The phosphatidylinositol transfer protein in 3T3 mouse fibroblast cells is associated with the Golgi system

A phosphatidylinositol transfer protein α-dependent survival factor protects cultured primary neurons against serum deprivation-induced cell death

Selective neuronal loss is a prominent feature in both acute and chronic neurological disorders. Recently, a link between neurodegeneration and a deficiency in the lipid transport protein phosphatidylinositol transfer protein alpha (PI-TPalpha) has been demonstrated. In this context it may be of importance that fibroblasts overexpressing PI-TPalpha are known to produce and secrete bioactive survival factors that protect fibroblasts against UV-induced apoptosis. In the present study it was investigated whether the conditioned medium of cells overexpressing PI-TPalpha (CMalpha) has neuroprotective effects on primary neurons in culture. We show that CMalpha is capable of protecting primary, spinal cord-derived motor neurons from serum deprivation-induced cell death. Since the conditioned medium of wild-type cells was much less effective, we infer that the neuroprotective effect of CMalpha is linked (in part) to the PI-TPalpha-dependent production of arachidonic acid metabolites. The neuroprotective activity of CMalpha is partly inhibited by suramin, a broad-spectrum antagonist of G-protein coupled receptors. Western blot analysis shows that brain cortex and spinal cord express relatively high levels of PI-TPalpha, suggesting that the survival factor may be produced in neuronal tissue. We propose that the bioactive survival factor is implicated in neuronal survival. If so, PI-TPalpha could be a promising target to be evaluated in studies on the prevention and treatment of neurological disorders.

Phosphatidylinositol transfer protein α regulates growth and apoptosis of NIH3T3 cells

Mouse fibroblast cells overexpressing phosphatidylinositol transfer protein alpha [PI-TPalpha; sense PI-TPalpha (SPIalpha) cells] show a significantly increased rate of proliferation and an extreme resistance toward ultraviolet- or tumor necrosis factor-alpha-induced apoptosis. The conditioned medium (CM) from SPIalpha cells or the neutral lipid extract from CM stimulated the proliferation of quiescent wild-type NIH3T3 cells. CM was also highly effective in increasing resistance toward induced apoptosis in both wild-type cells and the highly apoptosis-sensitive SPIbeta cells (i.e., wild-type cells overexpressing PI-TPbeta). CM from SPIalpha cells grown in the presence of NS398, a specific cyclooxygenase-2 (COX-2) inhibitor, expressed a diminished mitogenic and antiapoptotic activity. This strongly suggests that at least one of the bioactive factor(s) is an eicosanoid. In accordance, SPIalpha cells express enhanced levels of COX-1 and COX-2. The antiapoptotic activity of CM from SPIalpha cells tested on SPIbeta cells was inhibited by approximately 50% by pertussis toxin and suramin as well as by SR141716A, a specific antagonist of the cannabinoid 1 receptor. These inhibitors had virtually no effect on the COX-2-independent antiapoptotic activity of CM from SPIalpha cells. The latter results imply that PI-TPalpha mediates the production of a COX-2-dependent eicosanoid that activates a G-protein-coupled receptor, most probably a cannabinoid 1-like receptor.

Overexpression of phosphatidylinositol transfer protein β in NIH3T3 cells has a stimulatory effect on sphingomyelin synthesis and apoptosis

Phosphatidylinositol transfer proteins (PI-TPs) consist of two isoforms (PI-TPalpha and PI-TPbeta), which differ in phospholipid transfer properties and intracellular localization. Both PI-TP isoforms are substrates for protein kinase C and contain a minor phosphorylation site (Ser166 in PI-TPalpha; Ser165 in PI-TPbeta). Only PI-TPbeta contains a major phosphorylation site at Ser262, which must be phosphorylated for PI-TPbeta to be associated with the Golgi. The PI-TP isoforms are completely conserved between mammals. Although their function is still not clear, their importance follows from knock-out studies, showing that mice lacking PI-TPalpha die soon after birth and that embryonic stems cells lacking PI-TPbeta cannot be generated [Mol. Biol. Cell 13 (2002) 739]. We determined the levels of the PI-TP isoforms in various mouse tissues by immunoblotting. PI-TPalpha is present in all tissues investigated, with highest levels in brain (167 ng/100 microg total protein). The levels of PI-TPbeta are 50-100 times lower than those of PI-TPalpha, with relatively high levels found in liver and brain (1.2 and 1.8 ng/100 microg of total protein, respectively). In contrast to NIH3T3 cells overexpressing PI-TPalpha, cells overexpressing PI-TPbeta (SPIbeta cells) were able to maintain steady-state levels of sphingomyelin in plasma membrane under conditions where this lipid is degraded by exogenous sphingomyelinase. This process of rapid sphingomyelin replenishment is dependent on PI-TPbeta being associated with the Golgi as cells overexpressing a mutant PI-TPbeta in which the major phosphorylation site is replaced (PI-TPbeta(S262A) behave as wild-type NIH3T3 cells. Since the SPIbeta cells display a decreased growth rate (35 h as compared to 21 h for wtNIH3T3 cells), we have investigated the sensitivity of these cells towards UV-induced apoptosis. We have found that the SPIbeta cells, but not the cells overexpressing PI-TPbeta(S262A), are very sensitive. We are currently investigating whether a relationship exists between PI-TPbeta being involved in maintaining plasma membrane sphingomyelin levels and the enhanced sensitivity towards apoptosis.

Alteration of phosphatidylinositol transfer protein during global brain ischemia-reperfusion in gerbils

Phosphatidylinositol transfer proteins (PI-TPs) are responsible for the transport of phosphatidylinositol and other phospholipids. Moreover, these proteins are involved in vesicle transport and in the function of cytoskeleton. Our previous data indicated that brain ischemia affected phosphoinositides metabolism and the level of lipid derived second messengers. In this study, the effect of ischemia-reperfusion injury on the level of PI-TPs and of the role of NMDA receptor stimulation on the alteration of these proteins was investigated during reperfusion after 5 min of forebrain ischemia in gerbils. Some groups of animals were injected intraperitoneally with MK-801, an antagonist of NMDA receptor 30 min before ischemia. The levels of both PI-TP isoforms alpha+beta and separately the alpha-isoform were determined in cytosol and membrane fraction from brain cortex and hippocampus using Western blot analysis. In the cytosolic fractions, the concentration of both isoforms of PI-TP was 2 times higher when compared to the membrane fraction. In brain cortex, PI-TP alpha isoform consist about 32-44% but in hippocampus 72-82% of both isoforms (PI-TP alpha+beta) in cytosolic and membrane fraction respectively. Ischemia-reperfusion had no effect on PI-TPs in brain cortex. However, in hippocampus after 5 min ischemia and during whole reperfusion time up till 7 days the level of PI-TP alpha+beta and PI-TP alpha was significantly higher by about 20-55%, respectively when compared to control. MK-801 eliminated ischemia-reperfusion evoked alteration of PI-TPs. To confirm the role of NMDA receptor in PI-TP alteration additional experiments were carried out on PC-12 cells in culture. The results indicated that activation of NMDA receptor enhances significantly the level of PI-TP alpha. The competitive antagonist of NMDA receptor inhibited this effect. These results indicated that activation of NMDA receptor is connected with PI-TPs alteration and plays an important role in modulation of PI-TPs during ischemia-reperfusion injury that may have important physiopathological consequence.

Clofibrate-induced relocation of phosphatidylcholine transfer protein to mitochondria in endothelial cells

The phosphatidylcholine transfer protein (PC-TP) is a specific transporter of phosphatidylcholine (PC) between membranes. To get more insight into its physiological function, we have studied the localization of PC-TP by microinjection of fluorescently labeled PC-TP in foetal bovine heart endothelial (FBHE) cells and by expression of an enhanced yellow fluorescent protein-PC-TP fusion protein in FBHE cells, human umbilical vein endothelial cells, and HepG2 cells. Analysis by confocal laser scanning microscopy showed that PC-TP was evenly distributed throughout the cytosol with an apparently elevated level in nuclei. By measuring the fluorescence recovery after bleaching it was established that PC-TP is highly mobile throughout the cell, with its transport into the nucleus being hindered by the nuclear envelope. Given the proposed function of PC-TP in lipid metabolism, we have tested a number of compounds (phorbol ester, bombesin, A23187, thrombin, dibutyryl cyclic AMP, oleate, clofibrate, platelet-derived growth factor, epidermal growth factor, and hydrogen peroxide) for their ability to affect intracellular PC-TP distribution. Only clofibrate (100 microM) was found to have an effect, with PC-TP moving to mitochondria within 5 min of stimulation. This relocation did not occur with PC-TP(S110A), lacking the putative protein kinase C (PKC)-dependent phosphorylation site, and was restricted to the primary endothelial cells. Relocation did not occur in HepG2 cells, possibly due to the fact that clofibrate does not induce PKC activation in these cells.

The binding of phosphatidylcholine to the phosphatidylcholine transfer protein: affinity and role in folding

Bovine liver phosphatidylcholine transfer protein (PC-TP) has been expressed in Escherichia coli and purified to homogeneity from the cytosol fraction at a yield of 0.45 mg PC-TP per 10 mg total cytosolic protein. In addition, active PC-TP was obtained from inclusion bodies. An essential factor in the activation of PC-TP was phosphatidylcholine (PC) present in the folding buffer. PC-TP from the cytosol contains phosphatidylethanolamine (PE) and phosphatidylglycerol (PG) with a preference for the di-monounsaturated species over the saturated species as determined by fast atom bombardment mass spectrometry (FAB-MS). By incubation with microsomal membranes the endogenous PE and PG were replaced by PC. Relative to the microsomal PC species composition, PC-TP bound preferentially C16:0/C20:4-PC and C16:0/C18:2-PC (twofold enriched) whereas the major microsomal species C18:0/C18:1-PC and C18:0/C18:2-PC were distinctly less bound. PC-TP is structurally homologous to the lipid-binding domain of the steroidogenic acute regulatory protein (Nat. Struct. Biol. 7 (2000) 408). Replacement of Lys(55) present in one of the beta-strands forming the lipid-binding site, with an isoleucine residue yielded an inactive protein. This suggests that Lys(55) be involved in the binding of the PC molecule.

Overexpression of phosphatidylinositol transfer protein alpha in NIH3T3 cells activates a phospholipase A

In order to investigate the cellular function of the mammalian phosphatidylinositol transfer protein alpha (PI-TPalpha), NIH3T3 fibroblast cells were transfected with the cDNA encoding mouse PI-TPalpha. Two stable cell lines, i.e. SPI6 and SPI8, were isolated, which showed a 2- and 3-fold increase, respectively, in the level of PI-TPalpha. Overexpression of PI-TPalpha resulted in a decrease in the duration of the cell cycle from 21 h for the wild type (nontransfected) NIH3T3 (wtNIH3T3) cells and mock-transfected cells to 13-14 h for SPI6 and SPI8 cells. Analysis of exponentially growing cultures by fluorescence-activated cell sorting showed that a shorter G(1) phase is mainly responsible for this decrease. The saturation density of the cells increased from 0.20 x 10(5) cells/cm(2) for wtNIH3T3 cells to 0.53 x 10(5) cells/cm(2) for SPI6 and SPI8 cells. However, anchorage-dependent growth was maintained as shown by the inability of the cells to grow in soft agar. Upon equilibrium labeling of the cells with myo-[(3)H] inositol, the relative incorporation of radioactivity in the total inositol phosphate fraction was 2-3-fold increased in SPI6 and SPI8 cells when compared with wtNIH3T3 cells. A detailed analysis of the inositol metabolites showed increased levels of glycerophosphoinositol, Ins(1)P, Ins(2)P, and lysophosphatidylinositol (lyso-PtdIns) in SPI8 cells, whereas the levels of phosphatidylinositol (PtdIns) and phosphatidylinositol 4, 5-bisphosphate were the same as those in control cells. The addition of PI-TPalpha to a total lysate of myo-[(3)H]inositol-labeled wtNIH3T3 cells stimulated the formation of lyso-PtdIns. The addition of Ca(2+) further increased this formation. Based on these observations, we propose that PI-TPalpha is involved in the production of lyso-PtdIns by activating a phospholipase A acting on PtdIns. The increased level of lyso-PtdIns that is produced in this reaction could be responsible for the increased growth rate and the partial loss of contact inhibition in SPI8 and SPI6 cells. The addition of growth factors (platelet-derived growth factor, bombesin) to these overexpressers did not activate the phospholipase C-dependent degradation of phosphatidylinositol 4,5-bisphosphate.

Mice without phosphatidylcholine transfer protein have no defects in the secretion of phosphatidylcholine into bile or into lung airspaces

Phosphatidylcholine transfer protein (Pc-tp) is a highly specific carrier of phosphatidylcholine (PC) without known function. Proposed functions include the supply of PC required for secretion into bile or lung air space (surfactant) and the facilitation of enzymatic reactions involving PC synthesis or breakdown. To test these functions, we generated knock-out mice unable to make Pc-tp. Remarkably, these mice are normal and have no defect in any of the postulated Pc-tp functions analyzed. The lipid content and composition of the bile, as well as lung surfactant secretion and composition, of Pc-tp (-/-) mice, is normal. The lack of a Pc-tp contribution to biliary lipid secretion is in agreement with our finding that Pc-tp is down-regulated in adult mouse liver: whereas Pc-tp is abundant in the liver of mouse pups, Pc-tp levels decrease > 10-fold around 2 wk after birth, when bile formation starts. In adult mice, Pc-tp levels are high only in epididymis, testis, kidney, and bone marrow-derived mast cells. Absence of Pc-tp in bone marrow-derived mast cells does not affect their lipid composition or PC synthesis and degradation. We discuss how PC might reach the canalicular membrane of the hepatocyte for secretion into the bile, if not by Pc-tp.

Evidence that mammalian phosphatidylinositol transfer protein regulates phosphatidylcholine metabolism

Phosphatidylinositol transfer proteins (PITPs) and their yeast counterpart (SEC14p) possess the ability to bind phosphatidylinositol (PtdIns) and transfer it between membranes in vitro. However, the biochemical function of these proteins in vivo is unclear. In the present study, the physiological role of PITP was investigated by determining the biochemical consequences of lowering the cellular content of this protein. WRK-1 rat mammary tumour cells were transfected with a plasmid containing a full-length rat PITPalpha cDNA inserted in the antisense orientation and the resultant cell clones were analysed. Three clones expressing antisense mRNA for PITPalpha were compared with three clones transfected with the expression vector lacking the insert. The three antisense clones had an average of 25% less PITPalpha protein than control clones. Two of the three antisense clones also exhibited a decreased rate of growth. All three antisense clones exhibited a significant decrease in the incorporation of labelled precursors into PtdCho during a 90-min incubation period. Under the same conditions, however, there was no change in precursor incorporation into PtdIns. Further experimentation indicated that the decrease in precursor incorporation seen in antisense clones was not due to an increased rate of turnover. When choline metabolism was analysed more extensively in one control (2-5) and one antisense (4-B) clone using equilibrium-labelling conditions (48 h of incubation), the following were observed: (1) the decrease in radioactive labelling of PtdCho seen in short-term experiments was also observed in long-term experiments, suggesting that the total amount of PtdCho was lower in antisense-transfected clones (this was confirmed by mass measurements); (2) a similar decrease was seen in cellular sphingomyelin, lysoPtdCho and glycerophosphorylcholine; (3) an average two-fold increase in cellular phosphorylcholine was observed in the antisense-transfected clone; (4) cellular choline was, on average, decreased; and (5) cellular CDPcholine was not significantly altered.

Phosphatidylinositol transfer proteins: a requirement in signal transduction and vesicle traffic

Phosphatidylinositol transfer protein (PITP) was originally identified and named because of its ability to transport phosphatidylinositol through the aqueous phase from one membrane compartment to another. Recent data, however, indicate unanticipated roles for PITP in the coupling of PIP2 synthesis to signal transduction reactions and to membrane traffic in mammalian cells. PITP was recently purified on the basis of its ability to restore cellular functions in permeabilized cells depleted of cytosolic proteins. These functions include cell-surface receptor-regulated hydrolysis of PIP2 by phospholipases C beta- and gamma-isozymes, regulated release of secretory granules, and the budding of constitutive secretory vesicles and immature secretory granules from the trans-Golgi network. In the yeast Saccharomyces cerevisiae, a PITP was identified from a mutant strain with a defect in the secretory pathway (SEC14) and therefore required for cell viability; in Yarrowia lipolytica, PITP is required for differentiation from a yeast to a mycelial growth form. We are just beginning to unravel the intriguing mechanisms by which PITP/SEC14 may accomplish its function in eukaryotic cells in signal transduction and membrane trafficking.

Phosphatidylinositol transfer proteins: requirements in phospholipase C signaling and in regulated exocytosis

Phosphatidylinositol transfer proteins (PITP) are abundant cytosolic proteins originally identified because of their ability to act in vitro as specific transporters of phosphatidylinositol or phosphatidylcholine between membranes. However, the cellular function of mammalian PITP has remained enigmatic till recently. Due to the development of reconstitution assays in cytosol-depleted cells, PITP was found to be an essential component for phospholipase C-mediated hydrolysis of PIP2 and for regulated exocytosis. The exact mechanism how PITP exerts its effects is not known but the PI binding/transfer activity of PITP can partly explain its cellular function. PITP would enable the local synthesis of PIP2 by delivering PI to specialized signaling sites.

Phospholipid transfer proteins revisited

Phosphatidylinositol transfer protein (PI-TP) and the non-specific lipid transfer protein (nsL-TP) (identical with sterol carrier protein 2) belong to the large and diverse family of intracellular lipid-binding proteins. Although these two proteins may express a comparable phospholipid transfer activity in vitro, recent studies in yeast and mammalian cells have indicated that they serve completely different functions. PI-TP (identical with yeast SEC14p) plays an important role in vesicle flow both in the budding reaction from the trans-Golgi network and in the fusion reaction with the plasma membrane. In yeast, vesicle budding is linked to PI-TP regulating Golgi phosphatidylcholine (PC) biosynthesis with the apparent purpose of maintaining an optimal PI/PC ratio of the Golgi complex. In mammalian cells, vesicle flow appears to be dependent on PI-TP stimulating phosphatidylinositol 4,5-bisphosphate (PIP2) synthesis. This latter process may also be linked to the ability of PI-TP to reconstitute the receptor-controlled PIP2-specific phospholipase C activity. The nsL-TP is a peroxisomal protein which, by its ability to bind fatty acyl-CoAs, is most likely involved in the beta-oxidation of fatty acids in this organelle. This protein constitutes the N-terminus of the 58 kDa protein which is one of the peroxisomal 3-oxo-acyl-CoA thiolases. Further studies on these and other known phospholipid transfer proteins are bound to reveal new insights in their important role as mediators between lipid metabolism and cell functions.

The lipid transfer activity of phosphatidylinositol transfer protein is sufficient to account for enhanced phospholipase C activity in turkey erythrocyte ghosts

BACKGROUND

The minor membrane phospholipid phosphatidylinositol 4, 5-bisphosphate (PIP2) has been implicated in the control of a number of cellular processes. Efficient synthesis of this lipid from phosphatidylinositol has been proposed to require the presence of a phosphatidylinositol/phosphatidylcholine transfer protein (PITP), which transfers phosphatidylinositol and phosphatidylcholine between membranes, but the mechanism by which PITP exerts its effects is currently unknown. The simplest hypothesis is that PITP replenishes agonist-sensitive pools of inositol lipids by transferring phosphatidylinositol from its site of synthesis to sites of consumption. Recent cellular studies, however, led to the proposal that PITP may play a more active role as a co-factor which stimulates the activity of phosphoinositide kinases and phospholipase C (PLC) by presenting protein-bound lipid substrates to these enzymes. We have exploited turkey erythrocyte membranes as a model system in which it has proved possible to distinguish between the above hypotheses of PITP function.

RESULTS

In turkey erythrocyte ghosts, agonist-stimulated PIP2 hydrolysis is initially rapid, but it declines and reaches a plateau when approximately 15% of the phosphatidylinositol has been consumed. PITP did not affect the initial rate of PIP2 hydrolysis, but greatly prolonged the linear phase of PLC activity until at least 70% of phosphatidylinositol was consumed. PITP did not enhance the initial rate of phosphatidylinositol 4-kinase activity but did increase the unstimulated steady-state levels of both phosphatidylinositol 4-phosphate and PIP2 by a catalytic mechanism, because the amount of polyphosphoinositides synthesized greatly exceeded the molar amount of PITP in the assay. Furthermore, when polyphosphoinositide synthesis was allowed to proceed in the presence of exogenous PITP, after washing ghosts to remove PITP before activation of PLC, enhanced inositol phosphate production was observed, whether or not PITP was present in the subsequent PLC assay.

CONCLUSION

PITP acts by catalytically transferring phosphatidylinositol down a chemical gradient which is created as a result of the depletion of phosphatidylinositol at its site of use by the concerted actions of the phosphoinositide kinases and PLC. PITP is therefore not a co-factor for the phosphoinositide-metabolizing enzymes present in turkey erythrocyte ghosts.

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.

The yeast and mammalian isoforms of phosphatidylinositol transfer protein can all restore phospholipase C-mediated inositol lipid signaling in cytosol-depleted RBL-2H3 and HL-60 cells

The mammalian phosphatidylinositol transfer proteins (PITP) and the yeast Saccharomyces cerevisiae PITP (SEC14p) that show no sequence homology both catalyze exchange of phosphatidylinositol (PI) between membranes compartments in vitro. In HL-60 cells where the cytosolic proteins are depleted by permeabilization, exogenously added PITPalpha is required to restore G protein-mediated phospholipase Cbeta (PLCbeta) signaling. Recently, a second mammalian PITPbeta form has been described that shows 77% identity to rat PITPalpha. We have examined the ability of the two mammalian PITPs and SEC14p to restore PLC-mediated signaling in cytosol-depleted HL-60 and RBL-2H3 cells. Both PITPalpha and PITPbeta isoforms as well as SEC14p restore G protein-mediated PLCbeta signaling with a similar potency. In RBL-2H3 cells, crosslinking of the IgE receptor by antigen stimulates inositol lipid hydrolysis by tyrosine phosphorylation of PLCgamma1. Permeabilization of RBL cells leads to loss of PLCgamma1 as well as PITP into the extracellular medium and this coincides with loss of antigen-stimulated lipid hydrolysis. Both PLCgamma1 and PITP were required to restore inositol lipid signaling. We conclude that (i) because the PI binding/transfer activities of PITP/SEC14p is the common feature shared by all three transfer proteins, it must be the relevant activity that determines their abilities to restore inositol lipid-mediated signaling and (ii) PITP is a general requirement for inositol lipid hydrolysis regardless of how and which isoform of PLC is activated by the appropriate agonist.

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.

A role for phosphatidylinositol transfer protein in secretory vesicle formation

Vesicular traffic in eukaryotic cells is characterized by two steps of membrane rearrangement: the formation of vesicles from donor membranes and their fusion with acceptor membranes. With respect to vesicle formation, several of the cytosolic proteins implicated in budding and fission have been identified. A feature common to all these proteins is that their targets, when known, are other proteins rather than lipids. Here we report, using a previously established cell-free system derived from a neuroendocrine cell line, the purification of cytosolic factors that stimulate the formation of constitutive secretory vesicles and immature secretory granules from the trans-Golgi network. One such factor, referred to as CAST1, was identified as the alpha and beta isoforms of the mammalian phosphatidylinositol transfer protein (PtdIns-TP) (refs 3-5). The yeast PtdIns-TP, SEC14p (ref. 6), which has no sequence homology to mammalian PtdIns-TP (refs 7,8), was able to substitute for the mammalian PtdIns-TP in secretory vesicle formation. Our results suggest a highly conserved role for phosphoinositides in vesicle formation.

An isoform of the phosphatidylinositol-transfer protein transfers sphingomyelin and is associated with the Golgi system

An isoform of the phosphatidylinositol-transfer protein (PI-TP) was identified in the cytosol fraction of bovine brain. This protein, designated PI-TP beta, has an apparent molecular mass of 36 kDa and an isoelectric point of 5.4. The N-terminal amino acid sequence (21 residues) is 90% similar to that of bovine brain PI-TP, henceforth designated PI-TP alpha (molecular mass 35 kDa and pI 5.5). As observed for PI-TP alpha, PI-TP beta has a distinct preference for phosphatidylinositol over phosphatidylcholine. In addition, it expresses a high transfer activity towards sphingomyelin. PI-TP alpha lacks this activity completely. By indirect immunofluorescence we demonstrated that, in Swiss mouse 3T3 fibroblasts, PI-TP beta is preferentially associated with the Golgi system whereas PI-TP alpha is predominantly present in the cytoplasm and the nucleus. In cytosol-depleted HL60 cells, both PI-TP alpha and PI-TP beta were equally effective at reconstituting guanosine 5'-[gamma-thio]triphosphate-mediated phospholipase C beta activity.

Phosphatidylinositol transfer protein dictates the rate of inositol trisphosphate production by promoting the synthesis of PIP2

BACKGROUND

Phosphatidylinositol transfer protein (PI-TP), which has the ability to transfer phosphatidylinositol (PI) from one membrane compartment to another, is required in the inositol lipid signalling pathway through phospholipase C-beta (PLC-beta) that is regulated by GTP-binding protein(s) in response to extracellular signals. Here, we test the hypothesis that the principal role of PI-TP is to couple sites of lipid hydrolysis to sites of synthesis, and so to replenish depleted substrate for PLC-beta.

RESULTS

We have designed an experimental protocol that takes advantage of the different rates of release of endogenous PI-TP and PLC-beta from HL60 cells permeabilized with streptolysin O. We have examined the kinetics of stimulated inositol lipid hydrolysis in cells depleted of PI-TP, but not of endogenous PLC-beta, in the presence and absence of exogenous PI-TP. Linear time-courses were observed in the absence of any added protein, and the rate was accelerated by PI-TP using either guanosine 5'[gamma-thio]-triphosphate (GTP gamma S) or the receptor-directed agonist fMetLeuPhe as activators. In addition, depletion from the cells of both PI-TP and PLC-beta isoforms by extended permeabilization (40 minutes) allowed us to control the levels of PLC-beta present in the cells. Once again, PI-TP increased the rates of reactions. To identify whether the role of PI-TP was to make available the substrate phosphatidylinositol bisphosphate (PIP2) for the PLC, we examined the synthesis of PIP2 in cells depleted of PI-TP. We found that PI-TP was essential for the synthesis of PIP2.

CONCLUSIONS

The predicted function of PI-TP in inositol lipid signalling is the provision of substrate for PLC-beta from intracellular sites where PI is synthesized. We propose that PI-TP is in fact a co-factor in inositol lipid signalling and acts by interacting with the inositol lipid kinases. We hypothesize that the preferred substrate for PLC-beta is not the lipid that is resident in the membrane but that provided through PI-TP.

A sphingomyelin-transferring protein from chicken liver. Use of pyrene-labeled phospholipid

A phospholipid transfer protein was purified from chicken liver which, in addition to phosphatidylinositol (PI) and phosphatidylcholine (PC), carries sphingomyelin (SM) between membranes. For comparison, the PI-transfer protein from chicken liver only carries PI and PC. Specificity was established by use of phospholipids that carry a pyrene-labeled acyl chain. Based on the N-terminal sequence and Western blot analysis we conclude that this protein is an isoform of the PI-transfer protein. At increasing length of the pyrene-labeled acyl chain, the isoform expresses a high activity toward SM, a low activity toward PI, and virtually no activity toward PC.

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.

Characterization of mouse phosphatidylinositol transfer protein expressed in Escherichia coli

The cDNA encoding mouse phosphatidylinositol transfer protein (PI-TP) was isolated by means of reverse transcriptase polymerase chain reaction. The nucleotide sequence of this cDNA has a high similarity (98%) with that of rat PI-TP; the predicted amino acid sequence is 99.6% identical to that of rat PI-TP. The cDNA encoding mouse PI-TP was cloned into the expression vector pET3d and the Escherichia coli strain BL21(DE3) was transformed with the resulting plasmid. After induction of the bacteria with isopropyl-beta-D-thiogalactopyranoside, PI-TP was efficiently expressed in the E. coli strain. It was estimated that 5% of the total soluble cell protein consisted of PI-TP. The recombinant mouse PI-TP was purified from the bacterial lysate in four steps: ammonium sulphate precipitation, anion-exchange chromatography, heparin-Sepharose affinity and gel filtration chromatography. Fractionation on the heparin-Sepharose affinity column yielded two forms: PI-TP Hepa1 and Hepa2. These two proteins have the same molecular mass of 35 kDa, both contain a phosphatidylglycerol molecule and both are recognized by anti-PI-TP antibody. Both recombinant proteins have an isoelectric point of 5.4 as compared to 5.5 for bovine brain PI-TP. Sequence analysis of the first 25 N-terminal amino acid residues showed that both forms are identical, except that PI-TP Hepa1 contains the initiator methionine which is lacking from PI-TP Hepa2. The two PI-TP forms have similar phospholipid-binding and transfer activity, comparable to that of bovine brain PI-TP. Both forms and bovine brain PI-TP are phosphorylated equally well in a Ca2+/phospholipid-dependent way by protein kinase C.

Phospholipid-transfer proteins and their mRNAs in developing rat lung and in alveolar type-II cells

Gene expression of non-specific lipid-transfer protein (nsL-TP; identical with sterol carrier protein 2) and phosphatidylinositol-transfer protein (PI-TP) was investigated in developing rat lung. During the late prenatal period (between days 17 and 22) there is a 7-fold increase in the level of nsL-TP and a 2-fold rise in that of PI-TP. The prenatal increases in the levels of nsL-TP and PI-TP are accompanied by parallel increases in the levels of their mRNAs, indicating pretranslational regulation. Compared with whole lung, isolated alveolar type-II cells are enriched in nsL-TP and its mRNA, but not in PI-TP and its mRNA. The observation that the levels of nsL-TP and its mRNA in rat lung show a pronounced increase in the period of accelerated surfactant formation, together with the observation that the surfactant-producing type-II cells are enriched in nsL-TP and its mRNA, suggest that nsL-TP plays a role in the metabolism of pulmonary surfactant.

An essential role for phosphatidylinositol transfer protein in phospholipase C-mediated inositol lipid signaling

Transmembrane signaling by the phospholipase C-beta (PLC-beta) pathway is known to require at least three components: the receptor, the G protein, and the PLC. Recent studies have indicated that if the cytosol is allowed to leak out of HL60 cells, then G protein-stimulated PLC activity is greatly diminished, indicating an essential role for a cytosolic component(s). We now report the complete purification of one component based on its ability to reconstitute GTP gamma S-mediated PLC activity and identify it as the phosphatidylinositol transfer protein (PI-TP). Based on the in vitro effects of PI-TP, we surmise that it is involved in transporting PI from intracellular compartments for conversion to PI bisphosphate (PIP2) prior to hydrolysis by PLC-beta 2/PLC-beta 3, the endogenous PLC isoforms present in these cells.

Phosphorylation and redistribution of the phosphatidylinositol-transfer protein in phorbol 12-myristate 13-acetate- and bombesin-stimulated Swiss mouse 3T3 fibroblasts

By immunofluorescence microscopy it was shown that the phosphatidylinositol-transfer protein (PI-TP) becomes associated with the Golgi membranes when confluent (quiescent) Swiss mouse 3T3 fibroblast cells are stimulated with phorbol 12-myristate 13-acetate (PMA) and bombesin. Dibutyryl cyclic AMP or dexamethasone had no effect on the intracellular redistribution of PI-TP. In exponentially growing cells and in serum-starved (semi-quiescent) cells, PI-TP is already associated with Golgi structures. Stimulation of semi-quiescent cells by PMA resulted in a rapid redistribution of PI-TP. A similar yet slower response was observed after stimulation with bombesin. Stimulation of semi-quiescent 3T3 cells by PMA significantly increased the phosphorylation of PI-TP, as shown by immunoprecipitation of PI-TP from pre-labelled cells. No significant increase in phosphorylation of PI-TP was observed after stimulation of these cells by bombesin. Purified PI-TP was shown to be a substrate for protein kinase C in vitro. The possibility that the phosphorylation of PI-TP after activation of protein kinase C is involved in the observed redistribution of PI-TP is discussed.