The rapid uptake and release of [3H]adenosine by rat cerebral cortical synaptosomes

Similarities of adenosine uptake systems in astrocytes and neurons in primary cultures

Uptake of extracellular adenosine was studied in primary cultures of astrocytes or neurons. Both cell types showed a high affinity uptake. The Km values were not significantly different (6.5 +/- 3.75 microM in astrocytes and 6.1 +/- 1.86 microM in neurons), but the intensity of the uptake was higher in astrocytes than in neurons (Vmax values of 0.16 +/- 0.030 and 0.105 +/- 0.010 nmol x min-1 x mg-1 protein, respectively). The temperature sensitivity was similar in the two cell types. Adenosine uptake inhibitors and benzodiazepines inhibited the adenosine uptake systems in both astrocytes and neurons with IC50 values in the high nanomolar or the micromolar range and the rank order of potency was similar in the two cell types. In both cell types the (-) isomers of two sets of benzodiazepine stereoisomers were more potent than the (+) isomers. Dixon analysis showed that dipyridamole, papaverine, hexobendine and chlordiazepoxide inhibited the adenosine uptake competitively and clonazepam noncompetitively in both cell types.

A new class of adenosine receptors in brain. Characterization by 2-chloro[3H]adenosine binding

Micromolar concentrations of adenosine and its analogs have profound depressant effects on neuronal firing and synaptic transmission in many brain areas. Using the adenosine agonist 2-chloro[3H]adenosine (Cl[3H]Ado), we have identified a distinct class of micromolar-affinity adenosine binding sites in rat forebrain membranes. Specific Cl[3H]Ado binding was reversible and saturable with an apparent KD of 9.1 microM and a Bmax of 61 pmoles/mg protein. The present studies were conducted using washed brain membrane fractions not treated with adenosine deaminase. Specific Cl[3H]Ado binding under these conditions was insensitive to (-)-N6-(R-phenylisopropyl)adenosine ((-)PIA) and treatment with 3 mM N-ethylmaleimide, unlike high-affinity A1 adenosine receptor binding. Treatment of membranes with adenosine deaminase revealed an additional population of binding sites sensitive to (-)PIA. Inhibition of Cl[3H]Ado binding by adenosine analogs exhibited an order of potency ClAdo greater than 5'-N-ethylcarboxamide adenosine (NECA) greater than (-)PIA which differs from that of both A1 and A2 adenosine receptors. The potent A1 and A2 receptor antagonist 8-phenyltheophylline had no significant effect on binding up to 10 microM. Specific binding, however, was inhibited by the adenosine antagonists 8(p-sulfophenyl)theophylline, isobutylmethylxanthine, theophylline, and caffeine. Micromolar Cl[3H]Ado binding was highly selective for adenosine agonists and antagonists. These results suggest that the micromolar-affinity Cl[3H]Ado binding sites may represent a novel central purinergic receptor, distinct from the A1 and A2 adenosine receptors involved in the regulation of adenylate cyclase.

Nature of extrasynaptosomal accumulation of endogenous adenosine evoked by K+ and veratridine

When rat brain synaptosomes were incubated for 10 min at 37 degrees C, basal accumulation of adenosine in the medium was 66 pmol/mg of protein. An elevated K+ level (24 mM) evoked an additional accumulation of 200 pmol/mg of protein, and 50 microM veratridine evoked 583 pmol of adenosine accumulation/mg of protein. K+- and veratridine-evoked accumulation of adenosine did not arise from microsomal or mitochondrial contaminants of the synaptosomal preparation, because purified microsomes and mitochondria did not exhibit evoked accumulation of adenosine in the medium. K+-evoked accumulation of extrasynaptosomal adenosine was Ca2+-dependent, whereas veratridine-evoked accumulation of adenosine was increased in Ca2+-free medium. In the presence of alpha,beta-methylene ADP and GMP, which inhibit ecto-5'-nucleotidase, conversion of added ATP and AMP to adenosine was inhibited by 90% in synaptosomal suspensions. However, inhibition of ecto-5'-nucleotidase only reduced basal extrasynaptosomal accumulation of adenosine by 74%, veratridine-evoked accumulation of adenosine by 46%, and K+-evoked accumulation by 33%. Most of the basal accumulation of extrasynaptosomal adenosine appears to be derived from released nucleotide, probably ATP, but about half of the veratridine-evoked accumulation of adenosine and most of the K+-evoked accumulation may arise from adenosine released in its own right, rather than from a released nucleotide.

[3H]adenosine uptake and release from synaptosomes. Alterations by barbiturates

The effects of barbiturates on adenosine movements across the synaptic plasma membrane have been investigated using rodent whole brain synaptosomes. The hypothesis tested was that some of the depressant actions of these drugs may be mediated through interference with an endogenous adenosine system. Adenosine uptake was studied using synaptosomes prepared from Swiss-Webster mice. After preincubation at 37 degrees, [3H]adenosine was added to the synaptosomes in the presence or absence of pentobarbital, methohexital, phenobarbital, or 5-(2-cyclohexylideneethyl)-5-ethyl barbituric acid (CHEB) at various concentrations and times. All four compounds significantly inhibited [3H]adenosine uptake at concentrations of 100-300 microM. Pentobarbital did not affect the distribution of synaptosomal adenosine metabolites. Release of [3H]adenosine was studied using the P2 pellet from male CD-1 mice. Addition of 50 mM KCl caused an enhancement of 3H-efflux mainly due to increased release of adenosine and inosine. This effect was abolished in the presence of 250 microM ethylene glycol bis(beta-aminoethyl-ether)-N,N2-tetraacetic acid (EGTA). Pentobarbital, 0.3 mM, caused a significant increase in the net potassium-induced release of [3H]adenosine. These results suggest that some of the depressant effects of barbiturates may be due to inhibition of adenosine reuptake and enhancement of release resulting in elevated synaptic adenosine levels.

Novel adenosine receptors in rat hippocampus. Identification and characterization

2-Chloro[3H]adenosine, a stable analog of adenosine, was used to investigate the presence of adenosine receptors in rat hippocampal membranes that may mediate the depressant effects of adenosine on synaptic transmission in this tissue. Equilibrium binding studies reveal the presence of a previously undescribed class of receptors with a KD of 4.7 microM and a Bmax of 130 pmol/mg of protein. Binding is sensitive to alkylxanthines and to a number of adenosine-related compounds. The pharmacological properties of this binding site are distinct from those of the A1 and A2 adenosine receptors associated with adenylate cyclase. The results suggest that this adenosine binding site is a novel central purinergic receptor through which adenosine may regulate hippocampal excitability.

Adenosine uptake sites in rat brain: identification using [3H]nitrobenzylthioinosine and co-localization with adenosine deaminase

The binding characteristics of [3H]nitrobenzylthioinosine ([3H]NBI) to rat brain membrane preparations was examined, and the autoradiographic distribution of this ligand in brain sections was compared with the immunohistochemical localization of adenosine deaminase (ADA). It was found that [3H]NBI labels sites for which adenosine has far higher affinity than do other nucleosides, that these sites are heterogeneously distributed and that there is an exact correspondence between areas containing [3H]NBI sites and ADA-immunoreactive neurons. Our results indicate that [3H]NBI and ADA are potential markers for revealing anatomical sites at which actions of adenosine may be expressed.

Transport and metabolism of adenosine in relation to the transcriptional activity of hnRNA genes in Chironomus salivary gland cells

The transport and metabolism of adenosine in explanted salivary gland cells of Chironomus tentans have been investigated. The adenosine transport is rapid and reaches a maximum velocity within seconds after administration. Nevertheless, a transmembrane equilibrium in adenosine concentrations could never be attained because of the efficiency of the intracellular trapping reaction. Only about 10% or less of the extracellular adenosine concentration could be maintained intracellularly. The rapidity of adenosine phosphorylation did not allow us the assessment of transport kinetics with any degree of accuracy. At lower external [3H]adenosine doses, [3H]ATP was the predominating metabolite, yielding a [3H]ATP/[3H]AMP ratio of 2.5-3.5, while at higher concentrations the [3H]ATP/[3H]AMP ratio was lowered to below 0.9. The [3H]AMP fraction derived from [3H]adenosine-treated cells was not uniform, but rather it consisted of 3H-labeled 5'AMP, 3'AMP and 2'AMP isomers. Whereas the accumulation of 3H-labeled 5'AMP and ATP attained steady-state levels after 30-60 min of incubation at higher exogenous adenosine concentrations, the content of 3H-labeled 3'AMP and 2'AMP continuously and linearly increased. The data indicate that the metabolism of adenosine to 2'AMP and 3'AMP represents a salvage pathway operating at unphysiological adenosine levels and that the well-known inhibitory effect of adenosine on polymerase-II-promoted RNA transcription is not exerted by its phosphorylated metabolites.

Estradiol and progesterone potentiate adenosine's depressant action on rat cerebral cortical neurons

The effects of 17 beta-estradiol and progesterone on the uptake of adenosine by rat cerebral cortical synaptosomes have been correlated with the ability of these gonadal steroids to potentiate the depressant actions of adenosine on the spontaneous firing of rat cerebral cortical neurons. 17 beta-estradiol hemisuccinate competitively inhibited adenosine uptake with a Ki of 0.5 microM (Lineweaver-Burk plot) or 0.78 microM (Dixon plot). The Ki for progesterone was 0.34 microM (Lineweaver-Burk plot) or 0.36 microM (Dixon plot). When applied by iontophoresis, both steroids potentiated the depressant effects of adenosine on the firing of rat cerebral cortical neurons. Potentiation of the effect of endogenously released adenosine would account for the central depressant actions of these steroids.

Release of adenosine, inosine and hypoxanthine from rabbit non-myelinated nerve fibres at rest and during activity

The composition of the efflux from desheathed rabbit vagus nerve, loaded with radioactivity by incubation in [3H]adenosine, was studied at rest and during electrical activity and after application of inhibitors of ecto-enzymes and modifications of intermediary metabolism. In addition, the degradation of externally applied ATP and adenosine was examined. [3H]ATP applied to the incubation medium was degraded to ADP, AMP, adenosine and inosine. The hydrolysis to nucleosides was inhibited by alpha, beta-methylene ADP; the appearance of AMP and nucleosides was slowed by beta, gamma-methylene ATP. Deamination of [3H]adenosine was blocked by 2-deoxycoformycin. The effluent from resting and stimulated preparations showed the presence of large amounts of inosine and hypoxanthine, smaller amounts of adenosine and adenine and traces of nucleotides. The composition of the effluent was not significantly altered by addition of alpha, beta-methylene ADP; beta, gamma-methylene ATP or 2-deoxycoformycin. Application of glucose-free solutions caused a large release of adenosine instead of inosine and hypoxanthine and a small increase in resting and stimulated efflux of 3H. Addition of 2-deoxyglucose produced a large increase in resting efflux and increased liberation of adenosine. Cyanide, 2,4-dinitrophenol, arsenate or salicylate increased the resting efflux of adenosine, inosine and hypoxanthine, and the effect of activity. It is concluded that electrical activity leads to release of adenosine, inosine and hypoxanthine, in various proportions depending on metabolic state, and that there is practically no liberation of nucleotides from nerve axons.

Organic calcium channel blockers enhance [3H]purine release from rat brain cortical synaptosomes

The release of [3H]purines was investigated in a crude mitochondrial fraction (P2 fraction) from rat brain cortex pre-loaded with [3H]adenosine for 30 sec at 37 degrees C in vitro. Potassium, veratridine and glutamate were used as depolarizing agents to evoke the release of [3H]purines. Ca2+ removal, the addition of EGTA, and treatment with organic or inorganic Ca2+ antagonists did not inhibit [3H]purine release in this preparation. On the other hand, Ca2+ removal and the addition of EGTA greatly enhanced 3H-purine release induced by glutamate. D-600 and diltiazem enhanced K+-evoked [3H]purine release, and nifedipine increased veratridine evoked [3H]purine release indicating that either these Ca2+ antagonists have different sites of action, or that K+ and veratridine may release [3H]purine from different metabolic pools. Organic Ca2+ antagonists failed to enhance the [3H]purine release evoked by glutamate, further supporting the notion that various depolarizing agents may release [3H]purines from different cellular compartments.

Sodium gradient-energized concentrative transport of adenosine in renal brush border vesicles

The uptake of adenosine in brush border vesicles of the proximal tubule of the rat kidney has been studied with a filtration technique. The initial rate of uptake was almost 6 times greater in the presence of NaCl than in the presence of KCl. The stimulatory effect of Na+ was strictly dependent on a gradient of Na+ (out greater than in). The time course of uptake showed an overshoot with a maximum at 20 s with a gradient of NaCl, but not with KCl. Inosine and 5'-AMP were produced from adenosine within the vesicles. In the presence of an inhibitor or adenosine deaminase adenosine was not significantly metabolized during the first 20 s of uptake. Thus, kinetic parameters of transport could be studied in the absence of interferences with metabolism. A Km of 1.1 microM and a Vmax of 232 pmol X min-1 X mg protein-1 were calculated for the Na+ gradient-dependent transport. The dependency on a Na+ gradient, the capacity for uphill transport and the high affinity for adenosine situate this transport system apart from the mechanisms of transport of nucleosides described so far. It may be relevant in regard to the role of adenosine in the regulation of glomerular filtration.

Further studies on the inhibition of adenosine uptake into rat brain synaptosomes by adenosine derivatives and methylxanthines

Various adenosine derivatives, methylxanthines and other compounds were tested for their abilities to inhibit the rapid uptake of adenosine by rat cerebral cortical synaptosomes. Several pharmacologically potent derivatives of adenosine were weak inhibitors of uptake with IC20 values in excess of 10(-5) M. Derivatives in this category were adenosine-5'-N-ethylcarboxamide, adenosine-5'-cyclopropylcarboxamide, N6-cyclohexyladenosine, L-N6-phenylisopropyladenosine, 1-methylisoguanosine, 2-phenylaminoadenosine and 5-iodotubercidin. Several methylxanthines were very weak inhibitors of adenosine uptake. These included pentoxifylline, n-hexyltheophylline, n-butyltheobromine, and isoamyltheobromine. HL 725, a pyrimido-isoquinoline with potent phosphodiesterase inhibitory activity, inhibited adenosine uptake with an IC20 of 2.0 X 10(-6) M. PK 11195, a putative ligand for the peripheral benzodiazepine binding site did not alter uptake at a concentration of 10(-4) M.

Inhibition of adenosine accumulation by a CNS benzodiazepine antagonist (Ro 15-1788) and a peripheral benzodiazepine receptor ligand (Ro 05-4864)

Although benzodiazepines can inhibit adenosine uptake into central neurones, this effect is not antagonized by behaviourally effective 'benzodiazepine antagonists' such as Ro 15-1788. We now report that Ro 15-1788 and the 'peripheral' benzodiazepine ligand Ro 05-4864 themselves inhibit adenosine accumulation by rat brain synaptosomes. The inhibition of adenosine accumulation may thus underlie those behavioural effects of benzodiazepines which are mimicked but not antagonized by Ro 15-1788.

Uptake of adenosine by cultured cerebral vascular smooth muscle cells

Adenosine uptake by cerebral smooth muscle cells is a carrier-mediated process. The Km value for adenosine uptake is 10.0 microM and the Vmax is 0.95 nmol/min-mg cell protein. This uptake system is inhibited by the adenosine analog 2-chloroadenosine at low adenosine concentrations. These results prove the existence of a nucleoside transport system associated with cerebral smooth muscle.

Uptake of adenosine into cultured cerebral endothelium

Adenosine uptake by cultured cerebral endothelium is a carrier-mediated process. The Km value for adenosine uptake is 5.0 microM and the vmax is 1.15 nmol/min/mg cell protein. The uptake system is inhibited by the adenosine analog 2-chloroadenosine at low adenosine concentrations. The results prove the existence of a nucleoside transport system associated with cerebral capillary endothelium.

Calmodulin antagonists inhibit adenosine uptake by rat brain cortical synaptosomes

The purpose of these experiments was to determine if the adenosine uptake process in brain synaptosomes is regulated by calmodulin. Several calmodulin antagonists including trifluoperazine, W-7 and R24571 were tested for their ability to inhibit adenosine uptake by rat brain cortical synaptosomes. The results indicate that these agents inhibit adenosine uptake in a competitive manner. Their potencies as inhibitors of uptake were in good agreement with those reported for their inhibition of identified calmodulin regulated reactions. It is therefore concluded that the adenosine uptake process in rat brain synaptosomes is regulated by calmodulin or a calmodulin-like protein.

Adenosine transport by primary cultures of neurons from chick embryo brain

The transport of adenosine was studied in pure cultures of neurons from chick embryo brain. In order to avoid complications due to adenosine metabolism, the cells were depleted of ATP by treatment with cyanide and iodoacetate prior to incubation with [3H]adenosine. During the 5-25-s periods used for transport assays, no significant adenosine metabolism was detectable. ATP depletion reduced the initial rate of adenosine entry by less than 10%, but blocked over 90% of the radioactivity accumulated by untreated cells after 15 min. Elimination of sodium or chloride from the uptake medium had no effect on adenosine transport activity. The kinetics of adenosine entry into ATP depleted neurons obeyed the Michaelis-Menten relationship and yielded a Km of 13 microM and Vmax of 0.15 nmol/min/mg protein. The neuronal transport system has apparent selectivity for adenosine, since thymidine, inosine, or guanosine gave significant inhibition only at levels 10-100-fold higher than [3H]adenosine. Adenosine derivatives (N6-cyclohexyl-, N6-benzyl-, N6-methyl-, and 2-chloroadenosine) were more effective inhibitors; p-nitrobenzylthioinosine and dipyridamole were the most potent compounds found. These results describe a high-affinity, facilitated diffusion system for adenosine in cerebral neurons, which could participate in terminating regulatory actions of this compound in the nervous system.

Benzodiazepine inhibition of adenosine uptake is not prevented by benzodiazepine antagonists

Uptake of [3H]adenosine into rat cerebral cortex synaptosomes was studied. Hexobendine (10(-5) M) and the benzodiazepine agonists diazepam (10(-5) M) and flurazepam (10(-4) M) significantly inhibited this uptake, but only if the compounds were pre-incubated for 10 min in the case of the benzodiazepines. The benzodiazepine antagonists Ro15-1788 (10(-5) M) and CGS 8216 (10(-5) M) failed to reverse the action of benzodiazepine agonists or hexobendine on [3H]adenosine uptake. The results add weight to the view that inhibition of adenosine uptake processes by benzodiazepines do not contribute to their behavioural effects.

Adenosine metabolism in a rat hippocampal slice preparation: incorporation into S-adenosylhomocysteine

The incorporation of [14C]adenosine into various metabolites was studied in a hippocampal slice preparation in order to assess the extent of adenosine metabolism via synthesis of S-adenosylhomocysteine, a potent inhibitor of transmethylation reactions. Highest incorporation of 14C occurred into nucleotides, with only a few percent being recovered in inosine + hypoxanthine, S-adenosylhomocysteine, and the free adenosine pool. Labeling of S-adenosylhomocysteine did not significantly increase with higher concentrations of added adenosine despite greater accumulation of free [14C]adenosine in the tissue. Addition of L-homocysteine significantly increased the labelling of S-adenosylhomocysteine. The results indicate that S-adenosylhomocysteine synthesis is a minor pathway of adenosine metabolism in brain tissue under steady-state conditions. Further, changes in adenosine concentration, without a concomitant change in L-homocysteine availability, are unlikely to lead to a significant accumulation of S-adenosylhomocysteine. S-Adenosylhomocysteine is therefore not likely to play a significant role in mediating the biological effects of adenosine in the CNS via inhibition of transmethylations.

Inhibition of adenosine uptake into rat brain synaptosomes by prostaglandins, benzodiazepines and other centrally active compounds

A number of compounds have been tested for their abilities to inhibit the rapid uptake of adenosine by rat cerebral cortical synaptosomes. Prostaglandins PGI2, PGA2, and PGE1 and PGE2 were potent inhibitors of adenosine uptake with IC20 values in the 10(-7) M-10(-6) M range. PGA1, PGD2 and PGF2 alpha also inhibited uptake but were less active. The benzodiazepine antagonist Ro 15-1788 inhibited adenosine uptake and failed to antagonize the effects of diazepam. Another antagonist, ethyl-beta-carboline-3-carboxylate, was a weak inhibitor of adenosine uptake. Ro 5-4864, the so-called peripheral benzodiazepine ligand, inhibited adenosine uptake. Hydroxyzine and tracazolate, two anxiolytic agents, inhibited uptake as did flunarizine, a coronary vasodilator. Two calmodulin antagonists, W7 and R 24571, were effective inhibitors of adenosine uptake. Their IC50 values were comparable to those at which they have been demonstrated to inhibit calmodulin-mediated reactions in other systems. These observations suggest that adenosine uptake may be a calmodulin-regulated process.

Morphine enhances the release of 3H-purines from rat brain cerebral cortical prisms

In vitro experiments have shown that 3H-purines can be released from 3H-adenosine preloaded rat brain cortical prisms by a KCl-evoked depolarization. The KCl-evoked release of 3H-purines is dependent on the concentration of KCl present in the superfusate. At concentrations of 10(-7) approximately 10(-5)M morphine did not influence the basal release of 3H-purines from the prisms, although it enhanced the KCl-evoked release of 3H-purines. The enhancement of KCl-evoked 3H-purine release by morphine was concentration-dependent and was antagonized by naloxone, suggesting the involvement of opiate receptors. Uptake studies with rat brain cerebral cortical synaptosomes show that morphine is a very weak inhibitor of adenosine uptake. Comparisons with dipyridamole, a potent inhibitor of adenosine uptake, suggest that this low level of inhibition of the uptake did not contribute significantly to the release of 3H-purine by morphine seen in our experiments. It is therefore suggested that morphine enhances KCl-evoked 3H-purine release by an interaction with opiate receptors and that the resultant increase in extracellular purine (adenosine) levels may account for some of the actions of morphine.

Adenosine receptor agonists inhibit K+-evoked Ca2+ uptake by rat brain cortical synaptosomes

The uptake of Ca2+ by a K+-depolarized rat brain cerebral cortical crude synaptosomal preparation (P2 fraction) was investigated. The characteristics of the Ca2+ uptake system are similar to those observed by other investigators. The preparation is also a suitable model with which to study the effects of adenosine on Ca2+ uptake and neurotransmitter release, as it is generally accepted that K+-evoked Ca2+ uptake is intimately related to depolarization-induced release of neurotransmitters. We have demonstrated that an extracellular receptor is involved in mediating the adenosine-evoked inhibition of K+-evoked Ca2+ uptake. The pharmacological properties of the receptor suggest that it may be similar in some respects to the A2-receptor associated with adenylate cyclase. The adenosine uptake inhibitor, dipyridamole, potentiated the action of adenosine, suggesting that re-uptake is important in controlling the extracellular adenosine concentration and thus in the regulation of the adenosine receptor. The adenosine receptor antagonist theophylline inhibited the effects of adenosine. Calmodulin inhibited K+-evoked uptake of Ca2+ by the synaptosomal fraction.

Depolarizing agent-induced cyclic AMP accumulation in isolated rat spinal cord

The stimulation of cyclic adenosine 3',5'-monophosphate (cyclic AMP) accumulation by the depolarizing agents K+, ouabain and veratridine, was studied in rat and guinea pig spinal cord tissue slices. Significantly increased accumulation of cyclic AMP was produced by each of the agents in a concentration-dependent manner. Veratridine and ouabain were equipotent (EC50 = 5 x 10(-5)M) and approximately 500 fold more potent than K+ (EC50 = 10(-2)M). Depolarizing agent-induced cyclic AMP accumulation in slices from guinea pig spinal cord was approximately double the response in rat spinal cord. Maximum stimulation occurred within 2.5 min of incubation with these agents and lasted for at least 30 min. Regional studies demonstrated that the maximal accumulation of cyclic AMP occurred to a greater degree in tissue slices from the dorsal section of spinal cord from both rat and guinea pig. Whereas the ouabain and veratridine stimulatory responses are completely dependent on extracellular Ca++, the K+ response is only partially dependent. Stimulation due to ouabain and veratridine is dependent, and K+ is independent, of release of neurohumoral substances such as norepinephrine or adenosine from spinal neurons. These experiments indicate the possible modulatory role of depolarization-linked events in regulating the spinal cord cyclic AMP system.

Uptake of adenosine by isolated rat brain capillaries

Adenosine uptake by isolated rat brain capillaries is a carrier-mediated, temperature- and pH-sensitive process. The Km value for adenosine uptake is 4.74 microM and the Vmax is 21.7 picomol/mg protein/10 min. This is a high-affinity uptake system that can be cross-inhibited by several nucleosides and by the adenosine analogs tubercidin and 5'-deoxyadenosine. The uptake is very sensitive to inhibition by papaverine, hexobendine, and dipyridamole. These results confirm the existence of a nucleoside transport system associated with the blood-brain barrier observed during in vivo studies.

The effect of various centrally active drugs on adenosine uptake by the central nervous system

1. Adenosine and its analogs depress the firing of neurons in various brain regions. The primary mode of action of adenosine in exerting this effect appears to be the depression of transmitter release from presynaptic nerve terminals. This is a result of reduced calcium mobilization. 2. Adenosine uptake inhibitors and deaminase inhibitors depress the firing of central neurons. Adenosine antagonists, caffeine and theophylline, excite central neurons. Adenosine is therefore likely to be released in sufficient quantities to exert an ongoing modulation of synaptic transmission in the intact brain. 3. A number of groups of centrally active drugs inhibit adenosine uptake by brain synaptosomal preparations. These include the benzodiazepines, phenothiazines, various other sedatives and hypnotics, tricyclic antidepressants, non-steroidal anti-inflammatory analgesics, some steroids, diphenylhydantoin, puromycin and toyocamycin. 4. It is proposed that many agents with anxiolytic, sedative, analgesic or anti-convulsant actions may achieve their effects by inhibiting adenosine uptake and thus potentiating extracellular adenosine levels. 5. Morphine also elevates extracellular adenosine levels but achieves this by enhancing adenosine release.

Nucleoside transport in rat cerebral cortical synaptosomal membrane: a high affinity probe study

1. The nucleoside transport system in rat cerebral cortical synaptosomes was investigated using [H3]p-nitrobenzylthioinosine (NBMPR) as a high affinity probe. 2. There are high affinity and low affinity binding sites for NBMPR on rat synaptosomal membranes. The high affinity sites showed a KD value of 0.05 nM and a Bmax value of 113 fmol/mg protein. 3. Biochemical characterization of the high affinity [H3]NBMPR binding sites indicated that they probably correspond to nucleoside transport sites. 4. Several known adenosine uptake inhibitors including clonazepam were tested for their interaction with this high affinity binding site. 5. The results suggest that hexobendine and papaverine inhibit adenosine uptake by occupying the [H3]NBMPR high affinity binding sites. 6. Clonazepam and dipyridamole appear to inhibit adenosine uptake in rat cerebral cortical synaptosomes via an interaction at a different site.

Some biochemical properties of the rapid adenosine uptake system in rat brain synaptosomes

The rapid uptake of adenosine into rat brain cortical synaptosomes is mediated by a facilitated diffusion process. The carrier mediated uptake is sensitive to pH and temperature. The average Q10 value for the system is approximately 1.77 and the necessary activation energy (Ea) is estimated to be 8870 cal/mol. These values are essentially in agreement with values reported for adenosine uptake carriers of other tissues. Substrate specificity of the uptake system in the CNS demonstrates that nucleotides do not interact with the carrier until they have been hydrolyzed to nucleosides. Structural modification of the purine moiety at the "2" position did not have a profound effect on the ability of the molecule to serve as a substrate for the uptake system. Competitive inhibition by sulfhydryl reagents, p-chloromercuribenzoate, and N-ethylmaleimide on adenosine uptake suggests a direct involvement of sulfhydryl group(s) in the uptake mechanism. Other purines and pyrimidines also inhibit adenosine uptake, suggesting that a variety of nucleosides can interact with a common carrier system.