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.     

Inhibition of [3H]nitrendipine binding by phospholipase A2

Phospholipase A2 from several sources inhibited [3H]nitrendipine binding to membranes from brain, heart and ileal longitudinal muscle. The enzymes from bee venom and Russell's viper venom were most potent, having IC50 values of approximately 5 and 14 ng/ml, respectively, in all three membrane preparations. Inhibition of binding by bee venom phospholipase A2 was time- and dose-dependent. Mastoparan, a known facilitator of phospholipase A2 enzymatic activity, shifted the bee venom phospholipase A2 dose-response curve to the left. Pretreatment of brain membranes with bee venom phospholipase A2 (10 ng/ml) for 15 min caused a 2-fold increase in the Kd without changing the Bmax compared with untreated membranes. Extension of the preincubation period to 30 min caused no further increase in the Kd but significantly decreased the Bmax to 71% the value for untreated membranes. [3H]Nitrendipine, preincubated with bee venom phospholipase A2, was recovered and found to be fully active, indicating that the phospholipase A2 did not modify the ligand. It is concluded that phospholipase A2 acts on the membrane at or near the [3H]nitrendipine binding site and that phospholipids play a key role in the interactions of 1,4 dihydropyridine calcium channel antagonists with the dihydropyridine binding site.     

Membrane phospholipid polar heads influence the coupling of M2 muscarinic receptors to G proteins

Treating membranes from rat heart with phospholipase C (phosphatidylcholine choline-phosphohydrolase) fromClostridium perfringens increased the affinity of muscarinic acetylcholine receptors (M₂) for the agonists carbachol and oxotremorine. The affinity for antagonists was not affected. Phospholipase C activity, i.e., the cleavage of polar heads of membrane phospholipids, led to the disappearance of the guanine nucleotide-dependent rightward shift of the isotherm for agonist binding. The treatment of tracheal smooth muscle with phospholipase C led to a decrease in the maximum contractile effect of muscarinic (M₂) stimulation with no modification of the agonist EC₅₀, i.e., to the uncoupling of the stimulation-contraction process. These results demonstrate that when phospholipid polar heads are hydrolysed by phospholipase C, M₂ receptors are uncoupled from G proteins, which enhances their affinity for agonists but prevents information transfer.     

Effect of Phospholipase Digestion and Lysophosphatidylcholine on Dopamine Receptor Binding

[3H]Spiperone specific binding by microsomal membranes isolated from sheep caudate nucleus is decreased by trypsin and phospholipase A2 (Vipera russeli), but is insensitive to neuraminidase. The inhibitory effect of phospholipase A2 is correlated with phospholipid hydrolysis. After 15 min of phospholipase (5 micrograms/mg protein) treatment, a maximal effect is observed; the maximal lipid hydrolysis is about 56% and produces 82% reduction in [3H]spiperone binding. Equilibrium binding studies in nontreated and treated membranes showed a reduction in Bmax from a value of 388 +/- 9.2 fmol/mg protein before phospholipase treatment to a value of 52 +/- 7.8 fmol/mg protein after treatment, but no change in affinity (KD = 0.24 +/- 0.042 nM) was observed. Albumin washing of treated membranes removes 47% of lysophosphatidylcholine produced by phospholipid hydrolysis without recovering [3H]spiperone binding activity. However, the presence of 2.5% albumin during phospholipase A2 action (1.5 micrograms/mg protein) prevents the inhibitory effect of phospholipase on [3H]spiperone binding to the membranes, although 28% of the total membrane phospholipid is hydrolysed. Lysophosphatidylcholine, a product of phospholipid hydrolysis, mimics the phospholipase A2 effect on receptor activity, but the [3H]spiperone binding inhibition can be reversed by washing with 2.5% defatted serum albumin. Addition of microsomal lipids to microsomal membranes pretreated with phospholipase does not restore [3H]spiperone stereospecific binding. It is concluded that the phospholipase-mediated inhibition of [3H]spiperone binding activity results not only from hydrolysis of membrane phospholipids, but also from an alteration of the lipid environment by the end products of phospholipid hydrolysis.     

The role of lipid-protein interactions in NADH-cytochrome c reductase (rotenone-insensitive) of rat liver mitochondria

The phospholipid depletion of rat liver mitochondria, induced by acetone-extraction or by digestion with phospholipase A₂ or phospholipase C, greatly inhibited the activity of NADH-cytochrome c reductase (rotenone-insensitive). A great decrease of the reductase activity also occurred in isolated outer mitochondrial membranes after incubation with phospholipase A₂. The enzyme activity was almost completely restored by the addition of a mixture of mitochondrial phospholipids to either lipid-deficient mitochondria, or lipid-deficient outer membranes. The individual phospholipids present in the outer mitochondrial membrane induced little or no stimulation of the reductase activity. Egg phosphatidylcholine was the most active phospholipid, but dipalmitoyl phosphatidylcholine was almost ineffective. The lipid depletion of mitochondria resulted in the disappearance of the non-linear Arrhenius plot which characterized the native reductase activity. A non-linear plot almost identical to that of the native enzyme was shown by the enzyme reconstituted with mitochondrial phospholipids. Triton X-100, Tween 80 or sodium deoxycholate induced only a small activation of NADH-cytochrome c reductase (rotenone-insensitive) in lipiddeficient mitochondria. The addition of cholesterol to extracted mitochondrial phospholipids at a 1 : 1 molar ratio inhibited the reactivation of NADH-cytochrome c reductase (rotenone-insensitive) but not the binding of phospholipids to lipid-deficient mitochondria or lipid-deficient outer membranes.These results show that NADH-cytochrome c reductase (rotenone-insensitive) of the outer mitochondrial membrane requires phospholipids for its activity. A mixture of phospholipids accomplishes this requirement better than individual phospholipids or detergents. It also seems that the membrane fluidity may influence the reductase activity.     

Effect of membrane sterol content on the susceptibility of phospholipids to phospholipase A2

The effects of membrane sterol level on the susceptibility of LM cell plasma membranes to exogenous phospholipases A2 has been investigated. Isolated plasma membranes, containing normal or decreased sterol content, were prepared from mutant LM cell sterol auxotrophs. beta-Bungarotoxin-catalyzed hydrolysis of both endogenous phospholipids and phospholipids introduced into the membranes with beef liver phospholipid exchange proteins was monitored. In both cases, phosphatidylcholine (PC) and phosphatidylethanolamine (PE) were degraded at similar rates in normal membranes, while PC hydrolysis was specifically accelerated in sterol-depleted membranes. Additional data suggest that this preferential hydrolysis of PC is not a consequence of the phospholipid head group specificity of the phospholipase, nor of a difference in the accessibility of PC versus PE to the enzyme. Analysis of the reaction products formed during treatment of isolated membranes with phospholipase A2 showed almost no accumulation of lysophospholipids. This was found to be due to highly active lysophospholipase(s), present in LM cell plasma membranes, acting on the lysophospholipids formed by phospholipase A2 action. A soluble phospholipase A2 was partially purified from LM cells and found to behave as beta-bungarotoxin with regard to membrane sterol content. These results demonstrate that the nature of phospholipid hydrolysis, catalyzed by phospholipase A2, can be significantly affected by membrane lipid composition.     

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.     

Characterization of an 11,000-dalton beta-bungarotoxin: binding and enzyme activity on rat brain synaptosomal membranes

The binding and phospholipase A2 activity of an 11,000-dalton beta-bungarotoxin, isolated from Bungarus multicincutus venom, have been characterized using rat brain subcellular fractions as substrates. 125I-labeled beta-bungarotoxin binds rapidly (k = 0.14 min-1 and 0.11 min-1), saturably (Vmax = 130.1 +/- 5.0 fmoles/mg and 128.2 +/- 7.1) fmoles/mg), and with high affinity (apparent Kd = 0.8 +/- 0.1 nM and 0.7 +/- 0.1 nM) to rat brain mitochondria and synaptosomal membranes, respectively, but not to myelin. The binding to synaptosomal membranes is inhibited by divalent cations and by pretreatment with trypsin. The binding results suggest that the toxin binds to specific protein receptor sites on presynpatic membranes. The 11,000-dalton toxin rapidly hydrolyzes synaptosomal membrane phospholipids to lysophosphatides and manifests relative substrate specificity in the order phosphatidyl ethanolamine greater than phosphatidyl choline greater than phosphatidyl serine. These results indicate that the 11,000-dalton beta-bungarotoxin is a phospholipase A2 and can use presynaptic membrane phospholipids as substrates. The binding, phospholipase activity and other biological properties of the 11,000-dalton toxin are contrasted with those of the beta-bungarotoxin found in highest concentration in the venom (the 22,000-dalton beta-bungarotoxin), and the two toxins are shown to have qualitatively similar properties. Finally the results are shown to support the hypothesis that beta-bungarotoxins act in a two-step fashion to inhibit transmitter release: first, by binding to a protein receptor site on the presynatic membrane associated with Ca2+ entry, and second, by perturbing through enzymatic hydrolyses the phospholipid matrix of the membrane and thereby causing an increase in passive Ca2+ permeability.     

Characterization of an 11,000-Dalton β-Bungarotoxin: Binding and Enzyme Activity on Rat Brain Synaptosomal Membranes

The binding and phospholipase A₂ activity of an 11,000-dalton β-bungarotoxin, isolated from Bungarus multicinctus venom, have been characterized using rat brain subcellular fractions as substrates. 1z51-labeled p-bungarotoxin binds rapidly (k = 0.14 min-l and 0.1 1 min-l), saturably (V max = 130.1 -+- 5.0 fmoles/mg and 128.2 ±7.1 fmoles/mg), and with high affinity (apparent KCI = 0.8 ± 0.1 nM and 0.7 ± 0.1 nM) to rat brain mitochondria and synaptosomal membranes, respectively, but not to myelin. The binding to synaptosomal membranes is inhibited by divalent cations and by pretreatment with trypsin. The binding results suggest that the toxin binds to specific protein receptor sites on presynaptic membranes. The 1 1,000-dalton toxin rapidly hydrolyzes synaptosomal membrane phospholipids to lysophosphatides and manifests relative substrate specificity in the order phosphatidyl ethanolamine > phosphatidyl choline > phosphatidyl serine. These results indicate that the 1 1,000-dalton p-bungarotoxin is a phospholipase A2 and can use presynaptic membrane phospholipids as substrates. The binding, phospholipase activity and other biological properties of the 1 1,000-dalton toxin are contrasted with those of the p-bungarotoxin found in highest concentration in the venom (the 22,000-dalton p-bungarotoxin), and the two toxins are shown to have qualitatively similar properties. Finally the results are shown to support the hypothesis that p-bungarotoxins act in a two-step fashion to inhibit transmitter release: first, by binding to a protein receptor site on the presynaptic membrane associated with Ca2+ entry, and second, by perturbing through enzymatic hydrolyses the phospholipid matrix of the membrane and thereby causing an increase in passive Ca2+ permeability.     

Activation of phospholipase hydrolysis in the process of oxidative cell damage]

Effect of tert-butyl hydroperoxide toxic action on phospholipase A2 activity and the changes in phospholipid composition from mastocytoma P815 cells were investigated. Oxidative damage of tumor cell membranes was accompanied by the release of arachidonic acid from membrane phospholipids and the accumulation of lysophosphatidylcholine, the product of phospholipase A2 reaction and a potent detergent. Tert-butyl hydroperoxide also increased relative contents of sphingomyelin, phosphatidylserine and phosphatidic acid in tumor cell membranes. It is possible that phospholipase A2 activation and the changes of phospholipid molecular species contents may cause the damage of cell membrane stability.     

Involvement of distinct populations of phosphatidylglycerol and phosphatidylcholine molecules in photosynthetic electron-flow activities

When spinach thylakoid membranes were treated with pancreatic phospholipase A₂, phospholipids were degraded and the uncoupled non-cyclic electron-flow activity (from H₂O to NADP⁺) was progressively inhibited. To discriminate between the relative contributions of the hydrolysis products (free fatty acids and lysophospholipids) and of the phospholipid depletion per se to inhibit the activity, we made use of the known property of bovine serum albumin to remove such hydrolysis products from membranes. Using careful washings and adequate lipid extraction procedures, we could ascertain that all hydrolysis products generated by phospholipase A₂ were effectively removed from the thylakoid membrane by bovine serum albumin treatment. When bovine serum albumin was added to thylakoid membranes after various incubation times with the phospholipase A₂, the electron-flow activity was rapidly, but not completely restored. However, when phospholipid hydrolysis exceeded a certain extent (70–85%), the activity was totally inhibited and its restoration by albumin was no longer possible. Addition of EGTA to the phospholipase A₂-treated membranes blocked both the enzyme action and the progress of electron-flow inhibition. Under these conditions, the amplitude of the albumin-induced restoration of electron-flow rate did not depend on the time span between EGTA block and albumin addition. We show that phospholipid depletion of thylakoid membranes is entirely responsible for the irreversible (albumin-insensitive) inhibition of the electron flow from H₂O to NADP⁺ by phospholipase A₂. Plotting the extent (%) of this inhibition vs. the extent (%) of phospholipid depletion allowed us to distinguish three populations of both phosphatidylglycerol and phosphatidylcholine. The first one, which was easily accessible to the enzyme, did not support greatly the electron-flow activity (around 40% of each phospholipid destroyed vs. only 10% or less inhibition). On the other hand, the electron-flow activity strongly depended on the second, less accessible population of phospholipids (around 40% of each phospholipid destroyed vs. 90% inhibition). Finally, the third population of phospholipids was not involved in the uncoupled non-cyclic electron flow activity.     

Phospholipid dependence of rat liver microsomal acyl: CoA synthetase and acyl-CoA : 1-Acyl-sn-glycero-3-phosphocholine O-acyltransferase

Summary Investigations were performed on the influence of the phospholipid composition and physicochemical properties of the rat liver microsomal membranes on acyl-CoA synthetase and acyl-CoA : 1-acyl-sn-glycero-3-phosphocholine O-acyltransferase activities. The phospholipid composition of the membranes was modified by incubation with different phospholipids in the presence of lipid transfer proteins or by partial delipidation with exogenous phospholipase C and subsequent enrichment with phospholipids. The results indicated that the incorporation of phosphatidylglycerol, phosphatidylserine and phosphatidylethanolamine induced a marked activation of acyl-CoA synthetase for both substrates used—palmitic and oleic acids. Sphingomyelin occurred as specific inhibitor for this activity especially for palmitic acid. Palmitoyl-CoA: and oleoyl-CoA : lacyl-sn-glycero-3-phosphocholine acyltransferase activities were found to depend on the physical state of the membrane lipids. The alterations in the membrane physical state were estimated using two different fluorescent probes—1,6-diphenyl-1,3,5-hexatriene and pyrene. In all cases of membrane fluidization this activity was elevated. On the contrary, in more rigid membranes obtained by incorporation of sphingomyelin and dipalmitoylphosphatidylcholine, acyltransferase activity was reduced for both palmitoyl-CoA and oleoyl-CoA. We suggest a certain similarity in the way of regulation of membrane-bound acyltransferase and phospholipase A₂ which both participate in the deacylation-reacylation cycle.     

Membrane lipids as intracellular binders of chlorpromazine and related drugs

Equilibrium dialysis studies with chlorpromazine (CPZ) showed affinity and binding capacity values which were not significantly different with the following binders: rat liver microsomes, mitochondria, mitochondrial membranes, brain synaptosomes, myelin vesicles, and red blood cell membranes. There was no binding to cytosol or mitochondrial matrix. The same binding values as above were obtained with protein-free liposomes of lipids extracted from microsomes, mitochondrial and red cell membranes and of pure egg lecithin. The binding values of the two classes of binding sites of all these preparations were K₁ = 2.7 ± 1.0 · 10⁴ M^?1, K₂ = 3.8 ± 1.7 · 10³ M^?1, C₁ = 580 ± 230 and C₁₊₂ = 1410 ± 500 nmole/mg phospholipid. These values were not altered by elimination of the polar head groups of phospholipids with phospholipase C. The results were confirmed by a UV spectroscopic method whereby the strongest binding signals were obtained with CPZ in the presence of fatty acids such as oleate. It is concluded that the major intracellular binders for CPZ and related drugs are the nonpolar moieties of membrane phospholipids, whereby hydrophobic interactions are mainly involved.     

Effect of phospholipase A on the structure and functions of membrane vesicles from Mycobacterium phlei.

The phospholipid composition of the electron transport particles and coupling factor-depleted electron transport particles of Mycobacterium phlei are the same, but they differ in contents. The accessibility of partially purified phospholipase A to these membrane phospholipids was found to be different. Treatment of membranes of Mycobacterium phlei with phospholipase A impairs the rate of oxidation as well as phosphorylation. The inhibition of phosphorylation can be reversed by washing the membranes with defatted bovine serum albumin. The reconstitution of membrane-bound coupling factor-latent ATPase activity to phospholipase A-treated depleted electron transport particles and their capacity to couple phosphorylation to oxidation of substrates remained unaffected after phospholipase A treatment. However, the pH gradient as measured by bromthymol blue was not restored after reconstitution of phospholipase A-treated depleted electron transport particles with membrane-bound coupling factor-latent ATPase. These findings show that the phosphorylation coupled to the oxidation of substrates can take place without a pronounced pH gradient in these membrane vesicles. The dye 1-anilino-8-naphthalene sulfonic acid (ANS) exhibited low levels of energized and nonenergized fluorescence in phospholipase A-treated membranes. This decrease in the level of ANS fluorescence in phospholipase A-treated membranes was found to be directly related to the amount of phospholipids cleaved. The decrease in the energy-dependent ANS response in phospholipase A-treated electron transport particles, as compared with untreated electron transport particles, was shown to be a result of a change in the apparent K-d of the dye-membrane complex, and of a decrease in the number of irreversible or slowly reversible binding sites, with no change in the relative quantum efficiency of the dye. The decrease in ANS fluorescence in phospholipase A-treated particles appears to be due to a decrease in the hydrophobicity of the membranes.     

The effect of phospholipase on the binding of asialoglycorproteins by rat liver plasma membranes

The ability of hepatic plasma membrane to bind desialylated glycoproteins has been shown to be markedly diminished by prior treatment of the membranes with phospholipase A or phospholipase C. In the latter case, the decreased binding capacity was correlated with the loss of membrane-bound phosphate over a wide range of enzyme concentration. However, upon solubilization of the membrane associated binding protein, the sensivity to phospholipase-induced inhibition of binding was eliminated.Additional evidence is presented to support the concept that the observed inhibition is a consequence of non-specific changes in the membrane phospholipids and that phospholipid, per se, does not participate directly in the mechanism of binding.     

Phospholipase A2 hydrolysis of membrane phospholipids causes structural alteration of the nicotinic acetylcholine receptor

Thermal perturbation techniques have been used to probe structural alteration of the nicotinic acetylcholine receptor as a function of perturbations of its native membrane environment. Differential scanning calorimetry and a technique involving heat inactivation of the alpha-bungarotoxin-binding sites on the receptor protein reveal that there is a profound destabilization of the acetylcholine receptor structure when receptor-containing membranes are exposed to phospholipase A2. The characteristic calorimetric transition assigned to irreversible denaturation of the receptor protein and the heat inactivation profile of alpha-bungarotoxin-binding sites are shifted to lower temperatures by approx. 7 and 5 C degrees, respectively, upon exposure to phospholipase A2 at a phospholipase/neurotoxin binding site molar ratio of about 1:100. The effects of phospholipase A2 on receptor structure can be (i) reversed by using bovine serum albumin as a scavenger of phospholipase hydrolysis products of membrane phospholipids, and (ii) stimulated by incorporation into the membranes of free, polyunsaturated fatty acids. In particular, linolenic acid (18:3(n-3] causes detectable destabilization of the alpha-bungarotoxin binding sites on the receptor at free fatty acid/receptor molar ratios as low as 10:1. Furthermore, alteration of receptor structure by added phospholipase occurs very rapidly, which is consistent with the observation of rapid in situ phospholipase A2 hydrolysis of membrane phospholipids, particularly highly unsaturated phosphatidylethanolamine and phosphatidylserine. Based on previously published data on the inhibition of acetylcholine receptor cation-gating activity caused by the presence of either phospholipase A2 or free fatty acids (Andreasen T.J. and McNamee M.G. (1980) Biochemistry 19, 4719), we interpret our data as indicative of a correlation between structural and functional alterations of the membrane-bound acetylcholine receptor induced by phospholipase A2 hydrolysis products.     

Lipid-protein interactions in mitochondria. The effect of protein interaction on susceptibility of phospholipids to phospholipase A2 and C hydrolysis.

Phospholipase A₂ (Naja naja) and phospholipase C (from either Clostridium welchii or Bacillus cereus) have been tested on phospholipid dispersions and natural or reconstituted membranes; notwithstanding the different substrate specificities, the different enzymes gave comparable behaviors, suggesting that the results were the expression of sterical features in the lipid bilayers, i.e., availability of the phospholipids to enzymatic attack. The hydrolysis of phospholipids (Asolectin) in sonic protein-free vesicles is hindered by ionic interaction with basic proteins (cytochrome c or lysozyme). On the other hand binding of Asolectin to lipid-depleted mitochondria to obtain reconstituted mitochondria does not prevent phospholipase action on the phospholipids; similarly, phospholipids are hydrolyzed at maximal rates in natural membranes (mitochondria or submitochondrial particles). Surprisingly, ionic interaction of RM or natural membranes with basic proteins does not prevent phospholipase hydrolysis of the membrane phospholipids. The interpretation of this phenomenon may be related to the heterogeneity of phospholipid distribution in protein-containing membranes.     

Lipid Peroxides in the Free Radical Pathophysiology of Brain Diseases

1. Polyunsaturated fatty acids are essential for normal neural cell membrane functioning because many membrane properties, such as fluidity and permeability, are closely related to the presence of unsaturated and polyunsaturated side chains. Lipid peroxidation results in loss of membrane polyunsaturated fatty acids and oxidized phospholipids as polar species contributing to increased membrane rigidity.2. Polyunsaturated fatty acids are released from membrane phospholipids by a number of enzymic mechanisms involving the receptor-mediated stimulation of phospholipase A₂ and phospholipase C/diacylglycerol lipase pathways.3. The overstimulation of excitatory amino acid (EAA) receptors stimulates the activities of lipases and phospholipases, and this stimulation produces changes in membrane phospholipid composition, permeability, and fluidity, thus decreasing the integrity of plasma membranes.4. Alterations in properties of plasma membranes may be responsible for the degeneration of neurons seen in neurodegenerative diseases. Two major processes may be involved in neuronal injury caused by the overstimulation of EAA receptors. One is a large Ca²⁺ influx and the other is an accumulation of free radicals and lipid peroxides as a result of neural membrane phospholipid degradation. It is suggested that calcium and free radicals act in concert to induce neuronal injury in acute trauma (ischemia and spinal cord injury) and in neurodegenerative diseases.     

Identification of specific [3H]adenine-binding sites in rat brain membranes

We recently reported that adenine acts as a neurotrophic factor independent of adenosine or P2 receptors in cultured Purkinje cells [Watanabe S. et al. (2003) J. Neurosci. Res. 74, 754-759], suggesting the presence of specific receptors for adenine in the brain. In this study, the characterization of adenine-binding activity in the rat brain was performed to further characterize the receptor-like adenine-binding sites. Specific binding sites for [(3)H]adenine were detected in membrane fractions prepared from rat brains. The kinetics of [(3)H]adenine binding to membranes was described by the association and dissociation rate constants, 8.6 x 10(5) M(-1) min(-1) and 0.118 +/- 0.045 min(-1), respectively. A single binding site for [(3)H]adenine with a K (D) of 157.1 +/- 20.8 nM and a B (max) of 16.3 +/- 1.1 pmol/mg protein (n = 6) was demonstrated in saturation experiments. A displacement study involving various related compounds showed that the [(3)H]adenine binding was highly specific for adenine. It was also found that [(3)H]adenine-binding activity was inhibited by adenosine, although other adenosine receptor ligands were ineffective as to [(3)H]adenine binding. The brain, especially the cerebellum and spinal cord, showed the highest [(3)H]adenine-binding activity of the tissues examined. These results are consistent with the presence of a novel adenine receptor in rat brain membranes.     

Phylogenetic distribution of [3H]cyclohexyladenosine binding sites in nervous tissue

The specific binding of the A1 adenosine receptor ligand, [3H]CHA, was investigated in membrane fractions prepared from brains of eleven vertebrate species and ganglia of four invertebrate species. Substantial amounts of specific [3H]CHA binding sites were demonstrated in brain membranes of all vertebrate species examined; however, [3H]CHA binding sites were not detectable in nervous tissue of the invertebrate species studied. The densities of [3H]CHA binding sites in vertebrate brains increase in higher vertebrates. Moreover, the pharmacological characteristics of the site labeled by [3H]CHA in two divergent classes of vertebrates were similar. The broad phylogenetic distribution of A1 adenosine receptors in primitive as well as advanced vertebrate species suggests a fundamental role for adenosine in neuronal modulation.