The role of phospholipids in TSH stimulation of adenylate cyclase in thyroid plasma membranes

Treatment of bovine thyroid plasma membranes with phospholipase A or C inhibited the stimulation of adenylate cyclase activity by thyroid-stimulating hormone (TSH). In general, basal and NaF-stimulated adenylate cyclase activity was not influenced by such treatment. When plasma membranes were incubated with 1–2 units/ml phospholipase A, subsequent addition of phosphatidylcholine or phosphatidylserine but not phosphatidylethanolamine partially restored TSH stimulation. Phosphatidylcholine was more effective than phosphatidylserine in that it caused greater restoration of the TSH response and smaller amounts of phosphatidylcholine were active. However, when the TSH effect was obliterated by treatment of plasma membranes with 10 units/ml phospholipase A, phospholipids were unable to restore any response to TSH. Lubrol PX, a nonionic detergent, inhibited basal, TSH- and NaF-stimulated adenylate cyclase activities in thyroid plasma membranes. Although phosphatidylcholine partially restored TSH stimulation of adenylate cyclase activity in the presence of Lubrol PX, it did not have a similar effect on the stimulation induced by NaF. These results indicate that phospholipids are probably essential components in the system by which TSH stimulates adenylate cyclase activity in thyroid plasma membranes. The effects do not seem to involve the catalytic activity of adenylate cyclase but the data do not permit a distinction between decreased binding of TSH to its receptor or impairment of the signal from the bound hormone to the enzyme activity.     

Membrane phospholipid composition, fluidity and phospholipase A2 activity of human hepatoma cell line HepG2

1. Investigations have been carried out on the phospholipid composition, physical state and phospholipase A2 activity of plasma and microsomal membranes from HepG2 cells. 2. The results showed a great similarity in the physico-chemical properties of plasma and microsomal membranes from HepG2 cells. 3. The activity of phospholipase A2 was found to depend on the membrane physical state in both types of membranes.     

Change in membrane lipid fluidity induced by phospholipase A activation: a mechanism of endotoxic shock

The effects of endotoxin administration on the fluidity of dog liver plasma membranes and their relationship with changes in phospholipase A2 activity were studied. Endotoxin administration decreased the fluidity of liver plasma membranes and this decrease was reversible by phosphatidylcholine. The endotoxin-induced decrease in membrane fluidity could be mimicked by digesting control liver membranes with exogenous phospholipase A2. Endotoxin administration also increased the endogenous phospholipase A2 activity. Endotoxin in vitro had no phospholipase A2-like activity but it activated the hydrolytic activity of exogenous phospholipase A2. Based on these data, it is concluded that endotoxin administration decreased the fluidity of canine liver plasma membranes by acting through activation of phospholipase A2. The decrease in membrane lipid fluidity induced by endotoxin administration may play a significant role in the development of the pathophysiology of endotoxic shock at the cellular level.     

Effect of purified phospholipases on the binding of tetrodotoxin to axon plasma membrane

Summary The role of phospholipids in the binding of [³H] tetrodotoxin to garfish olfactory nerve axon plasma membrane was studied by the use of purified phospholipases. Treatment of the membranes with low concentrations of either phospholipase A₂ (Crotalus adamanteus andNaja naja) or phospholipase C (Bacillus cereus andClostridium perfringens) resulted in a marked reduction in tetrodotoxin binding activity. A 90% reduction in the activity occurred with about 45% hydrolysis of membrane phospholipids by phospholipase A₂, and with phospholipase C the lipid hydrolysis was about 60–70% for a 70–80% reduction in the binding activity. Phospholipase C fromB. cereus andCl. perfringens had similar inhibitory effects. Bovine serum albumin protected the tetrodotoxin binding activity of the membrane from the inhibitory effect of phospholipase A₂ but not from that of phospholipase C. In the presence of albumin about 25% of the membrane phospholipids remained unhydrolyzed by phospholipase A₂. It is suggested that these unhydrolyzed phospholipids are in a physical state different from the rest of the membrane phospholipids and that these include the phospholipids which are directly related to the tetrodotoxin binding component. It is concluded that phospholipids form an integral part of the tetrodotoxin binding component of the axon membrane and that the phospholipase-caused inhibition of the binding activity is due to effects resulting from alteration of the phospholipid components.     

Activity and subcellular distribution of phospholipase A1 from neuronal cell-enriched fractions of the rabbit cerebral cortex

Glycerophosphatides, specifically labeled either in the 1 or in the 2 position, were used to measure the activity of neuronal phospholipase A₁ and to investigate the subcellular distribution of the enzyme. The microsomes were found to possess the highest phospholipase activity, with a threefold increase as compared to the cell homogenate. A considerable enzymatic activity could still be observed in the plasma membranes isolated from the neuronal-enriched cell fraction. Microsomal phospholipase possessed the highest activity with phosphatidylcholine, whereas phosphatidylserine was cleaved at a much lower rate. The rate of release of labeled fatty acids from the substrates by the microsomal phospholipase decreased with increasing degree of unsaturation of the fatty acids at the 1 position. The presence of plasmalogens and of alkylacyl analogues in the incubation mixture caused an appreciable inhibition of the hydrolysis of the diacyl glycerophosphatides.     

Gonadotropin receptors in plasma membranes of bovine corpus luteum. II. Role of membrane phospholipids.

The role of phospholipids in the binding of 125I-choriogonadotropin to bovine corpus luteum plasma membranes has been investigated with the use of purified phospholipase A and phospholipase C to alter membrane phospholipids. The phospholipase C-digested plasma membrane preparation showed 85 to 90% inhibition of 125I-choriogonadotropin binding activity when 70% of the membrane phospholipid was hydrolyzed. Similarly treatment of plasma membranes with phospholipase A resulted in 45 to 55% hydrolysis of membrane phospholipid and almost 75% inhibition of receptor activity. Both these enzymes hydrolyzed membrane-associated phosphatidylcholine to a greater extent than phosphatidylethanolamine and phosphatidylserine. Phosphorylaminoalcohols of phospholiphase C end products were completely released into the medium, while phospholipase A by-products remained associated with plasma membranes. Addition of a phospholipids suspension or liposomes to plasma membranes pretreated with phospholipase A and C did not restore gonadotropin binding activity. Soluble phosphorylcholine, phosphorylethanolamine, and phosphorylserine and insoluble diglyceride products of phospholipase C action had no effect on receptor activity. In contrast, end products of the phospholipase A action, such as lysophosphatides and fatty acids, inhibited both on the membrane-associated and solubilized receptor activity. Lysophosphatidylcholine was the most effective end product inhibiting the binding of gonadotropin to the receptor, followed by lysophosphatidylethanolamine and lysophosphatidylserine. The inhibitory effects of phospholipase A or lysophosphatides were completely reversed upon removal of membrane-bound phospholipid end products by washing the membranes with defatted bovine serum albumin. However, phospholipase C inhibition could not be overcome by defatted albumin washings. Solubilization of plasma membranes with detergents which had been pretreated with phospholipase C partially restored the inhibited activity. It is concluded that the phospholipase-mediated inhibition of gonadotropin binding activity was due to hydrolysis and alterations of the phospholipid environment in the case of phospholipase C and by direct inhibition by end products in the case of phospholipase A.     

Characterization and distribution of a phospholipase A2 activity from adult rabbit lung

A phospholipase A2 activity was characterized in adult rabbit lung. This activity was calcium- and deoxycholate-dependent and displayed an alkaline pH optimum. Km and Vmax were 0.176 mM and 256.8 pmoles/min./mg protein respectively. The microsomal fraction displayed the highest enzymatic specific activity; the lowest activity was present in the cytosol. Yet this latter fraction accounted for the majority of the total activity. Although the specific activity was high within the lamellar body fraction this compartment contained only approximately 2% of the total activity. Phospholipase A2 activity was inhibited by bromophenacyl bromide, chlorpromazine and mepacrine in decreasing order of effectiveness. Treatment of the microsomes with increasing concentrations of NaC1 indicated that the lung phospholipase A2 activity was relatively loosely bound to the microsomal membranes and was maximally removed with salt at a concentration only slightly higher than physiological. Addition of calmodulin to the enzyme assay did not significantly alter hydrolysis of labelled phosphatidylcholine.     

Enzymatic degradation and partial biosynthetic reconstitution of microsomal and mitochondrial membranes.

Guinea pig liver microsomal and mitochondrial membranes were degraded with phospholipase C and D followed by partial biosynthetic reconstitution. Activities of phosphatidylinositol synthetase in microsomal membranes and NADPH-cytochrome c reductase were almost completely lost after phospholipase C and D treatment; almost complete restoration of the original activity was achieved after biosynthesis of phosphatidylcholine in degraded microsomes, but was not reparable after biosynthesis of cytidinediphosphodiglycerides (CDP-diglycerides). The mitochondrial biosynthesis of polyglycerophosphatides was completely retained after degradation of these membranes with phospholipase C, but after similar treatment with phospholipase D, only about one-quarter of the original activity remained, the relative composition of polyglycerophosphatides being significantly different. The activity of NADPH-cytochrome c reductase of microsomes represented about 76% of the original activity after phospholipase C treatment, but only approximately 1% after treatment with phospholipase D. Although this activity could not be restored with CDP-diglyceride synthesis, it was restored to about 75% of the original activity after the biosynthesis of phosphatidylcholine in these fragments. These and additional experimental findings are discussed in terms of the relation between structural organization of lipids and proteins and enzymatic activities of membrane-bound phospholipid-synthesizing enzymes in microsomal and mitochondrial membranes isolated from guinea pig liver.     

Modulation of the in vitro activity of lysosomal phospholipase A1 by membrane lipids

Lysosomal phospholipases play a critical role for degradation of cellular membranes after their lysosomal segregation. We investigated the regulation of lysosomal phospholipase A1 by cholesterol, phosphatidylethanolamine, and negatively-charged lipids in correlation with changes of biophysical properties of the membranes induced by these lipids. Lysosomal phospholipase A1 activity was determined towards phosphatidylcholine included in liposomes of variable composition using a whole-soluble lysosomal fraction of rat liver as enzymatic source. Phospholipase A1 activity was then related to membrane fluidity, lipid phase organization and membrane potential as determined by fluorescence depolarization of DPH, 31P NMR and capillary electrophoresis. Phospholipase A1 activity was markedly enhanced when the amount of negatively-charged lipids included in the vesicles was increased from 10 to around 30% of total phospholipids and the intensity of this effect depended on the nature of the acidic lipids used (ganglioside GM1相似文献   

Membrane composition and successful bioaugmentation. Studies of the interactions of model thylakoid and plasma cyanobacterial and bacterial membranes with fungal membrane-lytic enzyme Lecitase ultra

Cyanobacterial/bacterial consortia are frequently inoculated to soils to increase the soil fertility and to accelerate the biodegradation of organic pollutants. Moreover, such consortia can also be successfully applied in landfills especially for the biodegradation of plastic wastes. However, the bioaugmentation techniques turn out frequently inefficient due to the competition of the indigenous microorganisms attacking directly these inoculated or secreting to their surroundings cell wall and membrane-lytic enzymes. It can be hypothesized that the resistance of the microbial membrane to the enzymatic degradation is correlated with its lipid composition. To verify this hypothesis glycolipid and phospholipid Langmuir monolayers were applied as models of thylakoid and plasma cyanobacterial and bacterial membranes. Hybrid fungal enzyme Lecitase ultra joining the activity of lipase and phospholipase A1 was applied as the model of fungal membrane-lytic enzyme. It turned out that anionic thylakoid lipids sulfoquinovosyldiacylglycerol and phosphatidylglycerols were the main targets of Lecitase ultra in the model multicomponent thylakoid membranes. The resistance of the model plasma bacterial membranes to enzymatic degradation depended significantly to their composition. The resistance increased generally when the unsaturated lipids were exchanged to their saturated counterparts. However, most resistant turned out the membranes composed of unsaturated phosphatidylamine and saturated anionic phospholipids.     

Translocation of phospholipase A2 from cytosol to membranes induced by 1-oleoyl-2-acetyl-glycerol in serum-free cultured macrophages

Macrophages exhibit high activities of a phospholipase A2 which preferentially cleaves arachidonic acid (I. Flesch, B. Schmidt, and E. Ferber, Z. Naturforsch. 40c, 356-363, 1985). In unstimulated cells more than 90% of the total activity of this enzyme is localized in the cytosol. Treatment of these cells with 100 microM 1-oleoyl-2-acetyl-glycerol (OAG) for 30 min induced a translocation of phospholipase A2 to cellular membranes. The amount of translocated phospholipase A2 was about 30% of the total activity and correlated with a similar translocation of protein kinase C to membranes. These data suggest that the translocation of phospholipase A2 to membranes is related to the activation process of this enzyme.     

Purification and Characterization of Membrane-Bound Inositol Phospholipid-Specific Phospholipase C from Suspension-Cultured Rice (Oryza sativa L.) Cells (Identification of a Regulatory Factor)

A membrane-bound inositol phospholipid-specific phospholipase C was solubilized from rice (Oryza sativa L.) microsomal membranes and purified to apparent homogeneity using a series of chromatographic separations. The apparent molecular mass of the enzyme was estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be 42,000 D, and the isoelectric point was 5.1. The optimum pH for the enzyme activity was approximately 6.5, and the enzyme was activated by both Ca2+ and Sr2+. The chemical and catalytic properties of the purified membrane-bound phospholipase C differed from those of the soluble enzyme reported previously (K. Yotsushima, K. Nakamura, T. Mitsui, I. Igaue [1992] Biosci Biotech Biochem 56: 1247-1251). In addition, we found a regulatory factor for the phosphatidylinositol-4,5-bisphosphate (PIP2) hydrolyzing activity of phospholipase C from rice cells. The regulatory factor was dissociated from the catalytic subunit of phospholipase C during the purification. The regulatory factor was necessary to induce PIP2-hydrolyzing activity of both membrane-bound and -soluble phospholipase C; these purified enzymes had no activity alone. Because the plasma membranes isolated from rice cells could also act as a regulatory factor, the regulatory factor seems to be localized in the plasma membranes. Regulation of inositol phospholipid turnover in rice cells is discussed.     

Phospholipases A1 and A2 of rat liver plasma membranes; mechanism of action.

While V/S plots of phospholipase A1 show a phase transition, kinetic behaviour of phospholipase A2 acting in the same concentration range is hyperbolic. However after phospholipase A2 has been solubilized from the plasma membranes by 1 M NaCl, the V/S curve shows a phase transition. Membrane-bound phospholipase A1 shows a narrow optimum pH at 8.5 -9, while phospholipase A2 activity presents only small variations between pH 7 and 9.5. Towards exogenous phospholipids at the optimum pH 8.5 of phospholipase A1, the specific activity of the latter is 3-fold higher than phospholipase A2 specific activity. On the contrary towards endogenous phospholipids, phospolipase A2 activity is higher than phospholipase A2 activity. Moreover labeled endogenous PE hydrolysis by phospholipase A2 is decreased by addition of non labeled exogenous PE into the incubation medium. All these data suggest that the active site of phospholipase A1 is turned to the outside and acts only on exogenous substrates: for phospholipase A2 it would be inside, and exogenous phospholipids could be hydrolyzed only after penetrating the membrane.     

Properties of particulate, membrane-associated and soluble guanylate cyclase from cardiac muscle, skeletal muscle, cerebral cortex and liver.

1. Guanylate cyclase of washed particles and plasma membranes showed S-shaped progress curves when titrated with either GTP or Mn2+ ions; similar results were obtained with Triton X-100-solubilized enzyme preparation from washed particles. Hill plots of these data revealed multiple metal-nucleotide and free-metal binding sites. 2. Guanylate cyclase of supernatant fractions displayed typical Michaelis-Menten properties when enzyme required excess of (free) Mn2+ (over GTP) for maximal activities; Ka (free Mn2+) was about 0.15-0.25 mM at subsaturating concentrations of GTP. 4 MnATP, MnADP, and MnGDP were found to increase the activities of both particulate and superantant enzyme, when MnGTP concentration was below saturation and free Mn2+ ion concentration was low (less than 100 muM); MnATP (50muM-1 mM) inhibited both these activities at high free Mn2+ concentration (1.5 mM) and inhibition of the particulate enzyme was greater than that of supernatant enzyme. 5. Ca2+ ions stimulated supernatant-enzyme activity; the stimulatory concentration of Ca2+ ions depended on the concentration of Mn2+ and GTP. 6. A modest stimulation of particulate guanylate cyclase by pyrophosphate (0.02-1 mM) was observed; the pyrophosphate effect appeared to be competitive with respect to GTP. At a higher concentration (2 mM), pyrophosphate produced a marked inhibition of particulate enzyme; the nature of inhibitory effect appeared complex. 7. Inorganic salts (e.g. NaCl, KCl, LiBr, NaF) produced inhibition of particulate enzyme; the degree of inhibition of Triton X-100-stimulated activity was less than that of unstimulated activity. 9. Treatment of sarcolemmal or microsomal membranes with either phospholipase C or trypsin decreased, whereas phospholipase A increased, the activity of guanylate cyclase.     

The importance of glycine-30 for enzymatic activity of phospholipase A2

The nearly conserved glycine-30 in porcine pancreatic phospholipase A2 has been replaced by serine. The resulting mutant G30S was expressed in Escherichia coli, purified and characterized. The mutation caused a significant drop in enzymatic activity towards monomeric and aggregated substrates, but had a limited effect on substrate binding. In contrast the affinity for calcium ions, the essential cofactor, was reduced 10-fold. The reduced enzymatic activity is attributed to a reduced stabilization of the transition state. The results are discussed in view of naturally occurring inactive phospholipase A2 homologues from snake venom.     

ATPase and phosphatase activities from human red cell membranes. III. Stimulation of K+-activated phosphatase by phospholipase C.

Treatment of red cell membranes with pure phospholipase C inactivates (Na+ + K+)-ATPase activity and Na+-dependent phosphorylation but increases K+-dependent phosphatase activity. When phospholipase A2 replaces phospholipase C, all activities are lost. Activation of K+-dependent phosphatase by treatment with phospholipase C is caused by an increase in the maximum rate of hydrolysis of p-nitrophenylphosphate and in the maximum activating effect of K+, the apparent affinities for substrate and cofactors being little affected. After phospholipase C treatment K+-dependent phosphatase is no longer sensitive to ouabain but becomes more sensitive to N-ethylmaleimide. In treated membranes Na+ partially replaces K+ as an activator of the phosphatase. Although ATP still inhibits phosphatase activity, neither ATP, nor ATP+Na+ are able to modify the apparent affinity for K+ of K+-dependent phosphatase in these membranes.     

Human placental delta5-3beta hydroxysteroid dehydrogenase activity (delta5-3beta HSDH): intracellular distribution, kinetic properties, retroinhibition and influence of membrane delipidation.

Delta5-3beta HSDH activity has been assayed either by spectrophotometric method or by use of radioactive substrates. The enzymatic activity is equally distributed between mitochondrial and microsomal fractions verified by electronic microscopy. The specific activity is comparable in both fractions, as well as the optimal pH and the Km for NAD and for the substrates. The delta5-3beta Hut optimal pH, specific activity and sensitivity to the inhibitory action of various steroids are different when C19 and C21 steroids are used as substrates. Estrogens and cyclic AMP have also an inhibitory action on the oxidation of C21 steroids. Treatment of microsomal or mitochondrial membranes with phospholipase A releases fatty acids (mainly arachidonic) and decreases the enzymatic activity. "Adsorbtion" of the fatty acids on bovine serum albumin partially reactivates the delta5-3beta HSDH.     

Influence of phospholipid environment on the phosphatidylethanolamine: ceramide-phosphorylethanolamine transferase activity in rat liver plasma membranes.

1. Plasma membranes were treated with phospholipase A2, phospholipase C or phospholipase D. The phosphatidylethanolamine:ceramide-phosphorylethanolamine transferase was deactivated by phospholipase C treatment, whereas phospholipase A2 and phospholipase D did not affect the enzyme. 2. Incorporation of phosphatidylethanolamine and phosphatidylglycerol into partially delipidated plasma membranes resulted in significant stimulation of the transferase, whereas inclusion of sphingomyelin and phosphatidylserine suppressed the enzyme activity. Our results suggest that phosphatidylserine is a regulator of sphingomyelin level in membranes. 3. The activity of phosphatidylethanolamine:ceramide-phosphorylethanolamine transferase was not influenced by the fluidity of its lipid environment.     

Lipolytic enzymes in bovine thyroid tissue. I. Subcellular localization, purification and characterization of acid phospholipase A1.

In mammalian cells the catabolism of membrane phosphoglycerides proceeds probably entirely through a deacylation pathway catalysed by phospholipase A and lysophospholipase (Wise & Elwyn, 1965). In the initial attack of diacylphosphoglycerides by phospholipase A two enzymatic activities with different positional specificities have been distinguished: phospholipase A1 (phosphatidate 1-acyl hydrolase EN 3.1.1.32) and phospholipase A2 (phosphatidate 2-acyl hydrolase EN 3.1.1.4) (Van Deenen & De Haas, 1966). Studies on these intracellular phospholipases were mainly concerned with their subcellular localization. Only occasionally more detailed enzymatic investigations have been conducted on them, in contrast to export phospholipases e.g. from snake venom, bee venom and porcine pancreas, which have been extensively investigated (Brockerhoff & Jensen 1974a). In a previous paper (De Wolf et al., 1976a), the presence of phospholipase A1 and phospholipase A2 activities in bovine thyroid was demonstrated, using 1-[9, 10-3H] stearoyl-2-[1-14C] linoleyl-sn-glycero-3-phosphocholine as a substrate. Optimal activity was observed in both instances at pH 4. Addition of the anionic detergent sodium taurocholate increased the A2 type activity and decreased the A1 type activity suggesting the presence of different enzymes. The lack of influence of Ca2+-ions and EDTA and the acid pH optima could suggest lysosomal localization. In this paper the subcellular distribution of both acid phospholipase activities is described as well as a purification scheme for phospholipase A1. Some characteristics of the purified enzyme preparation are discussed.     

Phosphatidylinositol specific phospholipase C of plant stems : membrane associated activity concentrated in plasma membranes

A phosphatidylinositol-specific phospholipase C of plant stems (EC 3.1.4.10) assayed at pH 6.6 and at 30°C cleaved phosphatidylinositol such that more than 85% of the product was inositol-1-phosphate. Other phospholipids were cleaved 5 to 10% or less under these conditions. The phospholipase had both a soluble and a membrane-associated form. The soluble activity accounted for approximately 85 to 90% of the activity and 15% was associated with membranes. The membrane-associated activity was most concentrated in the plasma membranes of hypocotyl segments of both soybean (Glycine max) and bushbean (Phaseolus vulgaris). The plasma membrane location was verified by analysis of highly purified plasma membranes prepared both by aqueous two-phase partitioning and by preparative free-flow electrophoresis and from the quantitation of the activity in all major cell fractions. Internal membranes also contained phospholipase C activity but at specific activity levels of about 0.1 those present in plasma membranes. Golgi apparatus-enriched fractions from which plasma membrane contaminants were removed by two-phase partition contained the activity at specific activity levels 0.2 those of plasma membrane. Both the soluble and the membrane-associated activity was stimulated by calcium but not by calmodulin, either alone or in the presence of calcium.