Project description:All cells and organisms exhibit stress-coping mechanisms toensure survival. Cytoplasmic protein-RNA assemblies termedstress granules are increasingly recognized to promote cellularsurvival under stress. Thus, they might represent tumor vul-nerabilities that are currently poorly explored. The translation-inhibitory eIF2αkinases are established as main drivers ofstress granule assembly. Using a systems approach, we identifythe translation enhancers PI3K and MAPK/p38 as pro-stress-granule-kinases. They act through the metabolic master regu-lator mammalian target of rapamycin complex 1 (mTORC1) topromote stress granule assembly. When highly active, PI3K is themain driver of stress granules; however, the impact of p38becomes apparent as PI3K activity declines. PI3K and p38 thusact in a hierarchical manner to drive mTORC1 activity and stressgranule assembly. Of note, this signaling hierarchy is also presentin human breast cancer tissue. Importantly, only the recognition ofthe PI3K-p38 hierarchy under stress enabled the discovery of p38’srole in stress granule formation. In summary, we assign a new pro-survival function to the key oncogenic kinases PI3K and p38, as theyhierarchically promote stress granule formation

Project description:To comprehensively analyze the effects of mTORC1 inhibition on GSK3, we employed the use of a PI3K/mTOR-specific phospho-antibody microarray that analyzed the site-specific phosphorylation of over 130 kinases within the PI3K/mTOR pathway. The phosphorylation levels of different kinases in monocytes were measured when stimulated with LPS in the presence or absence of a kind of mTORC1 inhibitor, rapamycin More than 130 highly specific and characterized phospho-antibodies for the human mTOR signaling pathway were immobilized and replicated six times on glass slides. The same non-phosphorylated target antibodies were included to allow the determination of the relative level of phosphorylatioin

Project description:To comprehensively analyze the effects of mTORC1 inhibition on GSK3, we employed the use of a PI3K/mTOR-specific phospho-antibody microarray that analyzed the site-specific phosphorylation of over 130 kinases within the PI3K/mTOR pathway. The phosphorylation levels of different kinases in monocytes were measured when stimulated with LPS in the presence or absence of a kind of mTORC1 inhibitor, rapamycin

Project description:mRNA translation plays a major role in homeostasis, whereas its dysregulation underpins a variety of pathological states including cancer, metabolic syndrome and neurological disorders. Ternary complex (TC) and eIF4F complex assembly are two major rate-limiting steps in translation initiation that are thought to be regulated by eIF2α phosphorylation, and the mTOR/4E-BP pathway, respectively2. However, how TC and eIF4F assembly are coordinated remains largely unknown. Using polysome-profiling, we show that on a genome-wide scale mTOR suppresses translation of mRNAs, which are translationally activated under short-term ER stress when TC recycling is attenuated by eIF2α phosphorylation. During acute nutrient or growth factor stimulation, mTORC1 induces eIF2β phosphorylation, which increases recruitment of NCK1 to eIF2, decreases eIF2α phosphorylation and bolsters TC recycling. Accordingly, eIF2β appears to act as a previously unidentified mediator of mTORC1 on protein synthesis and proliferation. In addition, we demonstrate a formerly undocumented role for CK2 in regulation of translation initiation, whereby CK2 stimulates phosphorylation of eIF2β and simultaneously bolsters eIF4F complex assembly via the mTORC1/4E-BP pathway. These findings imply a previously unrecognized mode of translation regulation whereby mTORC1 and CK2 coordinate TC and eIF4F complex assembly to stimulate cell proliferation.

Project description:IL-7 r and Stat5 signaling drives early B lymphopoiesis, but it remains poorly understood how Stat5-dependent and independent pathways contribute to this process. We report the discrete effects of PI3K and mTOR signaling on Stat5 signaling and B cell development. PI3K was not engaged by IL-7 in pro-B cells but was actively suppressed by PTEN to ensure proper IL-7 r expression, Stat5 signaling and pro-B cell survival. Further, IL-7-mediated mTORC1 activation, which was uncoupled from PI3K signaling, orchestrated a unique program in early B cell development in a Stat5-independent but Myc-dependent manner. mTORC1 was also required for immunoglobulin heavy chain rearrangement and Myc-driven lymphomagenesis. Finally, mTORC2 was not essential for early B cell development but contributed to peripheral B cell maturation. Altogether, genetic dissection of PI3K, mTORC1, and mTORC2 reveals the distinct effects of these seemingly related pathways on B cell development and the intricate interplay between PI3K, mTOR and IL-7 r-Stat5 signaling.

Project description:Biochemical studies have established that the four-subunit negative elongation factor (NELF) complex mediates RNA polymerase II (Pol II) pausing at promoter proximal regions. Genetic ablation of individual NELF subunits destabilizes the entire NELF complex and causes lethality of cultured cells, leading to the prevailing concept that NELF-mediated Pol II pausing is essential for cell survival. Using separation-of-function mutations, we show here that NELFB’s effects on cell proliferation can be uncoupled from its function in Pol II pausing. NELFB mutants localized in the cytoplasm and incapacitated in the NELF complex assembly still retain their ability to support cell proliferation and at least part of NELFB-dependent transcriptome. Furthermore, we demonstrate that cytoplasmic NELFB physically and functionally interacts with multiple pro-survival signaling kinases, most notably PI3K/AKT. Enforced activation of PI3K/AKT-related kinases largely rescues deficiency of NELFB-depleted cells in proliferation, but not Pol II pausing. Together, these data revise the current understanding of the growth impact of Pol II pausing and underscore multiplicity of the biological function of individual NELF subunits.

Project description:Biochemical studies have established that the four-subunit negative elongation factor (NELF) complex mediates RNA polymerase II (Pol II) pausing at promoter proximal regions. Genetic ablation of individual NELF subunits destabilizes the entire NELF complex and causes lethality of cultured cells, leading to the prevailing concept that NELF-mediated Pol II pausing is essential for cell survival. Using separation-of-function mutations, we show here that NELFB’s effects on cell proliferation can be uncoupled from its function in Pol II pausing. NELFB mutants localized in the cytoplasm and incapacitated in the NELF complex assembly still retain their ability to support cell proliferation and at least part of NELFB-dependent transcriptome. Furthermore, we demonstrate that cytoplasmic NELFB physically and functionally interacts with multiple pro-survival signaling kinases, most notably PI3K/AKT. Enforced activation of PI3K/AKT-related kinases largely rescues deficiency of NELFB-depleted cells in proliferation, but not Pol II pausing. Together, these data revise the current understanding of the growth impact of Pol II pausing and underscore multiplicity of the biological function of individual NELF subunits.

Project description:Activation of the PI3K-mTOR pathway is central to breast cancer pathogenesis including resistance to many targeted therapies. The mTOR kinase forms two distinct complexes, mTORC1 and mTORC2, and understanding which is required for the survival of malignant cells has been limited by tools to selectively and completely impair either subcomplex. To address this, we used RMC-6272, a bi-steric molecule with a rapamycin-like moiety linked to an mTOR active-site inhibitor that displays >25-fold selectivity for mTORC1 over mTORC2 substrates. Complete suppression of mTORC1 by RMC-6272 causes apoptosis in ER+/HER2- breast cancer cell lines, particularly in those that harbor mutations in PIK3CA or PTEN, due to inhibition of the rapamycin resistant, mTORC1 substrate 4EBP1 and reduction of the pro-survival protein MCL1. RMC-6272 reduced translation of ribosomal mRNAs, MYC target genes, and components of the CDK4/6 pathway, suggesting enhanced impairment of oncogenic pathways compared to the partial mTORC1 inhibitor everolimus. RMC-6272 maintained efficacy in hormone therapy-resistant acquired cell lines and patient derived xenografts (PDX), showed increased efficacy in CDK4/6 inhibitor treated acquired resistant cell lines versus their parental counterparts, and was efficacious in a PDX from a patient experiencing resistance to CDK4/6 inhibition. Bi-steric mTORC1-selective inhibition may be effective in overcoming multiple forms of therapy-resistance in ER+ breast cancers.

Project description:ELABELA (ELA) is a peptide hormone required for heart development that signals via the Apelin Receptor (APLNR, APJ). ELA is also abundantly secreted by human embryonic stem cells (hESCs), which do not express APLNR. Here we show that ELA signals in a paracrine fashion in hESCs to maintain self-renewal. ELA inhibition by CRISPR/Cas9-mediated deletion, shRNA or neutralizing antibodies causes reduced hESC growth, cell death and loss of pluripotency. Global phosphoproteomic and transcriptomic analyses of ELA-pulsed hESCs show that it activates PI3K/AKT/mTORC1 signaling required for cell survival. ELA promotes hESC cell cycle progression and protein translation, and blocks stress-induced apoptosis. INSULIN and ELA have partially overlapping functions in hESC medium, but only ELA can potentiate the TGFβ pathway to prime hESCs towards the endoderm lineage. We propose that ELA, acting through an alternate cell-surface receptor, is an endogenous secreted growth factor in human embryos and hESCs that promotes growth and pluripotency. Global Transcriptomic Analysis of INSULIN versus ELA-pulsed human embryonic stem cells was performed to elucidate the functional overlap between these two ligands

Project description:Model V simulating stress induction with stress inputs on PI3K, Akt-pS473 and mTORC1. The model scheme is depicted in Figure S11 and the simulations are shown in Figure S12.