Inositides in nuclei of Friend cells: changes of polyphosphoinositide and diacylglycerol levels accompany cell differentiation

Methods to assess changes in the pattern of nuclear phosphoinositides

Phosphatidylinositol (PtdIns) and its phosphorylated derivatives represent less than 5% of total membrane phospholipids in cells. Despite their low abundance, they form a dynamic signalling system that is regulated in response to a variety of extra and intra-cellular cues (Curr Opin Genet Dev 14:196-202, 2004). Phosphoinositides and the enzymes that synthesize them are found in many different sub-cellular compartments including the nuclear matrix, heterochromatin, and sites of active RNA splicing, suggesting that phosphoinositides may regulate specific functions within the nuclear compartment (Nat Rev Mol Cell Biol 4:349-360, 2003; Curr Top Microbiol Immunol 282:177-206, 2004; Cell Mol Life Sci 61:1143-1156, 2004). The existence of distinct sub-cellular pools has led to the challenging task of understanding how the different pools are regulated and how changes in the mass of lipids within the nucleus can modulate nuclear specific pathways. Here we describe methods to determine how enzymatic activities that modulate nuclear phosphoinositides are changed in response to extracellular stimuli.

Diacylglycerol kinase zeta is associated with chromatin, but dissociates from condensed chromatin during mitotic phase in NIH3T3 cells

Diacylglycerol kinase (DGK) converts diacylglycerol (DG) to phosphatidic acid, both of which act as second messengers to mediate a variety of cellular mechanisms. Therefore, DGK contributes to the regulation of these messengers in cellular signal transduction. Of DGK isozymes cloned, DGKzeta is characterized by a nuclear localization signal that overlaps with a sequence similar to the myristoylated alanine-rich C-kinase substrate. Previous studies showed that nuclear DG is differentially regulated from plasma membrane DG and that the nuclear DG levels fluctuate in correlation with cell cycle progression, suggesting the importance of nuclear DG in cell cycle control. In this connection, DGKzeta has been shown to localize to the nucleus in fully differentiated cells, such as neurons and lung cells, although it remains elusive how DGK behaves during the cell cycle in proliferating cells. Here we demonstrate that DGKzeta localizes to the nucleus during interphase including G1, S, and G2 phases and is associated with chromatin although it dissociates from condensed chromatin during mitotic phase in NIH3T3 cells. Furthermore, this localization pattern is also observed in proliferating spermatogonia in the testis. These results suggest a reversible association of DGKzeta with histone or its related proteins in cell cycle, plausibly dependent on their post-translational modifications.

Phosphoinositide-specific phospholipase C (PI-PLC) β1 and nuclear lipid-dependent signaling

Over the last years, evidence has suggested that phosphoinositides, which are involved in the regulation of a large variety of cellular processes both in the cytoplasm and in the plasma membrane, are present also within the nucleus. A number of advances has resulted in the discovery that phosphoinositide-specific phospholipase C signalling in the nucleus is 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 hydrolysis generates second messengers such as diacylglycerol and inositol 1,4,5-trisphosphate, it is becoming increasingly clear that in the nucleus polyphosphoinositides may act by themselves to influence pre-mRNA splicing and chromatin structure. Among phosphoinositide-specific phospholipase C, the beta(1) isoform appears to be one of the key players of the nuclear lipid signaling. This review aims at highlighting the most significant and up-dated findings about phosphoinositide-specific phospholipase C beta(1) in the nucleus.

Profilin and Rop GTPases are localized at infection sites of plant cells

We have found 5 profilin cDNAs in cultured parsley cells, representing a small gene family of about 5 members in parsley. Specific antibodies were produced using heterologously expressed parsley profilin as antigen. Western blot analysis revealed the occurrence of similar amounts of profilin in roots and green parts of parsley plants. Immunocytochemical staining of parsley cells infected with the oomycetous plant pathogen Phytophthora infestans clearly revealed that profilin accumulates at the site on the plasma membrane subtending the oomycetous appressorium, where the actin cables focus. We also observed the accumulation of Rop GTPases around this site, which might point to a potential function in signaling to the cytoskeleton.

Erythroid cell differentiation is characterized by nuclear matrix localization and phosphorylation of protein kinases C (PKC) alpha, delta, and zeta

Protein kinases C (PKC) zeta expression and phosphorylation at nuclear level during dimethyl sulfoxide (DMSO)-induced differentiation in Friend erythroleukemia cells have been previously reported, suggesting a possible role of this PKC isoform in the DMSO-related signaling. In order to shed more light on this tantalizing topic, we investigated PKC intracellular and sub-cellular localization and activity during DMSO-induced erythroid differentiation. Results indicated that at least PKC alpha, zeta, and delta are strongly and temporally involved in the DMSO-induced differentiation signals since their expression and phosphorylation, though at different extents, were observed during treatments. Intriguingly, while PKC alpha and zeta associate to the nuclear matrix during the differentiation event, PKC delta appears to be residentially associated to the nuclear matrix. Furthermore, an evident downregulation of the beta-globin gene transcription (differentiation hallmark) was detected upon a progressive inhibition of these PKC isoforms by means of specific inhibitors, indicating, therefore, that PKC alpha, zeta, and delta phosphorylation play a crucial role in the control of erythroid differentiation.

Linking lipids to chromatin

Dynamic regulation of chromatin structure is thought to be a prerequisite for nuclear functions that require accessibility to DNA such as replication, transcription and DNA repair. The phosphoinositide (PI) pathway is a second messenger signalling system regulated in response to a variety of extracellular (growth factors, differentiation signals) and intracellular (cell cycle progression, DNA damage) stimuli. The presence of a PI pathway in the nucleus together with the recent findings that specific nuclear proteins can interact with and are regulated by phosphoinositides suggest that changes in the nuclear phosphoinositide profile may have a direct role in modulating chromatin structure.

Nuclear inositides: facts and perspectives

Strong evidence has been accumulating over the last 15 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. Several advances have resulted in the discovery that nuclear phosphoinositides are involved in cell growth and differentiation. Remarkably, the nuclear inositide metabolism is regulated independently from that present elsewhere in the cell. Although nuclear inositol lipids generate second messengers such as diacylglycerol and inositol 1,4,5-trisphosphate, it is becoming increasingly clear that in the nucleus polyphosphoinositides may act by themselves to influence pre-mRNA splicing and chromatin structure. This review aims at highlighting the most significant and updated findings about inositol lipid metabolism in the nucleus.

Phosphatidic acid is the prominent product of endogenous neuronal nuclear lipid phosphorylation, an activity enhanced by sphingosine, linked to phospholipase C and associated with the nuclear envelope

Using endogenous lipid substrates, assays of lipid phosphorylation indicated that neuronal nuclei had a considerable superiority in phosphatidic acid (PA) formation when compared with homogenates and other subfractions of cerebral cortex. This predominance of neuronal nuclear PA labelling was linked to a sizable pool of nuclear diacylglycerols that expanded significantly with incubation. PA was also the dominant product of neuronal nuclear lipid phosphorylation reactions. Nuclear envelope preparations and the parent neuronal nuclei showed specific rates of PA formation that were comparable, based upon membrane phospholipid contents. As well, using an exogenous diacylglycerol substrate, the distribution of diacylglycerol kinase activities closely followed phospholipid contents of subfractions derived from the neuronal nucleus during envelope preparation. This evidence suggested an association between diacylglycerol kinase and the neuronal nuclear envelope. Nuclear PA formation increased in the presence of sphingosine, while sphingosine decreased PA formation in other subfractions. Likely sphingosine exerted its effect on nuclear diacylglycerol kinase, as sphingosine did not elevate levels of nuclear diacylglycerols. Phosphoinositidase C was present in the nuclei and inhibitors of this enzyme did decrease PA formation, indicating diacylglycerols from inositides as substrates for nuclear diacylglycerol kinase. The nuclear envelope fraction had a considerably lower specific phosphoinositidase C activity than the parent nuclei, and showed an activation of PA formation by sphingosine, but a less efficient handling of the exogenous diacylglycerol substrate. It is possible that phosphoinositidase C and diacylglycerol kinase are closely situated within the neuronal nuclei, and a loss of the former activity may compromise the latter.

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.

Phosphatidylinositol 3-kinase in HL-60 nuclei is bound to the nuclear matrix and increases during granulocytic differentiation

We have used HL-60 leukemia cells to investigate phosphatidylinositol 3-kinase (PI 3-K) during granulocytic differentiation at the nuclear level. Nuclei of HL-60 cells showed a constitutive presence of PI 3-K that increased when cells were treated with differentiating doses of ATRA. PI 3-K was also detected tightly bound to nuclear matrices of HL-60 cells, isolated by nuclease treatment and high salt extraction. Four days of ATRA treatment induced a striking increase of nuclear matrix bound PI 3-K. In situ morphological analysis by confocal microscopy showed the translocation of PI 3-K to the nucleus and to the subnuclear fractions. PI 3-K enzymatic activity was stimulated during the granulocytic differentiation process and parallelled the increase in content of nuclei and subnuclear fractions. PI 3-K activity was recovered in nuclei also without the addition of exogenous substrates, consistent with the presence of both substrates and enzyme in the nucleus. These results indicate that specific intracellular localization of PI 3-K determines the production of different phosphoinositides in the sites of the enzyme translocation, and suggest that 3-phosphoinositide metabolism may play a specific role in the nucleus, candidating PI 3-K as a key enzyme in promoting granulocytic differentiation of HL-60 cells.

Phospholipid signalling in the nucleus. Een DAG uit het leven van de inositide signalering in de nucleus

Diverse methodologies, ranging from activity measurements in various nuclear subfractions to electron microscopy, have been used to demonstrate and establish that many of the key lipids and enzymes responsible for the metabolism of inositol lipids are resident in nuclei. PtdIns(4)P, PtdIns(4,5)P2 and PtdOH are all present in nuclei, as well as the corresponding enzyme activities required to synthesise and metabolise these compounds. In addition other non-inositol containing phospholipids such as phosphatidylcholine constitute a significant percentage of the total nuclear phospholipid content. We feel that it is pertinent to include this lipid in our discussion as it provides an alternative source of 1, 2-diacylglycerol (DAG) in addition to the hydrolysis of PtdIns(4, 5)P2. We discuss at length data related to the sources and possible consequences of nuclear DAG production as this lipid appears to be increasingly central to a number of general physiological functions. Data relating to the existence of alternative pathways of inositol phospholipid synthesis, the role of 3-phosphorylated inositol lipids and lipid compartmentalisation and transport are reviewed. The field has also expanded to a point where we can now also begin to address what role these lipids play in cellular proliferation and differentiation and hopefully provide avenues for further research.

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.

Erythropoietin stimulates nuclear localization of diacylglycerol and protein kinase C beta II in B6SUt.EP cells

Erythropoietin (EPO) is a hormone, as well as a hematopoietic growth factor, that specifically regulates the proliferation and differentiation of erythroid progenitor cells. Although the membrane-bound receptor for EPO has no intrinsic kinase activity, it triggers the activation of protein kinases via phospholipases A2, C, and D. A cascade of serine and threonine kinases, including Raf-1, MAP kinase and protein kinase C (PKC) is activated following tyrosine phosphorylation. In this study, we have examined whether changes in nuclear PKC and 1,2-diacylglycerol (DAG) are induced following EPO treatment of the murine target cell line, B6SUt.EP. Western blot analysis using isoform-specific antibodies demonstrated the presence of PKC beta II, but not PKC alpha, beta I, gamma, epsilon, delta, eta, or zeta in the nuclei of cells stimulated with EPO. The increase in nuclear beta II levels was accompanied by an immediate rise in DAG mass levels with both of the increases peaking by 1 min. These rapid increases in nuclear DAG and PKC beta II expression suggest a mechanism for EPO-induced changes in gene expression necessary for cell proliferation.

Changes of nuclear PI-PLC gamma1 during rat liver regeneration

We have previously demonstrated that rat liver nuclei contain PI-PLC beta1 and gamma1 in the inner nuclear matrix and lamina associated with specific phosphodiesterase activity (Bertagnolo et al., 1995, Cell Signall. 7, 669-678). Since compensatory hepatic growth is an informative and well characterized model for natural cell proliferation, the presence of specific PI-PLC isoforms and their activity as well as PIP2 recovery were studied at various regenerating times, ranging from 3 to 22 h after partial hepatectomy. Three PI-PLC isoforms (beta1, gamma1, delta1) were examined in control and regenerating liver cells by using specific antibodies. By means of in situ immunocytochemistry and confocal microscopy, PI-PLC beta1 was found mainly in the nucleoplasm and this pattern was not modified after hepatectomy. On the contrary, the nuclear gamma1 isoform showed a marked decrease at 3 and 16 h after hepatectomy, but a clear increase at 22 h covering with bright intensity the whole nucleus. The PI-PLC delta1 isoform, which is exclusively cytoplasmic, was not altered during rat liver regeneration. By western blotting analysis on whole cell homogenates, none of the PI-PLC isozymes under study showed proliferation-linked modification. However, analyses of isolated nuclei identified changes in the nucleus associated PI-PLC gamma1 that paralleled the in situ observation whereas the beta1 isoform was unmodified at all the times examined. Nuclear phosphodiesterase activity on PIP2 was lower at 3 and 16 h, in comparison with sham operated rats, increased at 6 h and reached the highest value after 22 h. Consistently, the recovery of PIP2, obtained in conditions that optimise PIP-kinase activity, showed a marked decrease at 3 h and an increase up to 16 h of liver regeneration, followed by a further decrease at 22 h. These data are consistent with a close relationship between cell proliferation and the nuclear inositide cycle, depending, in rat liver, predominantly on the modulation of the gamma1 isoform of PI-PLC.

Intranuclear translocation of phospholipase C beta2 during HL-60 myeloid differentiation

Phospholipases C (PLC) beta3, gamma1, and gamma2 were detected in nuclei of HL-60 promyelocitic leukaemia cells. When HL-60 cells undergo terminal myeloid differentiation in the presence of ATRA, the beta2 isoform appeared inside nuclei and was up-regulated until 72 hours of ATRA treatment. The beta3 isozyme was also increased until 72 hours and both isoforms lowered their intranuclear amount at 96 hours and following days of treatment. By contrast PLC gamma1 and gamma2 progressively increased in the nucleus during granulocytic differentiation even after 72 hours of treatment. Terminal differentiation was characterised by the expression of high levels of PLC gamma1 and gamma2 and by low levels of PLC beta2 and beta3 in the nucleus. PIP2 and PIP hydrolysis paralleled the prevalence of the beta or gamma subfamily, respectively. Moreover, at all the examined times no changes of PLCs in the whole cell were detectable, indicating a de novo nuclear translocation of the beta2 and an increased accumulation of beta3, gamma1, and gamma2 isoforms. Thus, the intranuclear presence, expression, and activity of PLC isozymes, which are modulated during differentiation of HL-60 cells, implicate a role for nuclear phosphoinositide signalling in the process of cell maturation. In particular the nuclear translocation of PLC beta2 candidates this PLC as a key enzyme in the granulocytic differentiative commitment of HL-60 cells.

Altered phospholipid metabolism in sodium butyrate-induced differentiation of C6 glioma cells

We examined the changes in phospholipid metabolisms in sodium butyrate-treated C6 glioma cells. Treatment of 2.5 mM sodium butyrate for 24 h induced an increase in the activity of glutamine synthetase, suggesting that these cells were under differentiation. Similar treatment was associated with (i) increased arachidonic acid incorporation into phosphatidylcholine, and (ii) decreased arachidonic acid incorporation into phosphatidylinositol and (iii) phosphatidylethanolamine. These effects were subsequently investigated by examining the acylation process, de novo biosynthesis, and the agonist-stimulated phosphoinositides hydrolysis in these cells. Our results indicated that sodium butyrate stimulated the acylation of arachidonic acid into lysophosphatidylcholine, lysophosphatidylethanolamine, and lysophosphatidylinositol. The glycerol incorporation into these lipids was not affected, but the inositol incorporation into total chloroform extracts and Pl and phosphatidylinositol 4-phosphate was decreased in the sodium butyrate-treated cells. Moreover, the accumulation of the rapid histamine-stimulated phosphoinositide metabolites, i.e., inositol monophosphate, inositol diphosphate, and inositol triphosphate (IP3) was decreased in these cells. To elucidate whether the decreased inositol phosphates were due to a decrease in the phosphoinositides hydrolysis, we measured the transient IP3 production directly by a receptor-binding assay. Our results indicated that histamine-stimulated transient IP3 formations were decreased. Taken together, these results indicated that multiple changes by multiple mechanisms of phospholipid metabolisms were found in sodium butyrate-treated C6 glioma cells. The decreased IP3 formation and its subsequent action, i.e., Ca2+ mobilization, may play an early but pivotal role by which sodium butyrate induces C6 glioma cell differentiation.

Phosphoinositide signalling in nuclei of Friend cells: DMSO-induced differentiation reduces the association of phosphatidylinositol-transfer protein with the nucleus

Friend erythroleukemia cells have a nuclear phosphoinositide cycle which is related to both mitogen-stimulated cell growth and erythorid differentiation. Because of the important role of the phosphatidylinositol-transfer protein (PI-TP) in phosphatidylinositol 4,5-bisphosphate (PtdInsP2) synthesis, we have analysed nuclei isolated from Friend cells for the presence of PI-TP. By Western Blotting it was demonstrated that both intact nuclei and nuclei deprived of the outer membrane contained the PI-TP alpha isoform. Upon induction of erythroid differentiation by DMSO, the amount of nuclear PI-TP alpha was greatly diminished. As shown previously, under these same conditions, nuclear phospholipase C beta1 (PLC beta1) is down-regulated as well.

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.

Changes in the components of a nuclear inositide cycle during differentiation in murine erythroleukaemia cells

Differentiation of murine erythroleukaemia cells with the chemical agent DMSO leads to a cessation of proliferation and the production of a number of erythrocyte markers such as haemoglobin. We have previously demonstrated that activation of proliferation leads to an increase in the production of nuclear diacylglycerol (DAG). Here we demonstrate that differentiation leads to a decrease in the levels of nuclear DAG and the activity of the nuclear-associated phosphoinositidase C (PIC). The change in activity appears to be due to a decrease in the mass levels of the beta 1 isoform, as demonstrated by the use of isoform-specific antibodies. Moreover, the changes correlate with the cessation of proliferation and an increase in the number of cells in G1 phase of the cell cycle, rather than with the number of cells which have differentiated. Indeed, although treatment of the cells with phorbol 12-myristate 13-acetate (PMA) inhibits the differentiation programme as assessed by haemoglobin staining, it does not inhibit the number of cells blocking in G1 of the cell cycle or the changes in nuclear DAG or PIC activity. The possible involvement of this nuclear inositide cycle during progression through the cell cycle is discussed.

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.