Angelita Rebollo

Protein phosphatase 1α is a Ras‐activated Bad phosphatase that regulates interleukin‐2 deprivation‐induced apoptosis

Growth factor deprivation is a physiological mechanism to regulate cell death. We utilize an interleukin‐2 (IL‐2)‐dependent murine T‐cell line to identify proteins that interact with Bad upon IL‐2 stimulation or deprivation. Using the yeast two‐hybrid system, glutathione S‐transferase (GST) fusion proteins and co‐immunoprecipitation techniques, we found that Bad interacts with protein phosphatase 1α (PP1α). Serine phosphorylation of Bad is induced by IL‐2 and its dephosphorylation correlates with appearance of apoptosis. IL‐2 deprivation induces Bad dephosphorylation, suggesting the involvement of a serine phosphatase. A serine/threonine phosphatase activity, sensitive to the phosphatase inhibitor okadaic acid, was detected in Bad immunoprecipitates from IL‐2‐stimulated cells, increasing after IL‐2 deprivation. This enzymatic activity also dephosphorylates in vivo 32P‐labeled Bad. Treatment of cells with okadaic acid blocks Bad dephosphorylation and prevents cell death. Finally, Ras activation controls the catalytic activity of PP1α. These results strongly suggest that Bad is an in vitro and in vivo substrate for PP1α phosphatase and that IL‐2 deprivation‐induced apoptosis may operate by regulating Bad phosphorylation through PP1α phosphatase, whose enzymatic activity is regulated by Ras.

Bcl-2 Targets Protein Phosphatase 1α to Bad

The diverse forms of protein phosphatase 1 (PP1) in vivo result from the association of the catalytic subunit with different regulatory subunits. We recently have described that PP1α is a Ras-activated Bad phosphatase that regulates IL-2 deprivation-induced apoptosis. With the yeast two-hybrid system, GST fusion proteins, indirect immunofluorescence, and coimmunoprecipitation, we found that Bcl-2 interacts with PP1α and Bad. In contrast, Bad did not interact with 14-3-3 protein. Bcl-2 depletion decreased phosphatase activity and association of PP1α to Bad. Bcl-2 contains the RIVAF motif, analogous to the well characterized R/KXV/IXF consensus motif shared by most PP1-interacting proteins. This sequence is involved in the binding of Bcl-2 to PP1α. Disruption of Bcl-2/PP1α association strongly decreased Bcl-2 and Bad-associated phosphatase activity and formation of the trimolecular complex. These results suggest that Bcl-2 targets PP1α to Bad.

Segregation of Bad from lipid rafts is implicated in the induction of apoptosis

Many molecules relocate subcellularly in cells undergoing apoptosis. Using coimmunoprecipitation experiments we demonstrate that Bad is not associated to 14-3-3 protein, suggesting a new mechanism for the control of the proapoptotic role of Bad. Here we show, by confocal microscopy and cellular fractionation, that Bad is attached to lipid rafts in IL-4-stimulated cells and thymocytes while associated with mitochondria in IL-4-deprived cells. Disruption of lipid rafts by methyl-β-cyclodextrin treatment induces segregation of Bad from rafts, which correlates with apoptosis. Our results suggest that the interaction of Bad with rafts is a dynamic process regulated by IL-4 and involved in the control of apoptosis.

Aiolos and Ikaros: regulators of lymphocyte development, homeostasis and lymphoproliferation.

Aiolos and Ikaros encode hemopoietic-specific zinc finger transcription factors that are important regulators of lymphocyte differentiation. Aiolos and Ikaros play a critical role in regulating B and T cell development. Gene targeting studies in mice have shown that inactivation of Ikaros family proteins leads to a complete absence of T, B, NK and dendritic cells, whereas a reduction of Ikaros activity induce hyperproliferation and lymphomas. Aiolos knock-out mice have quantitatively normal lymphoid cells but have chronically activated B cells producing autoantibodies and develop lymphomas with increased frequency. These proteins are involved in the control of gene expression and, associated to nuclear complexes, participate in nucleosome remodeling. This protein family governs cell fate decisions and regulates homeostasis through complex isoforms expression and dimerization. Changes in this regulatory network may reflect differentiation and proliferation adjustments made in lymphoid progenitors and precursors. The direct involvement of aberrant Ikaros protein expression in human hematological oncogenesis, although suggested by several studies, remains to be settled at the genomic level. These points will be discussed in the present review.

Novel aspects of Ras proteins biology: regulation and implications.

The importance of Ras proteins as crucial crossroads in cellular signaling pathways has been well established. In spite of the elucidation of the mechanism of RAS activation by growth factors and the delineation of MAP kinase cascades, the overall framework of Ras interactions is far from being complete. Novel regulators of Ras GDP/GTP exchange have been identified that may mediate the activation of Ras in response to changes in intracellular calcium and diacylglycerol. The direct activation of Ras by free radicals such as nitric oxide also suggests potential regulation of Ras function by the cellular redox state. In addition, the array of Ras effectors continues to expand, uncovering links between Ras and other cellular signaling pathways. Ras is emerging as a dual regulator of cellular functions, playing either positive or negative roles in the regulation of proliferation and apoptosis. The signals transmitted by Ras may be modulated by other pathways triggered in parallel, resulting in the final order for proliferation or apoptosis. The diversity of ras-mediated effects may be related in part to differential involvement of Ras homologues in distinct cellular processes. The study of Ras posttranslational modifications has yielded a broad battery of inhibitors that have been envisaged as anti-cancer agents. Although an irreversible modification, Ras isoprenylation appears to be modulated by growth factors and by the activity of the isoprenoid biosynthetic pathway, which may lead to changes in Ras activity.

The Association of Aiolos Transcription Factor and Bcl-xL Is Involved in the Control of Apoptosis

We have analyzed the mechanism implicated in the control of the anti-apoptotic role of Bcl-xL. We show that IL-4 deprivation induces apoptosis, but does not modulate Bcl-xL expression. Because Bcl-xL does not promote cell survival in the absence of IL-4, we investigate the mechanism by which Bcl-xL was unable to inhibit apoptosis. Using yeast two-hybrid system, coimmunoprecipitation, and indirect immunofluorescence techniques, we found that Bcl-xL interacts with the transcription factor Aiolos in IL-4-stimulated cells, increasing upon IL-4 deprivation. IL-4 does not promote translocation of Aiolos or Bcl-xL, but induces tyrosine phosphorylation of Aiolos, which is required for dissociation from Bcl-xL. Transfection experiments confirm that cells overexpressing Bcl-xL are able to prevent apoptosis in the absence of IL-4. On the contrary, cells that overexpress Bcl-xL and Aiolos are unable to block apoptosis in the absence of IL-4. We propose a model for the regulation of the Bcl-xL anti-apoptotic role via Aiolos.

Ras-mediated cell proliferation and cell death: some clues from the interleukin-2 receptor system

Oncoproteins of the Ras family have been extensively studied because of their implication in human cancer. Their roles have been primarily assigned to the commandment of cell proliferation and suppression of apoptosis, which has also been demonstrated by the involvement of Ras activation in the signal transduction pathways triggered by most cytokine receptors. Nevertheless, the functions of Ras proteins have been extended in the last years by the findings showing that they can also act as promoters or enhancers of apoptosis in various systems and conditions. These considerations have raised the issue as to how the signals delivered by Ras are regulated and translated in terms of cellular responses, suggesting that signal complementation may direct the final fate of cells. As an example, the interleukin-2 receptor system may represent a useful model in which the meaning of Ras signals may be evaluated in terms of interactions with other simultaneous signalling events, since knowledge of the biochemical events triggered by the interaction of interleukin-2 with its cell surface receptor in lymphocytes has allowed the proposal of a complete signalling model arranged in three independent channels, one of which is mediated by Ras.