Ing1 mediates p53 accumulation and chromatin modification in response to oncogenic stress

ING proteins are putative tumor suppressor proteins linked to the p53 pathway and to the chromatin modification machinery. Here we have analyzed the role of the products of the murine Ing1 locus in cellular tumor-protective responses, using mouse primary fibroblasts where the Ing1 locus has been inactivated by the integration of a betageo cassette. We show that Ing1-deficient mouse embryonic fibroblasts display a defective senescence-like antiproliferative response against oncogenic Ras, affecting several senescence-specific markers. This phenotype is accompanied by a reduced accumulation of p53, which can be explained by the reduced basal p53 protein stability in the Ing1-deficient background. Ing1 deficiency also results in defects in the appearance of heterochromatic marks upon expression of oncogenic Ras, suggestive of impaired heterochromatin formation during oncogene-induced senescence. Our results support an important role for the Ing1 locus in protection against oncogenic stress in vivo, both as a mediator of p53 activation and as a regulator of chromatin remodeling processes.     

Stimulation of mitogen-activated protein kinase by oncogenic Ras p21 in Xenopus oocytes. Requirement for Ras p21-GTPase-activating protein interaction.

p21ras plays an important role in the control of cell proliferation. The molecular mechanisms implicated are unknown. We report that the injection of oncogenic Lys12 Ras into Xenopus laevis oocytes promoted the activation of mitogen-activated protein kinase (MAP kinase) after a lag of about 90 min. MAP kinase activity was 10-fold higher 4 h after injection of oncogenic Lys12 Ras than after injection of nononcogenic Gly12 Ras. The stimulated MAP kinase activity remained at a plateau for at least 18 h. Maximal stimulation was obtained with 5 ng of Lys12 Ras, which is similar to the amount that elicits germinal vesicle breakdown. DEAE-Sephacel chromatography of extracts from Lys12 Ras-injected oocytes showed one peak of MAP kinase. MAP kinase activation by Lys12 Ras was associated with tyrosine phosphorylation of MAP kinase (p42). As previously shown, the S6-kinase II (likely pp90rsk), which is activated in vitro by MAP kinase, was also activated by oncogenic Lys12 Ras. Lys12 Ras with an additional mutation (Glu38) in the effector region that binds GTPase-activating protein (GAP) did not promote MAP kinase or S6 kinase activations. Thus, GAP may be involved downstream to Ras in these activation processes. Our results indicate that the Ras-GAP complex promotes MAP kinase activation in oocytes. This supports the idea that Ras-GAP controls MAP kinase, a kinase implicated in the action of various stimuli.     

Serine and tyrosine phosphorylations cooperate in Raf-1, but not B-Raf activation

The Raf family of serine/threonine protein kinases couple growth factor receptor stimulation to mitogen activated protein kinase activation, but their own regulation is poorly understood. Using phospho-specific antisera, we show that activated Raf-1 is phosphorylated on S338 and Y341. Expression of Raf-1 with oncogenic Ras gives predominantly S338 phosphorylation, whereas activated Src gives predominantly Y341 phosphorylation. Phosphorylation at both sites is maximal only when both oncogenic Ras and activated Src are present. Raf-1 that cannot interact with Ras-GTP is not phosphorylated, showing that phosphorylation is Ras dependent, presumably occurring at the plasma membrane. Mutations which prevent phosphorylation at either site block Raf-1 activation and maximal activity is seen only when both are phosphorylated. Mutations at S339 or Y340 do not block Raf-1 activation. While B-Raf lacks a tyrosine phosphorylation site equivalent to Y341 of Raf-1, S445 of B-Raf is equivalent to S338 of Raf-1. Phosphorylation of S445 is constitutive and is not stimulated by oncogenic Ras. However, S445 phosphorylation still contributes to B-Raf activation by elevating basal and consequently Ras-stimulated activity. Thus, there are considerable differences between the activation of the Raf proteins; Ras-GTP mediates two phosphorylation events required for Raf-1 activation but does not regulate such events for B-Raf.     

S6K1 is a multifaceted regulator of Mdm2 that connects nutrient status and DNA damage response

p53 mediates DNA damage‐induced cell‐cycle arrest, apoptosis, or senescence, and it is controlled by Mdm2, which mainly ubiquitinates p53 in the nucleus and promotes p53 nuclear export and degradation. By searching for the kinases responsible for Mdm2 S163 phosphorylation under genotoxic stress, we identified S6K1 as a multifaceted regulator of Mdm2. DNA damage activates mTOR‐S6K1 through p38α MAPK. The activated S6K1 forms a tighter complex with Mdm2, inhibits Mdm2‐mediated p53 ubiquitination, and promotes p53 induction, in addition to phosphorylating Mdm2 on S163. Deactivation of mTOR‐S6K1 signalling leads to Mdm2 nuclear translocation, which is facilitated by S163 phosphorylation, a reduction in p53 induction, and an alteration in p53‐dependent cell death. These findings thus establish mTOR‐S6K1 as a novel regulator of p53 in DNA damage response and likely in tumorigenesis. S6K1–Mdm2 interaction presents a route for cells to incorporate the metabolic/energy cues into DNA damage response and links the aging‐controlling Mdm2–p53 and mTOR‐S6K pathways.     

p38γ Mitogen-activated Protein Kinase Signals through Phosphorylating Its Phosphatase PTPH1 in Regulating Ras Protein Oncogenesis and Stress Response

Phosphatase plays a crucial role in determining cellular fate by inactivating its substrate kinase, but it is not known whether a kinase can vice versa phosphorylate its phosphatase to execute this function. Protein-tyrosine phosphatase H1 (PTPH1) is a specific phosphatase of p38γ mitogen-activated protein kinase (MAPK) through PDZ binding, and here, we show that p38γ is also a PTPH1 kinase through which it executes its oncogenic activity and regulates stress response. PTPH1 was identified as a substrate of p38γ by unbiased proteomic analysis, and its resultant phosphorylation at Ser-459 occurs in vitro and in vivo through their complex formation. Genetic and pharmacological analyses showed further that Ser-459 phosphorylation is directly regulated by Ras signaling and is important for Ras, p38γ, and PTPH1 oncogenic activity. Moreover, experiments with physiological stimuli revealed a novel stress pathway from p38γ to PTPH1/Ser-459 phosphorylation in regulating cell growth and cell death by a mechanism dependent on cellular environments but independent of canonical MAPK activities. These results thus reveal a new mechanism by which a MAPK regulates Ras oncogenesis and stress response through directly phosphorylating its phosphatase.     

p53-mediated activation of the mitochondrial protease HtrA2/Omi prevents cell invasion

Oncogenic Ras induces cell transformation and promotes an invasive phenotype. The tumor suppressor p53 has a suppressive role in Ras-driven invasion. However, its mechanism remains poorly understood. Here we show that p53 induces activation of the mitochondrial protease high-temperature requirement A2 (HtrA2; also known as Omi) and prevents Ras-driven invasion by modulating the actin cytoskeleton. Oncogenic Ras increases accumulation of p53 in the cytoplasm, which promotes the translocation of p38 mitogen-activated protein kinase (MAPK) into mitochondria and induces phosphorylation of HtrA2/Omi. Concurrently, oncogenic Ras also induces mitochondrial fragmentation, irrespective of p53 expression, causing the release of HtrA2/Omi from mitochondria into the cytosol. Phosphorylated HtrA2/Omi therefore cleaves β-actin and decreases the amount of filamentous actin (F-actin) in the cytosol. This ultimately down-regulates p130 Crk-associated substrate (p130Cas)-mediated lamellipodia formation, countering the invasive phenotype initiated by oncogenic Ras. Our novel findings provide insights into the mechanism by which p53 prevents the malignant progression of transformed cells.     

Functional conservation of hematopoietic factors in Drosophila and vertebrates

The GATA, Friend of GATA, and Runt homology domain protein families function during hematopoiesis to promote progenitor cell development and regulate lineage commitment and differentiation. The hematopoietic functions of these factors have been remarkably conserved across taxonomic groups, ranging from flies to humans. Furthermore, aspects of hematopoiesis and hemocyte function appear to be conserved. Thus, comparative studies using Drosophila and vertebrate models should enhance our understanding of blood cell development.     

Ouabain‐induced changes in MAP kinase phosphorylation in primary culture of rat cerebellar cells

Cardiotonic steroid (CTS) ouabain is a well‐established inhibitor of Na,K‐ATPase capable of inducing signalling processes including changes in the activity of the mitogen activated protein kinases (MAPK) in various cell types. With increasing evidence of endogenous CTS in the blood and cerebrospinal fluid, it is of particular interest to study ouabain‐induced signalling in neurons, especially the activation of MAPK, because they are the key kinases activated in response to extracellular signals and regulating cell survival, proliferation and apoptosis. In this study we investigated the effect of ouabain on the level of phosphorylation of three MAPK (ERK1/2, JNK and p38) and on cell survival in the primary culture of rat cerebellar cells. Using Western blotting we described the time course and concentration dependence of phosphorylation for ERK1/2, JNK and p38 in response to ouabain. We discovered that ouabain at a concentration of 1 μM does not cause cell death in cultured neurons while it changes the phosphorylation level of the three MAPK: ERK1/2 is phosphorylated transiently, p38 shows sustained phosphorylation, and JNK is dephosphorylated after a long‐term incubation. We showed that ERK1/2 phosphorylation increase does not depend on ouabain‐induced calcium increase and p38 activation. Changes in p38 phosphorylation, which is independent from ERK1/2 activation, are calcium dependent. Changes in JNK phosphorylation are calcium dependent and also depend on ERK1/2 and p38 activation. Ten‐micromolar ouabain leads to cell death, and we conclude that different effects of 1‐μM and 10‐μM ouabain depend on different ERK1/2 and p38 phosphorylation profiles. Copyright © 2016 John Wiley & Sons, Ltd.     

A 32 kDa protein--whose phosphorylation correlates with oncogenic Ras-induced cell cycle arrest in activated Xenopus egg extracts--is identified as ribosomal protein S6

Oncogenic Ras induces cell-cycle arrest in mammalian cells and in fertilized Xenopus eggs. How oncogenic Ras induces cell-cycle arrest remains unclear. We previously showed that oncogenic Ras induces cell-cycle arrest in activated Xenopus egg extracts (cycling extracts) and that the induced cell-cycle arrest correlates with hyperphosphorylation of a 32 kDa protein. However, the identity of the 32 kDa protein was not known. By using a sucrose density-gradient centrifugation, Triton X-100-acetic acid-urea (TAU)-gel electrophoresis, composite agarose-polyacrylamide gel electrophoresis (CAPAGE), SDS-PAGE, and partial tryptic peptide sequence analysis, the 32 kDa protein has now been identified as S6, a 40S subunit ribosomal protein. Hence, our results indicate that the oncogenic Ras-induced cell-cycle arrest is correlated with hyperphosphorylation of S6, suggesting that phosphorylation of S6 plays an important role in the induced cell-cycle arrest. It has been shown that conditional deletion of gene encoding S6 in mammalian cells prevents proliferation, demonstrating the importance of S6 in cell proliferation. The exact role S6 plays in cell proliferation is unclear. However, phosphorylation of S6 has been implicated in the regulation of protein synthesis. Thus, our results are consistent with the concept that oncogenic Ras induces S6 phosphorylation to influence protein synthesis, thereby contributing to the cell-cycle arrest. In addition, our results also demonstrate that composite agarose-polyacrylamide gel electrophoresis is suitable for the separation of large molecular complexes.