Nicholas Artinian scite author profile

One mechanism by which AKT kinase-dependent hypersensitivity to mammalian target of rapamycin (mTOR) inhibitors is controlled is by the differential expression of cyclin D1 and c-MYC. Regulation of post-transcriptional processes has been demonstrated to be crucial in governing expression of these determinants in response to rapamycin. Our previous data suggested that cyclin D1 and c-MYC expression might additionally be coordinately regulated in an AKT-dependent manner at the level of transcription. Under conditions of relatively quiescent AKT activity, treatment of cells with rapamycin resulted in upregulation of cyclin D1 and c-MYC nascent transcription, while in cells containing active AKT, exposure repressed transcription. Promoter analysis identified AKT-dependent rapamycin responsive elements containing AP-1 transactivation sites. Phosphorylated c-JUN binding to these promoters correlated with activation of transcription while JUNB occupancy was associated with promoter repression. Forced overexpression of JunB or a conditionally active JunB-ER allele repressed cyclin D1 and c-MYC promoter activity in quiescent AKT-containing cells following rapamycin exposure. AIP4/Itch-dependent JUNB protein degradation was found to be markedly reduced in active AKT-containing cells compared to cells harboring quiescent AKT. Moreover, silencing AIP4/Itch expression or inhibiting JNK mediated AIP4 activity abrogated the rapamycin-induced effects on cyclin D1 and c-MYC promoter activities. Our findings support a role for the AKT-dependent regulation of AIP4/Itch activity in mediating the differential cyclin D1 and c-MYC transcriptional responses to rapamycin.

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Conditional Astroglial Rictor Overexpression Induces Malignant Glioma in Mice

Bashir

Cloninger

Artinian

et al. 2012

PLoS ONE

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BackgroundHyperactivation of the mTORC2 signaling pathway has been shown to contribute to the oncogenic properties of gliomas. Moreover, overexpression of the mTORC2 regulatory subunit Rictor has been associated with increased proliferation and invasive character of these tumor cells.Methodology/Principal FindingsTo determine whether Rictor overexpression was sufficient to induce glioma formation in mice, we inserted a Cre-lox-regulated human Rictor transgene into the murine ROSA26 locus. This floxed Rictor strain was crossed with mice expressing the Cre recombinase driven from the glial fibrillary acidic protein (GFAP) promoter whose expression is limited to the glial cell compartment. Double transgenic GFAP-Cre/RictorloxP/loxP mice developed multifocal infiltrating glioma containing elevated mTORC2 activity and typically involved the subventricular zone (SVZ) and lateral ventricle. Analysis of Rictor-dependent signaling in these tumors demonstrated that in addition to elevated mTORC2 activity, an mTORC2-independent marker of cortical actin network function, was also elevated. Upon histological examination of the neoplasms, many displayed oligodendroglioma-like phenotypes and expressed markers associated with oligodendroglial lineage tumors. To determine whether upstream oncogenic EGFRvIII signaling would alter tumor phenotypes observed in the GFAP-Cre/RictorloxP/loxP mice, transgenic GFAP-EGFRvIII; GFAP-Cre/RictorloxP/loxP mice were generated. These mice developed mixed astrocytic-oligodendroglial tumors, however glioma formation was accelerated and correlated with increased mTORC2 activity. Additionally, the subventricular zone within the GFAP-Cre/RictorloxP/loxP mouse brain was markedly expanded, and a further proliferation within this compartment of the brain was observed in transgenic GFAP-EGFRvIII; GFAP-Cre/RictorloxP/loxP mice.Conclusion/SignificanceThese data collectively establish Rictor as a novel oncoprotein and support the role of dysregulated Rictor expression in gliomagenesis via mTOR-dependent and mTOR-independent mechanisms. Furthermore, oncogenic EGFRvIII signaling appears to potentiate the in vivo proliferative capacity of GFAP-Cre/RictorloxP/loxP gliomas.

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Phosphomimetic Substitution of Heterogeneous Nuclear Ribonucleoprotein A1 at Serine 199 Abolishes AKT-dependent Internal Ribosome Entry Site-transacting Factor (ITAF) Function via Effects on Strand Annealing and Results in Mammalian Target of Rapamycin Complex 1 (mTORC1) Inhibitor Sensitivity

Martin

Masri

Cloninger

et al. 2011

Journal of Biological Chemistry

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The relative activity of the AKT kinase has been demonstrated to be a major determinant of sensitivity of tumor cells to mammalian target of rapamycin (mTOR) complex 1 inhibitors. Our previous studies have shown that the multifunctional RNAbinding protein heterogeneous nuclear ribonucleoprotein (hnRNP) A1 regulates a salvage pathway facilitating internal ribosome entry site (IRES)-dependent mRNA translation of critical cellular determinants in an AKT-dependent manner following mTOR inhibitor exposure. This pathway functions by stimulating IRES-dependent translation in cells with relatively quiescent AKT, resulting in resistance to rapamycin. However, the pathway is repressed in cells with elevated AKT activity, rendering them sensitive to rapamycin-induced G 1 arrest as a result of the inhibition of global eIF-4E-mediated translation. AKT phosphorylation of hnRNP A1 at serine 199 has been demonstrated to inhibit IRES-mediated translation initiation. Here we describe a phosphomimetic mutant of hnRNP A1 (S199E) that is capable of binding both the cyclin D1 and c-MYC IRES RNAs in vitro but lacks nucleic acid annealing activity, resulting in inhibition of IRES function in dicistronic mRNA reporter assays. Utilizing cells in which AKT is conditionally active, we demonstrate that overexpression of this mutant renders quiescent AKT-containing cells sensitive to rapamycin in vitro and in xenografts. We also demonstrate that activated AKT is strongly correlated with elevated Ser(P) 199 -hnRNP A1 levels in a panel of 22 glioblastomas. These data demonstrate that the phosphorylation status of hnRNP A1 serine 199 regulates the AKT-dependent sensitivity of cells to rapamycin and functionally links IRES-transacting factor annealing activity to cellular responses to mTOR complex 1 inhibition.A broad range of tumor types have been reported to exhibit hypersensitivity to mTORC1 2 inhibition with rapalogs depending on their degree of AKT activation (1-3). The cells that have elevated AKT activity as a result of dysregulated PI3K activity, AKT gene amplification, or a loss of PTEN display markedly increased G 1 arrest following rapamycin exposure relative to cells having quiescent AKT (2, 3). Our previous studies have demonstrated that this differential sensitivity can be explained, in part, by continued IRES-initiated mRNA translation of cyclin D1 and c-MYC in the face of mTOR inhibition mediated by the ITAF hnRNP A1 (4). We have also demonstrated that direct phosphorylation of the ITAF hnRNP A1 on serine 199 by AKT regulates differential cyclin D1 and c-MYC IRES activity (5).The ability of IRES-mediated protein synthesis to contribute to aberrant gene expression in cancer and during integrated cell stress responses is well documented (6 -8); however, the processes regulating IRES function are poorly defined. Cellular IRESs require ITAFs to recruit the 40 S small ribosomal subunit leading to the formation of a competent preinitiation complex (9). Some ITAFs have been shown to directly interact with components of the ribosome to f...

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