Adenosine receptors in myelin fractions and subfractions: the effect of the agonist (R)-phenylisopropyladenosine on myelin membrane microviscosity

Involvement of adenosine in the neurobiology of schizophrenia and its therapeutic implications

Based on the neuromodulatory and homeostatic actions of adenosine, adenosine dysfunction may contribute to the neurobiological and clinical features of schizophrenia. The present model of adenosine dysfunction in schizophrenia takes into consideration the dopamine and glutamate hypotheses, since adenosine exerts neuromodulatory roles on these systems, and proposes that adenosine plays a role in the inhibitory deficit found in schizophrenia. Given the role of adenosine activation of adenosine A1 receptor (A1R) in mediating neurotoxicity in early stages of brain development, pre- and peri-natal complications leading to excessive adenosine release could induce primary brain changes (i.e., first hit). These events would lead to an adenosine inhibitory deficit through a partial loss of A1R that may emerge as reduced control of dopamine activity and increased vulnerability to excitotoxic glutamate action in the mature brain (i.e., second hit). Adenosine dysfunction is reasonably compatible with symptoms, gray and white matter abnormalities, progressive brain loss, pre- and peri-natal risk factors, age of onset, response to current treatments, impaired sensory gating and increased smoking in schizophrenia. Pharmacological treatments enhancing adenosine activity could be effective for symptom control and for alleviating deterioration in the course of the illness. Accordingly, allopurinol, which may indirectly increase adenosine, has been effective and well tolerated in the treatment of schizophrenia. Since much of the evidence for the adenosine hypothesis is preliminary and theoretical, further investigation in the field is warranted.

Molecular mechanisms and therapeutical implications of intramembrane receptor/receptor interactions among heptahelical receptors with examples from the striatopallidal GABA neurons

The molecular basis for the known intramembrane receptor/receptor interactions among G protein-coupled receptors was postulated to be heteromerization based on receptor subtype-specific interactions between different types of receptor homomers. The discovery of GABAB heterodimers started this field rapidly followed by the discovery of heteromerization among isoreceptors of several G protein-coupled receptors such as delta/kappa opioid receptors. Heteromerization was also discovered among distinct types of G protein-coupled receptors with the initial demonstration of somatostatin SSTR5/dopamine D2 and adenosine A1/dopamine D1 heteromeric receptor complexes. The functional meaning of these heteromeric complexes is to achieve direct or indirect (via adapter proteins) intramembrane receptor/receptor interactions in the complex. G protein-coupled receptors also form heteromeric complexes involving direct interactions with ion channel receptors, the best example being the GABAA/dopamine D5 receptor heteromerization, as well as with receptor tyrosine kinases and with receptor activity modulating proteins. As an example, adenosine, dopamine, and glutamate metabotropic receptor/receptor interactions in the striatopallidal GABA neurons are discussed as well as their relevance for Parkinson's disease, schizophrenia, and drug dependence. The heterodimer is only one type of heteromeric complex, and the evidence is equally compatible with the existence of higher order heteromeric complexes, where also adapter proteins such as homer proteins and scaffolding proteins can exist. These complexes may assist in the process of linking G protein-coupled receptors and ion channel receptors together in a receptor mosaic that may have special integrative value and may constitute the molecular basis for some forms of learning and memory.

Regulation of heptaspanning-membrane-receptor function by dimerization and clustering

G-protein-coupled receptors form homomers and heteromers; agonist-induced conformational changes within interacting receptors of the oligomer modify their pharmacology, signalling and/or trafficking. When these receptors are activated, the oligomers rearrange and cluster and a novel mechanism of receptor-operation regulation by oligomer intercommunication is possible. This intercommunication would be assisted by components of the plasma membrane and by scaffolding proteins. Receptor cross-sensitization, cross-desensitization and novel, integrated receptor responses can then develop between oligomeric receptor complexes of the cluster without direct contact between them. This concept gives a new perspective to the understanding of neurotransmission and neuronal plasticity.

Fatty acid synthesizing enzymes intrinsic to myelin

A recent study showing incorporation of acetyl groups from neuronal N-acetylaspartate into myelin lipids suggested the presence of fatty acid synthesizing enzymes in myelin that utilize the acetyl groups liberated by myelin-associated aspartoacylase [J. Neurochem. 78 (2001) 736]. We report here detection of the fatty acid synthase (FAS) complex and acetyl-CoA carboxylase (ACC) in purified myelin. The activity of myelin FAS was approximately half that of cytosolic FAS and, unlike the latter, required detergent for activation. Intrinsic association of FAS with myelin was indicated by failure to remove the activity with NaCl or Na-taurocholate. Myelin-associated ACC was approximately 10% of cytosolic ACC in myelin isolated by gradient centrifugation, and this was reduced by half following osmotic shock; this suggested bimodal distribution of myelin ACC, some being loosely associated within inter-lamellar cytoplasmic spaces and the remainder more firmly associated in a manner that resists NaCl/Na-taurocholate treatments. These results, in combination with earlier findings, provide a possible mechanism for the observed incorporation of neuronal NAA acetyl groups into myelin lipids.

Myelin contains neutral sphingomyelinase activity that is stimulated by tumor necrosis factor-alpha

Purified myelin from mouse brain was found to contain two forms of neutral sphingomyelinase, one Mg2+ dependent and the other Mg2+ independent. The former had a pH optimum of 7.5 and Km of 0.35 mM, whereas the corresponding values for the latter were pH 8.0 and Km 3.03 mM. Specific activity of the Mg(2+)-dependent enzyme showed a rostral-caudal gradient, ranging from 75 nmol/mg protein/hr in myelin from cerebral hemispheres to 21 nmol/mg protein/hr in myelin from spinal cord. Relative specific activity was approximately 20% that of brain stem or cerebral hemisphere homogenate. Treatment of myelin with taurocholate or high salt concentration did not significantly reduce activity of the Mg(2+)-dependent enzyme. The activity of that enzyme did not change with time or in the presence or absence of protease inhibitors; by contrast, that of Mg(2+)-independent enzyme decreased sharply in the absence of protease inhibitors but rose in their presence. To test for the effect of tumor necrosis factor-alpha (TNF alpha) on myelin sphingomyelinase, mouse brain myelin was labeled in vivo by intracerebral injection of [3H]acetate into 18-20-day-old mice. After 40 hr, brain stems were removed, minced, and treated with TNF alpha in Krebs-Ringer solution, after which myelin was immediately isolated. Separation and counting of individual lipids revealed TNF alpha treatment to cause increased labeling of myelin ceramide and cholesterol ester with concomitant decrease in myelin sphingomyelin. Western blotting of myelin proteins using antibodies to the two TNF alpha receptors as probes revealed the presence of the p75 receptor. Implications of these findings in relation to possible mechanisms of autoimmune demyelination are discussed.

Characterization of guanylyl cyclase in purified myelin

This study was undertaken to characterize the enzymatic properties of the particulate guanylyl cyclase previously shown to be present at a high level of activity in purified rat brain myelin. Significant activation was achieved by both Lubrol-PX and Triton X-100, the latter being somewhat more effective. A pH optimum of 7.8 was observed, compared to 7.4 for microsomes. Employing 1.2 mM GTP with 1% Triton X-100, linearity of response was observed up to 60 min and approximately 1.2 mg of myelin protein. Kinetic analysis revealed Km values of 0.258mM and 0.486mM for myelin and microsomes, respectively, similar values being obtained by Lineweaver-Burke analysis or Direct Linear Plot. Vmax values were 20 and 266 pmol/mg protein/min for myelin and microsomes, respectively. Washing of the myelin with 0.5 M NaCl or 0.1% Na taurocholate did not remove a significant amount of guanylyl cyclase activity, indicating the enzyme to be intrinsic to the myelin sheath.

Ionic fluxes through myelin membrane vesicles

Technical difficulties and a lack of reproducibility in procedures aimed at the production of myelin vesicles have delayed functional studies on membrane transport through myelin. Myelin vesicles could provide an excellent model for the study of the transport of ions and water, etc., across this type of membrane. They could also help improve our understanding of the molecular functions of the myelin sheath. In this investigation, a novel, nonaggressive method of producing central nervous system myelin vesicles is presented. Purified bovine myelin was incubated with iminodiacetic acid (an insoluble chelating agent that is easy to remove and does not interfere with further functional assays), and rendered insoluble on 1% crosslinked polystyrene beads (Chelex-100). Myelin vesicles obtained were impermeable to sugars (sucrose, glucose, and galactose), but showed a degree of permeability towards potassium salts as determined by light-scattering. Further experiments with fluorescent probes revealed an electrogenic K+ influx, as measured by oxonol V fluorescence quenching, and a significant H+ permeability measured using the pH-sensitive probe acridine orange. H+ permeability was not detected in control liposomes made from the same endogenous myelin lipids without protein. The results are discussed with reference to previous studies performed using purified myelin proteins in reconstituted systems. The relevance of these results with respect to ionic transport across myelin membrane is discussed.

A1 adenosine receptors can occur manifesting two kinetic components of 8-cyclopentyl-1,3-[3H]dipropylxanthine ([3H]DPCPX) binding

The results described in this paper show, for the first time, that A1 adenosine receptors can have two kinetic components for the binding of the antagonist [3H]DPCPX. At low ionic strength (< or = 42 mmol/l), dissociation of [3H]DPCPX bound to A1 receptors fitted better to a two kinetic components model than to a one kinetic component model. The kinetic constants were consistent with comparable Kd values for the two components of the antagonist binding, and therefore these two components cannot be distinguished by saturation isotherm analysis.

Role of histidine residues in agonist and antagonist binding sites of A1 adenosine receptor

The influence of pH on the equilibrium dissociation constant and on kinetic association and dissociation constants was studied for adenosine receptor agonist L-N6-[adenine-2,8-3H, ethyl-2-3H]phenylisopropyladenosine ([3H]R-PIA) and antagonist 8-cyclopentyl-1,3-[3H]-dipropylxanthine ([3H]DPCPX). Two ionizable groups, of pK 7.0 and pK 7.4, are involved in the [3H]R-PIA associations with high- and low-affinity states of the receptor, and another group, of pK 6.0, is involved in the association with the low-affinity state. No ionizable group is involved in the dissociation process for the high-affinity state, whereas two ionizable groups, of pK 6.0 and 6.5, are involved in the low-affinity state. For [3H]DPCPX, three ionizable groups (pK 6.0, 7.4, and 8.0) are involved in the association process and only one group, (pK 6.0), is involved in the dissociation step. The apparent pK values obtained agree with histidine residues. We thus studied the effect of diethylpyrocarbonate (DEP), which reacts irreversibly with histidine residues, on agonist and antagonist binding to A1 adenosine receptors from pig brain cortical membranes. DEP treatment of membrane reduced the affinity (KD) and the total binding (R) of the agonist and the antagonist. Membrane preincubation with unlabeled ligand (R-PIA or DPCPX) prevented the effect of DEP modification observed when the same ligand, but with label, is added to the same membranes, but did not prevent the DEP modification on different, labeled ligand.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of adenosine receptors in brush-border membranes from pig kidney

1. The adenosine receptors from pig kidney proximal tubules have been studied in membrane vesicle preparations derived from either luminal (brush-border membranes-BBM-) or basolateral (BL) sides. There was a substantial amount of A2-like NECA binding in both preparations, but the A1 subtype of adenosine receptors was not found in either BBM or BL membranes. The use of [3H]-CGS21680 which is a more specific ligand for A2a receptors revealed true adenosine receptors in the BBM. 2. The kinetic parameters for [3H]-CGS21680 binding to pig renal BBM were: Bmax = 1.48 pmol mg-1 protein and Kd = 150 nM. In the presence of Gpp(NH)p the affinity decreased (Kd = 220 nM), whereas the addition of Mg2+ induced a marked increase in affinity (Kd = 83 nM). These equilibrium constants are higher than those found for the A2a adenosine receptors present in pig brain striatal membranes (Kd = 12 nM), and are close to those found in rat renal BBM (Kd = 90 nM). 3. The order of potency of agonist and antagonists was not consistent with the presence of either A1 or A2 receptors, but it was very similar to the agonist order of potency for the A3 receptor subtype. Furthermore, the blockade of the [3H]-CGS21680 binding by both cholera and pertussis toxin further supports the view that the subtypes present in BBM are neither A1 nor A2. 4. Overall the results suggest the presence in BBM of an A3 receptor, or of a new subtype of adenosine receptor, which is linked to G proteins sensitive to both cholera and pertussis toxins.

The distribution of A1 adenosine receptor and 5'-nucleotidase in pig brain cortex subcellular fractions

Pig brain cerebral cortex was subfractionated by isopycnic centrifugation in sucrose gradients. In each subfraction the content of the agonist [3H]R-PIA binding, the activity of adenosine metabolizing enzymes (5'-nucleotidase and adenosine deaminase) and the activity of membrane marker enzymes were determined. The fractions were also examined by electron microscope. In general, the results suggest a widespread distribution of A1 adenosine receptors in membranes from different origins. Marker enzyme profile characterization indicated an enrichment of A1 adenosine receptor in pre-synaptic membranes isolated from the crude synaptosomal fraction (P2B subfraction) as well as in membranes of glial origin such as myelin. The receptor is also present in the endoplasmic reticulum and in membranes isolated from the microsomal fraction that seem to have a post-synaptic origin (P3B). In subfractions having a high content of adenosine receptor the equilibrium binding parameters were obtained as well as the proportion of high- to low-affinity sites. From the values of the equilibrium constants it was not possible to find differences between the receptor in the different subfractions. Analysis of the affinity state distribution showed a diminished percentage of high-affinity sites in fraction P3A, which can be accounted by the existence of myelin membranes; in contrast the percentage of high-affinity states was higher in P2 and P3B, indicating that in these fractions the receptor is present in synaptosomal membranes. The close correlation shown between the enzyme 5'-nucleotidase specific activity and the specific ligand binding distributions led us to postulate an important role for the enzyme in the regulation of adenosine action in pig brain cortex.

Modulation of adenosine agonist [3H]N6-(R)-phenylisopropyladenosine binding to pig brain cortical membranes by changes of membrane fluidity and of medium physicochemical characteristics

The binding of [3H]N6-(R)-phenylisopropyladenosine ([3H]R-PIA) to pig brain cortical membranes was investigated as a function of membrane fluidity and of the physicochemical characteristics of the medium. The two affinity states of the A1 adenosine receptor behave differently in the experiments performed. Increases (up to 6.7 poises) or reduction (up to 1.3 poises) in membrane microviscosity did not lead to significant variation of equilibrium parameter values except for a slight modification of the low-affinity Kd value at 1.3 poises. Addition of cholesterol to raise the microviscosity up to 9.0 poises led to a marked decrease of binding to the high-affinity state without modifying the Kd. Furthermore, the Kd value for the low-affinity state rose markedly. Addition of sucrose, which modifies the conductance, viscosity and density of the aqueous medium, did not lead to significant changes when used at a concentration of 0.25 M, either in isolation or in radioligand binding assay medium. The presence of 0.32 M sucrose in the isolation medium led to a 30% fall in the total binding without affecting the distribution and Kd values for either affinity state very much. However, the presence of greater than or equal to 0.32 M sucrose in the binding assay medium produced the disappearance of the low-affinity states and the appearance of high-affinity states; only one affinity state was found to have a somewhat increased Kd value. On the other hand, increases of the medium conductance did not lead to the disappearance of the low-affinity state although some decrease of the binding was observed at high Tris concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)