Molecular underpinnings of tumor suppression of colon and triple-negative breast cancers

Wong, Chen Khuan

21 February 2019

Colon and breast cancers are amongst the leading causes of cancer deaths in the United States, mostly attributed to metastasis and resistance to therapy. Hence, there is a critical need to identify novel biomarkers for effective prognosis and to design targeted therapies to combat the metastatic diseases. Loss of heterozygosity (LOH) at chromosome 18q and inactivation of the target gene, SMAD4, corresponds to resistance to the common chemotherapeutic agent, 5-fluorouracil (5-FU), in colon cancer. Our examination of the therapeutic resistance phenomenon in SMAD4-negative colon cancer cells with the three common agents revealed significant resistance to both 5-FU and irinotecan but not to oxaliplatin. We also followed up with the earlier findings from our group, which suggested that SMAD4 might interact with metastasis-promoting factors to suppress metastatic progression and render sensitivity to chemotherapy. Co-immunoprecipitation and mass spectrometry analysis revealed that SMAD4 interacts with and inhibits RICTOR, a component of mTORC2 that activates oncogenic AKT via phosphorylation at Serine 473. Overexpression of SMAD4, depletion of RICTOR, or inhibition of AKT signaling restores sensitivity to irinotecan in SMAD4-negative colon cancer cells in vitro. Furthermore, as expected pharmacological inhibition of AKT sensitizes these cells to irinotecan in vivo. Interestingly, high RICTOR/AKT expression correlates with worse survival in colon cancer patients, suggesting them as novel prognostic biomarkers and therapeutic targets. On the other hand, triple-negative breast cancer (TNBC) is the most aggressive form of breast cancer due to lack of effective targeted therapies. Using miRNA expression profiling of a model for epithelial-mesenchymal transition in TNBC, we found suppression of miR-4417 during the progression from non-malignant to malignant stage. Furthermore, localization of miR-4417 to chromosome 1p36, a region corresponding to high frequency of LOH in multiple cancers and low-level expression in TNBC patients associated with poor overall survival is consistent with its likely role as a tumor suppressor. Interestingly, we found that overexpression of miR-4417 is sufficient to inhibit migration and tumorigenecity of TNBC cells in vitro. Overall, our findings suggest miR-4417 exerts a tumor-suppressive effect and could serve as a novel prognostic biomarker and therapeutic tool against TNBC. / 2021-02-20T00:00:00Z

Genetics

Colon cancer

Irinotecan

miR-4417

RICTOR

SMAD4

Triple-negative breast cancer

Polyunsaturated fatty acid synthesis and type 2 diabetes complications

Tripathy, Sasmita

27 July 2013

Type 2 diabetes mellitus (T2DM) is a disease of multi-complications affecting more than 20 million US adults. Hyperglycemia is the classic clinical feature of diabetes, and uncontrolled hyperglycemia leads to deadly health complications. Thus, control of blood glucose represents a major goal for diabetics. Human and rodent studies revealed another clinical feature; diabetics have low tissue and plasma levels of polyunsaturated fatty acids (PUFAs), an effect often attributed by impaired endogenous PUFA synthesis. In this context, rodent studies have revealed a possible link between PUFA synthesis and high fat diet induced obesity and diabetes. These studies have shown that obese and diabetic mice have low hepatic expression and activity of fatty acid elongase-5 (Elovl5), a key enzyme involved in the PUFA synthesis pathway. Over-expression of Elovl5 in livers of chow fed C57BL/6J mice decreased fasting blood glucose and increased hepatic glycogen contents. Therefore, my hypothesis for the current work is that elevated hepatic Elovl5 activity or improved hepatic PUFA synthesis will improve systemic and hepatic carbohydrate metabolism in a mouse model of diet induced obesity and diabetes. Using a recombinant adenovirus approach, we over-expressed Elovl5 in livers of high fat diets (60% calories derived from fat as lard, Research Diets) induced obese-diabetic mice. Elevated hepatic Elovl5 activity increased hepatic and plasma C��������������� PUFA contents, reduced homeostatic model assessment for insulin resistance (HOMA-IR), improved glucose tolerance and lowered fasting blood glucose to euglycemic levels in obese-diabetic mice. The mechanism for insulin mimetic effect of Elovl5 on hepatic glucose metabolism was correlated with increased phosphorylation of Akt-S��������, FoxO1-S�������� and PP2Acat-Y��������, decreased nuclear content of FoxO1, and decreased expression of Pck1 and G6Pase; important enzymes involved in gluconeogenesis (GNG) and glucose production. Phospho-FoxO1 is excluded from nuclei, ubiquitinated and degraded by the proteasome. Loss of nuclear FoxO1, due to its increased phosphorylation, leads to the reduction in the expression of key genes involved in gluconeogenesis, i.e., Pck1 and G6Pase. Using obese-diabetic mice liver extracts and HepG2 cells, I established that Elovl5 uses two mechanisms to control hepatic GNG. The first mechanism involves Elovl5 mediated increased Akt2-S�������� and FoxO1-S�������� phosphorylation via mTORC2-rictor pathway. The second mechanism involves Elovl5 mediated attenuation of de-phosphorylation of FoxO1 via PP2A inhibition. Together, these mechanisms increase FoxO1 phosphorylation status in livers of fasted obese-diabetic mice, lower hepatic FoxO1 nuclear abundance and FoxO1 capacity to sustain transcription of GNG genes and inhibit GNG and restore blood glucose levels in fasted obese-diabetic mice. Results of these studies showed Elovl5 corrected high fat diet induced hyperglycemia in C57BL/6J mice, identified the molecular mechanism of Elovl5 control of GNG and explained how Elovl5 or PUFA synthesis controls GNG. Therefore, these findings will be eventually helpful in developing a therapeutic target to combat hyperglycemia. / Graduation date: 2013 / Access restricted to the OSU Community at author's request from July 27, 2012 - July 27, 2013

Elovl5

Hyperglycemia

FoxO1

Gluconeogenesis

Rictor

Diabetes -- Complications

Hyperglycemia

Unsaturated fatty acids -- Synthesis

Gluconeogenesis -- Regulation

Molecular Mechanisms of AMPK- and Akt-Dependent Survival of Glucose-Starved Cardiac Myocytes

Chopra, Ines

16 February 2012

Muscle may experience hypoglycemia during ischemia or insulin infusion. During severe hypoglycemia energy production is blocked and an increase in AMP:ATP activates the energy sensor and putative insulin-sensitizer AMP-dependent protein kinase (AMPK). AMPK promotes energy conservation and survival by shutting down anabolism and activating catabolic pathways. We investigated the molecular mechanism of a unique glucose stress defense pathway involving AMPK-dependent, insulin-independent activation of the insulin signaling pathway. Results from my work showed that the central insulin signaling pathway is rapidly activated when cardiac and skeletal myocytes are subjected to conditions of glucose starvation. The effect occurred independently of insulin receptor ligands (insulin and IGF-1). There was a >10-fold increase in the activity of Akt as determined by phosphorylation on both Thr308 and Ser473. Phosphorylation of glycogen synthase 3 beta (GSK3b) increased in parallel, but phosphorylation of ribosomal 70S subunit-S6 protein kinase (S6K) and the mammalian target of rapamycin complex 1 (mTORC1) decreased. We identified AMPK as an intermediate in this signaling network; AMPK was activated by glucose starvation and many of the effects were mimicked by the AMPK-selective activator aminoimidazole carboxamide ribonucleotide (AICAR) and blocked by AMPK inhibitors. Glucose starvation increased the phosphorylation on IRS-1 on Ser789, but phosphomimetics revealed that this conferred negative regulation. Glucose starvation enhanced tyrosine phosphorylation of IRS-1 and the insulin receptor, effects that were blocked by AMPK inhibition and mimicked by AICAR. In vitro kinase assays using purified proteins confirmed that the insulin receptor is a direct target of AMPK. Insulin receptor kinase activity was essential for cardiac myocytes to survive gluose starvation as inhibition of the IR led to increased cell death in glucose-starved myocytes. Selective activation of mTORC2 by glucose starvation to increase Akt-Ser473 phosphorylation was dependent on the presence of rictor. SIN1 also seemed to be instrumental in the activation of mTORC2 as its levels and binding to rictor increased under glucose starvation. AMPK-mediated activation of the insulin signaling pathway conferred significant protection against the stresses of glucose starvation. Glucose starvation promoted energy conservation, augmented glucose uptake and enhanced insulin sensitivity in an AMPK- and Akt-dependent manner. My results describe a novel ligand-independent and AMPK-dependent activation of the insulin signaling pathway via direct phosphorylation and activation of the IR followed by activation of PI3K and Akt. These results may be relevant in conditions of myocardial ischemia superimposed with type 2 diabetes where AMPK could directly modify the IR to promote cell survival and confer protection.

AMPK

Akt

glucose starvation

cardiac myocytes

insulin receptor

skeletal muscle

mTOR-rictor

phosphorylation

Differential Roles of Mammalian Target of Rapamycin Complexes 1 and 2 in Migration of Prostate Cancer Cells

Venugopal, Smrruthi Vaidegi

20 May 2019

In this study, we investigated differential activation and the role of two mTOR complexes in cell migration of prostate cancer cells. Specific knock-down of endogenous RAPTOR and RICTOR by siRNA resulted in decreased cell migration in LNCaP, DU145, and PC3 cells indicating that both mTORC1 and mTORC2 are required for cell migration. EGF treatment induced the activation of both mTORC1 and mTORC2 as determined by complex-specific phosphorylation of mTOR protein. Specific knock-down or inhibition of Rac1 activity in PC3 cells blocked EGF-induced activation of mTORC2, but had no effect on mTORC1 activation. Furthermore, the over-expression of constitutively active Rac1 (Rac1Q61L) resulted in significant increase in cell migration and activation of mTORC2 in PC3 cells, but had no effect on mTORC1 activation. Constitutively active Rac1 (Rac1Q61L) in PC3 cells was localized in the plasma membrane and was found to be in a protein complex which contained mTOR and RICTOR proteins, but not RAPTOR. In conclusion, we suggested that EGF-induced activation of Rac1 causes the phosphorylation/activation of mTORC2 via RICTOR, specific regulator of mTORC2 activation in numerous cancer cells. The major role played by mTOR in a wide array of cancers has in the recent decades led to the development of numerous mTOR inhibitors. One of the drawback of these first generation mTOR inhibitors are that m TORC1 activity is inhibited but effect on mTORC2 activity require high dosages and prolonged exposure in different cancer cell types including HeLa, PC3, LNCaP, and A549. High dosage of rapamycin and its associated rapalogs required for mTORC2 inhibition is clinically unsuitable. Studies have shown that the dual mTORC1/C2 inhibitors trigger feedback loops causing metastasis and affect the cell viability of normal tissues in vitro and in vivo. There is a need for specific mTORC1 and mTORC2 inhibitor, which overcome the disadvantages of the previously developed mTOR inhibitors. The Rac1-RICTOR axis suggested in this study could be used as a potential target for the development of mTORC2 inhibitor and lead to a potential therapeutic treatment for aggressive prostate cancer.

Cell migration

prostate cancer

mTOR

Rac1

PI3K/AKT pathway

RICTOR

Biology

Cancer Biology

Cell Biology

Laboratory and Basic Science Research