A number of pro-fibrogenic stimuli, such as growth factors, cytokines and extracellular matrix (ECM) proteins, involve Akt and its downstream substrates in mediating their effects. We previously reported that absence of Akt1, which is the predominant isoform of the three gene Akt family in vascular cells, resulted in impaired ECM remodeling in skin and vasculature. In the current study, we investigated the importance of Akt1 in TGFβ-and bleomycin-induced synthesis and secretion of ECM proteins by fibroblasts. We observed that both TGFβ and bleomycin stimulated the synthesis of ECM proteins in a dose-and time-dependent manner. Treatment with TGFβ and bleomycin also resulted in increased phosphorylation of Akt, mammalian target of rapamycin (mTOR) and their downstream signaling partners, p70S6 Kinase, Ribosomal S6 protein and 4E-BP1, resulting in the activation of this pathway. The effects of TGFβ and bleomycin on ECM synthesis were blunted by pre-treatment with an mTOR inhibitor rapamycin. Whereas mTOR is responsible for the transcriptional regulation of a number of ECM proteins, adhesion molecules and matrix metalloproteases (MMPs), synthesis of major ECM proteins such as fibronectin and collagens (types I, II and V) by fibroblasts in response to TGFβ and bleomycin is regulated by mTOR at the translational level. These findings indicate the importance of the AktmTOR signaling pathway in TGF-mediated fibrogenic events in vivo.
Background: Statins are a class of drugs that inhibits HMG-CoA reductase, a rate liming enzyme in cholesterol synthesis. Simvastatin, a widely used generic drug for preventing cardiovascular events inhibit inflammation and stabilize atherosclerotic plaques. Growing body of evidences suggest that statins have the potential to reduce the risk of many cancer types. Objectives and Hypothesis: Our long-term goal is to enable the development of new and innovative therapeutics for prostate cancer through better understanding of the molecular mechanisms regulating prostate cancer growth and bone metastasis. In prostate cancer cells, simvastatin is known to induce apoptosis. Akt, a multitask signaling molecule, is the major survival kinase activated in cancer cells. Our central hypothesis is that treatment with simvastatin will inhibit Akt affecting prostate cancer cell function, tumor growth and metastasis. The rationale for the proposed research is that, once it is known mechanistically how simvastatin regulates prostate cancer cell function, it is likely that prostate tumor growth and metastasis can be downregulated therapeutically utilizing simvastatin using a novel drug-repurposing strategy. This would be of singular importance in the management of this disease. Experimental Design and Results: In the current study, we sought to investigate the pleiotropic effects of simvastatin on major signaling pathways in prostate cancer cells with respect to the regulation of cellular functions such as migration, proliferation, colony/foci formation and invasion, along with its already known effects on apoptosis. Time- and dose-effects of simvastatin on LNCaP (androgen-dependent) and PC-3 (androgen-independent) cells indicated that treatment with as low as 25µM simvastatin was sufficient to inhibit serum-stimulated activation of Akt-mTOR and cRaf-ERK pathways. Akin to this, treatment with 25µM simvastatin significantly inhibited serum- and EGF-induced cell migration, invasion, colony formation and proliferation. Simvastatin-mediated effects on cell migration and colony formation was rescued by adenovirus-mediated expression of constitutively active Akt (myristoylated Akt) in androgen-independent prostate cancer cells lines such as PC3 and LnCAP C4-2. A xenograft model performed in nude mice exhibited reduced PC3 prostate tumor growth with simvastatin treatment (2mg/kg body weight/day for 2 weeks) demonstrating the therapeutic potential of simvastatin for prostate cancer therapy. Conclusions and Future Directions: Our findings suggest a link between simvastatin and Akt/ERK signaling in the regulation of prostate cancer growth and metastasis. Further investigation is currently underway in our laboratory to unravel the molecular mechanisms on simvastatin-mediated effects on prostate cancer leading to tumor growth and bone metastasis in vivo using transgenic mouse models such as AKt+ and TRAMP+ mice. We also plan to undertake a clinical study on patients with prostate cancer who were on statin treatment prior to and after diagnosis and analyze biopsy specimen from these patients. A prospective study will look at the role statins in prostate cancer prevention and/or on management. Our ultimate aim is to investigate if statins can be used as an adjuvant drug in the treatment of patients already diagnosed with prostate cancer. Citation Information: Clin Cancer Res 2010;16(14 Suppl):B47.
Aldosterone plays an important role in blood pressure homeostasis, and hyperaldosteronism can result in hypertension. Aldosterone is considered to be a link between hypertension and obesity; obese individuals have high serum levels of very low‐density lipoprotein (VLDL). VLDL has been shown to stimulate aldosterone production in multiple zona glomerulosa cell models via phospholipase D (PLD), an enzyme that hydrolyzes phosphatidylcholine to phosphatidic acid (PA), a lipid second messenger. In addition, sphingosine‐1‐phosphate (S1P), a bioactive sphingolipid also elevated in obesity, has been reported to be a novel stimulator of aldosterone secretion and PLD activity. The mechanisms underlying the action of these non‐conventional secretagogues of aldosterone remain to be elucidated. Angiotensin II, a classical aldosterone secretagogue, not only activates PLD but also elevates the expression of lipin‐1, an enzyme that converts PA to another lipid second messenger, diacylglycerol (DAG), in human adrenocortical carcinoma (HAC15) cells. However, it is unclear which of the two lipid signals, PA or DAG, underlies PLD’s role in aldosterone production. Herein, we used HAC15 cells to determine whether VLDL and an S1P1 receptor (S1PR1) agonist (SEW2871) stimulate aldosterone production by increasing steroidogenic gene expression via lipin‐1‐mediated metabolism of PA to DAG. We overexpressed lipin‐1 using an adenovirus or inhibited it using propranolol followed by treatment with or without VLDL or SEW2871 for 24 h. The expression of steroidogenic genes and aldosterone secretion were monitored using qRT‐PCR and radioimmunoassay. We demonstrated that lipin‐1 overexpression enhanced the VLDL‐stimulated 55‐fold increase in CYP11B2 expression by 75% while lipin‐1 inhibition decreased the VLDL‐stimulated 21‐fold increase in CYP11B2 expression by 66%. A parallel trend was observed with aldosterone secretion levels: VLDL‐stimulated increase in aldosterone production was enhanced by lipin‐1 overexpression (182%) and was decreased by propranolol (80%). Similar results were obtained with SEW2871. Our results are, therefore, suggestive of DAG being the key lipid signal since lipin‐1 regulates VLDL‐ and S1PR1 agonist‐stimulated expression of steroidogenic genes and ultimately, aldosterone production. Our study warrants further investigation into these steroidogenic signaling pathways which can lead to the identification of novel therapeutic targets such as lipin‐1, or its downstream pathways, to potentially treat obesity‐associated hypertension. Support or Funding Information This work was supported in part by the Augusta University Adrenal Center. WBB was also supported by VA Merit Award #BX001357.
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