Heart muscle maintains blood circulation, while skeletal muscle powers skeletal movement. Despite having similar myofibrilar sarcomeric structures, these striated muscles differentially express specific sarcomere components to meet their distinct contractile requirements. The mechanism responsible is still unclear. We show here that preservation of the identity of the two striated muscle types depends on epigenetic repression of the alternate lineage gene program by the chromatin remodeling complex Chd4/NuRD. Loss of Chd4 in the heart triggers aberrant expression of the skeletal muscle program, causing severe cardiomyopathy and sudden death. Conversely, genetic depletion of Chd4 in skeletal muscle causes inappropriate expression of cardiac genes and myopathy. In both striated tissues, mitochondrial function was also dependent on the Chd4/NuRD complex. We conclude that an epigenetic mechanism controls cardiac and skeletal muscle structural and metabolic identities and that loss of this regulation leads to hybrid striated muscle tissues incompatible with life.
Apoptosis occurs through a sequence of specific biochemical and morphological alterations that define the progress of cell death. The changes of the mitochondrial inner membrane potential (DC m ), the release of cytochrome c to the cytosol, the apoptotic volume decrease (AVD) and the activation of caspases have been measured in RAW 264.7, HeLa and Jurkat T cells incubated with molecules that induce apoptosis through the mitochondrial pathway. Our data show that NO, staurosporine, etoposide and camptothecin increased DC m in macrophages but not in HeLa and Jurkat cells, that exhibited a DC m decrease. Moreover, the apoptosis induced by NO in macrophages, but not that promoted by staurosporine, might occur in the absence of AVD. Analysis of the sequence of apoptotic manifestations shows that DC m precedes AVD and caspase activation in RAW 264.7 cells. Inhibition of AVD abrogates apoptosis in HeLa and Jurkat T cells regardless of the stimuli used. These data suggest that the changes of DC m are cell-type dependent and that AVD is dispensable for apoptosis in macrophages.
Formation of the coronary vasculature requires reciprocal signaling between endothelial, epicardially derived smooth muscle and underlying myocardial cells. Our studies show that calcineurin-NFAT signaling functions in endothelial cells within specific time windows to regulate coronary vessel development. Mouse embryos exposed to cyclosporin A (CsA), which inhibits calcineurin phosphatase activity, failed to develop normal coronary vasculature. To determine the cellular site at which calcineurin functions for coronary angiogenesis, we deleted calcineurin in endothelial, epicardial and myocardial cells. Disruption of calcineurin-NFAT signaling in endothelial cells resulted in the failure of coronary angiogenesis, recapitulating the coronary phenotype observed in CsA-treated embryos. By contrast, deletion of calcineurin in either epicardial or myocardial cells had no effect on coronary vasculature during early embryogenesis. To define the temporal requirement for NFAT signaling, we treated developing embryos with CsA at overlapping windows from E9.5 to E12.5 and examined coronary development at E12.5. These experiments demonstrated that calcineurin-NFAT signaling functions between E10.5 and E11.5 to regulate coronary angiogenesis. Consistent with these in vivo observations, endothelial cells exposed to CsA within specific time windows in tissue culture were unable to form tubular structures and their cellular responses to VEGF-A were blunted. Thus, our studies demonstrate specific temporal and spatial requirements of NFAT signaling for coronary vessel angiogenesis. These requirements are distinct from the roles of NFAT signaling in the angiogenesis of peripheral somatic vessels, providing an example of the environmental influence of different vascular beds on the in vivo endothelial responses to angiogenic stimuli.
The role of hepatic nitric oxide (NO) in liver regeneration after partial hepatectomy (PH) was studied in animals carrying a nitric oxide synthase-2 transgene under the control of the phospho(enol)pyruvate carboxykinase promoter. These mice expressed NOS-2 in liver cells under fasting conditions. Liver mass recovery and molecular parameters related to cell proliferation were determined after PH. Preexisting hepatic NO synthesis, as well as NO delivery by NO-donors, impaired early signaling (for example, attenuated NF-kappaB activation and TNF-alpha and IL-6 release). The regenerative process was also impaired as a result of an insufficient proliferative response, but mouse survival after surgery was not compromised. However, NO exerted a protective role against apoptosis in transgenic hepatectomized mice. Local production of NO in liver cells, achieved by hydrodynamic-based transfection with a NOS-2-encoding plasmid, also resulted in delayed liver recovery after PH and also protected against Fas-mediated apoptosis. These data show that sustained presence of NO after PH exerts a dual role: attenuating liver regeneration while efficiently protecting against liver apoptosis.
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