Phospholipase D Activity of Rat Brain Neuronal Nuclei

Abstract: Phospholipase D activity of rat brain neuronal nuclei, measured with exogenous phosphatidylcholine as substrate, was characterized. The measured activity of neuronal nuclei was at least 36-fold greater than the activity in glia nuclei. The pH optimum was 6.5, and unsaturated but not saturated fatty acids stimulated the enzyme. The optimal concentration of sodium oleate for stimulation of the enzyme activity was 1.2 m M in the presence of 0.75 m M phosphatidylcholine. This phospholipase D activity was cation independent. In the absence of NaF, used as a phosphatidic acid phosphatase inhibitor, the principal product was diglyceride; whereas in the presence of NaF, the principal product was phosphatidic acid. The phospholipase D, in addition to having hydrolytic activity, was able to catalyze a transphosphatidylation reaction. Maximum phosphatidylethanol formation was seen with 0.2–0.3 M ethanol. GTPγS, ATPγS, BeF₂, AIF₃, phosphatidic acid, and phosphatidylethanol inhibited the neuronal nuclei phospholipase D activity. The addition of the cytosolic fraction of brain, liver, kidney, spleen, and heart to the incubation mixtures resulted in inhibition of the phospholipase D activity. Phospholipase D activity was detectable in nuclei prepared from rat kidney, spleen, heart, and liver.     

Membrane-Associated Phospholipase D Activity in Rat Sciatic Nerve

Rat sciatic nerve contains a membrane-bound phospholipase D that catalyzes the hydrolysis of exogenous phosphatidylcholine (PC) to phosphatidic acid (PA) and choline. The enzyme is associated with a particulate fraction consisting primarily of microsomes and myelin. This fraction also contains phosphatidate phosphohydrolase activity leading to the production of diacylglycerols (DAG). The phosphohydrolase activity can be completely inhibited by NaF. Hydrolysis of exogenous PC requires detergent and is linear up to about 40 micrograms of protein at a pH optimum of 6.5. In the absence of NaF, the sum of PA and DAG increases linearly for 40 min, whereas in its presence, PA production is linear for only 15 min. At optimum conditions, PC hydrolysis proceeds at 15 nmol/h/mg of protein. Addition of increasing amounts of ethanol to the incubation system leads to the generation of increasing amounts of phosphatidylethanol, indicating transphosphatidylation activity. At an ethanol concentration of 0.4 M, phosphatidylethanol represents about one-half of the reaction products generated at approximately the same rate of enzymic activity observed in the absence of ethanol. Higher ethanol concentrations are inhibitory.     

Spexin Expression in Normal Rat Tissues

Spexin is a highly conserved peptide which was recently identified through the bioinformatics approach. Immunohistochemical analysis of its expression has not yet been performed. Thus, in this study, we examined spexin location in a wide range of rat organs by both RT-PCR and IHC. RT-PCR identified spexin mRNA in all tissues examined. Spexin immunoreaction was mainly cytoplasmic. Spexin was immunohistochemically detected, although with different staining intensities, in epithelia and glands of skin and respiratory, digestive, urinary, and reproductive systems. Smooth muscle cells showed weak immunostaining, and connective tissue was negative. In the central nervous system, neuronal groups showed different intensities for reaction product. Immunoreaction was also found in ganglionic cells of both trigeminal and superior cervical ganglia and in photoreceptor, inner nuclear, and ganglionic layers of the retina. In the endocrine system, spexin immunoreaction was detected in the hypothalamic paraventricular and supraoptic nuclei; adenohypophysis, thyroid, and parathyroid glands; adrenal cortex and medulla (mainly ganglionic cells); Leydig cells; and thecal, luteal, and interstitial cells of the ovary. Because of its widespread expression, spexin is probably involved in many different physiological functions; in particular, location of spexin in neurons and endocrine cells suggests its roles as neurotransmitter/neuromodulator and endocrine factor. (J Histochem Cytochem 58:825–837, 2010)     

Intracellular Localization of Phospholipase D in Leaves and Seedling Tissues of Castor Bean

The intracellular distribution of phospholipase D (PLD; EC 3.1.4.4) in castor bean (Ricinus communis L.) tissues was investigated by subcellular fractionation and by immuno-electron microscopy. Centrifugal fractionation revealed that most PLD in young leaves was soluble, whereas in mature leaves a majority of PLD was associated with microsomal membranes. Further separation of microsomal membranes by a two-phase partitioning system indicated that PLD was associated with both plasma and intracellular membranes. Sucrose gradient separation of intracellular membranes showed PLD present in the endoplasmic reticulum, a submicrosomal band, and in soluble fractions but not in mitochondria and glyoxysomes of postgermination endosperm. Immunocytochemical studies found high gold labeling in vacuoles in young leaves, suggesting that the high level of soluble PLD in young leaves is due to release of PLD from vacuoles during tissue disruption. In addition to the labeling in vacuoles, gold particles were also found in the cytoplasmic matrices and plasma membrane in leaves and in 2-d postgermination seedlings. Collectively, these results show that PLD in castor bean leaf and seedling tissues is localized in the vacuole and is associated with the endoplasmic reticulum and plasma membrane and that the relative distribution between the soluble and membrane compartments changes during castor bean leaf development.     

Eosinophilic leucocytes and phospholipase B of rat tissues

The correlation between the eosinophilic leucocyte population and the phospholipase B activity of rat tissues has been tested with isolated cell preparations from intestine, lung, blood, bone marrow and spleen containing eosinophils in varying proportions and with pure eosinophil fractions separated by centrifugation on discontinuous metrizoate and metrizamide gradients. A uniform value of activity per cell was found in all these tissues extending previous histochemical and biochemical evidence that the eosinophil is the carrier cell for the phospholipase B to all major sites of distribution. The enzyme marker approach has been used for estimating the normal eosinophil population of rat organs and show the distribution pattern of the eosinophils in peripheral organs in the wake of increased production and release from the marrow.     

Inositol Phospholipid Hydrolysis by Rat Sciatic Nerve Phospholipase C

Rat sciatic nerve cytosol contains a phosphodiesterase of the phospholipase C type that catalyzes the hydrolysis of inositol phospholipids, with preferences of phosphatidylinositol 4'-phosphate (PIP) greater than phosphatidylinositol (PI) much greater than phosphatidylinositol 4',5'-bisphosphate (PIP2), at a pH optimum of 5.5-6.0 and at maximum rates of 55, 13, and 0.7 nmol/min/mg protein, respectively. Analysis of reaction products by TLC and formate exchange chromatography shows that inositol 1,2-cyclic phosphate (83%) and diacylglycerol are the major products of PI hydrolysis. [32P]-PIP hydrolysis yields inositol bisphosphate, inositol phosphate, and inorganic phosphate, indicating the presence of phosphodiesterase, phosphomonoesterase, and/or inositol phosphate phosphatase activities in nerve cytosol. Phosphodiesterase activity is Ca2+-dependent and completely inhibited by EGTA, but phosphomonoesterase activity is independent of divalent cations or chelating agents. Phosphatidylcholine (PC) and lysophosphatidylcholine (lysoPC) inhibit PI hydrolysis. They stimulate PIP and PIP2 hydrolysis up to equimolar concentrations, but are inhibitory at higher concentrations. Both diacylglycerols and free fatty acids stimulate PI hydrolysis and counteract its inhibition by PC and lysoPC. PIP2 is a poor substrate for the cytosolic phospholipase C and strongly inhibits hydrolysis of PI. However, it enhances PIP hydrolysis up to an equimolar concentration.     

Phospholipase A-deficient mutants of Escherichia coli B

Phospholipase A-deficient mutants were isolated from Escherichia coli B/SM as follows. Replica plates were incubated to allow formation of colonies and then overlayed with soft agar containing washed sheep erythrocytes, lecithin Ca++, colistin, lysozyme and streptomycin. The mutant colonies were detected as colonies without hemolytic zones. Two or three cycles of treatment with mutagen and selection were necessary for their isolation. The mutants obtained could grow in a synthetic medium with glucose as the sole carbon source, and their phospholipid compositions were similar to that of the parent. They also gave the same agglutination titer as the parent with rabbit antiserum against the parent strain. They supported the growth of all members of the T-series of bacteriophages as effectively as the parent. Some hemolytic substance was produced from either lecithin or bacterial constituents when the mutants were infected with T even phages, but not with T odd phages. When the parent strain was infected with either T1 or T4, free fatty acids (FFA) were produced in the cell debris. Only a trace of FFA was formed in the debris of one of these mutants on infection with T4 and no FFA was formed on infection with T1.     

Fatty Acid Activation and Temperature Perturbation of Rat Brain Microsomal Phospholipase D

Abstract: The hydrolytic and transphosphatidylation activities of rat brain microsomal phospholipase D were highly latent in the absence of an appropriate activator. The most suitable surfactants for this activation were oleate and palmitoleate. Besides the bile acids and unsaturated fatty acids, other naturally occurring surfactants, such as lysophospholipids, acidic phospholipids, acyl-CoA's, and gangliosides, were inactive. Taurodeoxycholate, at optimal concentration, produced a profound inhibition of oleate activation. Phospholipase D activity was detectable in all rat tissues investigated. The optimal incubation temperature for phospholipase D was 30°C, with a break point at 16.1°C in an Arrhenius plot.     

KATP通道基因在大鼠组织中的表达

为检测大鼠肺动脉平滑肌及支气管平滑肌中KATP．通道亚基的表达情况,应用RT-PCR技术．从原代培养的Wistar大鼠肺动脉平滑肌及支气管平滑肌细胞第3—5代提取总RNA,逆转录．并进行PCR扩增鉴定．发现肺动脉平滑肌细胞有Kir6.1、SUR1和SUR2B的表达,其中SUR1表达量较弱,支气管平滑肌细胞有Kir6.1和SUR2B的表达。     

A Cytosolic Phospholipase A2 from Potato Tissues Appears to Be Patatin

Phospholipase (PL) A₂ is involved in signal transduction inthe resistance reaction that is induced in potato by inoculationof an incompatible race of Phytophthora infestans, the lateblight fungus, or by treatment with fungal elicitor hyphal wallcomponents (Kawakita et al. 1993). In this study, PLA₂ in thesoluble fraction from potato tuber was purified. The followingresults suggested that the enzyme was, in fact, patatin: (1)the molecular mass of the purified enzyme was 40 kDa, the sameas that of patatin; (2) the pI of the purified enzyme was approximately4.75, which corresponds to that of patatin; and (3) the amino-terminalamino acid sequence of the purified enzyme showed a high degreeof homology to that of patatin. Patatin is known as a storageprotein of the potato tuber and it has been shown to have esteraseactivity. However, other enzymatic activities and the function(s)of patatin are unknown. We investigated the PLA activities ofthe purified patatin. The PLA₂ activity of the patatin was muchhigher than the PLA₁ activity, even though the protein exhibitedboth activities. The PLA₂ activity of the enzyme was particularlyapparent when phosphatidylcholine with linoleic acid at thesn-2 position was used as substrate. Lower activity was observedwith phosphatidylcholine with palmitic acid, oleic acid andarachidonic acid at the sn-2 position. (Received October 5, 1995; Accepted February 9, 1996)     

大鼠肾脏和其它组织中磷酸酪氨酸蛋白的研究

本文采用P-tyr-BSA为免疫原免疫家无得抗血清。将纯化的IgG与HRP偶联,建立了P-tyr-Pr的ELISA法,并测定了正常大鼠肾脏等组织中P-tyr-Pr含量,其分布规律如下:上清中P-tyr-Pr含量高者,其颗粒部分则低,反之亦然;其中肾脏上清中含量远比其它组织(脾、肺、肝等)高。在此基础上,又研究了膜性肾炎大鼠肾脏P-tyr-Pr含量,发现其上清中的含量远远高于正常大鼠肾脏中的含量。     

Phosphatidylethanol Formation via Transphosphatidylation by Rat Brain Synaptosomal Phospholipase D

Phosphatidylethanol (Peth) formation catalyzed by the transphosphatidylation activity of phospholipase D was demonstrated to occur in a rat brain synaptosomal enriched preparation. The optimal pH was determined to be 6.5, and the optimal ethanol concentration was determined to be 0.3-0.4 M with an apparent Km of 0.2 M. Peth formation was barely detectable in the absence of an appropriate activator and several unsaturated fatty acids were found to be effective activators. The concentrations of oleic acid required for maximum activation varied with the concentration of exogenous phosphatidylcholine present in the incubation mixtures. All detergents tested were significantly less active than the unsaturated fatty acids and divalent ions were not required for Peth formation. Phosphatidylcholine was the most effective phosphatidyl donor of the phospholipids tested. Peth forming activity was greatest in the synaptic membrane fraction of the various brain subfractions examined. The 12,000 g-100,000 g particulate fraction of lung, heart, and adipose tissue had activities similar to that of brain.     

The Presence of Phospholipase D In Rat Central Nervous System Axolemma

An axolemma-enriched fraction prepared from a purified myelinated axon fraction isolated from rat CNS was found to contain phospholipase D at a specific activity similar to that of a microsomal fraction isolated from whole brain. There was a concomitant threefold enrichment in the specific activity of phospholipase D and acetylcholinesterase in the axolemma-enriched fraction compared with the specific activities of these enzymes in the starting white matter whole homogenate. This axonal phospholipase D may be involved in remodeling of phospholipid, which in turn may affect axonal functions such as ion translocation.     

Effect of Dietary Lipids on Phospholipase D Activity in Rat Brain

Phospholipase D (PLD) is emerging as a major player in many novel signaling pathways. Based on recent studies correlating membrane composition with enzyme function, we speculated that feeding of dietary lipids to the newborns has a major impact on brain PLD activity. To test this hypothesis, the rat dams were fed fat-free powder containing either safflower oil or fish oil, and a control powdered chow. The pups were weaned onto the diet and sacrificed at 30 days of age. PLD activity was measured by transphosphatidylation assays using rat brain membranes. This study shows that microsome GTPS-dependent PLD activity in rats fed safflower oil or fish oil was significantly reduced by 38% and 30% respectively compared to controls. Oleate-dependent PLD activity in the safflower oil group, however, was significantly increased by 38%. In contrast, synaptosome membrane (P2) GTPS-dependent PLD activity in rats consuming safflower oil was significantly increased by 29%, but there was no difference in oleate-dependent PLD activity. Likewise, no difference was observed in microsome oleate-dependent PLD and P2 GTPS-dependent PLD activity between the fish oil and the control groups. These results indicate that dietary lipid intake appears to modulate phospholipid metabolism and differential expression of PLD isozymes in the brain.     

Phospholipase A2 and phospholipase B activities in fungi

As saprophytes or disease causing microorganisms, fungi acquire nutrients from dead organic material or living host organisms. Lipids as structural components of cell membranes and storage compartments play an important role as energy-rich food source. In recent years, it also has become clear that lipids have a wide range of bioactive properties including signal transduction and cell to cell communication. Thus, it is not surprising that fungi possess a broad range of hydrolytic enzymes that attack neutral lipids and phospholipids. Especially during infection of a mammalian host, phospholipase A(2) (PLA(2)) enzymes released by fungi could play important roles not only for nutrient acquisition and tissue invasion, but for intricate modulation of the host's immune response. Sequencing of fungal genomes has revealed a wide range of genes encoding PLA(2) activities in fungi. We are just beginning to become aware of the significance these enzymes could have for the fungal cells and their interaction with the host.