Hw Cook

Differences in the metabolism of inositol and phosphoinositides by cultured cells of neuronal and glial origin

Phosphoinositide and inositol metabolism was compared in glioma (C6), neuroblastoma (N1E-115) and neuroblastoma X glioma hybrid (NG 108-15) cells. All cell lines had similar proportions of phosphatidylinositol (PI), phosphatidylinositol 4-phosphate (PIP), and phosphatidylinositol 4,5-bisphosphate (PIP2). Neuroblastoma and hybrid cells had almost identical phospholipid and phosphoinositide compositions and similar activities for the enzymes metabolizing polyphosphoinositides (PI kinase, PIP phosphatase, PIP kinase, PIP2 phosphatase, PIP2 phosphodiesterase). Glioma cells differed by having greater proportions of ethanolamine plasmalogen and sphingomyelin, lower PIP kinase, 3-5-fold higher PIP phosphatase activity and 10-15-fold greater PIP2 phosphodiesterase activity. Higher PIP phosphatase and PIP2 diesterase activities appear to be characteristic of cells of glial origin, since similar activities were found in primary cultures of astroglia. Glioma cells also metabolize inositol differently. In pulse and pulse-chase experiments, glioma cells transported inositol into a much larger water-soluble intracellular pool and maintained a concentration gradient 30-times greater than neuroblastoma cells. Label in intracellular inositol was less than in phosphoinositides in neuroblastoma and exchanged rapidly with extracellular inositol. In glioma, labeling of intracellular inositol greatly exceeded that of phosphoinositides. As a consequence, radioactivity in prelabeled phosphoinositides could not be effectively chased from glioma cells by excess unlabeled inositol. Such differences between cells of neuronal and glial origin suggest different and possibly supportive roles for these two cell types in maintaining functions regulated through phosphoinositide-linked signalling systems in the central nervous system.

Phosphatidylcholine biosynthesis in cultured glioma cells: evidence for channeling of intermediates

The major pathway of choline (Cho) incorporation into phosphatidylcholine (PtdCho) in mammalian cells is sequential conversion of Cho to phosphocholine (PCho), cytidinediphosphate choline (CDP-Cho) and PtdCho. In intact cells, this sequence is usually demonstrated using radiolabeled Cho since PCho and CDP-Cho do not enter the cell intact. We have studied the incorporation of radiolabeled Cho, PCho and CDP-Cho into rat glioma (C6) cells following electropermeabilization. C6 cells were permeable as judged by [U-14C]sucrose and Erythrosin B uptake and more rapid incorporation of [1,2,3-3H]glycerol into cell lipids, and viable as assessed by uptake and incorporation of [methyl-3H]Cho, [1-14C]oleate and [1,2,3-3H]glycerol into complex lipids. Despite rapid incorporation of [methyl-3H]Cho into PtdCho in permeabilized cells, there was no incorporation of [methyl-14C]PCho or CDP-[methyl-14C]Cho into PtdCho. PCho (300 microM) and CDP-Cho (300 microM) failed to significantly reduce incorporation of 28 microM [methyl-3H]Cho into PtdCho. Radioactivity in PtdCho of cells prelabeled with [methyl-3H]Cho prior to permeabilization could be chased with 4 mM Cho but not with 4 mM PCho or 4 mM CDP-Cho. The water-soluble products of Cho metabolism--PCho, CDP-Cho and glycerophosphocholine--were retained at 37 degrees C in permeabilized cells compared with controls while there was uniform leakage from permeabilized cells at 4 degrees C. Hemicholinium-3, an inhibitor of high-affinity Cho transport, decreased [methyl-3H]Cho incorporation into PtdCho in permeabilized cells, as in controls, suggesting that even in permeabilized cells, Cho incorporation into PtdCho is linked to the transport system. We propose that individual steps of the cytidine pathway of PtdCho biosynthesis are functionally linked and that reaction intermediates are not freely diffusible within the cell but are channeled to PtdCho biosynthesis.

Phosphoinositide metabolism in cultured glioma and neuroblastoma cells: subcellular distribution of enzymes indicate incomplete turnover at the plasma membrane.

The hypothesis that the small portion of cellular phosphoinositide participating in signal transduction might be preferentially recycled within the plasma membrane was tested in rat glioma (C6) and murine neuroblastoma (N1E-115) cells. Percoll density gradient centrifugation was used to isolate a purified plasma membrane fraction and the subcellular distribution of all enzymes mediating phosphoinositide turnover was assessed. A small but significant proportion of PtdInsP2-specific phosphodiesterase was located in the plasma membrane but only two of the five enzymes required to replace PtdInsP2 (diacylglycerol kinase and PtdInsP kinase) also were present. CTP:phosphatidate cytidylyltransferase and CMP-phosphatidate:inositol phosphatidyltransferase were located exclusively in a microsomal fraction containing enriched levels of endoplasmic reticulum markers. Thus, diacylglycerol from agonist-stimulated cleavage of PtdInsP2, or phosphatidic acid formed from it, must be transferred to the endoplasmic reticulum for conversion to PtdIns. Plasma membrane also lacked PtdIns kinase. If the soluble PtdIns kinase has access to membrane-bound substrate, PtdIns may be phosphorylated to PtdInsP before or during transport to the plasma membrane. Phosphorylation by the predominantly plasma membrane PtdInsP kinase to form PtdInsP2 completes the cycle. PtdInsP phosphatase was present in all membrane fractions suggesting that PtdInsP can be returned to the PtdIns pool in plasma membrane and elsewhere. PtdInsP2 phosphatase was almost exclusively in the cytosol suggesting that reversible interchange between PtdInsP and PtdInsP2 in the plasma membrane may be modulated by the ability of this phosphatase to act on PtdInsP2 in the membrane. Thus, PtdIns resynthesis in the plasma membrane of these cells does not occur and is not required for phosphoinositide-mediated signal transduction.

Lipopolysaccharide stimulates differential expression of myristoylated protein kinase C substrates in murine microglia.

Microglia rapidly respond to lipopolysaccharide (LPS) by transformation from resting to active states and secretion of several neuro‐ and immuno‐regulators including tumour necrosis factor alpha (TNF‐α), interleukin 1β (IL‐1β), and interleukin 6 (IL‐6). With longer LPS treatment, microglia are converted to reactive or phagocytic states with characteristics similar to macrophages in inflammation and injury processes. We have investigated LPS‐mediated changes in two myristoylated substrates of protein kinase C (PKC): MARCKS (myristoylated alanine‐rich C kinase substrate) and MRP (MARCKS‐related protein). Within 6 hours of addition, LPS induced a twofold increase in [3H]myristoylated and immunoreactive MARCKS protein and a sevenfold increase in MRP. The differential effect of LPS on expression of MRP vs. MARCKS was even more dramatic at the level of transcription: S1 nuclease protection assays revealed a 40‐fold increase in MRP mRNA levels (maximum at 4–6 hours), whereas a threefold increase was observed for MARCKS. TNFα and colony‐stimulating factor 1 (CSF‐1), two cytokines which are induced by LPS, did not reproduce the observed effect of LPS on MARCKS and MRP gene transcription. CSF‐1 also induced differential transcription of MRP, but of lower magnitude (threefold) and more sustained than by LPS. Accordingly, these two substrates for PKC are differentially up‐regulated by LPS, apparently independent of TNFα or CSF‐1.

Overexpression of MARCKS, but Not Protein Kinase C‐α, Increases Phorbol Ester‐Stimulated Synthesis of Phosphatidylcholine in Human SK‐N‐MC Neuroblastoma Cells

Abstract: To investigate the regulation of phorbol ester‐stimulated synthesis of phosphatidylcholine (PtdCho), myristoylated alanine‐rich protein kinase C substrate (MARCKS) and the α‐isoform of protein kinase C (PKC‐α) were overexpressed in a human neuroblastoma (SK‐N‐MC) cell line that does not increase PtdCho synthesis in response to 4β‐12‐O‐tetradecanoylphorbol 13‐acetate (TPA). In five clones with a less than fivefold increase in MARCKS protein level, the synthesis of PtdCho from [methyl‐3H]choline was stimulated 1.88–2.34‐fold in the presence of 100–200 nM TPA. In clones overexpressing PKC‐α (30–40‐fold increased level of protein) or in mock‐transfected vector controls, TPA had much less of a stimulatory effect (1.04–1.43‐fold) on PtdCho synthesis. TPA caused translocation of PKC‐α and increased phosphorylation of MARCKS, indicating that both overexpressed proteins responded to stimulation. Thus, in SK‐N‐MC cells, MARCKS is required for TPA‐stimulated synthesis of PtdCho, and PKC‐α alone is insufficient for supporting enhanced synthesis.

Clofibrate and other peroxisomal proliferating agents relatively specifically inhibit synthesis of ethanolamine phosphoglycerides in cultured human fibroblasts.

Effects of several classes of peroxisomal proliferators on peroxisomal functions, hepatomegaly, hepatocarcinogenesis and lipid metabolism have been extensively investigated in rodents. Less is known about influences of these agents, some used as hypolipidemic drugs, on various metabolic parameters in humans. We examined effects of clofibrate, di(2-ethyl-hexyl)phthalate (DEHP) and pirinixic acid (WY-14,643) on phospholipid metabolism in human fibroblasts in culture. Clofibrate inhibited incorporation of [1-14C]hexadecanol and [1-14C]linolenic acid into ethanolamine phosphoglycerides in a time- and concentration-dependent manner; labeling of plasmalogens and non-plasmalogen ethanolamine phosphoglycerides was reduced by 40-80% compared to a generalized 10-30% inhibition of labeling of other phospholipids, including phosphatidylcholine. In pulse and pulse-chase experiments, selective inhibition of incorporation of [1,2-14C]ethanolamine, compared to [methyl-3H]choline, confirmed relative specificity of inhibition of ethanolamine phosphoglycerides. Similar concentration dependence and specificity for inhibition of phospholipid turnover was observed for DEHP and WY-14,643, in both control and mutant (Zellweger and adrenoleukodystrophy) fibroblasts, in the absence of major effects on peroxisomal markers. These observations that peroxisomal proliferators specifically inhibit ethanolamine phosphoglyceride turnover in human fibroblasts should be considered when assessing the efficacy and safety of such agents as hypolipidemic drugs or when evaluating mechanisms of proliferator action at the cellular level.

Thapsigargin selectively stimulates synthesis of phosphatidylglycerol in N1E-115 neuroblastoma cells and phosphatidylinositol in C6 glioma cells

Phospholipid metabolism was studied in N1E-115 neuroblastoma and C6 glioma cells exposed to thapsigargin, a selective inhibitor of endoplasmic reticulum Ca(2+)-ATPase that raises the cytosolic free Ca2+ concentration [Ca2+]i. Thapsigargin caused only a transient increase of [Ca2+]i (< 1 min) in N1E-115 cells similar in magnitude and duration to agonist-induced calcium release mediated by inositol trisphosphate. Sustained elevation of [Ca2+]i due to influx of extracellular calcium, as occurs in most other cell lines including C6 cells, did not occur in N1E-115 cells. Increased uptake of inorganic phosphate (Pi) associated calcium influx was observed in C6 but not in N1E-115 cells. Thapsigargin affected phospholipid synthesis in both cell lines, most likely by inhibiting phosphatidic acid phosphohydrolase as indicated by diversion of [3H]oleic acid incorporation from triacylglycerol to phospholipid synthesis and stimulation of [32P]Pi incorporation into anionic phospholipids at the expense of phosphatidylcholine synthesis. The response to increased phosphatidate/phosphatidyl-CMP availability was cell specific. Thapsigargin (> 100 nM) selectively stimulated phosphatidylglycerol synthesis 20-30-fold in N1E-115 neuroblastoma cells while phosphatidylinositol synthesis was increased < 2-fold. In contrast, phosphatidylglycerol was not affected in C6 glioma cells and phosphatidylinositol synthesis was stimulated 8-fold by thapsigargin (> 1 microM). Agonist-stimulated calcium release did not increase phosphatidylglycerol synthesis in N1E-115 cells. Thapsigargin-stimulated phosphatidylglycerol synthesis and agonist-stimulated phosphatidylinositol synthesis could occur at the same time. Similar results were obtained with TMB-8, an inhibitor of intracellular Ca2+ release that decreases diacylglycerol utilization by blocking choline uptake and phosphatidylcholine synthesis without affecting resting [Ca2+]i. Thus [Ca2+]i does not directly mediate the effects of thapsigargin, TMB-8 or agonist stimulation on anionic phospholipid metabolism. These additional effects may limit the use of thapsigargin to assess Ca(2+)-dependence of phospholipid metabolism associated with Ca(2+)-mediated signal transduction.

Lipopolysaccharide Induction of MARCKS-Related Protein and Cytokine Secretion are Differentially Impaired in Microglia from LPS-nonresponsive (C3H/HeJ) Mice

Many events involved in activation of microglia and leukocytes by lipopolysaccharide (LPS) are mediated by protein kinase C (PKC), and we have recently demonstrated that a major PKC substrate, MARCKS-related protein (MRP), is selectively induced by LPS in murine microglia. In microglia from LPS-nonresponsive (C3H/HeJ) mice, induction of MRP and secretion of CSF-1 required much higher LPS concentrations (≥100 ng/ml) than in normal (C3H/OuJ) microglia (≤10 ng/ml). By contrast, TNFα production was not significantly increased in C3H/HeJ microglia even at 1 μg LPS/ml. Microglia expressed PKC isoforms α, β, δ, and ζ (but not γ and ε); PKC isoform levels were similar in both normal and C3H/HeJ microglia and no significant change in response to LPS was noted. Our results indicate that LPS alters PKC substrate (rather than kinase) expression, and that the Lpsd mutation in C3H/HeJ mice differentially affects regulation of several gene products implicated in microglial function.

Phospholipid Catabolism and Phospholipid Turnover in Cultured Cells

Phosphatidylcholine (PC) and sphingomyelin (SM) constitute >50% of the phospholipids of most mammalian cell membranes1. They differ in many of their physical properties and variations in their relative proportions have profound effects on the membrane bilayer1,2. The differences in physical properties are determined in part by variations in acyl chain composition and result in micro-heterogeneity within each choline-lipid class. The relative proportions of these subspecies of the two major choline-lipid classes, and of the two major choline-lipid species themselves is controlled by synthetic and degradative enzymes. Both synthesis and degradation are continuous processes and are reflected in a high rate of turnover of PC and SM. As the amount of choline lipid per mg protein is relatively constant in the cell, there must be a close co-ordination between the synthetic and degradative pathways to maintain an appropriate balance. The nature of the interactions between these two processes is largely unknown.