Cardioprotective effects of osteopontin-1 during development of murine ischemic cardiomyopathy.

Repetitive brief ischemia and reperfusion (I/R) is associated with ventricular dysfunction in pathogenesis of murine ischemic cardiomyopathy and human hibernating myocardium. We investigated the role of matricellular protein osteopontin-1 (OPN) in murine model of repetitive I/R. One 15-min LAD-occlusion followed by reperfusion was performed daily over 3, 5, and 7 consecutive days in C57/Bl6 wildtype- (WT-) and OPN(-/-)-mice (n = 8/group). After echocardiography hearts were processed for histological and mRNA-studies. Cardiac fibroblasts were isolated, cultured, and stimulated with TGF- ß 1. WT-mice showed an early, strong, and cardiomyocyte-specific osteopontin-expression leading to interstitial macrophage infiltration and consecutive fibrosis after 7 days I/R in absence of myocardial infarction. In contrast, OPN(-/-)-mice showed small, nontransmural infarctions after 3 days I/R associated with significantly worse ventricular dysfunction. OPN(-/-)-mice had different expression of myocardial contractile elements and antioxidative mediators and a lower expression of chemokines during I/R. OPN(-/-)-mice showed predominant collagen deposition in macrophage-rich small infarctions. We found lower induction of tenascin-C, MMP-9, MMP-12, and TIMP-1, whereas MMP-13-expression was higher in OPN(-/-)-mice. Cultured OPN(-/-)-myofibroblasts confirmed these findings. In conclusion, osteopontin seems to modulate expression of contractile elements, antioxidative mediators, and inflammatory response and subsequently remodel in order to protect cardiomyocytes in murine ischemic cardiomyopathy.

Of mice and dogs: species-specific differences in the inflammatory response following myocardial infarction.

Large animal models have provided much of the descriptive data regarding the cellular and molecular events in myocardial infarction and repair. The availability of genetically altered mice may provide a valuable tool for specific cellular and molecular dissection of these processes. In this report we compare closed chest models of canine and mouse infarction/reperfusion qualitatively and quantitatively for temporal, cellular, and spatial differences. Much like the canine model, reperfused mouse hearts are associated with marked induction of endothelial adhesion molecules, cytokines, and chemokines. Reperfused mouse infarcts show accelerated replacement of cardiomyocytes by granulation tissue leading to a thin mature scar at 14 days, when the canine infarction is still cellular and evolving. Infarcted mouse hearts demonstrate a robust but transient postreperfusion inflammatory reaction, associated with a rapid up-regulation of interleukin-10 and transforming growth factor-beta. Unlike canine infarcts, infarcted mouse hearts show only transient macrophage infiltration and no significant mast cell accumulation. In correlation, the growth factor for macrophages, M-CSF, shows modest and transient up-regulation in the early days of reperfusion; and the obligate growth factor for mast cells, stem cell factor, SCF, is not induced. In summary, the postinfarction inflammatory response and resultant repair in the mouse heart shares many common characteristics with large mammalian species, but has distinct temporal and qualitative features. These important species-specific differences should be considered when interpreting findings derived from studies using genetically altered mice.

Development of murine ischemic cardiomyopathy is associated with a transient inflammatory reaction and depends on reactive oxygen species.

We examined the effects of daily repetitive brief (15 min) myocardial ischemia and reperfusion (I/R) in WT C57BL6 and extracellular superoxide dismutase (EC-SOD)-overexpressing mice. In the absence of myocardial necrosis, I/R resulted in persistent fibrosis in ischemic areas of C57/BL6 mice associated with persistent global and segmental anterior wall dysfunction. The I/R protocol induced chemokines (peak 3 days) followed sequentially by infiltration of macrophages and myofibroblasts (5 days). Fibrosis peaked at 7 days and was stable at 28 days despite regression of the chemokine and cellular response. Discontinuation of I/R at 7 or 28 days led to regression of fibrosis and ventricular dysfunction. In contrast, the EC-SOD mice developed markedly less chemokine induction, cell response, and fibrosis, with no ventricular dysfunction. Reversible fibrosis and ventricular dysfunction are features of human hibernating myocardium. The reduction of the cellular and functional response in EC-SOD mice suggests a role for reactive O(2) in the pathogenesis of ischemic cardiomyopathy.

Mast cells and macrophages in normal C57/BL/6 mice.

Mast cells and macrophages have an important role in immunity and inflammation. Because mice are used extensively for experimental studies investigating immunological and inflammatory responses, we examined mast cell and macrophage distribution in normal murine tissues. Mast cells were abundant in the murine dermis, tongue, and skeletal muscle but were rarely found in the heart, lung, spleen, kidney, liver, and the bowel mucosa. In contrast, dogs exhibited large numbers of mast cells in the lung parenchyma, liver, and bowel. Some murine dermal mast cells had long cytoplasmic projections filled with granular content. Mouse mast cells demonstrated intense histamine immunoreactivity and were identified with histochemical enzymatic techniques for tryptase and chymase. Macrophages, identified using the monoclonal antibody F4/80, were abundant in the spleen, lung, liver, kidney, and bowel but relatively rare in the heart, tongue, and dermis. Using a nuclease protection assay we investigated mRNA expression of stem cell factor (SCF), a crucial survival factor for mast cells, and the macrophage growth factors macrophage colony stimulating factor (M-CSF) and granulocyte macrophage colony stimulating factor (GM-CSF). Stem cell factor mRNA was highly expressed in the murine lung. Relatively low levels of SCF mRNA expression were found in the tongue and earlobe, which are tissues containing a high number of mast cells. Macrophage CSF and GM-CSF mRNA was highly expressed in the lung and spleen. The murine heart, an organ with a low macrophage content, expressed high levels of M-CSF but negligible levels of GM-CSF mRNA. Constitutive growth factor mRNA expression in murine tissues without significant populations of mast cells and macrophages may suggest an alternative role for these factors in tissue homeostasis.