Distinction between two populations of islet-1-positive cells in hearts of different murine strains.

Islet-1 expression identifies populations of progenitor cells in embryonic, fetal, and newborn murine hearts that are able to give rise to all cardiac cell lineages ex vivo and in vivo. Using systematic immunohistochemistry, we investigated whether islet-1-positive cells are present in adult mouse heart from the perspective of their potential therapeutic utility. The presence, localization, and nature of islet-1-positive cells were assessed in mice of different strains, ages, and conditions. Islet-1-positive cells were present in mouse heart from postnatal day 1 to young adulthood. Depending on the strain, these cells were organized in either 1 or 2 types of clusters localized to restricted areas, at a distance of 6%-35% of the heart length from the base. The first type of cluster was present in all strains and consisted of neural crest-derived cells that formed cardiac ganglia. The number of cells remained stable (a few hundred) from neonatal up to adult ages, and variations were noted between strains regarding their long-term persistency. The second type of cluster was essentially present in 129SvJ or Balb/C strains and absent from the other strains tested (C57BL/6J, C3H, SJL). It consisted of cells expressing highly ordered sarcomeric actin, consistent with their having cardiomyocyte identity. These cells disappeared in animals older than 4 months. Neither the number nor the type of islet-1-positive cells varied with time in a mouse model of dilated cardiomyopathy. Our studies demonstrate that islet-1-positive cells are relatively few in number in adult murine heart, being localized in restricted and rather inaccessible areas, and can represent both neural crest and cardiomyocyte lineages.

MMP-9 overexpression improves myogenic cell migration and engraftment.

Myoblast migration requires matrix metalloproteinase (MMP) activity but the contribution of individual MMPs or tissue inhibitors of matrix metalloproteinase (TIMPs), particularly MMP-9 and TIMP-1, is lacking. Using two clones derived for differential regulation of MMP-2, MMP-9, and TIMP-1, we correlated protein expression with cell migration. MMP/TIMP regulation was determined by zymography, western blots, and quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR). Cell migration was compared in vitro and after grafting into nude-mdx mouse muscles. C2M9 clones produced high MMP-9 and low MMP-2, and migrated better than C2F clones, which secreted low MMP-9, but overexpressed MMP-2 and TIMP-1. Improvement of C2F invasion by MMP-9 and inhibition of C2M9 migration by MMP-9 inhibitor I confirmed the role of MMP-9 and pointed to potential inhibition by TIMP-1. Higher complementation achieved by C2M9 grafts corroborated the beneficial effect of MMP-9 overexpression. Modulation of MMP-9 expression opens perspectives for improved efficacy of cell therapy for muscular dystrophies.

Ca2+ overload and mitochondrial permeability transition pore activation in living delta-sarcoglycan-deficient cardiomyocytes.

Muscular dystrophies are often associated with significant cardiac disease that can be the prominent feature associated with gene mutations in sarcoglycan. Cardiac cell death is a main feature of cardiomyopathy in sarcoglycan deficiency and may arise as a cardiomyocyte intrinsic process that remains unclear. Deficiency of delta-sarcoglycan (delta-SG) induces disruption of the dystrophin-associated glycoprotein complex, a known cause of membrane instability that may explain cardiomyocytes cytosolic Ca2+ increase. In this study we assessed the hypothesis that cytosolic Ca2+ increase triggers cardiomyocyte death through mitochondrial Ca2+ overload and dysfunction in the delta-SG-deficient CHF147 hamster. We showed that virtually all isolated CHF147 ventricular myocytes exhibited elevated cytosolic and mitochondrial Ca2+ levels by the use of the Fura-2 and Rhod-2 fluorescent probes. Observation of living cells with Mito-Tracker red lead to the conclusion that approximately 15% of isolated CHF147 cardiomyocytes had disorganized mitochondria. Transmission electron microscope imaging showed mitochondrial swelling associated with crest and membrane disruption. Analysis of the mitochondrial permeability transition pore (MPTP) activity using calcein revealed that mitochondria of CHF147 ventricular cells were twofold leakier than wild types, whereas reactive oxygen species production was unchanged. Bax, Bcl-2, and LC3 expression analysis by Western blot indicated that the intrinsic apoptosis and the cell death associated to autophagy pathways were not significantly activated in CHF147 hearts. Our results lead to conclusion that cardiomyocytes death in delta-SG-deficient animals is an intrinsic phenomenon, likely related to Ca2+-induced necrosis. In this process Ca2+ overload-induced MPTP activation and mitochondrial disorganization may have an important role.

Short-term treatment using insulin-like growth factor-1 (IGF-1) improves life expectancy of the delta-sarcoglycan deficient hamster.

BACKGROUND: The hamster strain CHF147 presents a progressive dilated cardiomyopathy (DCM) due to a large deletion of the delta-sarcoglycan gene that leads to heart failure. This cardiomyopathy induces premature death. We have previously shown that a short-term treatment using IGF-1 preserves cardiac structure and improves function of the CHF147 hamster. METHODS: In the current study, we measured long-term effects of short-term treatment with recombinant human IGF-1 (rhIGF-1) in CHF147 hamsters. CHF147 hamsters (7-8 months old) were implanted under the skin with an osmotic pump filled either with saline or with recombinant human IGF-1 at a total dose of 25 microg. The osmotic pump allowed a continuous delivery of the protein for a mean duration of 19 days. RESULTS: We observed a significant increase in overall survival, as well as preservation of cardiac function, in the rhIGF-1-treated group. At the time of death, hearts of treated animals did not present any macroscopical or histological differences compared to those of sham hamsters. These results show that rhIGF-1 treatment slows down the evolution of the DCM in the CHF147 hamster. Moreover, the low dose treatment did not increase IGF-1 serum levels. CONCLUSIONS: This study is the first one reporting beneficial effects of IGF-1 treatment on survival of an animal model presenting DCM. Our results raise hopes for a new therapeutic approach of this pathology.

Administration of insulin-like growth factor-1 (IGF-1) improves both structure and function of delta-sarcoglycan deficient cardiac muscle in the hamster.

Dilated cardiomyopathies (DCM) are due to progressive dilatation of the cardiac cavities and thinning of the ventricular walls and lead unavoidably to heart failure. They represent a major cause for heart transplantation and, therefore, defining an efficient symptomatic treatment for DCM remains a challenge. We have taken advantage of the hamster strain CHF147 that displays progressive cardiomyopathy leading to heart failure to test whether stimulation of a hypertrophic pathway could delay the process of dilatation.Six month old CHF147 hamsters were treated with IGF-1 so that we could compare the efficacy of systemic administration of human recombinant IGF-1 protein (rh IGF-1) at low dose to that of direct myocardial injections of a plasmid DNA containing IGF-1 cDNA (pCMV-IGF1).IGF-1 treatment did not induce a significant variation of ventricle mass, but preserved left ventricular (LV) wall thickness and delayed dilatation of cardiac cavities when compared to non-treated hamsters. Together with this reduction of dilatation, we also noted a reduction in the amount of interstitial collagen. Furthermore, IGF-1 treatment induced beneficial effects on cardiac function since treated hamsters presented improved cardiac output and stroke volume, decreased end diastolic pressure when compared to nontreated hamsters and also showed a trend towards increased contractility (dP/dt(max)).This study provides evidence that IGF-1 treatment induces beneficial structural and functional effects on DCM of CHF147 hamsters, hence making this molecule a promising candidate for future gene therapy of heart failure due to DCM.