Nuclear phosphatidylinositol 3,4,5-trisphosphate, phosphatidylinositol 3-kinase, Akt, and PTen: emerging key regulators of anti-apoptotic signaling and carcinogenesis.

Inositol lipid-derived second messengers have long been known to have an important regulatory role in cell physiology. Phosphatidylinositol 3-kinase (PI3K) synthesizes the second messenger 3,4,5'-phosphatidylinositol trisphosphate (Ptdlns 3,4,5P3) which controls a multitude of cell functions. Down-stream of PI3K/PtdIns 3,4,5P3 is the serine/threonine protein kinase Akt (protein kinase B, PKB). Since the PI3K/ PtdIns 3,4,5P3 /Akt pathway stimulates cell proliferation and suppresses apoptosis, it has been implicated in carcinogenesis. The lipid phosphatase PTEN is a negative regulator of this signaling network. Until recently, it was thought that this signal transduction cascade would promote its anti-apoptotic effects when activated in the cytoplasm. Several lines of evidence gathered over the past 20 years, have highlighted the existence of an autonomous nuclear inositol lipid cycle, strongly suggesting that lipids are important components of signaling pathways operating at the nuclear level. PI3K, PtdIns(3,4,5)P3, Akt, and PTEN have been identified within the nucleus and recent findings suggest that they are involved in cell survival also by operating in this organelle, through a block of caspase-activated DNase and inhibition of chromatin condensation. Here, we shall summarize the most updated and intriguing findings about nuclear PI3K/ PtdIns(3,4,5)P3/Akt/PTEN in relationship with carcinogenesis and suppression of apoptosis.

TNF-related apoptosis-inducing ligand (TRAIL) and erythropoiesis: a role for PKC epsilon.

The regulation of the hematopoietic stem cell pool size and the processes of cell differentiation along the hematopoietic lineages involve apoptosis. Among the different factors with a recognized activity on blood progenitor cells, TRAIL - a member of the TNF family of cytokines - has an emerging role in the modulation of normal hematopoiesis.PKC(epsilon) levels are regulated by EPO in differentiating erythroid progenitors and control the protection against the apoptogenic effect of TRAIL. EPO-induced erythroid CD34 cells are insensitive to the apoptogenic effect of TRAIL between day 0 and day 3, due to the lack of specific surface receptors expression. Death receptors appear after day 3 of differentiation and consequently erythroid cells become sensitive to TRAIL up to day 9/10, when the EPO-driven up-regulation of PKC epsilon intracellular levels inhibits the TRAIL-mediated apoptosis, via Bcl-2. In the time interval between day 3 and 9, therefore, the number of erythroid progenitors can be limited by the presence of soluble or membrane-bound TRAIL present in the bone marrow microenvironment.

Significance of nuclear phospholipase C signaling through type 1 IGF receptor.

The existence of a nuclear polyphosphoinositol metabolism independent from that at the plasma membrane is now widely recognized. Specific changes in the nuclear phosphatidylinositol (Ptdlns) metabolism have been implicated in cell growth, differentiation, and neoplastic transformation. Here we shall review the main features of nuclear inositol lipid signaling through type I IGF receptor, focusing the attention on the role of inositide-specific phospholipase C (PI-PLC) beta1 in cell proliferation and differentiation, given its peculiar localization in the nuclear compartment.

New frontiers of inositide-specific phospholipase C in nuclear signalling.

Strong evidence has been obtained during the last 16 years suggesting that phosphoinositides, which are involved in the regulation of a large variety of cellular processes in the cytoplasm and in the plasma membrane, are present within the nucleus. A number of advances has resulted in the discovery that nuclear phosphoinositides and their metabolizing enzymes are deeply involved in cell growth and differentiation. Remarkably, the nuclear inositide metabolism is regulated independently from that present elsewhere in the cell. Even though nuclear inositol lipids generate second messengers such as diacyglycerol and inositol 1,4,5-trisphosphate, it is becoming increasingly clear that in the nucleus polyphosphoinositides may act by themselves to influence functions such as pre-mRNA splicing and chromatin structure. This review aims at highlighting the most significant and up-dated findings about inositol lipid metabolism in the nucleus.

Chromatin fibers organization within the nucleus.

In order to evaluate at the ultrastructural level the three dimensional arrangement of the dispersed chromatin during the intephase, the immunogold detection of Bromodeoxyuridine (BrdU), of the DNA polymerase alpha and of the proliferating cell nuclear antigen (PCNA) was performed on human HL60 leukemia cells and nuclear matrices extracted from the same cellular model. The Field Emission In lens Scanning Electron Microscopy analysis of the ultrathin cryosectioned cells revealed the presence of a chromatin three dimensional network where the different constituents appeared repetitively assembled. Also the nuclear matrix showed a repetitive structure, on which the deprivation of the DNA corresponded to the selective loss of particular class sized fibers. The single or multiple combined immunolocalization of different structures involved in the DNA replication, where BrdU, DNA polymerase alpha and PCNA represent, respectively, the substratum, the polymerizing enzyme and a regulator of the reaction, allowed the understanding of its reciprocal spatial relationship on the dispersed interphasic chromatin and the role of the nuclear matrix in the replicative process.

Phosphatidylinositol 3-kinase translocation to the nucleus is an early event in the interleukin-1 signalling mechanism in human osteosarcoma Saos-2 cells.

Interleukin 1 (IL-1) is a proinflammatory cytokine which can elicit proliferative, differentiative, or metabolic responses. The molecular mechanisms by which IL-1 signals are transduced from the plasma membrane to the nucleus, although extensively studied, have not been completely elucidated. We previously demonstrated that human osteosarcoma Saos-2 cells incubated with IL-1 presented a rapid and transient increase of phospholipase C activity exclusively at the nuclear level. Moreover, we presented evidence that not only the canonical inositol lipid signalling pathway was involved, but also the D3-phosphorylated lipids generated by phosphatidylinositol 3-kinase (PI 3-kinase) were affected. The results of this study indicate that in Saos-2 cells PI 3-kinase is recruited and activated by IL-1 receptor I (IL-1RI) through binding of the SH2 domains to the consensus sequence on the C-terminal tail of the receptor, and that Tyr-479 is essential for PI 3-kinase activation. Moreover, IL-1 treatment triggers PI 3-kinase translocation to the nucleus; this event is rapid and transient in cells expressing high levels of IL-1RI (Saos-2/IL-1R) as well as in untransfected cells, although to a lesser extent. The data, based on immunochemical and immunocytochemical quantitative methods, indicate that PI 3-kinase translocation to the nucleus depends on PI 3-kinase activation. In fact, inactivation by two independent mechanisms, addition of specific PI 3-kinase inhibitors, or overexpression of a mutant form of IL-1RI, resulted in a substantial inhibition of PI 3-kinase translocation to the nucleus. These data suggest that PI 3-kinase recruitment by the activated receptor is a limiting step in PI 3-kinase activation and nuclear translocation. This early event in the IL-1 signalling mechanisms confirms that D3 inositides, as well as canonical inositides produced by nuclear phospholipase C isoforms, are involved in this pathway of activation of transcription factors.

Inositides in the nucleus: further developments on phospholipase C beta 1 signalling during erythroid differentiation and IGF-I induced mitogenesis.

Inositol lipids originally shown to be metabolized in the cytosol have been detected also in the nucleus, where they are both synthesized and hydrolyzed. In the case of erythroid differentiation of murine erythroleukemia cells (Friend cells) it has been previously shown that PLC beta 1, which is the major nuclear PLC, undergoes down-regulation upon treatment with DMSO or tiazofurin which act as differentiative agents. On the contrary, i.e., during IGF-I induced mitogenesis, it has been shown that PLC beta 1 is rapidly activated and this event is essential for the onset of DNA synthesis. Even though its key role in cell growth has been shown, both the mechanism by which nuclear PLC beta 1 is activated and the direct relationship with erythroid differentiation are still unknown. We have addressed the question if PLC beta 1 expression and activity in the nucleus are directly related or not to the establishment of the differentiated state and we have checked the two main ways of activation, i.e., via G-protein or via phosphorylation, in order to establish whether nuclear PLC beta 1 is regulated the same way as the one at the plasma membrane or not. The data reported here show that nuclear PLC beta 1 is responsible for a continuous recycling of Friend cells, acting as a negative regulator of differentiation and that its activation is dependent on the phosphorylation state.

Inefficient phospholipase C activation and reduced Lck expression characterize the signaling defect of umbilical cord T lymphocytes.

Adult and neonatal immunocompetent cells exhibit important functional distinctions, including differences in cytokine production and susceptibility to tolerance induction. We have investigated the molecular features that characterize the immune response of cord blood-derived T lymphocytes compared with that of adult T lymphocytes. Our findings demonstrate that phospholipase C (PLC) isozymes, which play a pivotal role in the control of protein kinase C activation and Ca2+ mobilization, are differently expressed in cord and adult T lymphocytes. PLCbeta1 and delta1 are expressed at higher levels in cord T cells, while PLCbeta2 and gamma1 expression is higher in adult T lymphocytes. PLCdelta2 and gamma2 appear to be equally expressed in both cell types. In addition, a functional defect in PLC activation via CD3 ligation or pervanadate treatment, stimuli that activate tyrosine kinases, was observed in cord blood T cells, whereas treatment with aluminum tetrafluoride (AlF4-), a G protein activator, demonstrated a similar degree of PLC activation in cord and adult T cells. The impaired PLC activation of cord blood-derived T cells was associated with a a very low expression of the Src kinase, Lck, along with a reduced level of ZAP70. No mitogenic response to CD3 ligation was observed in cord T cells. However, no signaling defect was apparent downstream of PLC activation, as demonstrated by the mitogenic response of cord T cells to the pharmacologic activation of protein kinase C and Ca2+ by treatment with PMA and ionomycin. Thus, neonatal cord blood-derived T cells show a signaling immaturity associated with inadequate PLCgamma activation and decreased Lck expression.

Inositides in the nucleus: taking stock of PLC beta 1.

The nucleus was shown to be a site for inositol lipid cycle which can be affected by treatment of quiescent cells with growth factors such as IGF-I. In fact, the exposure of Swiss 3T3 cells to IGF-I results in a rapid and transient increase in nuclear PLC beta 1 activity. In addition, several other reports have shown the involvement of PLC beta 1 in nuclear signalling in different cell types. Indeed, PLC beta 1 differs from the PLC gamma and della isozymes in that it has a long COOH-terminal sequence which contains a cluster of lysine residues that are critical for association with the nucleus. Although the demonstration of PtInsP and PtdInsP2 hydrolysis by nuclear PLC beta 1 established the existence of nuclear PLC signalling, the significance of this autonomous pathway in the nucleus has yet to be thoroughly clarified. By inducing both the inhibition of PLC beta 1 expression by antisense RNA and its overexpression we show that this nuclear PLC is essential for the onset of DNA synthesis following IGF-I stimulation of quiescent Swiss 3T3 cells. Moreover, using a different cell system, i.e. Friend erythroleukemia cells induced to differentiate towards erythrocytes, it has been evidenced that there is a relationship between the expression and activity of nuclear PLC beta 1 and the association of PI-PT alpha with the nucleus in that, when PLC activity ceases, in differentiated and resting cells at the same time there is a dramatic decrease of the association of PI-PT alpha with the nucleus.

Kinetics of in vitro natural killer activity against K562 cells as detected by flow cytometry.

Natural killer (NK) cells bind to K562 tumor target cells in vitro and kill them. The binding and cytotoxic activities of NK cells are tightly related to each other: degranulation of the cytotoxic effector is the basis for target cell damage and a consequence of effector-target recognition and binding. However, the two phases of NK activity, binding and killing, have always been measured separately by various methodologies and under different experimental conditions, because of the lack of a comprehensive methodology able to measure both of them at one time. Here we describe the simultaneous measurement of the binding and killing activities against K562 of resting and cytokine (IL-2 or IL-12)-stimulated NK cells by flow cytometry. NK, K562 and conjugates can be identified and measured by flow cytometry on the basis of NK mAb staining and target cells autofluorescence (Binding Plot). Within each population of the binding plot, killed targets can be identified and measured by their scatter characteristics (Cytotoxicity Plot). We show that i) the conjugate formation is enhanced in cytokine-stimulated cells, even at relatively short co-incubation times; ii) the conjugate release is also accelerated by cytokines; iii) the conjugate release is always quicker than the induction of the morphological changes in the target cell that generate its modified scattering properties.

Cytochemistry of the functional domains of the nucleus in normal and in pathologic conditions.

By means of ultrastructural cytochemistry significant advances have been made in understanding the functional roles of many nuclear domains. This review gives schematic information about the main nuclear domains involved in replication, transcription, processing and transport of the transcripts in normal and in pathologic conditions. Particular attention is paid to a functional domain that appears to be involved in signal transduction. Data are reported on the intranuclear specific localization of key elements of the polyphosphoinositide signal transduction system in different cell types including human osteosarcoma cell lines. Compared with the compartmentalization of the cytoplasm, the nucleus has long been considered as relatively unstructured. On the other hand, fundamental nuclear functions, such as DNA replication and RNA transcription, can be molecularly characterized also in cell-free systems, suggesting that supramolecular organization is not so strictly required as for other cell functions occurring within intact cytoplasmic organelles. Nevertheless, a stringent organization is required for packing about 200 cm of DNA in the about 30 micron 3 of the nucleus. In the absence of membrane-delimited organelles, the nuclear organization is based on functional compartments, or domains, whose spatial localization involves the nuclear matrix, which shares many properties with the cytoskeleton. The nuclear domains are defined as structural compartments, not necessarily stable but dynamically variable, which perform specific metabolic functions through the partitioning of molecular complexes. Their identification has been made possible in the last few years by the development of specific nuclear probes for confocal and electron microscope immunocytochemistry. Therefore, the complex network of structures and enzymatic functions that make up the nucleus is in several cases yielding to molecular analysis, but a large part remains unknown (Strouboulis and Wolffe, 1996; Laemmli and Tjian, 1996). Rapid advances in understanding the functional role of the nuclear domains have been made recently: in particular, of the nuclear envelope, of the nucleolus, and of RNA splicing. In other cases, e.g. the precise localization of the nuclear domains involved in signal transduction, much remains to be clarified (Forbes and Johnson, 1997). It is conceivable that in the near future unexpected new nuclear domains will come to light and new nuclear functions may emerge, especially in field of post-transcriptional processing and transport of RNAs, and in the relationships between the nucleo-skeleton and enzymic fixed sites involved in replication, transcription and signal transduction. The aim of this review is to provide information about the morphological characteristics, the associated functions and the molecular composition of the main nuclear domains found to date. To simplify the exposition, the main data on each nuclear domain are reported in Tables, together with the principal references on the subject. Figures refer to original findings on some aspects of nuclear domain organization.

Nuclear lipid-dependent signal transduction in human osteosarcoma cells.

The enzymes and substrates involved in phosphoinositide signal transduction which have been detected in the nucleus of several cell types have been demonstrated to be responsive to agonists. The complexity of this aspect of inositide function has been previously analyzed in some cell models characterized by a mitogenic or differentiating response to specific factors. An interesting experimental model is represented by human derived osteosarcoma Saos-2 cells, characterized by the expression of high affinity receptors for interleukin 1 alpha (IL-1 alpha), which is one of the most potent stimulators of bone resorption. In particular, we investigated the earliest intracellular events following the binding of IL-1 alpha to its receptor, involving the inositide signal transduction pathway. Saos-2 cells present a partitioning of the phosphoinositidase (PLC) isoforms; in fact, the nucleus contains both PLC beta 1 and gamma 1, while the cytoplasm contains almost exclusively the gamma 1 isoform. IL-1 alpha evokes a rapid and transient increase of the PLC beta 1 activity in the nucleus, which causes the hydrolysis of phosphatidylinositol mono- and bis-phosphate. In response to IL-1 alpha, not only the canonical inositol lipid pathway appears to be involved; also the 3'-phosphorylated lipids generated by phosphatidylinositol 3-kinase (PI 3-K), which may act as second messengers, appear to be affected. In fact, Saos-2 cells present a nuclear PI 3-K activity which can be enhanced by the IL-1 alpha treatment. Among the possible targets of the second messengers released by the nuclear PLC beta 1 activation, we found that some protein kinase C isoforms, namely the epsilon and zeta, which are present within the nucleus, are activated after IL-1 alpha exposure. These activated PKC isoforms, in turn, could modulate the activity of the transcription factor NFkB, which, 5 min after IL-1 alpha treatment, has already translocated to the nucleus and bound to DNA to promote gene activation. The actual role of the inositide pathway in the Saos-2 cell function has also been investigated by utilizing cell clones transfected with the mouse sequence of the PLC beta 1.

Selective enrichment in human megakaryocyte progenitors by the B203.13 surface differentiation antigen.

The B203.13 monoclonal antibody specifically recognizes a subset (8-18.5%) of human CD34+ haemopoietic progenitors, which are significantly (P<0.05) enriched in megakaryocyte progenitors (CFU-meg). Moreover B203.13 expression was progressively lost as maturation proceeded along the megakaryocytic lineage. In fact: (i) CFU-meg derived from CD34+/B203.13+ showed a greater number of cells/colony with respect to CD34+/B203.13-; (ii) after 10 d of liquid cultures with 100 ng/ml of thrombopoietin, only a minority of CD34-derived cells positive for CD41 coexpressed B203.13; (iii) in situ immunocytochemical staining revealed that B203.13 was expressed exclusively on immature megakaryoblasts; (iv) circulating platelets did not express B203.13.

Inositol lipid cycle and autonomous nuclear signalling.

The involvement of phospholipids and in particular polyphosphoinositides in cellular signalling has been documented in detail in the last 20 years. In addition to the plasma membrane localization also the nucleus is shown to be a site for both synthesis and hydrolysis of the phosphorylated forms of phosphatidylinositol. Previous observation have established that the nucleus possesses a specific PLC for inositol lipids, i.e., the PLC beta 1 isoform, which undergoes rapid and transient activation after IGF-I stimulation of quiescent Swiss 3T3 cells and is down-regulated after treatment of Friend erythroleukemia cells with DMSO. Here we have reviewed: (i) the potential of nuclear PLC beta 1 to be a target for anti-cancer drug, (ii) the capability of this PLC isoform, when activated by IGF-I, to be a key signalling molecule in the onset of DNA synthesis, via DAG generation and PKC alpha translocation to the nucleus, (iii) the chromosome mapping of PLC beta 1 gene. The differentiation program of Friend cells can be activated by other agents besides DMSO including tiazofurin, an anti-tumor drug, also capable of affecting the nuclear inositol lipid cycle. Tiazofurin induces a lowering of the activity of PLC beta 1 due to down regulation of this isoform as revealed by both Western blotting and Northern blotting analyses. Using Swiss 3T3 cells stably transformed with an antisense PLC beta 1 construct, the knock-out of the PLC beta 1 gene induces both a loss of PLC beta 1 expression, as determined by Western blots, and a loss of the mitogenic responsiveness to IGF-I. These events show a direct relationship between nuclear PLC beta 1 evoked signals and IGF-I induced cell proliferation. Finally, the assignment of the PLC beta 1 gene to the band q35-36 of rat chromosome 3 paves the way for further genetic studies given the fact that the region where PLC beta 1 gene maps is a hot spot for genetic alterations in a number of experimentally induced rat tumors. Taken as a whole, these results assign a key role to the regulation of nuclear PLC activity and expression both in growth-factor activated mitogenesis and in in vitro erythroid differentiation.

Stimulation of nuclear polyphosphoinositide synthesis by GTP-gamma-S: a potential regulatory role for nuclear GTP-binding proteins.

The nonhydrolyzable GTP analogue GTP-gamma-S was capable of stimulating in vitro phosphorylation of polyphosphoinositides in isolated nuclei prepared from mouse erythroleukemia cells. On the contrary, GDP-beta-S was ineffective. The stimulation was not detectable when nuclei were prepared from erythroleukemia cells induced to differentiate by exposure to dimethyl sulfoxide. Both nuclear phosphomonoesterase and phospholipase C activities were not influenced by GTP-gamma-S. Our results point to the likelihood that nuclear phosphoinositide kinases might be regulated by a GTP-binding protein.

Immunocytochemical detection of the intranuclear variations of phosphatidylinositol 4,5-bisphosphate amount associated with changes of activity and amount of phospholipase C beta 1 in cells exposed to mitogenic or differentiating agonists.

The intracellular localizations of phosphatidylinositol 4,5-bisphosphate (PIP2) and of its hydrolyzing enzyme phospholipase C (PLC; in this case the beta 1 isoform) have been evaluated by electron microscope immunocytochemistry in cells exposed to mitogenic or differentiating agents. These cells have been previously demonstrated to present a signal transduction system based on the polyphosphoinositide hydrolysis localized at the nuclear level, which can be specifically modulated by agonists. The results demonstrate that in Swiss 3T3 mouse fibroblasts mitogenically stimulated by insulin-like growth factor I (IGF-I), a rapid and transient decrease of the PIP2 detectable by immunogold labeling occurs at the nuclear interior. This effect appears due to the activation of the PLC beta 1 isozyme already present in the nucleus, since no significant variations of the enzyme amount and distribution can be detected by immunolabeling. However, after 30 min of exposure to IGF-I, when the PLC beta 1 activity is returned to basal level, a slight but significant increase of the enzyme amount is detected both in the nucleus and in the cytoplasm. On the other hand, an increased accumulation of PIP2 in the nucleus, accompanied by a decrease of the intranuclear amount of PLC beta 1 isozyme, have been observed in mouse erythroleukemia Friend cells, induced to erythroid differentiation by dimethylsulfoxide (DMSO). These results indicate that quantitative immunocytochemistry represents an increment in the available methodologies to investigate the complex regulation of nuclear PI-signalling.

Nuclear inositol lipid cycle and differentiation.

Previous investigations from our laboratory and others have shown the existence of an autonomous intranuclear inositide cycle endowed with conventional lipid kinases and PLC which in PC12 pheochromocytoma cells, human osteosarcoma SaOS-2 cells, rat liver and Swiss 3T3 cells is the isoform beta 1, which in the latter cells is activated upon IGF-I stimulation. The behavior of the nuclear inositol lipid cycle has been investigated in nuclei of Friend erythroleukemia cells. These nuclei possess both lipid kinases and PLC. The cycle upon treatment with differentiating agents (i.e., DMSO and tiazofurin) is characterized by an accumulation of polyphosphoinositides and a decrease of DAG due to down-regulation of a specific PLC. Indeed, even if both beta 1 and gamma 1 isoforms are present in these nuclei, when Friend cells undergo terminal erythroid differentiation only the PLC beta 1 isoform is down-regulated as shown by immunochemical and immunocytochemical analysis, by direct determination of enzymatic activity and in the presence of neutralizing monoclonal antibodies as well as by Northern blot for PLC beta 1 message, whilst the amount of PLC gamma 1 and its activity are unaffected by erythroid differentiation. In conclusion, the presence of a specific nuclear PLC whose activity and expression are down-regulated during differentiation of erythroleukemia cells points out a role for nuclear phosphoinositide signalling in the processes of cell differentiation and hints at the nuclear PLC beta 1 as an important step of the cycle in relation to the erythroid differentiative commitment of murine erythroleukemia cells.

Immunocytochemical analysis of phosphatidylinositol-specific phospholipase C in PC12 cells: predominance of the delta isoform during neural differentiation.

The rat pheochromocytoma PC12 cell line, which differentiates into sympathetic neurons under nerve growth factor (NGF) treatment, contains at least three phosphoinositidase C (PIC) isozymes, PIC beta, PIC gamma, PIC delta. These isozymes have been previously shown to display a different subcellular localization. To determine whether or not NGF induces changes in the presence and/or distribution of PIC isozymes during PC12 neural differentiation, studies were carried out by means of in situ immunocytochemistry. After NGF administration the proliferative activity was progressively reduced to very low levels, as measured by bromodeoxy Uridine incorporation, and a neuron-like morphology was displayed by almost all cells. In unstimulated PC12 cells, PIC beta was detected in the nucleus whereas PIC delta was only cytoplasmic; PIC gamma was found in both cell compartments. In cells treated with NGF for 3 days, neural processes extended to twice the diameter of the cell body; the gamma isoform was concentrated near the nucleus, while the immunoreactivity of the beta form remained constant and the delta form was increased. After 10 days of treatment with NGF, PIC beta was hardly detectable and PIC gamma immunostaining was considerably decreased. On the contrary, PIC delta progressively increased and, after 14 days of NGF exposure, fully differentiated cells displayed an intense labelling of cell body and neurites. In the same cells, PIC beta and PIC gamma were almost negative. These results suggest that NGF dependent neural differentiation is related to the selective down regulation of PIC beta and gamma and the increase of PIC delta isozyme associated with the decrease of cell proliferation.