BackgroundPrevious work has shown reduced expression levels of let-7 in lung tumors. But little is known about the expression or mechanisms of let-7a in prostate cancer. In this study, we used in vitro and in vivo approaches to investigate whether E2F2 and CCND2 are direct targets of let-7a, and if let-7a acts as a tumor suppressor in prostate cancer by down-regulating E2F2 and CCND2.Methodology/PrincipalFindings Real-time RT-PCR demonstrated that decreased levels of let-7a are present in resected prostate cancer samples and prostate cancer cell lines. Cellular proliferation was inhibited in PC3 cells and LNCaP cells after transfection with let-7a. Cell cycle analysis showed that let-7a induced cell cycle arrest at the G1/S phase. A dual-luciferase reporter assay demonstrated that the 3′UTR of E2F2 and CCND2 were directly bound to let-7a and western blotting analysis further indicated that let-7a down-regulated the expression of E2F2 and CCND2. Our xenograft models of prostate cancer confirmed the capability of let-7a to inhibit prostate tumor development in vivo.Conclusions/SignificanceThese findings help to unravel the anti-proliferative mechanisms of let-7a in prostate cancer. Let-7a may also be novel therapeutic candidate for prostate cancer given its ability to induce cell-cycle arrest and inhibit cell growth, especially in hormone-refractory prostate cancer.
Nonalcoholic fatty liver disease (NAFLD) is the most common liver disease and affects millions of people worldwide. Despite the increasing prevalence of NAFLD, the exact molecular/cellular mechanisms remain obscure and effective therapeutic strategies are still limited. It is well-accepted that free fatty acid (FFA)-induced lipotoxicity plays a pivotal role in the pathogenesis of NAFLD. Inhibition of FFA-associated hepatic toxicity represents a potential therapeutic strategy. Glycyrrhizin (GL), the major bioactive component of licorice root extract, has a variety of pharmacological properties including anti-inflammatory, antioxidant, and immune-modulating activities. GL has been used to treat hepatitis to reduce liver inflammation and hepatic injury; however, the mechanism underlying the antihepatic injury property of GL is still poorly understood. In this report, we provide evidence that 18 -glycyrrhetinic acid (GA), the biologically active metabolite of GL, prevented FFA-induced lipid accumulation and cell apoptosis in in vitro HepG2 (human liver cell line) NAFLD models. GA also prevented high fat diet (HFD)-induced hepatic lipotoxicity and liver injury in in vivo rat NAFLD models. GA was found to stabilize lysosomal membranes, inhibit cathepsin B expression and enzyme activity, inhibit mitochondrial cytochrome c release, and reduce FFA-induced oxidative stress. These characteristics may represent major cellular mechanisms, which account for its protective effects on FFA/HFD-induced hepatic lipotoxicity. Conclusion: GA significantly reduced FFA/HFD-induced hepatic lipotoxicity by stabilizing the integrity of lysosomes and mitochondria and inhibiting cathepsin B expression and enzyme activity.
Obesity and related metabolic diseases associated with chronic low-grade inflammation greatly compromise human health. Previous observations on the roles of interferon regulatory factors (IRFs) in the regulation of metabolism prompted investigation of the involvement of a key family member, IRF3, in metabolic disorders. IRF3 expression in the liver is decreased in animals with diet-induced and genetic obesity. The global knockout (KO) of IRF3 significantly promotes chronic high-fat diet (HFD)-induced hepatic insulin resistance and steatosis; in contrast, adenoviral-mediated hepatic IRF3 overexpression preserves glucose and lipid homeostasis. Furthermore, systemic and hepatic inflammation, which is increased in IRF3 KO mice, is attenuated by the overexpression of hepatic IRF3. Importantly, inhibitor of nuclear factor kappa B kinase beta subunit / nuclear factor kappa B (IKKb/NF-jB) signaling is repressed by IRF3, and hepatic overexpression of the inhibitor of jB-a (IjBa) reverses HFD-induced insulin resistance and steatosis in IRF3 KO mice. Mechanistically, IRF3 interacts with the kinase domain of IKKb in the cytoplasm and inhibits its downstream signaling. Moreover, deletion of the region of IRF3 responsible for the IRF3/IKKb interaction inhibits the capacity of IRF3 to preserve glucose and lipid homeostasis. Conclusion: IRF3 interacts with IKKb in the cytoplasm to inhibit IKKb/NF-jB signaling, thus alleviating hepatic inflammation, insulin resistance, and hepatic steatosis. (HEPATOLOGY 2014;59:870-885) M etabolic diseases, including obesity, type 2 diabetes (T2D), and nonalcoholic fatty liver disease (NAFLD), currently threaten human lives due to continued urbanization and population aging.1 Evidence from both clinical and basic research substantiates the notion that inflammation underlies the etiology of obesity-related metabolic disorders.
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