Transforming growth factor ß neutralization ameliorates pre-existing hepatic fibrosis and reduces cholangiocarcinoma in thioacetamide-treated rats.

Considerable evidence has demonstrated that transforming growth factor ß (TGF-ß) plays a key role in hepatic fibrosis, the final common pathway for a variety of chronic liver diseases leading to liver insufficiency. Although a few studies have reported that blocking TGF-ß with soluble receptors or siRNA can prevent the progression of hepatic fibrosis, as yet no evidence has been provided that TGF-ß antagonism can improve pre-existing hepatic fibrosis. The aim of this study was to examine the effects of a murine neutralizing TGF-ß monoclonal antibody (1D11), in a rat model of thioacetamide (TAA)-induced hepatic fibrosis. TAA administration for 8 weeks induced extensive hepatic fibrosis, whereupon 1D11 dosing was initiated and maintained for 8 additional weeks. Comparing the extent of fibrosis at two time points, pre- and post-1D11 dosing, we observed a profound regression of tissue injury and fibrosis upon treatment, as reflected by a reduction of collagen deposition to a level significantly less than that observed before 1D11 dosing. Hepatic TGF-ß1 mRNA, tissue hydroxyproline, and plasminogen activator inhibitor 1 (PAI-1) levels were significantly elevated at the end of the 8 week TAA treatment. Vehicle and antibody control groups demonstrated progressive injury through 16 weeks, whereas those animals treated for 8 weeks with 1D11 showed striking improvement in histologic and molecular endpoints. During the course of tissue injury, TAA also induced cholangiocarcinomas. At the end of study, the number and area of cholangiocarcinomas were significantly diminished in rats receiving 1D11 as compared to control groups, presumably by the marked reduction of supporting fibrosis/stroma. The present study demonstrates that 1D11 can reverse pre-existing hepatic fibrosis induced by extended dosing of TAA. The regression of fibrosis was accompanied by a marked reduction in concomitantly developed cholangiocarcinomas. These data provide evidence that therapeutic dosing of a TGF-ß antagonist can diminish and potentially reverse hepatic fibrosis and also reduce the number and size of attendant cholangiocarcinomas.

Deletion of cytosolic phospholipase A2 promotes striated muscle growth.

Generation of arachidonic acid by the ubiquitously expressed cytosolic phospholipase A2 (PLA2) has a fundamental role in the regulation of cellular homeostasis, inflammation and tumorigenesis. Here we report that cytosolic PLA2 is a negative regulator of growth, specifically of striated muscle. We find that normal growth of skeletal muscle, as well as normal and pathologic stress-induced hypertrophic growth of the heart, are exaggerated in Pla2g4a-/- mice, which lack the gene encoding cytosolic PLA2. The mechanism underlying this phenotype is that cytosolic PLA2 negatively regulates insulin-like growth factor (IGF)-1 signaling. Absence of cytosolic PLA2 leads to sustained activation of the IGF-1 pathway, which results from the failure of 3-phosphoinositide-dependent protein kinase (PDK)-1 to recruit and phosphorylate protein kinase C (PKC)-zeta, a negative regulator of IGF-1 signaling. Arachidonic acid restores activation of PKC-zeta, correcting the exaggerated IGF-1 signaling. These results indicate that cytosolic PLA2 and arachidonic acid regulate striated muscle growth by modulating multiple growth-regulatory pathways.

Strategic advantages of insulin-like growth factor-I expression for cardioprotection.

BACKGROUND: Insulin-like growth factor-I (IGF-I) peptide has beneficial effects on cardiomyocyte function and survival, many of which are mediated through the serine-threonine kinase, Akt. However, concerns about systemic effects of IGF-I peptide limit its clinical application. The present study tested whether local IGF-I expression could mediate cardioprotection without elevating serum [IGF-I]. METHODS: The ability of a recombinant adenovirus encoding IGF-IB (Ad.IGF-I) to activate Akt and protect cardiomyocytes from hypoxia-induced apoptosis in vitro was compared with the effects of IGF-I peptide or expression of constitutively active Akt (myr-Akt). In vivo, cardiac IGF-I gene transfer was performed prior to ischemia-reperfusion injury (IRI). Effects on the ischemic and infarcted areas were assessed while serum [IGF-I] was measured by radioimmunoassay. RESULTS: Compared with IGF-I peptide, Ad.IGF-I achieved more sustained activation of Akt and reduced hypoxia-induced apoptosis at lower media IGF-I concentrations. In a co-culture system, Ad.IGF-I protected both infected and uninfected cells from hypoxic injury, while myr-Akt protected only infected cells. In vivo cardiac injection of Ad.IGF-I mediated significant local IGF-I expression, without affecting serum [IGF-I] levels. After IRI, Ad.IGF-I did not affect the ischemic area but reduced infarct size approximately 50% (32 +/- 13 vs. 64 +/- 14% AAR in Ad.GFP rats, p < 0.003), although the transgene was expressed in only approximately 15% of the ischemic region, consistent with possible paracrine benefit. CONCLUSIONS: Somatic gene transfer of IGF-I may offer strategic advantages over both systemic delivery of IGF-I peptide and expression of cell autonomous cardioprotective transgenes such as Akt by mediating autocrine and paracrine cardiomyocyte protection without elevating serum [IGF-I] levels.

Akt signaling mediates postnatal heart growth in response to insulin and nutritional status.

Akt is a serine-threonine kinase that mediates a variety of cellular responses to external stimuli. During postnatal development, Akt signaling in the heart was up-regulated when the heart was rapidly growing and was down-regulated by caloric restriction, suggesting a role of Akt in nutrient-dependent regulation of cardiac growth. Consistent with this notion, reductions in Akt, 70-kDa S6 kinase 1, and eukaryotic initiation factor 4E-binding protein 1 phosphorylation were observed in mice with cardiac-specific deletion of insulin receptor gene, which exhibit a small heart phenotype. In contrast to wild type animals, caloric restriction in these mice had little effect on Akt phosphorylation in the heart. Furthermore, forced expression of Akt1 in these hearts restored 70-kDa S6 kinase 1 and eukaryotic initiation factor 4E-binding protein 1 phosphorylation to normal levels and rescued the small heart phenotype. Collectively, these results indicate that Akt signaling mediates insulin-dependent physiological heart growth during postnatal development and suggest a mechanism by which heart size is coordinated with overall body size as the nutritional status of the organism is varied.