Organization of the phosphoinositide cycle. Assessment of inositol transferase activity in purified plasma membranes

The interface between phosphatidylinositol transfer protein function and phosphoinositide signaling in higher eukaryotes

Phosphoinositides are key regulators of a large number of diverse cellular processes that include membrane trafficking, plasma membrane receptor signaling, cell proliferation, and transcription. How a small number of chemically distinct phosphoinositide signals are functionally amplified to exert specific control over such a diverse set of biological outcomes remains incompletely understood. To this end, a novel mechanism is now taking shape, and it involves phosphatidylinositol (PtdIns) transfer proteins (PITPs). The concept that PITPs exert instructive regulation of PtdIns 4-OH kinase activities and thereby channel phosphoinositide production to specific biological outcomes, identifies PITPs as central factors in the diversification of phosphoinositide signaling. There are two evolutionarily distinct families of PITPs: the Sec14-like and the StAR-related lipid transfer domain (START)-like families. Of these two families, the START-like PITPs are the least understood. Herein, we review recent insights into the biochemical, cellular, and physiological function of both PITP families with greater emphasis on the START-like PITPs, and we discuss the underlying mechanisms through which these proteins regulate phosphoinositide signaling and how these actions translate to human health and disease.

Subcellular localization of phosphatidylinositol synthesis

It is well-established that the endoplasmic reticulum is the major site of phosphatidylinositol (PtdIns) synthesis. The PtdIns synthetic ability of other organelles, such as plasma membrane and nucleus, remains controversial. In the present study, we re-examine this question by comparing PtdIns synthesis in isolated cytoplasts (enucleated cells) with that in corresponding karyoplasts (nuclei surrounded by plasma membrane but lacking most cytoplasmic components). We report that cytoplasts are competent to carry out both basal and stimulated PtdIns synthesis as well as polyphosphoinositide hydrolysis, while karyoplasts can neither synthesize PtdIns nor hydrolyze phosphoinositides in response to agonists. The karyoplasts are, however, capable of synthesizing phosphatidylcholine (PtdCho), as previously reported. From these data, we conclude that PtdIns synthesis is limited to cytoplasmic components, and cannot be sustained by either plasma membrane or nucleus under conditions that permit robust PtdCho synthesis.

Regulation of mammalian cell membrane biosynthesis

This review explores current information on the interrelationship between phospholipid biochemistry and cell biology. Phosphatidylcholine is the most abundant phospholipid and it biosynthesis has been studied extensively. The choline cytidylyltransferase regulates phosphatidylcholine production, and recent advances in our understanding of the mechanisms that govern cytidylyltransferase include the discovery of multiple isoforms and a more complete understanding of the lipid regulation of enzyme activity. Similarities between phosphatidylcholine formation and the phosphatidylethanolamine and phosphatidylinositol biosynthetic pathways are discussed, together with current insight into control mechanisms. Membrane phospholipid doubling during cell cycle progression is a function of periodic biosynthesis and degradation. Membrane homeostasis is maintained by a phospholipase A-mediated degradation of excess phospholipid, whereas insufficient phosphatidylcholine triggers apoptosis in cells.

Resynthesis of phosphatidylinositol in permeabilized neutrophils following phospholipase Cbeta activation: transport of the intermediate, phosphatidic acid, from the plasma membrane to the endoplasmic reticulum for phosphatidylinositol resynthesis is not dependent on soluble lipid carriers or vesicular transport

Receptor-mediated phospholipase C (PLC) hydrolysis of phosphoinositides is accompanied by the resynthesis of phosphatidylinositol (PI). Hydrolysis of phosphoinositides occurs at the plasma membrane, and the resulting diacylglycerol (DG) is converted into phosphatidate (PA). Two enzymes located at the endoplasmic reticulum (ER) function sequentially to convert PA back into PI. We have established an assay whereby the resynthesis of PI could be followed in permeabilized cells. In the presence of [gamma-32P]ATP, DG generated by PLC activation accumulates label when converted into PA. The 32P-labelled PA is subsequently converted into labelled PI. The formation of labelled PI reports the arrival of labelled PA from the plasma membrane to the ER. Cytosol-depleted, permeabilized human neutrophils are capable of PI resynthesis following stimulation of PLCbeta (in the presence of phosphatidylinositol-transfer protein), provided that CTP and inositol are also present. We also found that wortmannin, an inhibitor of endocytosis, or cooling the cells to 15 degrees C did not stop PI resynthesis. We conclude that PI resynthesis is dependent neither on vesicular transport mechanisms nor on freely diffusible, soluble transport proteins. Phosphatidylcholine-derived PA generated by the ADP-ribosylation-factor-stimulated phospholipase D pathway was found to accumulate label, reflecting the rapid cycling of PA to DG, and back. This labelled PA was not converted into PI. We conclude that PA derived from the PLC pathway is selected for PI resynthesis, and its transfer to the ER could be membrane-protein-mediated at sites of close membrane contact.

Evidence for a model of integrated inositol phospholipid pools implies an essential role for lipid transport in the maintenance of receptor-mediated phospholipase C activity in 1321N1 cells

The compartmentation of inositol phospholipids was examined by using a combination of radiolabelling approaches in intact and permeabilized 1321N1 astrocytoma cells. A 'chase' protocol was developed with whole cells in which phosphoinositide (PI) pools were labelled to steady state with [3H]inositol and the cellular [3H]inositol pool was then diluted selectively with non-radioactive inositol. In these cells muscarinic-receptor-stimulated phospholipase C (PLC) hydrolysed [3H]PI at approx. 1-2%/min. However, after the chase procedure the relative specific radioactivity of [3H]Ins(1,3,4)P3, a rapidly metabolized and sensitive marker of PLC activity, decreased only after more than 5 min and over a time course similar to that during which the labelling of each [3H]PtdIns, [3H]PtdInsP and [3H]PtdInsP2 declined by at least 50%. These results demonstrate a large receptor-responsive [3H]PI pool that is accessed by stimulated PLC without apparent metabolic compartmentation, despite its probable distribution between different membrane fractions. Support for this was obtained in intact cells by using an acute [3H]inositol labelling method in which increases in the specific radioactivity of [3H]inositol phosphates stimulated by carbachol occurred only in parallel with similar increases in the labelling of the bulk of cellular [3H]PI. In [3H]inositol-prelabelled cells permeabilized to deplete cytosolic proteins, carbachol and guanosine 5'-[gamma-thio]triphosphate stimulated the endogenous PLC to degrade only approx. 5% of [3H]PI. This was increased to approx. 30% in the presence of exogenous PtdIns transfer protein, which, at a concentration approx. 5-10% of that in 1321N1 cell cytosol, was sufficient to support PLC activity comparable with that observed in response to carbachol in whole cells. These and earlier results in 1321N1 cells suggest a model of integrated PI pools involving an obligatory role for lipid transport. Given the multifunctional capacity of PI in cellular signalling mechanisms, this model has important implications, particularly for the hypothesis that the ability of Li+ ions to influence these selectively might account for its therapeutic actions.

The role of CDP-diacylglycerol synthetase and phosphatidylinositol synthase activity levels in the regulation of cellular phosphatidylinositol content

The regulation of phosphatidylinositol synthesis was examined by cloning and expressing in COS-7 cells the human cDNAs encoding the two enzymes in the biosynthetic pathway. Human CDP-diacylglycerol synthetase (cds1) and phosphatidylinositol synthase (pis1) clones were identified in the human expressed sequence-tagged (EST) data base, and full-length cDNAs were obtained by library screening. The cds1 cDNA did not possess a recognizable mitochondrial import signal, and the activity of the expressed Cds1 protein was stimulated by nucleoside triphosphates in vitro, indicating that cds1 did not encode the mitochondrial-specific isozyme. There were two mRNA species (3.9 and 5.6 kilobases) detected on Northern blots hybridized with the cds1 probe that were expressed at distinctly different levels in various human tissues. Consistent with the presence of the two mRNAs, a cDNA predicted to encode a second human CDP-diacylglycerol synthetase (cds2) was also uncovered in the EST data base. In contrast to the two cds mRNAs, a single, 2.1-kilobase pis1 mRNA was uniformly expressed in all human tissues examined. Expression of the pis1 gene led to the overproduction of both phosphatidylinositol synthase and phosphatidylinositol:inositol exchange reactions, indicating that the Pis1 polypeptide catalyzed both of these activities. Phosphatase treatment of cell extracts abolished the CMP-independent phosphatidylinositol:inositol exchange reaction, and exchange activity was completely restored by the addition of CMP. Overexpression of cds1 or pis1 alone or in combination did not enhance the rate of phosphatidylinositol biosynthesis. Also, overexpression did not result in a significant proportional increase in the cellular levels of CDP-diacylglycerol or phosphatidylinositol. These data illustrate that the levels of Cds1 and Pis1 protein expression are not critical determinants of cellular PtdIns content and argue against a determining role for the activity of either of these enzymes in the regulation of PtdIns biosynthesis.

Organization of the receptor-mediated phosphoinositide cycle: relationship between receptor occupancy and accession of phosphatidylinositol

We have previously reported the existence of separate hormone-responsive and -unresponsive pools of inositol phospholipids in WRK-1 cells. In order to further explore this concept, we have performed experiments to examine the relationship between the plasma membrane receptor and the pool of phosphatidylinositol (Ptdlns) that is metabolized in response to hormonal stimulation. The results support the following conclusions. 1) The amount of Ptdlns metabolized in WRK-1 cells in response to vasopressin is proportional to the number of receptors occupied; neither prolonged activation with nor readdition of submaximal concentration of vasopressin induced the same degree of Ptdlns metabolism as maximal concentration of vasopressin. 2) Dissociation of cytoskeletal structures by incubation with cytochalasin D did not alter the amount of Ptdlns accessed during hormonal stimulation. 3) Accession of Ptdlns from internal membranes does not depend on internalization and recycling of the receptor; cells incubated in potassium-free medium failed to internalize receptor-ligand complexes, yet they accessed the same amount of Ptdlns in response to vasopressin as did control cells. 4) Golgi-mediated phosphatidylinositol transport is not involved in hormone-stimulated phosphoinositide turnover, since brefeldin A, which interferes with Golgi-mediated transport processes, had no effect on the amount of Ptdlns accessed during vasopressin stimulation. 5) Phosphoinositide breakdown and compensatory resynthesis is not a closed process; newly synthesized Ptdlns is not preferentially localized to a hormone-responsive pool but is generally redistributed between responsive and unresponsive pools.

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.

Homologous and heterologous regulation of receptor-stimulated phosphoinositide hydrolysis

Signal transduction at a diverse range of pharmacologically distinct receptors is effected by the enhanced turnover of inositol phospholipids, with the attendant formation of inositol 1,4,5-trisphosphate and diacylglycerol. Although considerable progress has been made in recent years towards the identification and characterization of the individual components of this pathway, much less is known of mechanisms that may underlie its regulation. In this review, evidence is presented for the potential regulation of inositol lipid turnover at the level of receptor, phosphoinositide-specific phospholipase C and substrate availability in response to either homologous or heterologous stimuli. Available data indicate that the extent of receptor-stimulated inositol lipid hydrolysis is regulated by multiple mechanisms that operate at different levels of the signal transduction pathway.

Identification of rat liver phosphatidylinositol synthase as a 21 kDa protein

Substantial purification of rat liver phosphatidylinositol (PtdIns) synthase has been achieved by a combination of Hecameg extraction, heat treatment, affinity chromatography and chromatography on PBE-94. The activity chromatographs as a single peak which has an apparent molecular mass between 150 and 200 kDa on Sepharose 4B. When analysed by SDS/PAGE, two major bands are seen. The enzyme activity is correlated with a protein band of 21 kDa. A second band, at 51 kDa, is eluted from a PBE-94 column slightly ahead of the activity. Manganese is an absolute requirement for stabilization of activity in the presence of detergent. The effect of manganese is optimal at 0.5 mM; magnesium at a concentration of 10 mM is only minimally effective. Substrate Kms are 1.3 mM and 9.5 microM for inositol and CDP-diacylglycerol respectively. The activity eluting from the PBE-94 column is purified 5000-fold over the post-mitochondrial supernatant.

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.