Project description:An orally bioavailable small molecule inhibitor of plasminogen activator inhibitor?1 (PAI?1) is currently being clinically assessed as a novel antithrombotic agent. Although PAI?1 is known to serve a key role in the pathogenesis of metabolic syndrome (MetS) including nonalcoholic steatohepatitis (NASH), the pharmacological action of an oral PAI?1 inhibitor against the development of MetS?related liver fibrosis remains unclear. The current study was designed to explicate the effect of TM5275, an oral PAI?1 inhibitor, on MetS?related hepatic fibrogenesis. The in vivo antifibrotic effect of orally administered TM5275 was investigated in two different rat MetS models. Fischer 344 rats received a choline?deficient L?amino?acid?defined diet for 12 weeks to induce steatohepatitis with development of severe hepatic fibrosis. Otsuka Long?Evans Tokushima Fatty rats, used to model congenital diabetes, underwent intraperitoneal injection of porcine serum for 6 weeks to induce hepatic fibrosis under diabetic conditions. In each experimental model, TM5275 markedly ameliorated the development of hepatic fibrosis and suppressed the proliferation of activated hepatic stellate cells (HSCs). Additionally, the hepatic production of tumor growth factor (TGF)??1 and total collagen was suppressed. In vitro assays revealed that TGF??1 stimulated the upregulation of Serpine1 mRNA expression, which was inhibited by TM5275 treatment in cultured HSC?T6 cells, a rat HSC cell line. Furthermore, TM5275 substantially attenuated the TGF??1?stimulated proliferative and fibrogenic activity of HSCs by inhibiting AKT phosphorylation. Collectively, TM5275 demonstrated an antifibrotic effect on liver fibrosis in different rat MetS models, suppressing TGF??1?induced HSC proliferation and collagen synthesis. Thus, PAI?1 inhibitors may serve as effective future therapeutic agents against NASH?based hepatic fibrosis.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The numerous processes involved in the etiology of breast cancer such as cell survival, metabolism, proliferation, differentiation, and angiogenesis are currently being elucidated. However, underlying mechanisms that drive breast cancer progression and drug resistance are still poorly understood. As we discuss here in detail, the Notch signaling pathway is an important regulatory component of normal breast development, cell fate of normal breast stem cells, and proliferation and survival of breast cancer initiating cells. Notch exerts a wide range of critical effects through a canonical pathway where it is expressed as a type I membrane precursor heterodimer followed by at least two subsequent cleavages induced by ligand engagement to ultimately release an intracellular form to function as a transcriptional activator. Notch and its ligands are overexpressed in breast cancer, and one method of effectively blocking Notch activity is preventing its cleavage at the cell surface with ?-secretase inhibitors. In the context of Notch signaling, the application of clinically relevant anti-Notch drugs in treatment regimens may contribute to novel therapeutic interventions and promote more effective clinical response in women with breast cancer.

Project description:The phenotypic transformation of hepatic myofibroblasts (MFs) is involved in the whole process of the progression and regression of liver fibrosis. Notch signaling has been demonstrated to modulate the fibrosis. In this study, we found that Notch signaling in MFs was overactivated and suppressed with the progression and regression of hepatic fibrosis respectively, by detecting Notch signaling readouts in MFs. Moreover, we inactivated Notch signaling specifically in MFs with Sm22αCreER-RBPjflox/flox mice (RBPjMF-KO), and identified that MFs-specific down-regulation of Notch signaling significantly alleviated CCl4-induced liver fibrosis during the progression and regression. During the progression of liver fibrosis, MFs-specific blockade of Notch signaling inhibited the activation of HSCs to MFs and increases the expression of MMPs to reduce the deposition of ECM. During the regression of fibrosis, blocking Notch signaling in MFs increased the expression of HGF to promote proliferation in hepatocytes and up-regulated the expression of pro-apoptotic factors, Ngfr and Septin4, to induce apoptosis of MFs, thereby accelerating the reversal of fibrosis. Collectively, the MFs-specific disruption of Notch signaling attenuates liver fibrosis by modulating fibrosis progression and regression, which suggests a promising therapeutic strategy for liver fibrosis.

Project description:As the prevalence of obesity-induced type 2 diabetes mellitus (T2DM) and nonalcoholic steatohepatitis (NASH) continue to increase, the need for pharmacologic therapies becomes urgent. However, endeavors to identify and develop novel therapeutic strategies for these chronic conditions are balanced by the need for safety, impeding clinical translation. One shared pathology of these two diseases is a maladaptive reactivation of the Notch signaling pathway in liver. Notch antagonism with γ-secretase inhibitors effectively suppresses hepatic glucose production and reduces liver fibrosis in NASH, but its extrahepatic side effects, particularly goblet cell metaplasia, limit therapeutic utility. To overcome this barrier, we developed a nanoparticle-mediated delivery system to target γ-secretase inhibitor to liver (GSI NPs). GSI NP application reduced hepatic glucose production in diet-induced obese mice and reduced hepatic fibrosis and inflammation in mice fed a NASH-provoking diet, without apparent gastrointestinal toxicity. By changing the delivery method, these results provide proof-of-concept for the repurposing of a previously intolerable medication to address unmet needs in the clinical landscape for obesity-induced T2DM and NASH.

Project description:Approximately 10% of skeletal fractures result in healing complications and non-union, while most fractures repair with appropriate stabilization and without pharmacologic intervention. It is the latter injuries that cannot be underestimated as the expenses associated with their treatment and subsequent lost productivity are predicted to increase to over $74 billion by 2015. During fracture repair, local mesenchymal stem/progenitor cells (MSCs) differentiate to form new cartilage and bone, reminiscent of events during skeletal development. We previously demonstrated that permanent loss of gamma-secretase activity and Notch signaling accelerates bone and cartilage formation from MSC progenitors during skeletal development, leading to pathologic acquisition of bone and depletion of bone marrow derived MSCs. Here, we investigated whether transient and systemic gamma-secretase and Notch inhibition is capable of accelerating and enhancing fracture repair by promoting controlled MSC differentiation near the fracture site. Our radiographic, microCT, histological, cell and molecular analyses reveal that single and intermittent gamma-secretase inhibitor (GSI) treatments significantly enhance cartilage and bone callus formation via the promotion of MSC differentiation, resulting in only a moderate reduction of local MSCs. Biomechanical testing further demonstrates that GSI treated fractures exhibit superior strength earlier in the healing process, with single dose GSI treated fractures exhibiting bone strength approaching that of un-fractured tibiae. These data further establish that transient inhibition of gamma-secretase activity and Notch signaling temporarily increases osteoclastogenesis and accelerates bone remodeling, which coupled with the effects on MSCs likely explains the accelerated and enhanced fracture repair. Therefore, we propose that the Notch pathway serves as an important therapeutic target during skeletal fracture repair.

Project description:Inhibition of endothelial Notch signaling attenuates inflammation

Project description:OBJECTIVE:Tissue fibrosis caused by pathologic activation of fibroblasts with increased synthesis of extracellular matrix components is a major hallmark of systemic sclerosis (SSc). Notch signaling regulates tissue differentiation, and abnormal activation of Notch signaling has been implicated in the pathogenesis of various malignancies. The present study was undertaken to investigate the role of Notch signaling in SSc and to evaluate the therapeutic potential of Notch inhibition for the treatment of fibrosis. METHODS:Activation of the Notch pathways was analyzed by staining for the Notch intracellular domain (NICD) and quantification of levels of HES-1 messenger RNA. In the mouse model of bleomycin-induced dermal fibrosis and in tight skin 1 mice, Notch signaling was inhibited by the ?-secretase inhibitor DAPT and by overexpression of a Notch-1 antisense construct. RESULTS:Notch signaling was activated in SSc in vivo, with accumulation of the NICD and increased transcription of the target gene HES-1. Overexpression of a Notch antisense construct prevented bleomycin-induced fibrosis and hypodermal thickening in tight skin 1 mice. Potent antifibrotic effects were also obtained with DAPT treatment. In addition to prevention of fibrosis, targeting of Notch signaling resulted in almost complete regression of established experimental fibrosis. CONCLUSION:The present results demonstrate that pharmacologic as well as genetic inhibition of Notch signaling exerts potent antifibrotic effects in different murine models of SSc. These findings might have direct translational implications because different inhibitors of the ?-secretase complex are available and have yielded promising results in cancer trials.

Project description:Vascular endothelial cells upregulate the Notch ligand Jagged1 in response to inflammatory activation. Here we show that abrogation of endothelial Notch1 signaling impairs induction of key inflammatory target genes. Accordingly, inducible endothelial-targeted knockout of the canonical Notch transcription factor RBPJ reduces inflammation in a murine model of contact hypersensitivity, while overexpression of constitutive active Notch1 has the opposite effect. We show that the proinflammatory role of Notch1 can be attributed to direct genomic priming of the inflammatory landscape involving crosstalk with NF-κB/RelA and selective activation of enhancers associated with Notch-dependent inflammatory genes. This is the first evidence that canonical Notch signaling supports endothelial activation in response to inflammatory cytokines on the chromatin level.

Project description:A phase I trial of PF-03084014, an oral reversible ?-secretase inhibitor, in solid tumor malignancies shows drug tolerability in patients. Evidence of Notch pathway inhibition was demonstrated in peripheral blood. A surprisingly high rate of response was seen in desmoid tumors, a rare but sometimes locally aggressive sarcoma.