A cascade involving p85, Cdc42 and septin 2 regulates cytokinesis.

Mitosis, the final phase of cell division, includes the processes of nuclear division and cytosolic division (cytokinesis). Cytokinesis occurs when DNA separation terminates, and involves a number of proteins that induce furrowing at the region of cell separation, formation of new membrane, and abscission. This process is remarkably complex, and the list of proteins that regulate it is long. Our understanding is limited as to how these players are organized in space and time to ensure that the cytosol divides equally, and only after nuclear division. Class I(A) PI3K (phosphoinositide 3-kinase) is an enzyme activated by growth factor receptor stimulation, but it is re-activated in early mitosis and regulates mitosis entry. By the end of mitosis, PI3K activity is low; at this point, the class I(A) PI3K regulatory subunit p85 contributes to co-ordination of the cytoskeletal changes required for cytokinesis. The impact of these observations on current models of cytokinesis execution is discussed here.

Phosphoinositide 3-kinase and Forkhead, a switch for cell division.

Cell cycle progression is a tightly controlled process. To initiate cell division, mitogens trigger a number of early signals that promote the G(0)-G(1) transition by inducing cell growth and the activation of G(1) cyclins. Activation of cyclin E/cdk2 (cyclin-dependent kinase 2) at the end of G(1) is then required to trigger DNA synthesis (S phase entry). Among the early signals induced by mitogens, activation of PI3K (phosphoinositide 3-kinase) appears essential to induce cell cycle entry, as it regulates cell growth signalling pathways, which in turn determine the rate of cell cycle progression. Another mechanisms by which PI3K and its downstream effector protein kinase B regulate cell cycle entry is by inactivation of the FOXO (Forkhead Box, subgroup O) transcription factors, which induce expression of quiescence genes such as those encoding p27(kip), p130 and cyclin G2. PI3K/FOXO then work as a complementary switch: when PI3K is active, FOXO transcription factors are inactive. The switch is turned on and off at different phases of the cell cycle, thus regulating cell cycle progression.

A cAMP-activated pathway, including PKA and PI3K, regulates neuronal differentiation.

Neuronal differentiation is a complex process in which many different signalling pathways may be involved. An increase in the intracellular levels of cyclic AMP (cAMP) has been shown to induce neuronal differentiation and also to cooperate with NGF to induce PC12 neurite outgrowth in a Ras-dependent manner. However, the neuritogenic activities associated with cAMP are still not well understood. The purpose of this study was to investigate the potential neuritogenic activities mediated by cAMP. For this purpose, we used the human neuroblastoma cell line SH-SY5Y. These neuroblastoma cells respond to cAMP by forming neurite-like extensions. We tried to identify some essential pathways involved in the cAMP-induced neurite elongation of these cells. Our results indicated that PKA is transiently activated in this elongation model. When we blocked PKA activity, elongation did not take place. Similarly, PI3K also plays an essential role because when we blocked this kinase activity, there was no neurite elongation. Indeed, over-expression of the p110-catalytic subunit or an activating form of the p85-regulatory subunit (p65) is able to induce some degree of neurite extension. Moreover, our results showed that when elongation is initiated, PI3K is still essential for maintenance of the neuronal morphology, whereas PKA or MAPK (ERKs or p38) activation does not appear to be necessary during this process.

Forkhead transcription factors contribute to execution of the mitotic programme in mammals.

Cell cycle progression is a process that is tightly controlled by internal and external signals. Environmental cues, such as those provided by growth factors, activate early signals that promote cell cycle entry. Cells that have progressed past the restriction point become independent of growth factors, and cell cycle progression is then controlled endogenously. The phosphatidylinositol 3OH kinase (PI(3)K)/protein kinase B (PKB) pathway must be activated in G1 to inactivate forkhead transcription factors (FKH-TFs) and allow cell cycle entry. Here we show that subsequent attenuation of the PI(3)K/PKB pathway is required to allow transcriptional activation of FKH-TF in G2. FKH-TF activity in G2 controls mammalian cell cycle termination, as interference with FKH transcriptional activation by disrupting PI(3)K/PKB downregulation, or by expressing a transcriptionally inactive FKH mutant, induces cell accumulation in G2/M, defective cytokinesis, and delayed transition from M to G1 of the cell cycle. We demonstrate that FKH-TFs regulate expression of mitotic genes such as cyclin B and polo-like kinase (Plk). Our results support the important role of forkhead in the control of mammalian cell cycle completion, and suggest that efficient execution of the mitotic programme depends on downregulation of PI(3)K/PKB and consequent induction of FKH transcriptional activity.

Hypoxia induces the activation of the phosphatidylinositol 3-kinase/Akt cell survival pathway in PC12 cells: protective role in apoptosis.

Hypoxia is a common environmental stress that influences signaling pathways and cell function. Several cell types, including neuroendocrine chromaffin cells, have evolved to sense oxygen levels and initiate specific adaptive responses to hypoxia. Here we report that under hypoxic conditions, rat pheochromocytoma PC12 cells are resistant to apoptosis induced by serum withdrawal and chemotherapy treatment. This effect is also observed after treatment with deferoxamine, a compound that mimics many of the effects of hypoxia. The hypoxia-dependent protection from apoptosis correlates with activation of the phosphatidylinositol 3-kinase (PI3K)/Akt pathway, which is detected after 3-4 h of hypoxic or deferoxamine treatment and is sustained while hypoxic conditions are maintained. Hypoxia-induced Akt activation can be prevented by treatment with cycloheximide or actinomycin D, suggesting that de novo protein synthesis is required. Finally, inhibition of PI3K impairs both the protection against apoptosis and the activation of Akt in response to hypoxia, suggesting a functional link between these two phenomena. Thus, reduced oxygen tension regulates apoptosis in PC12 cells through activation of the PI3K/Akt survival pathway.

Mutation of E2F2 in mice causes enhanced T lymphocyte proliferation, leading to the development of autoimmunity.

E2Fs are important regulators of proliferation, differentiation, and apoptosis. Here we characterize the phenotype of mice deficient in E2F2. We show that E2F2 is required for immunologic self-tolerance. E2F2(-/-) mice develop late-onset autoimmune features, characterized by widespread inflammatory infiltrates, glomerular immunocomplex deposition, and anti-nuclear antibodies. E2F2-deficient T lymphocytes exhibit enhanced TCR-stimulated proliferation and a lower activation threshold, leading to the accumulation of a population of autoreactive effector/memory T lymphocytes, which appear to be responsible for causing autoimmunity in E2F2-deficient mice. Finally, we provide support for a model to explain E2F2's unexpected role as a suppressor of T lymphocyte proliferation. Rather than functioning as a transcriptional activator, E2F2 appears to function as a transcriptional repressor of genes required for normal S phase entry, particularly E2F1.

Role of the PI3K regulatory subunit in the control of actin organization and cell migration.

Cell migration represents an important cellular response that utilizes cytoskeletal reorganization as its driving force. Here, we describe a new signaling cascade linking PDGF receptor stimulation to actin rearrangements and cell migration. We demonstrate that PDGF activates Cdc42 and its downstream effector N-WASP to mediate filopodia formation, actin stress fiber disassembly, and a reduction in focal adhesion complexes. Induction of the Cdc42 pathway is independent of phosphoinositide 3-kinase (PI3K) enzymatic activity, but it is dependent on the p85alpha regulatory subunit of PI3K. Finally, data are provided showing that activation of this pathway is required for PDGF-induced cell migration on collagen. These observations show the essential role of the PI3K regulatory subunit p85alpha in controlling PDGF receptor-induced cytoskeletal changes and cell migration, illustrating a novel signaling pathway that links receptor stimulation at the cell membrane with actin dynamics.

Increased phosphoinositide 3-kinase activity induces a lymphoproliferative disorder and contributes to tumor generation in vivo.

Alterations in the cell division:cell death ratio induce multiple autoimmune and transformation processes. Phosphoinositide 3-kinase (PI3K) controls cell division and cell death in vitro, but its effect on the function of the cellular immune system and on tumor formation in mammals is poorly characterized. Here we show that transgenic mice expressing in T lymphocytes an active form of PI3K derived from a thymic lymphoma, p65(PI3K), developed an infiltrating lymphoproliferative disorder and autoimmune renal disease with an increased number of T lymphocytes exhibiting a memory phenotype and reduced apoptosis. This pathology was strikingly similar to that described in mice exhibiting heterozygous loss of the tumor suppressor PTEN, a lipid and protein phosphatase. We show that overexpression of PTEN selectively blocks p65(PI3K)-induced 3T3 fibroblast transformation. Moreover, the early development of T cell lymphomas in p65(PI3K) Tg p53(-/-) mice indicated that PI3K contributes to tumor development. These observations demonstrate that constitutive activation of PI3K extends T cell survival in vivo, affects T cell homeostasis, and contributes to tumor generation, supporting a model in which selective increases in one type of PTEN substrate, the PI3K-derived lipid products, induce tumorigenesis. PI3K thus emerges as a potential target in autoimmune disease and cancer therapy.

The identification of phosphatidylinositol 3,5-bisphosphate in T-lymphocytes and its regulation by interleukin-2.

In recent times 3-phosphoinositides have emerged as important regulators of cell metabolism, survival, and proliferation. During the last year, the phospholipid phosphatidylinositol 3, 5-bisphosphate (PtdIns3,5P2) was identified in yeast, fibroblasts, SV40-transformed kidney (COS-7) cells, and platelets. The discovery of this novel phospholipid has increased the complexity of the metabolism relating to the generation of biologically active inositol-containing lipids. We describe here the identification of PtdIns3,5P2 in the CTLL-2 mouse T-lymphocyte cell line using two in vivo radiolabeling protocols. Treatment of the cells with UV radiation led to an increase in the cellular content of PtdIns3,5P2. In contrast, preincubation of the cells with wortmannin or treatment with hypertonic medium (high concentration sorbitol) led to the opposite effect. Herein we demonstrate that interleukin-2 (IL-2), the growth factor required for CTLL-2 cell proliferation, was able to increase the level of PtdIns3,5P2 with similar kinetics to that of the formation of phosphatidylinositol 3,4-bisphosphate (PtdIns3, 4P2). An increase in this novel 3-phosphorylated lipid in response to IL-2 seems to be a general property of this cytokine because a similar result was obtained when the pre-B cell line BaF/3 expressing the high affinity IL-2 receptor was used. Using a constitutively active regulatory subunit of type I phosphatidylinositol 3-kinase and cells expressing a deletion of the serine-rich domain of the IL-2 receptor beta chain, which is required for IL-2-stimulated type I phosphatidylinositol 3-kinase activation, we demonstrate that IL-2-induced generation of PtdIns3, 5P2 is related to the activation of this enzyme. The results show for the first time the identification of PtdIns3,5P2 in both T- and B-lymphocytes and indicate its positive regulation by the mitogen IL-2.

Identification and characterization of a new oncogene derived from the regulatory subunit of phosphoinositide 3-kinase.

p85/p110 phosphoinositide 3-kinase (PI3K) is a heterodimer composed of a p85-regulatory and a p110-catalytic subunit, which is involved in a variety of cellular responses including cytoskeletal organization, cell survival and proliferation. We describe here the cloning and characterization of p65-PI3K, a mutant of the regulatory subunit of PI3K, which includes the initial 571 residues of the wild type p85alpha-protein linked to a region conserved in the eph tyrosine kinase receptor family. We demonstrate that this mutation, obtained from a transformed cell, unlike previously engineered mutations of the regulatory subunit, induces the constitutive activation of PI3K and contributes to cellular transformation. This report links the PI3K enzyme to mammalian tumor development for the first time.

Lck is necessary and sufficient for Fas-ligand expression and apoptotic cell death in mature cycling T cells.

Apoptotic cell death is induced in mature cycling T cells upon ligation of the Ag-specific TCR. This process is essential for the maintenance of homeostasis in the immune system, as it is capable of down-regulating ongoing immune responses. The analysis of the mechanism underlying TCR-induced programmed cell death has focused the attention of many scientists recently. In this regard, several recent reports have implicated Fas/Fas-ligand molecules as the final mediators of this process. Several other gene products have been implicated in the control of apoptosis (as Bcl-2, p53, and c-Myc); however, no information was available in the early signaling molecules that trigger this phenomena. The results presented in this work indicate that pp56(lck) src family kinase is actually required for the TCR to trigger cell death in mature cycling T cells. In fact, while inhibition of pp56(lck) expression with antisense oligonucleotides blocked TCR-induced apoptosis, pharmacologic inhibition of phosphatidylinositol 3-kinase activity had no effect. Accordingly, ligation of the Ag receptor in a cell line defective for pp56(lck) expression was unable to induce apoptosis, although it induced cellular stimulation, as measured by the expression of CD69. In addition, we show in this work that expression of constitutively active pp56(lck) mutants, but not pp59(fyn) mutants, in the absence of any other TCR-derived signal, is sufficient to induce apoptosis not only in transformed, but also in normal cycling T cells. Finally, evidence is presented indicating that a mechanism through which pp56(lck) regulates TCR-induced apoptosis in mature cycling T cells is by controlling Fas-ligand expression.

Intermediate affinity interleukin-2 receptor mediates survival via a phosphatidylinositol 3-kinase-dependent pathway.

Peripheral blood T lymphocytes require two signals to enter and progress along the cell cycle from their natural quiescent state. The first activation signal is provided by the stimulation through the T cell receptor, which induces the synthesis of cyclins and the expression of the high affinity interleukin-2 receptor. The second signal, required to enter the S phase, is generated upon binding of interleukin-2 to the high affinity alphabetagamma interleukin-2 receptor. However, resting T cells already express intermediate affinity betagamma interleukin-2 receptors. As shown here, T cell stimulation through intermediate affinity receptors is capable of inducing cell rescue from the apoptosis suffered in the absence of stimulation. Characterization of the signaling pathways utilized by betagamma interleukin-2 receptors in resting T cells, indicated that pp56(lck), but not Jak1 or Jak3, is activated upon receptor triggering. Compelling evidence is presented indicating that phosphatidylinositol 3-kinase associates with the intermediate affinity interleukin-2 receptor and is activated upon interleukin-2 addition. Bcl-xL gene was also found to be induced upon betagamma interleukin-2 receptor stimulation. Finally, pharmacological inhibition of phosphatidylinositol 3-kinase blocked both interleukin-2-mediated bcl-xL induction and cell survival. We conclude that betagamma interleukin-2 receptor mediates T-cell survival via a phosphatidylinositol 3-kinase-dependent pathway, possibly involving pp56(lck) and bcl-xL as upstream and downstream effectors, respectively.

IL-2 signaling controls actin organization through Rho-like protein family, phosphatidylinositol 3-kinase, and protein kinase C-zeta.

IL-2 and IL-4 induce proliferation of TS1 alpha beta cells. Activation of the zeta isoform of protein kinase C is an important step in IL-2-, but not IL-4-mediated proliferation. In addition, protein kinase C-zeta is implicated in IL-2-mediated actin organization. Given the established involvement of the Rho family of small guanine nucleotide-binding proteins in organization of actin structures, we analyze the possible relationships between Rho and protein kinase C-zeta. Using the Rho-like protein family-specific toxin B from Clostridium difficile, we report in this work that IL-2, but not IL-4, induces a Rho-dependent activation of protein kinase C-zeta. This signaling event is mediated by the activation of phosphatidylinositol 3-kinase. In contrast, IL-4 induces a Rho-independent, phosphatidylinositol 3-kinase-mediated activation of protein kinase C-zeta, but this pathway has no implications in cytoskeleton organization.

Evidence for B cell participation in the in vitro and in vivo maintenance of in vivo staphylococcal enterotoxin B-induced T cell anergy.

The mechanisms involved in the maintenance of staphylococcal enterotoxin B (SEB)-induced T cell anergy are poorly understood. Here, we demonstrate that CD4+ T cell anergy induced by SEB treatment is under partial B cell control. This effect is not mediated by anti-SEB antibodies or any in vitro B cell-produced suppresser factor. At day 13 after SEB immunization, T cells from B cell-deficient mice proliferate upon in vitro stimulation with SEB. These results suggest that SEB-induced T cell anergy is reversible and that B cells have an important function in anergy maintenance in CD4+ T cells, both in vivo and in vitro.

The catalytic domain of pp56(lck), but not its regulatory domain, is sufficient for inducing IL-2 production.

The lymphoid src kinase pp56(lck) has been shown to be essential for the induction of different T lymphocyte responses, including CD4-mediated enhancement of Ag-induced T cell activation, early T cell differentiation, induction of IL-2 production, and cytotoxicity. It is assumed that pp56(lck) acts on these processes by phosphorylating substrates. However, it has been recently reported that the NH2 regulatory domain is sufficient to mediate CD4 accessory function. In this report we address the contribution of the regulatory and catalytic domains of pp56(lck) to another function of this enzyme independent of CD4: TCR-induced IL-2 production. Two pp56(lck) mutants lacking either the entire catalytic domain or the entire NH2 regulatory domain were generated, and their abilities to trigger transactivation of the TCR-regulated nuclear factor of activated T cells (NF-AT) region of the IL-2 promoter were compared. Only the catalytic, but not the NH2 regulatory, domain of pp56(lck) was able to induce NF-AT region transactivation on its own and to cooperate with other intracellular signals to trigger this response. Moreover, the catalytic domain of pp56(lck) was able to induce IL-2 cytokine production to an extent similar to that of wild-type pp56(lck). We conclude that different domains of the pp56(lck) molecule contribute to regulate distinct biologic functions. In fact, while the NH2 regulatory domain is sufficient to mediate CD4 accessory function, we show here that the catalytic domain of pp56(lck) is sufficient for induction of IL-2 production, mimicking TCR ligation.

Enterotoxin septic shock protection and deficient T helper 2 cytokine production in growth hormone transgenic mice.

Neuroendocrine hormones have long been thought to play a role in lymphoid development and function. In particular, growth hormone has been shown to mediate thymic development as well as to promote T cell engraftment in severe combined immunodeficiency mice. Murine T helper cells are classified into two subsets based on their cytokine production pattern. Here, we report that transgenic mice for bovine growth hormone show significant alterations in T cell function and decreased capability for cytokine production, an effect that is more acute in T helper cells as measured by their inability to produce IL-4 upon in vivo injection with Staphylococcus aureus enterotoxin B. Furthermore, upon immunization with conventional Ags, growth hormone transgenic mice produce an altered Ig isotype pattern characterized by a response shift from IgG1 in nontransgenic mice to IgG2 in transgenic mice. The impaired T cell responses correlated with survival from septic shock mediated by bacterial enterotoxins. We conclude that growth hormone may have the potential of regulating immune responses in pathologic processes associated with hyperactivation of T cells or with massive cytokine production.

Linomide prevents the lethal effect of anti-Fas antibody and reduces Fas-mediated ceramide production in mouse hepatocytes.

Fas is an apoptosis-signaling receptor molecule expressed in vivo on thymocytes, liver, heart, and ovary. In vivo administration of the anti-Fas Jo2 antibody in mice induces severe apoptotic liver damage leading to fulminant hepatitis and death. Linomide, a quinoline 3-carboxamide, inhibits apoptosis of B and T cells induced by various stimuli including viruses, superantigens, and glucocorticoids. Mice treated with linomide survived the lethal effect of anti-Fas antibody, did not accumulate ceramide in hepatocytes, and recovered liver structure and function within 96 h of anti-Fas injection, as confirmed by histology and glutamic oxalacetic transaminase, glutamic pyruvic transaminase, and lactate dehydrogenase levels. Surviving mice showed severe depletion of cortical thymocytes, but medullar thymic cells expressing high CD3 and Fas levels also survived the treatment with anti-Fas in the presence of linomide. Heart, lung, and ovary showed no signs of apoptosis promoted by Fas ligation. These results suggest that linomide prevents cell death triggered by Fas ligation and can be useful for therapeutic intervention in fulminant hepatitis.

Role of the autophosphorylation site on the biological function of pp56lck.

Src-family tyrosine kinases act as signaling molecules in a wide array of cellular activation processes. The existence of the various src-family members reflects the requirement for different cell-surface receptors to transmit cell-type specific intracellular signals. The structural basis for the functional specificity of src-kinases is being actively investigated. In the present report we have analysed the contribution of the area surrounding the autophosphorylation site (located at subdomain VII of the catalytic domain) in determining src-kinases activity and functional specificity. To this end we analysed the kinase activities of the lymphoid src-kinase pp56lck and a mutant of pp56lck in which this region has been exchanged for the corresponding area of the serine/threonine kinase c-Raf. Our studies indicate that the change at subdomain VII affected the ability of pp56lck to phosphorylate physiological substrates. Furthermore, when analysed in T cells, the mutant at subdomain VII failed to induce interleukin-2 production, a specific biological function of pp56lck. Thus, the area surrounding the autophosphorylation site of pp56lck plays a critical role in mediating its specific biological function.

Lck unique domain influences Lck specificity and biological function.

Src-family tyrosine kinases share structural and amino acid sequence homology, particularly in the catalytic domain as well as in the SH2 and SH3 domains of the regulatory region. However, each src-family member also contains a unique domain which is specific to and characteristic of each individual tyrosine kinase. These unique or specific domains may contribute to the functional specificity of each src-family kinase. To address this possibility, we analyzed the kinase activities and substrate specificities of the lymphoid src-kinase, pp56lck, and a mutant of pp56lck lacking its specific domain. Our data show that both the wild type enzyme and the specific domain-deleted mutant displayed similar affinities for ATP and the non-physiological substrate denatured enolase. However, the specific domain-deleted mutant failed to phosphorylate a number of physiological substrates of pp56lck. In addition, the ability of pp56lck to mediate induction of the interleukin-2 promoter was strongly impaired upon deletion of its specific domain. Thus, the unique domain is not required for the intrinsic kinase activity of pp56lck, however, it influences substrate preference and contributes to the unique physiological function of this src-family tyrosine kinase.