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Regulation of Glucose Homeostasis by the PHLPP1 PhosphataseLarson, Kara L 01 January 2014 (has links)
Type 2 diabetes mellitus is a metabolic disease that affects one in ten people in the United States. It is caused by a combination of genetics and lifestyle factors. Disease progression begins with insulin resistance in peripheral tissues followed by pancreatic beta-cell failure. The mechanisms behind disease progression are not completely understood. PH domain leucine rich repeat protein phosphatase 1 (PHLPP1) is a known regulator of Akt and other members of the AGC kinase family. Akt has been established to play a role in numerous metabolic signaling pathways, including insulin action. It is hypothesized that as a regulator of Akt, PHLPP1 would have an important function in glucose homeostasis. Glucose tolerance tests performed on 8-week old Phlpp1-/- mice revealed no significant difference in glucose tolerance compared to wild type, however these mice did exhibit increased fasting blood glucose levels. Glucose tolerance tests were repeated at 20 weeks on the same mice and, interestingly, they displayed impaired glucose tolerance compared to wild type. Insulin tolerance tests showed that 8-week old mice have increased insulin sensitivity, however, the 20-week old mice were insulin-resistant compared to control animals. The 20-week old knockout mice also had significantly higher fasting blood glucose levels compared to 8-week old mice. To determine if the increased fasting blood glucose levels are due to increased hepatic glucose output, pyruvate tolerance tests were performed on both the 8 & 20 week old mice. Old mice displayed significantly increased hepatic glucose production compared to wild type. EchoMRI done on 24-week old mice showed significantly increased fat mass and decreased lean mass in the Phlpp1-/- mice compared to wild type littermates. Western blot analysis of liver samples from 32 week old Phlpp1-/- mice indicates loss of Akt signaling accompanied by a decrease in IRS2 protein levels, a common indicator of insulin resistance. These data suggest that Phlpp1-/- mice mimic the development of type 2 diabetes in humans, and provide a unique animal model to study the progression of type 2 diabetes and diabetes-associated complications.
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THE ROLE OF PHLPP IN PANCREATIC CANCERSmith, Alena J. 01 January 2015 (has links)
Medicine has come a long way in recent years with reliable treatments for many cancers. Pancreatic ductal adenocarcinoma (PDAC) has very few treatment options available. PDAC has a dismal 5 year survival rate of 4% and a median survival span of 6 months from point of diagnosis; with a high rate of chemotherapy and radiation resistance. A better understanding of the molecular events leading to cancer progression is needed in order to improve the treatment and prognosis of PDAC patients. We begin to elucidate the functional importance of PHLPP on suppressing progression and metastasis of PDAC. PHLPP belongs to a novel family of Ser/Thr protein phosphatases. Our previously published studies have demonstrated that PHLPP plays a tumor suppressor role in colon cancer by negatively regulating Akt and inhibiting cell proliferation. To determine the effect of PHLPP on cell migration and invasion, stable cells were generated to knock down or overexpress PHLPP in PDAC cells. The ability of cells to migrate and invade was examined using Transwell assays. We found that increased PHLPP expression significantly reduced the rate of migration and invasion in PDAC cells whereas knockdown of PHLPP had the opposite effect. To begin to elucidate the molecular mechanism underlying PHLPP-mediated inhibition of migration and invasion in PDAC cells, we discovered that the expression level of β4 Integrin was decreased in PHLPP overexpressing cells and increased in PHLPP knockdown cells. The increased expression of β4 Integrin has been shown to promote PDAC development and metastasis, although the mechanism leading to β4 Integrin upregulation is less clear. Interestingly, we found that the expression of β4 Integrin was highly sensitive to PI3K/Akt/mTOR activity in cells in which inhibition of PI3K/Akt/mTOR signaling significantly decreased the expression of β4 Integrin. Moreover, the quantitative real-time RT-PCR analysis revealed that the mRNA expression of β4 Integrin was not altered by changes in PHLPP expression or PI3K/Akt/mTOR activity, thus suggesting a post-transcriptional mechanism. Taken together, these results identify a tumor suppressor role of PHLPP in PDAC. Mechanistically, PHLPP suppresses PDAC cell migration and invasion by negatively controlling β4 Integrin expression through its ability to inhibit PI3K/Akt/mTOR signaling.
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Role of AMP-Activated Protein Kinase in Cancer Cell Survival under Matrix-Deprived ConditionsSaha, Manipa January 2015 (has links) (PDF)
Cancer progression is a multi-step process requiring cells to acquire specific properties that aid the neoplastic growth. One such property is the ability to survive in the absence of matrix-attachment, a critical necessity for cells to traverse in circulation and seed metastases. Therefore, understanding the signalling mechanisms that protect cells from undergoing death in matrix-deprived condition, termed as anoikis, is important. We have used two systems to study this, one involving experimental transformation model, and another involving cancer cell lines.
In the in vitro transformation model system involving the serial introduction of oncogenes, the ability to survive in anchorage-independent condition and generate spheres/colonies was dependent on the presence of the Simian Virus Small T antigen, SV40 ST. We identified that the viral antigen mediates its effects, at least in part, by activating the master metabolic regulator and cellular stress kinase AMP-activated protein kinase (AMPK) leading to maintenance of energy homeostasis.
Consistent with this, our lab has previously identified both activation of AMPK upon matrix-deprivation in breast cells, as well as its requirement for survival under these conditions. However, a pathway often associated with survival under matrix-deprivation is the PI3K/Akt pathway. Surprisingly, we observed an AMPK-dependent decrease in Akt activity under conditions of matrix-detachment. Since this was contrary to the general notion, we probed deeper into a possible crosstalk between these two kinases. Our work revealed that AMPK activation in suspension inhibits Akt via upregulation of a known Akt phosphatase, pleckstrin homology domain leucinrich repeat protein phosphatise (PHLPP). We further show that the AMPK-PHLPP-Akt signalling axis is important for anoikis-resistance and metastasis. In addition, our results point to a yet unidentified protumorigenic role of PHLPP in breast cancer progression.
With an aim to identify cellular proteins differentially regulated upon AMPK activation in breast cancer cells, we undertook a proteomics approach. Using 2-dimensional gel electrophoresis followed by mass spectrometric analysis, we identified some candidate proteins. We have validated the increase in levels of one of these proteins, annexin A2, in cancer cells upon AMPK activation.
In summary, the present study unveils novel oncogenic functions of AMPK in cancer cells under the stress of matrix-deprivation. Furthermore, our results elucidate a double-negative feedback loop between two critical cellular kinases AMPK and Akt, and also identify a novel pro-tumorigenic role of PHLPP in breast cancer. In addition, we identify PHLPP and annexin A2 as novel proteins upregulated by AMPK in cancer cells. Thus, our results begin to identify pathways utilised by cancer cells to aid anchorage-independent growth, a critical step for cancer metastasis. Based on our results, inhibition of AMPK or perturbation of signalling axes involving AMPK, and PHLPP or annexin A2 might be considered as novel therapeutic approaches to combat cancer progression
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