Browsing by Subject "AKT"
- Results Per Page
- Sort Options
Item Open Access Akt, Glucose Metabolism, and the Bcl-2 Family(2010) Coloff, Jonathan LouisNormal cells require input from extrinsic growth factors to control proliferation and survival. Recent studies have demonstrated that these same extrinsic signals also regulate cellular metabolism to ensure that metabolism adequately supports the demands of cell function, proliferation, and cell survival. The PI3K/Akt pathway is downstream of many growth factors and can promote both glucose metabolism and cell survival. Aberrant activation of the PI3K/Akt pathway is common in cancer, and its activation can contribute to the growth factor independence that is a hallmark of neoplastic cells. Metabolic demand is high in stimulated and leukemic T cells, and activation of Akt can increase glucose metabolism to meet these requirements. There is great interest in targeting the unique metabolism of cancer cells for cancer therapy, thus making an understanding of the interaction of metabolism and cell death essential.
Akt is also anti-apoptotic and can inhibit cell death by regulating members of the Bcl-2 family. Interestingly, the ability of Akt to prevent cell death is inextricably linked to its metabolic function. Several recent studies have demonstrated that glucose metabolism can affect Bcl-2 to family members to promote cell survival, but the role of Akt-dependent glucose metabolism in the regulation of Bcl-2 family members is not understood. Using a model of growth factor withdrawal-induced apoptosis, we show that Akt prevents cell death by maintaining glucose metabolism to regulate the Bcl-2 family members Puma and Mcl-1, and demonstrate the importance of this pathway in the survival of stimulated T lymphocytes and leukemia.
After growth factor withdrawal, active Akt suppressed Puma induction in abundant glucose, but Puma was rapidly upregulated in glucose-deficient conditions and was necessary and sufficient to promote efficient cell death. Importantly, glucose was not uniquely required, as provision of alternative mitochondrial fuels allowed Akt to suppress Puma and maintain survival. This metabolic regulation of Puma was mediated through partially p53-dependent transcriptional induction as well as control of Puma protein stability.
In addition to inhibiting Puma expression, active Akt prevented the loss of Mcl-1 after growth factor withdrawal by sustaining Mcl-1 protein synthesis in a glucose-dependent manner. Mcl-1 was essential for preventing Bim-induced apoptosis, as Akt could not inhibit Bim induction after growth factor deprivation. Slowing of Mcl-1 synthesis by inhibiting glucose metabolism reversed Mcl-1-mediated resistance of leukemic cells to the Bcl-2 inhibitor ABT-737. Importantly, Akt and glucose-reliant Mcl-1 expression required mTOR-dependent phosphorylation of 4EBP, and treatment with mTOR inhibitors also reversed ABT-737 resistance.
Together, this study demonstrates that Akt promotes cell survival by preventing metabolic checkpoints that stimulate Puma expression and stability and inhibit Mcl-1 synthesis, advancing our understanding of the links between metabolism and cell death. These studies highlight the importance of cellular metabolism--including a potential role for the alternative sugar fructose--in cancer cell survival that may provide a mechanistic understanding to drive development of metabolism-targeted cancer therapies.
Item Open Access Cancer Stem Cells in Brain Tumors: Identification of Critical Biological Effectors(2010) Eyler, Christine ElissaHuman cancer is a leading cause of morbidity and mortality in the developed world. Contrary to the classical model in which tumors are homogeneously composed of malignant cells, accumulating evidence suggests that subpopulations of highly malignant cells play a dominant role in tumor initiation and growth. These cells have the capacity for prolonged self-renewal and they efficiently generate tumors that phenotypically resemble the parental tumor in transplantation assays. Such characteristics are reminiscent of normal stem cells, and these potently tumorigenic cells have therefore been called cancer stem cells (CSCs). Importantly, studies have shown that CSCs are central mediators of therapeutic resistance, tumor angiogenesis, and metastatic or invasive potential. In the case of malignant glioma, poor patient survival and the paucity of effective therapeutic advances have been attributed to inherent CSC growth potential and treatment resistance, respectively. For this reason, there is great interest in elucidating the molecular features of CSCs, with the ultimate hope of developing CSC-directed therapies.
Given the overlap between the highly malignant characteristics exhibited by CSCs and those promoted by the PI3K/AKT pathway, we hypothesized that AKT activity within CSCs could represent a reasonable therapeutic target for CSC-directed therapies. Indeed, a pharmacological inhibitor of AKT preferentially targeted glioma CSCs versus non-CSCs and was associated with increased apoptosis and impaired tumorigenesis. These data suggest that interventions targeting AKT could effectively target glioma CSCs.
Quite distinct from the PI3K/AKT pathway, we hypothesized that the pro-survival and pro-growth features of nitric oxide (NO) might also operate in glioma CSCs. Our experiments found that glioma CSCs produced more NO than non-CSCs, which is attributed to inducible nitric oxide synthase (iNOS) expression and activity within the CSCs. Interference with iNOS activity or expression, as well as selective NO consumption, attenuated CSC growth and tumorigenicity. The mechanism behind iNOS-mediated survival appears to involve, at least in part, suppression of the cell cycle inhibitor CDA1. iNOS inhibition decreased glioma growth in murine xenografts and human expression studies demonstrate an inverse correlation between iNOS expression and patient survival.
To more fully evaluate the biological effects of NO in CSCs, we designed a novel strategy to consume NO within mammalian cells through heterologous expression of E. coli flavohemoglobin (FlavoHb). This enzyme is a highly specific NO dioxygenase which converts NO to inert nitrate several orders of magnitude faster than iNOS synthesizes NO. Expression of FlavoHb in mammalian cells is therefore a novel and functional tool to interrogate the role of NO in cellular stress and signaling.
In summary, this doctoral thesis focuses on several molecular characteristics that define malignant CSCs and describes a novel strategy for studying NO, which is one of the CSC-specific molecular effectors.
Item Open Access FRA1 promotes squamous cell carcinoma growth and metastasis through distinct AKT and c-Jun dependent mechanisms.(Oncotarget, 2016-06-07) Zhang, Xiaoling; Wu, Joseph; Luo, Suju; Lechler, Terry; Zhang, Jennifer YFRA1 (Fos-like antigen 1) is highly expressed in many epithelial cancers including squamous cell carcinoma of the skin (cSCC) and head and neck (HNSCC). However, the functional importance and the mechanisms mediating FRA1 function in these cancers are not fully understood. Here, we demonstrate that FRA1 gene silencing in HNSCC and cSCC cells resulted in two consequences - impaired cell proliferation and migration. FRA1 regulation of cell growth was distinct from that of c-Jun, a prominent Jun group AP-1 factor. While c-Jun was required for the expression of the G1/S phase cell cycle promoter CDK4, FRA1 was essential for AKT activation and AKT-dependent expression of CyclinB1, a molecule required for G2-M progression. Exogenous expression of a constitutively active form of AKT rescued cancer cell growth defect caused by FRA1-loss. Additionally, FRA1 knockdown markedly slowed cell adhesion and migration, and conversely expression of an active FRA1 mutant (FRA1DD) expedited these processes in a JNK/c-Jun-dependent manner. Through protein and ChIP-PCR analyses, we identified KIND1, a cytoskeletal regulator of the cell adhesion molecule β1-integrin, as a novel FRA1 transcriptional target. Restoring KIND1 expression rescued migratory defects induced by FRA1 loss. In agreement with these in vitro data, HNSCC cells with FRA1 loss displayed markedly reduced rates of subcutaneous tumor growth and pulmonary metastasis. Together, these results indicate that FRA1 promotes cancer growth through AKT, and enhances cancer cell migration through JNK/c-Jun, pinpointing FRA1 as a key integrator of JNK and AKT signaling pathways and a potential therapeutic target for cSCC and HNSCC.