by pharmacological postconditioning using cardioprotective agents. Neuregulin-1β is a potential candidate, but previous studies in an isolated heart model of ischemia and reperfusion displayed controversial results. An in situ model of ischemia/reperfusion was used to clarify whether the remote application of neuregulin-1β can reduce the reperfusion injury. A second aim was to evaluate, if the effects are specific for reperfused tissue or if this is a general antiapoptotic effect. In addition, the contributing molecular mechanisms were investigated. METHODS: In an open chest model, mouse hearts were subjected to a regional ischemia (45-minute) using ligature of the left anterior descending artery. Neuregulin-1β (80 ng/kg) was given using an intraperitoneal bolus injection 5 minutes before reopening of the ligature followed by a 30-minute reperfusion. RESULTS: Remote application of recombinant neuregulin-1β protected the heart from reperfusion injury without influencing hemodynamics. This beneficial effect specifically targets reperfusion injury. In contrast, nonreperfused needle trauma was not reduced by neuregulin-1β when applied remotely. Pharmacological blocking experiments and enzyme activation analysis using Western blot analysis revealed a crucial involvement of the antiapoptotic reperfusion injury salvage kinase cascade. In contrast, contribution of the survivor activating factor enhancement pathways to this early cardioprotection was not observed. CONCLUSIONS: Remote application of neuregulin-1β protects hearts from early reperfusion injury by activation of the reperfusion injury salvage kinase pathway without relevant effects on intracardiac pressures in myocardial infarction. Besides its potential pharmacological application, neuregulin-1β might act as an endogenously produced mediator in remote postconditioning.
BACKGROUND: The myocardial infarct size can be reduced by pharmacological postconditioning using cardioprotective agents. Neuregulin-1β is a potential candidate, but previous studies in an isolated heart model of ischemia and reperfusion displayed controversial results. An in situ model of ischemia/reperfusion was used to clarify whether the remote application of neuregulin-1β can reduce the reperfusion injury. A second aim was to evaluate, if the effects are specific for reperfused tissue or if this is a general antiapoptotic effect. In addition, the contributing molecular mechanisms were investigated. METHODS: In an open chest model, mouse hearts were subjected to a regional ischemia (45-minute) using ligature of the left anterior descending artery. Neuregulin-1β (80 ng/kg) was given using an intraperitoneal bolus injection 5 minutes before reopening of the ligature followed by a 30-minute reperfusion. RESULTS: Remote application of recombinant neuregulin-1β protected the heart from reperfusion injury without influencing hemodynamics. This beneficial effect specifically targets reperfusion injury. In contrast, nonreperfused needle trauma was not reduced by neuregulin-1β when applied remotely. Pharmacological blocking experiments and enzyme activation analysis using Western blot analysis revealed a crucial involvement of the antiapoptotic reperfusion injury salvage kinase cascade. In contrast, contribution of the survivor activating factor enhancement pathways to this early cardioprotection was not observed. CONCLUSIONS: Remote application of neuregulin-1β protects hearts from early reperfusion injury by activation of the reperfusion injury salvage kinase pathway without relevant effects on intracardiac pressures in myocardial infarction. Besides its potential pharmacological application, neuregulin-1β might act as an endogenously produced mediator in remote postconditioning.