Myocardial maladaptation to pressure overload in CB2 receptor-deficient mice.

BACKGROUND: Adaptation to aortic valve stenosis leads to myocardial hypertrophy, which has been associated with inflammation, fibrosis and activation of the endocannabinoid system. Since the endocannabinoid system and the CB2 receptor provide cardioprotection and modulate immune response in experimental ischemia, we investigated the role of CB2 in a mouse model of cardiac pressure overload. METHODS: Transverse aortic constriction was performed in CB2 receptor-deficient (Cnr2-/-) mice and their wild-type littermates (Cnr2+/+). After echocardiography and Millar left heart catheter hemodynamic evaluation hearts were processed for histological, cellular and molecular analyses. RESULTS: The endocannabinoid system showed significantly higher anandamide production and CB2 receptor expression in Cnr2+/+ mice. Histology showed non-confluent, interstitial fibrosis with rare small areas of cardiomyocyte loss in Cnr2+/+ mice. In contrast, extensive cardiomyocyte loss and confluent scar formation were found in Cnr2-/- mice accompanied by significantly increased apoptosis and left ventricular dysfunction when compared with Cnr2+/+ mice. The underlying cardiac maladaptation in Cnr2-/- mice was associated with significantly reduced expression of myosin heavy chain isoform beta and less production of heme oxygenase-1. Cnr2-/- hearts presented after 7 days with stronger proinflammatory response including significantly higher TNF-alpha expression and macrophage density, but lower density of CD4+ and B220+ cells. At the same time, we found increased apoptosis of macrophages and adaptive immune cells. Higher myofibroblast accumulation and imbalance in MMP/TIMP-regulation indicated adverse remodeling in Cnr2-/- mice. CONCLUSIONS: Our study provides mechanistic evidence for the role of the endocannabinoid system in myocardial adaptation to pressure overload in mice. The underlying mechanisms include production of anandamide, adaptation of contractile elements and antioxidative enzymes, and selective modulation of immune cells action and apoptosis in order to prevent the loss of cardiomyocytes.

Cardiomyocyte specific peroxisome proliferator-activated receptor-α overexpression leads to irreversible damage in ischemic murine heart.

AIMS: Peroxisome proliferator-activated receptor (PPAR)-α is downregulated in ischemic myocardium resulting in substrate switch from fatty acid oxidation to glucose utilization. Pharmacological PPAR-α activation leads to increased fatty acid oxidation and myocardial lipotoxicity. The aim of our study was to investigate the role of cardiomyocyte specific PPAR-α overexpression in myocardial adaptation to repetitive ischemic injury without myocardial infarction. MAIN METHODS: Repetitive, brief I/R was performed in male and female MHC-PPAR-α overexpressing and wildtype-C57/Bl6 (WT)-mice, age 10-12 weeks, for 3 and 7 consecutive days. After echocardiography, their hearts were excised for histology and gene/protein-expression measurements (Taqman/Western blot). KEY FINDINGS: MHC-PPAR-α mice developed microinfarctions already after 3 days of repetitive I/R in contrast to interstitial fibrosis in WT-mice. We found higher deposition of glycogen, increased apoptosis and dysfunctional regulation of antioxidative mediators in MHC-PPAR-α mice. MHC-PPAR-α mice presented with maladaptation of myosin heavy chain isoforms and worse left ventricular dysfunction than WT-mice. We found prolonged, chemokine-driven macrophage infiltration without induction of proinflammatory cytokines in MHC-PPAR-α mice. Persistent accumulation of myofibroblasts in microinfarctions indicated active remodeling resulting in scar formation in contrast to interstitial fibrosis without microinfarctions in WT-mice. However, MHC-PPAR-α hearts had only a weak induction of tenascin-C in contrast to its strong expression in WT-hearts. SIGNIFICANCE: Cardiomyocyte-specific PPAR-α overexpression led to irreversible cardiomyocyte loss with deteriorated ventricular function during brief, repetitive I/R episodes. We identified higher glycogen deposition, increased apoptosis, deranged antioxidative capacity and maladaptation of contractile elements as major contributors involved in the modulation of post-ischemic inflammation and remodeling.