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Notizen: Abstract: The present study investigated the effect of the administration of oxypurinol (40 mg/kg), an inhibitor of xanthine oxidase, on adenosine and adenine nucleotide levels in the rat brain during ischemia and reperfusion. The brains of the animals were microwaved before, at the end of a 20-min period of cerebral ischemia, and after 5, 10, 45, and 90 min of reperfusion. Cerebral ischemia was elicited by four-vessel occlusion with arterial hypotension to 45–50 mm Hg. Adenosine and adenine nucleotide levels in the oxypurinol-pretreated (administered intravenously 20 min before ischemia) rats were compared with those in nontreated animals exposed to the same periods of ischemia and reperfusion. Oxypurinol administration resulted in significantly elevated ATP levels at the end of ischemia and 5 min after ischemia, but not at 10 min after ischemia. ADP levels were also elevated, in comparison with those in the control rats, at the end of the ischemic period. Conversely, AMP levels were significantly reduced at the end of ischemia and during the initial (5 min) period of reperfusion. Adenosine levels were lower in oxypurinol-treated rats, during ischemia, and in the initial reperfusion phase. Oxypurinol administration resulted in a significant increase in the energy charge both during ischemia and after 5 min of reperfusion. Physiological indices, namely, time to recovery of mean arterial blood pressure and time to onset of respiration, were also shortened in the oxypurinol-treated animals. These beneficial effects of oxypurinol may have been a result of its purine-sparing (salvage) effects and of its ability to inhibit free radical formation by the enzyme xanthine oxidase. Preservation of high-energy phosphates during ischemia likely contributes to the cerebroprotective potency of oxypurinol.

Notizen: Abstract: The effects of selective adenosine receptor agonists [N6-cyclopentyladenosine (CPA) and N-ethylcarboxamidoadenosine (NECA)] and antagonists {8-cyclopentyl-1,3-dipropylxanthine (DPCPX) and 9-chloro-2-(2-furanyl)-5,6-dihydro-1,2,4-triazolo[1,5-c]quinazoline-5-imine (CGS-15943A)} on aspartate and glutamate release from the ischemic rat cerebral cortex were studied with the cortical cup technique. Cerebral ischemia (for 20 min) was elicited by four-vessel occlusion. Excitatory amino acid releases were compared from control ischemic rats and drug-treated rats. Basal levels of aspartate and glutamate release were not greatly affected by pretreatment with the adenosine receptor agonists or antagonists. However, CPA (10−10M) and NECA (10−9M) significantly inhibited the ischemia-evoked release of aspartate and glutamate into cortical superfusates. The ability to block ischemia-evoked release of excitatory amino acids was not evident at higher concentrations of CPA (10−6M) or NECA (10−5M). The selective A1 receptor antagonist DPCPX also had no effect on release when administered at a low dosage (0.01 mg/kg, i.p.) but blocked the ischemia-evoked release of aspartate and glutamate at a higher dosage (0.1 mg/kg). Evoked release was inhibited by the selective A2 receptor antagonist CGS-15943A (0.1 mg/kg, i.p.). Thus, adenosine and its analogs may suppress ischemia-evoked release of excitatory neurotransmitter amino acids via high-affinity A1 receptors, whereas coactivation of lower-affinity A2 receptors may block (or reverse) the A1-mediated response.

Notizen: Abstract: Changes in cerebral cortical adenine nucleotide and adenosine levels during 10-, 20-, or 40-min periods of four-vessel occlusion producing cerebral ischemia in rats and reperfusions of 10, 45, or 90 min were determined to evaluate the effects of ischemia duration on mitochondrial function. Substantial recovery was evident following 10 or 20 min of cerebral ischemia but not, however, after a 40-min period of ischemia. A secondary decline in the cortical levels of ATP became evident following 40 min of cerebral ischemia and 90 min of reperfusion. Longer periods of ischemia may be associated with a loss of adenosine, limiting the resynthesis of ATP during reperfusion. A separate group of rats, resuscitated with 100% O2, demonstrated a more rapid recovery of mitochondrial function compared with animals that received room air during reperfusion following 20 min of cerebral ischemia. No detrimental effects of 100% O2 were observed during the 90-min period of reperfusion, indicating that 100% O2 does not promote early mitochondrial dysfunction.

Notizen: Abstract: The effects of a potent adenosine deaminase inhibitor, deoxycoformycin, on purine and amino acid neuro-transmitter release from the ischemic rat cerebral cortex were studied with the cortical cup technique. Cerebral ischemia (20 min) was elicited by four-vessel occlusion. Purine and amino acid releases were compared from control ischemic animals and deoxycoformycin-pretreated ischemic rats. Ischemia enhanced the release of glutamate, aspartate, and γ-aminobutyric acid into cortical perfusates. The levels of adenosine, inosine, hypoxanthine, and xanthine in the same perfusates were also elevated during and following ischemia. Deoxycoformycin (500 μ/kg) enhanced ischemia-evoked release of adenosine, indicating a marked rise in the adenosine content of the interstitial fluid of the cerebral cortex. Inosine, hypoxanthine, and xanthine levels were depressed by deoxycoformycin. Deoxycoformycin pretreatment failed to alter the pattern of amino acid neurotransmitter release from the cerebral cortex in comparison with that observed in control ischemic animals. The failure of deoxycoformycin to attenuate amino acid neurotransmitter release, even though it markedly enhanced adenosine levels in the extracellular space, implies that the amino acid release during ischemia occurs via an adenosine-insensitive mechanism. Inhibition of excitotoxic amino acid release is unlikely to be responsible for the cerebroprotective actions of deoxycoformycin in the ischemic brain.

Notizen: A rat four vessel occlusion model was utilized to examine the effects of ischemia/reperfusion on cortical window superfusate levels of amino acids, glucose, and lactate. Superfusate aspartate, glutamate, phosphoethanolamine, taurine, and GABA were significantly elevated by cerebral ischemia, then declined during reperfusion. Other amino acids were affected to a lesser degree. Superfusate lactate rose slightly during the initial ischemic period, declined during continued cerebral ischemia and then was greatly elevated during reperfusion. Superfusate glucose levels declined to near zero levels during ischemia and then rebounded beyond basal levels during the reperfusion period. Inhibition of neuronal lactate uptake with α-cyano-4-hydroxycinnamate dramatically elevated superfusate lactate levels, enhanced the ischemia/reperfusion evoked release of aspartate but reduced glutamine levels. Topical application of an alternative metabolic fuel, glutamine, had a dose dependent effect. Glutamine (1 mm) elevated basal superfusate glucose levels, diminished the decline in glucose during ischemia, and accelerated its recovery during reperfusion. Lactate levels were elevated during ischemia and reperfusion. These effects were not evident at 5 mm glutamine. At both concentrations, glutamine significantly elevated the superfusate levels of glutamate. Topical application of sodium pyruvate (20 mm) significantly attenuated the decline in superfusate glucose during ischemia and enhanced the levels of both glucose and lactate during reperfusion. However, it had little effect on the ischemia-evoked accumulation of amino acids. Topical application of glucose (450 mg/dL) significantly elevated basal superfusate levels of lactate, which continued to be elevated during both ischemia and reperfusion. The ischemia-evoked accumulations of aspartate, glutamate, taurine and GABA were all significantly depressed by glucose, while phosphoethanolamine levels were elevated. These results support the role of lactate in neuronal metabolism during ischemia/reperfusion. Both glucose and glutamine were also used as energy substrates. In contrast, sodium pyruvate does not appear to be as effectively utilized by the ischemic/reperfused rat brain since it did not reduce ischemia-evoked amino acid efflux.

Notizen: Histochemical procedures for the localisation of AChE have been used on the cerebella of normal and operated cats to investigate the presence of cholinergic pathways. The evidence indicates that some mossy afferent fibres and deep nuclear cells are cholinergic. The presence of AChE in many cells in the granule cell layer suggests that some parallel fibres and association pathways in the cerebellum may also be cholinergic. The relationship of these results to studies on the pharmacology and distribution of choline acetyltransferase in the cerebellum is discussed.

Notizen: : Uptake of adenosine, a putative inhibitory transmitter or modulator, was investigated in rat cerebral cortical synaptosomes. The accumulation of [3H]adenosine into synaptosomes, using an adenosine concentration of 10 μ.m, was linear for 30 min at 37°C. The uptake appeared to be mediated by kinetically saturable processes with apparent Km's of 1 μam (“high-affinity A”) and 5 μm (“high-affinity B”), both of which were partially sensitive to the presence of external sodium and calcium ions. Both uptake processes were partially inhibited by 2,4-dinitrophenol, implying the presence of active uptake and diffusional components. A study of the metabolites of adenosine taken up by the two uptake systems indicates that the major metabolites were adenosine and nucleotides. However, adenosine incorporated by the high-affinity A uptake system is more likely to form deaminated metabolites, such as hypoxanthine and inosine, indicating a possible functional difference between the two uptake processes. A detailed comparison of the inhibitory properties of certain adenosine analogues and other pharmacological agents has revealed differences between the two adenosine uptake systems. Since the glial contamination in synaptosomal preparations is well established, one of the uptake systems we observed in the present study might be of glial origin. This notion is supported by the findings that the Km values and kinetic properties of papaverine action in the synaptosomal high-affinity A uptake system are similar to those of astrocytes reported in the literature. In conclusion, the uptake processes of synaptosomal preparations show that accumulation of adenosine into neuronal (and possibly glial) elements may play a major role in regulating the extracellular adenosine concentration. Uptake inhibitors, such as diazepam, may exert, at least in part, their pharmacological actions by interfering with the regulation of extracellular adenosine concentrations.

Notizen: Abstract: Adenosine, a putative inhibitory transmitter or modulator in the brain, is rapidly transported by rat cerebral cortical synaptosomes. The uptake may represent a facilitated diffusion process, which is saturable and temperature-dependent. In this study, the uptake process was very rapid, reaching completion within 60 s of incubation at 37°C, and had an apparent Km value of 0.9μM and a Vmax value of 5.26 pmol/mg protein/ 30 s. Over 70% of the adenosine taken up remained unchanged, whereas 14% was metabolized to inosine. Twelve percent of the adenosine was converted to nucleotides. Rapid uptake of adenosine into rat cerebral cortical synaptosomes was partially inhibited by replacing Na+ with choline chloride in the medium. Ca2+ ion is important for the uptake process, as inhibition of adenosine uptake occurs in the presence of either Co2- or EGTA. Rapid uptake of adenosine is apparently mediated by a nucleoside carrier, a conclusion based on its inhibition by a variety of purine and pyrimidine nucleosides. Uptake was inhibited by dipyridamole, hexobendine, papaverine, flurazepam, and morphine. Over 60% of the adenosine taken up by the rapid uptake system (30 s) was released by depolarizing agents. In contrast, only 30% of the adenosine taken up during a 15-min incubation period was released under the same conditions. [3H]Adenosine was the predominant purine released in the presence or absence of depolarizing agents. The basal and KCl-evoked release mechanisms were found to be at least partially Ca2+-dependent, however, the release of adenosine by veratridine was increased in the presence of EGTA. This finding is in agreement with the reported Ca2+-independent release of ATP from brain synaptosomes. The present findings suggest that there are at least two functional pools of adenosine in synaptosomes. Adenosine taken up by different uptake systems may be destined for different uses (metabolism or release) in the neuron.