2 results
Search Results
Now showing 1 - 2 of 2
Item Understanding the Role of the Receptor for Advanced Glycation End-Products (Rage) in Pancreatic Cancer(North Dakota State University, 2019) Swami, PriyankaExpression of the Receptor for Advanced Glycation End Products (RAGE) and is upregulated in a several cancers. Based on published studies, we hypothesized that RAGE, when overexpressed in pancreatic cancer cells, will promote cell proliferation and migration. To study the role of RAGE in pancreatic cancer, we selected the human pancreatic cancer cell-line PANC-1, and stably transfected the cells with full length RAGE to generate model cell-lines that overexpress RAGE. We obtained two cell-lines PANC-1 FLR2 and PANC-1 FLR3 and examined the influence of RAGE on cellular properties. A significant increase in proliferation but a reduction in migratory abilities of PANC-1 FLR2 and PANC-1 FLR3 cells was observed. The increase in proliferation and reduction in migration was reverted upon knockdown of RAGE in PANC-1 FLR2 cells with siRNA specific for RAGE. The reduction in migration was supported by the reduced levels of vimentin and several integrins in RAGE transfected cells. Furthermore, we observed a downregulation in FAK, AKT, ERK1/2 and NF-κB activity. Growing evidence supports that RAGE is essential for pancreatic cancer progression. It has also been shown that RAGE facilitates pancreatic tumor cell survival by enhancing autophagy and inhibiting apoptosis. The goal of our study was to determine the effect of RAGE inhibition during gemcitabine chemotherapy on the growth of pancreatic tumor. Hence, we investigated the effect of RAGE inhibitors and their combination with gemcitabine in an orthotopic mouse model of pancreatic cancer using mouse pancreatic cancer cell-line KPC 5508. We used two RAGE inhibitors, an anti-RAGE monoclonal antibody (IgG2A11) and a small molecule RAGE inhibitor (FPS-ZM1). We observed a significant reduction in tumor weights of the mice treated with the combination of IgG2A11 and gemcitabine as compared to gemcitabine alone treated mice. The reduction in tumor growth was accompanied with increase in p62 levels (marker of autophagy) and increase in levels of cleaved PARP (marker of apoptosis). We also observed reduction in HMGB1 and phosphorylation levels of ERK1/2 in tumors from the group treated with the combination as compared to the gemcitabine alone treated group.Item Understanding the Role of Receptor for Advanced Glycation Endproducts (RAGE) in Pancreatic Cancer and Melanoma(North Dakota State University, 2021) Taneja, SakshiIn this project we study the role of RAGE in the melanoma and pancreatic cancer progression. Based on published studies, we hypothesized that RAGE localization in melanoma varies with different cellular architectures. To test this hypothesis, we utilized an in vitro spheroid model and a lung colonization mice model to compare the RAGE localization in 3D architecture vs 2D monolayer culture. RAGE was found at the cell surface in WM115 and B16F10 spheroids, whereas RAGE is mostly distributed intracellularly in WM266. We also observed that RAGE is present at the surface of B16F10 melanoma cells within tumor nodules in the lungs of mice colonized with B16F10 cells. Previously, our group has demonstrated that RAGE promotes pancreatic tumor cell survival under normoxic conditions, upon gemcitabine administration. Hypoxia is also associated with increased tumor aggressiveness. Based on published reports, we hypothesized that RAGE upregulation under hypoxic conditions contributes to autophagy and migration in pancreatic cancer cells. We observed that autophagy decreases after RAGE inhibition by FPSZM1. Moreover, we observed decreased cell migration after RAGE blockage, indicating that RAGE also mediates migration under hypoxia. We also investigated Advanced Glycation Endproducts (AGEs) on proliferation and migration of pancreatic cancer cells. Based on published reports, we hypothesized that RAGE activation by AGEs contributes to the proliferation and migration in pancreatic cancer cells. We employed ribose modified BSA to activate RAGE in the murine KPC 5517 pancreatic cancer cell line. We observed that AGE-treated samples showed significant increase in migration but no change in proliferation. As RAGE is involved in the progression of melanoma and pancreatic cancer, our results will help researchers to better understand the biology of RAGE. Our research can help to design RAGE-specific antibodies and inhibitors that could target RAGE more effectively. Moreover, our findings on AGE-RAGE interactions, and on the role of RAGE in pancreatic cancer progression under hypoxia, may contribute to reduce the progression of pancreatic cancer. Our results showing that a RAGE inhibitor can reduce autophagy and migration of pancreatic tumor cells, suggest that FPS-ZM1 could be utilized as a potential therapeutic aid for the treatment of pancreatic cancer.