Background and Objectives: Polycystic ovary syndrome (PCOS) is one of the most prevalent disorders among women of reproductive age. It is considered as a pro-inflammatory state with chronic low-grade inflammation, one of the key factors contributing to the pathogenesis of this disorder. Polycystic ovary is a well-established criterion for PCOS. The present investigation aimed at finding the role of hyperandrogenism, the most important feature of PCOS, in the development of this inflammatory state. To address this problem, we adopted a model system that developed polycystic ovary morphology (PCOM), which could be most effectively used in order to study the role of non-aromatizable androgen in inflammation in PCOS. Materials and Methods: Six rats were used to induce PCOM in 21-days-old female Wistar albino rats by using a pre-determined release of dihydrotestosterone (DHT), a potent non-aromatizable androgen, achieved by implanting a DHT osmotic pump, which is designed to release a daily dose of 83 μg. Results: After 90 days, the rats displayed irregular estrous cycles and multiple ovarian cysts similar to human PCOS. Elevated serum inflammatory markers such as tumor necrosis factor-α (TNF-α) and interleukin-1β (IL-1β), and the presence of a necrotic lesion in the liver, osteoclast in the femur, multinucleated giant cells and lymphocytes in the ovary based on histopathological observation of DHT-treated rats clearly indicated the onset of inflammation in the hyperandrogenic state. Our results show no significant alterations in serum hormones such as luteinizing hormone (LH), follicle stimulating hormone (FSH), insulin, and cortisol between control and hyperandrogenised rats. DHT was significantly elevated as compared to control. mRNA studies showed an increased expression level of TNF-α and IL-1β, further, the mRNA expression of urocortin 1 (Ucn-1) was stupendously elevated in the liver of hyperandrogenised rats. Conclusions: Thus, results from this study provide: (1) a good PCOM model system in order to study the inflammatory changes in PCOS aspects, (2) alteration of inflammatory markers in PCOM rats that could be either due to its direct effect or by the regulation of various inflammatory genes and markers in the liver of hyperandrogenic state suggesting the regulatory role of DHT, and (3) alteration in stress-related protein in the liver of PCOM rats.
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Background: Pancreatic cancer metastasis is characterized by a higher incidence of morbidity and mortality. The present study attempts to identify phytocomponents with the potential to inhibit the secretion of MMP-2 by pancreatic cancer cells and ascertain the efficacy of individual components. Methods: Overall survival analysis carried out revealed reduced survival of patients with high MMP-2 expression. Data analysis from TCGA revealed increased MMP-2 expression in pancreatic cancer patients compared to adjacent normal tissues. The expression of MMP-2 was reported at different stages of pancreatic cancer (Stage I-IV). To understand the relevance of phytocomponents in binding to the catalytic site of MMP-2, molecular docking studies were performed to find the effectiveness based on Glide score/energy. To substantiate the in-silico analysis, the eight components were also tested in vitro for reducing the survival in PANC-1 cells at three different time points (24, 48, and 72 hours). Finally, zymography analysis was performed using the eight components in the PANC-1 conditioned media of treated cells to ascertain the enzymatic activity of MMP-2. Results: The obtained results suggest plumbagin, emodin, and EGCG exert potential inhibition in PANC-1 cells, among other phytocomponents tested. Therefore, as assessed using computational studies, the binding ability of plumbagin, emodin, and EGCG can be interpreted as inhibiting effects on MMP-2 activities. Conclusion: These compounds could find potential application in preventing the progression, sustenance, and metastasis of pancreatic cancer and need to be explored further using a pre-clinical model system in order to validate the efficacy, bioavailability, and safety.
Background: In individuals with ovarian cancer, an increase in the circulating level of the epidermal growth factor (EGF) is readily apparent. Ovarian cancer cells exhibit signaling pathway of the epidermal growth factor (EGFR) and respond to the EGF. Annona Muricata (AM) has been shown to decrease ovarian cell proliferation however, role of AM in regulating EGF actions is not yet to be reported. Objective: In this study, we proposed that the fractionated compound acetogenin can inhibit the activation of EGFRregulated signaling cascades such as MAPK7 / PI3K-Akt / mTOR / STAT upon EGF stimulation. Methods: Ethanolic extract was prepared for the whole AM plant and Thin Layer Chromatography (TLC) was performed to characterize the secondary metabolites and each fraction was assessed using kedde reagent for the presence of acetogenin. The effects of acetogenins were then tested on the survival of PA-1 ovarian cancer cells under basal and EGF stimulated conditions. To delineate the role of acetogenin in EGFR signaling cascades, the in silico docking studies were conducted. Discussion: The vital regulatory role of acetogenin reported in this study indicate significant anticancer activities of acetogenin from AM. The in silico study of the acetogenin function predicted that it binds specifically to Asp837 (phosphoracceptor site) of EGFR, essential for phosphorylation of substrates in the TK domain and RU which promote downstream signaling. Conclusion: This study, proposed that acetogenin isolated from AM effectively inhibited the survival of PA-1 ovarian cancer cells through impaired EGF signaling.
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