Expression, release, and biological activity of parathyroid hormone-related peptide from coronary endothelial cells.

Ventricular cardiomyocytes have previously been identified as potential target cells for parathyroid hormone-related peptide (PTHrP). Synthetic PTHrP peptides exert a positive contractile effect. Because systemic PTHrP levels are normally negligible, this suggests that PTHrP is expressed in the ventricle and acts as a paracrine mediator. We investigated the ventricular expression of PTHrP and its expression in cultured cells isolated from the ventricle, studied the release of PTHrP from hearts and cultures, and investigated whether this authentic PTHrP mimics the biological effects previously described for synthetic PTHrP on ventricular cardiomyocytes. We found PTHrP expressed in ventricles of neonatal and adult rat hearts. In cells isolated from adult hearts, we found PTHrP expression exclusively in coronary endothelial cells but not in cardiomyocytes. The latter, however, are target cells for PTHrP. PTHrP was released from isolated perfused hearts during hypoxic perfusion and from cultured coronary endothelial cells under energy-depleting conditions. This PTHrP was biologically active; ie, it exerted a positive contractile and lusitropic effect on cardiomyocytes. Authentic PTHrP was glycosylated and showed a slightly higher potency than synthetic PTHrP. These results suggest that PTHrP is an endothelium-derived modulator of ventricular function.

Central role for ornithine decarboxylase in beta-adrenoceptor mediated hypertrophy.

OBJECTIVE: TGF-beta stimulation of cardiac myocytes induces a hypertrophic responsiveness to beta-adrenoceptor stimulation. This study investigates whether this beta-adrenoceptor mediated effect depends on induction of ornithine decarboxylase (ODC). METHODS: Isolated adult ventricular cardiomyocytes from rats were used as an experimental model. Cells were either cultured in 20% (v/v) FCS to activate autocrine released TGF-beta or used without pre-treatment. The hypertrophic response was characterized by an increased 14C-phenylalanine incorporation, RNA and protein mass or by an increased expression of atrionatriurectic factor and ODC. The results on cell cultures were compared to those achieved by isoprenaline perfused mice hearts from transgenic mice overexpressing TGF-beta 1. RESULTS: ODC activity and expression increased within 2 h in TGF-beta 1 pre-treated cells under isoprenaline. In the presence of ODC inhibitors (alpha-methylornithine or difluoromethylornithine) this increase remained absent and the increases in 14C-phenylalanine incorporation, protein and RNA mass under isoprenaline were abolished. In cells not exposed to TGF-beta no induction of ODC was observed. Isoprenaline also induced ODC in isolated perfused ventricles from transgenic mice overexpressing TGF-beta 1, but not in ventricles from their nontransgenic counterparts. CONCLUSIONS: This study shows first, a pivotal role for ODC induction in the hypertrophic response of cardiomyocytes to beta-adrenoceptor stimulation and second, that ODC induction in vivo and in vitro requires pre-treatment of cardiomyocytes with TGF-beta. It is concluded that TGF-beta induces a hypertrophic responsiveness to beta-adrenoceptor stimulation that is characterized by ODC induction.

Hypertrophic effect of selective beta(1)-adrenoceptor stimulation on ventricular cardiomyocytes from adult rat.

We investigated whether selective beta(1)-adrenoceptor stimulation causes hypertrophic growth on isolated ventricular cardiomyocytes from adult rat. As parameters for the induction of hypertrophic growth, the increases of [(14)C]phenylalanine incorporation, protein and RNA mass, and cell size were determined. Isoproterenol (Iso, 10 microM) alone had no growth effect. In the presence of the beta(2)-adrenoceptor antagonist ICI-118551 (ICI, 10 microM), Iso caused an increase in [(14)C]phenylalanine incorporation, protein and RNA mass, cell volume, and cross-sectional area. We showed for phenylalanine incorporation that the growth effect of Iso+ICI could be antagonized by beta(1)-adrenoceptor blockade with atenolol (10 microM) or metoprolol (10 microM), indicating that it was caused by selective beta(1)-adrenoceptor stimulation. The growth response to Iso+ICI was accompanied by an increase in ornithine decarboxylase (ODC) activity and expression. Inhibition of ODC by the ODC antagonist difluoromethylornithine (1 mM) attenuated this hypertrophic response, indicating that ODC induction is causally involved. The growth response to Iso+ICI was found to be cAMP independent but was sensitive to genistein (100 microM) or rapamycin (0.1 microM). The reaction was enhanced in the presence of pertussis toxin (10 microM). We conclude that selective beta(1)-adrenoceptor stimulation causes hypertrophic growth of ventricular cardiomyocytes by a mechanism that is independent of cAMP but dependent on a tyrosine kinase and ODC.

Autocrine regulation of TGF beta expression in adult cardiomyocytes.

As shown before, TGF beta acts in an autocrine manner on the induction of hypertrophic responsiveness to beta-adrenoceptor stimulation in cultured ventricular cardiomyocytes of adult rat. We now investigated how TGF beta expression and activation is regulated in these cultures and how beta-adrenoceptor stimulation influences TGF beta -mRNA expression. It was found that freshly isolated cardiomyocytes secrete latent TGF beta in the culture medium. Supplementation of the cultures with 20% FCS resulted in activation of the secreted TGF beta to 4.1+/-0.2 ng/ml active TGF beta after 6 days. Presence of the protease inhibitor aprotinin (50 microg/ml) reduced TGF beta activity by 44+/-5% (n=5, P<0.05). In cultures supplemented with 5% FCS, TGF beta was not activated. Active TGF beta downregulated its mRNA-expression: after 6 days TGF beta(1)-mRNA was reduced to 55.1+/-11.0%, TGF beta(2)-mRNA to 30.1+/-16.5%, and TGF beta(3)-mRNA to 0.3+/-0.4% in 20% FCS-cultures as compared to their expression in freshly isolated cells (n=4, P<0.05). TGF beta-mRNA expression did not change in cultures without active TGF beta. Isoprenaline (1 microm) increased TGF beta(1)-mRNA only in cultures which had been pre-exposed to active TGF beta. This effect was also seen when hearts from normal mice were compared with hearts from transgenic mice overexpressing TGF beta(1): only in hearts from transgenic animals perfusion with isoprenaline increased TGF beta(1)-mRNA. In conclusion, isolated cardiomyocytes release latent TGF beta, which is activated by external proteases. Active TGF beta downregulates its own mRNA expression. Preexposure to TGF beta is necessary for a beta-adrenoceptor-mediated increase in TGF beta(1)-mRNA in cardiomyocytes.

TGF-beta(1) downregulates PTHrP in coronary endothelial cells.

Parathyroid hormone-related peptide (PTHrP) is expressed throughout the cardiovascular system including coronary endothelial cells. Factors involved in the regulation of cardiac PTHrP expression have not been examined before. This study investigates the influence of transforming growth factor (TGF)-beta(1)on ventricular PTHrP expression. Coronary endothelial cells were isolated from ventricles of adult rats and PTHrP protein expression in these cultures was analysed by immunoblotting. TGF-beta(1)caused a concentration-dependent reduction in PTHrP protein within 24 h. In transgenic mice over-expressing TGF-beta(1)ventricular PTHrP protein expression and release was reduced compared to non-transgenic littermates. Similar concerns hold for PTHrP mRNA content (RT-PCR). Since ventricular TGF-beta(1)expression increases under pathophysiological conditions like arterial hypertension, ventricular PTHrP expression was further determined in aging spontaneously hypertensive (SHR-SP) and normotensive rats. TGF- beta(1)expression was increased in SHR-SP and ventricular PTHrP mRNA expression was downregulated at the age of 10 months. PTHrP expression did not recover in elder SHR-SP in which TGF-beta(1)expression was normalized again. Finally, we investigated ventricular PTHrP expression in rats after banding of the ascending aorta which generates a pressure induced hypertrophy without an induction of TGF-beta(1)expression. In ventricles from these animals, PTHrP expression was transiently increased and normalized at day 3. In conclusion, PTHrP expression was reduced under all conditions in which coronary endothelial cells were exposed to TGF-beta(1). PTHrP expression does not correlate with cardiac hypertrophy. Since coronary endothelial cells represent the majority of PTHrP producing cells in the ventricle its downregulation by TGF- beta(1)seems to be relevant for the paracrine effects of PTHrP.