POST-ISCHEMIC CHANGES IN CERTAIN METABOLITES FOLLOWING PROLONGED ISCHEMIA IN THE GERBIL CEREBRAL CORTEX

-Eight metabolites were measured in the post-ischemic period following either 1 or 3 h of unilateral ischemia in the gerbil cerebral cortex. The levels of ATP, P-creatine, glucose, glycogen and GABA were essentially restored by 1 h after ischemia. In the 3 h ischemic animals. glycogen continued to increase to greater than control values aftcr 5 and 20 h of recirculation. The Icvels of glutamate were unchanged during the ischemic episode, but decreased to 60% of control at Smin and 1 h after either period of ischemia. The concentrations of cyclic AMP, which were 4-to 5-fold elevated during ischemia. increased an additional 6-fold 5 min after recirculation in both groups. Arter 1 h of recovery. the levels were not different from control values. After the 1 h ischemic period, lactate levels recovered between 5 and 20 h of recirculation. In the 3 h ischemic animals. lactate concentrations were still elevated even after 20 h of recirculation. These data suggest that with the exception of lactate. recovery of metabolites is not sevcrely compromiscd by either 1 or 3 h of ischemia. Furthermore, the changes in glycogen. glutamate and cyclic AMP after recirculation suggest that the recovery process is not just a rcversal of the changes observed during ischemia.     

Cyclic AMP Concentrations in Rat Neocortex and Hippocampus During and Following Incomplete Ischemia: Effects of Central Noradrenergic Neurons, Prostaglandins, and Adenosine

The concentrations of cyclic AMP, noradrenaline, glycogen, glucose, lactate, pyruvate, labile phosphate compounds, and free fatty acids were investigated in the rat neocortex and hippocampus during and following cerebral ischemia. An incomplete ischemia of 5 and 15 min duration was induced by bilateral carotid clamping combined with hypotension. The postischemic events were studied after 5, 15, and 60 min of recirculation. Five minutes of ischemia did not significantly alter the neocortical or hippocampal concentrations of cyclic AMP. After 15 min of ischemia the neocortical levels decreased significantly below control values. In the recirculation period following ischemia a significant elevation of the cyclic AMP concentrations was observed. Following 5 min of recirculation after 5 min of ischemia the levels increased from 2.53 +/- 0.21 nmol X g-1 to 5.18 +/- 0.09 nmol X g-1 in the neocortex and from 2.14 +/- 0.16 nmol X g-1 to 3.52 +/- 0.35 nmol X g-1 in the hippocampus. Five minutes of recirculation following 15 min of ischemia led to a significant increase in the levels of cyclic AMP, to 12.86 +/- 1.43 nmol X g-1 in the neocortex to 5.58 +/- 0.57 nmol X g-1 in the hippocampus. With longer recirculation periods the cyclic AMP levels progressively decreased and were similar to control values after 60 min. Depletion of cortical noradrenaline by at least 95% was performed by injections of 6-hydroxydopamine into the ascending axon bundles from the locus ceruleus. The lesion did not significantly change the ischemic or post-ischemic neocortical and hippocampal levels of cyclic AMP, glycogen, or free fatty acids including arachidonic acid.(ABSTRACT TRUNCATED AT 250 WORDS)     

ALTERATIONS OF CYCLIC NUCLEOTIDE-RELATED ENZYMES AND ATPase DURING UNILATERAL ISCHEMIA AND RECIRCULATION IN GERBIL CEREBRAL CORTEX

Abstract— Several enzyme activities were determined in gerbil cerebral cortex during unilateral ischemia or in the post-ischemic period following 1 h of ischemia. Adenylate cyclase and Na ⁺ -K ⁺ -activated ATPase showed essentially the same pattern. Neither enzyme changed during ischemia but the activities decreased on recirculation to 40–60% of right side control by 5 h. The ATPase had returned to control level by 20h; the adenylate cyclase by 7 days of recirculation. Particulate cyclic AMP-dependent protein kinase in the ischemic left hemisphere decreased throughout the 6h of ischemia. It remained depressed in the first 5 h of the post-ischemic period but returned to control by 20 h. The soluble protein kinase activity, the soluble cyclic AMP and cyclic GMP phosphodiesterase and the Mg²⁺ dependent ATPase did not change significantly during the ischemic or post-ischemic periods. The results suggest that ischemia and/or recirculation may affect cellular membranes and membrane-bound enzymes, in particular. Furthermore, the results imply that despite apparent metabolite recovery during the post-ischemic period, enzymatic changes are occurring that may be important for both the quality of recovery and the response to further ischemic insult.     

Changes in Brain Energy Metabolism and Protein Synthesis Following Transient Bilateral Ischemia in the Gerbil

The time course of the reduction in brain protein synthesis following transient bilateral ischemia in the gerbil was characterized and compared with changes in a number of metabolites related to brain energy metabolism. The recovery of brain protein synthesis was similar following ischemic periods of 5, 10, or 20 min; in vitro incorporation activity of brain supernatants was reduced to approximately 10% of control at 10 or 30 min recirculation, showed slight recovery at 60 min, and returned to 60% of control activity by 4 h. Protein synthesis activity was indistinguishable from control at 24 h. One minute of ischemia produced no detectable effect on protein synthesis measured after 30 min reperfusion; longer periods of ischemia resulted in progressive inhibition, with 5 min producing the maximal effect. Pentobarbital (50 mg/kg) increased by 1-2 min the threshold ischemic duration required to produce a given effect. Whereas most metabolites recovered quickly following 5 min ischemia, glycogen showed a delayed recovery comparable to that seen for protein synthesis. These results are discussed in relation to possible mechanisms for the coordinate regulation of brain energy metabolism and protein synthesis. An improved method for the fluorimetric measurement of guanine nucleotides is described.     

Metabolism and excretion of exogenous adenosine 3':5'-monophosphate and guanosine 3':5'-monophosphate. Studies in the isolated perfused rat kidney and in the intact rat.

Isolated rat kidneys were perfused with a recirculating medium containing exogenous adenosine 3':5'-monophosphate (cyclic AMP) or guanosine 3':5'-monophosphate (cyclic GMP) at an initial concentration of 0.1 mM. Both cyclic nucleotides were rapidly removed from the perfusate. Urinary excretion accounted for about 20% and 40% of the respective cyclic AMP and cyclic GMP lost from the perfusate. The metabolism of the cyclic nucleotides was studied by 14C-labeled cyclic nucleotides in the perfusate. During 60 min, 30% of added cyclic [14C]AMP was metabolized to renal [14C]adenine nucleotides (ATP, ADP, and AMP) and 30% to perfusate [14C]uric acid. Similarly, 20% of cyclic[14C]GMP was metabolized to renal [14C]guanine nucleotides (GTP, GDP, and GMP) and 30% to perfusate [14C]uric acid. Urine contained principally unchanged 14C-labeled cyclic nucleotide. Addition of 0.1 mM cyclic AMP to the perfusate elevated the renal ATP and ADP contents 2-fold. Addition of 0.1 mM of either cyclic AMP or cyclic GMP to the perfusate also elevated the renal production of uric acid 2- to 3-fold. The production and distribution of metabolites of exogenous cyclic nucleotides were also studied in the intact rat. Within 60 min after injection, 3.3 mumol of either 14C-labeled cyclic AMP or cyclic GMP was cleared from the plasma. Kidney cortex and liver were the principal tissues for 14C accumulation. Urinary excretion accounted for about 20 and 45% of the cyclic [14C]AMP and cyclic [14C]GMP lost from the plasma, respectively. The 14C found in the kidney and liver was present almost entirely as the respective purine mono-, di-, and trinucleotides. The other principal metabolite was [14C]allantoin, found in the urine and, to a lesser extent, the liver. The urine contained mostly unchanged 14C-labeled cyclic nucleotide. Unlike the findings with the perfused kidney, [14C]uric acid was not a significant metabolite of the 14C-labeled cyclic nucleotides in these in vivo experiments.     

On the role of cyclic AMP and cyclic GMP in steroid production by bovine cortical cells

The time course of corticotropin-induced steroidogenesis and changes in intracellular cyclic AMP and cyclic GMP levels were investigated in isolated bovine adrenocortical cells prepared by trypsin digestion. Corticotropin produced a pea a peak rise in cyclic AMP during the first 5 min of stimulation and enhanced steroid production after 15 min. Corticotropin also caused a decrease in cortical cyclic GMP at 5 min; this decrease in cyclic GMP reverted to a 2–3 fold increase at 15–30 min which gradually subsided by 60 min. A steroidogenic concentration of prostaglandin E₂ also produced an elevation in the levels of both nucleotides, but the rise in cyclic GMP preceded the rise incyclic AMP. These results suggest that the relative amount of cyclic AMP and cyclic GMP, rather than the absolute levels of cyclic AMP, may be a key factor in the regulation of steroidogenesis.     

On the role of cyclic AMP and cyclic GMP in steroid production by bovine cortical cells.

The time course of corticotropin-induced steroidogenesis and changes in intracellular cyclic AMP and cyclic GMP levels were investigated in isolated bovine adrenocortical cells prepared by trypsin digestion. Corticotropin produced a peak rise in cyclic AMP during the first 5 min of stimulation and enhanced steroid production after 15 min. Corticotropin also caused a decrease in cortical cyclic GMP at 5 min; this decrease in cyclic GMP reverted to a 2-3 fold increase at 15-30 min which gradually subsided by 60 min. A steroidogenic concentration of prostaglandin E2 also produced an elevation in the levels of both nucleotides, but the rise in cyclic GMP preceded the rise in cyclic AMP. These results suggest that the relative amounts of cyclic AMP and cyclic GMP, rather than the absolute levels of cyclic AMP, may be a key factor in the regulation of steroidogenesis.     

CYCLIC NUCLEOTIDES IN MURINE BRAIN: THE TEMPORAL RELATIONSHIP OF CHANGES INDUCED IN ADENOSINE 3',5'-MONOPHOSPHATE AND GUANOSINE 3',5'-MONOPHOSPHATE FOLLOWING MAXIMAL ELECTROSHOCK OR DECAPITATION

–Adenosine 3′,5′-cyclic monophosphate (cyclic AMP) levels increase about 5-fold in the cerebral cortex and 2-fold in the cerebellum following electroconvulsive shock (ECS). The peak levels of cyclic AMP occur at 45 s after ECS in the cerebral cortex, and at 15 s in the cerebellum. In the cerebral cortex, ECS produces twice the cyclic AMP accumulation as does decapitation in a comparable time period; however, the relative effect of a number of neurotropic agents on the cyclic AMP accumulation is essentially the same, whether stimulated by decapitation or by ECS. In the cerebellum, the levels of guanosine 3′,5′-cyclic monophosphate (cyclic GMP) also increase following ECS. The cyclic GMP levels are greatest at 60 s after ECS during the postictal depression. An association between elevated cerebellar cyclic GMP and depression seems unlikely, since CNS depressants either lowered or had no effect on cyclic GMP levels. From these results, cyclic nucleotide profiles following treatments such as ECS or decapitation may be useful in elucidating the molecular events involved in seizures, brain injury and ischemia.     

Regulation of cyclic GMP, cyclic AMP and lactate dehydrogenase by putative neurotransmitters in the C6 rat glioma cell line.

In C6 cells norepinephrine and dopamine caused transient increases in cyclic GMP and cyclic AMP, as well as an induction of lactate dehydrogenase. All of these responses were blocked by l-propranolol, suggesting mediation by a β-receptor. Phentolamine potentiated the NE-increased cAMP levels by 5-fold when NE was used at suboptimal doses, suggesting the presence of α-adrenergic receptors in C6 cells. Carbamylcholine decreased the levels of both cyclic nucleotides, with hexamethonium partially reversing the effect on cyclic GMP. Dibutyryl-cyclic GMP or carbamylcholine reduced catecholamine-induced cyclic AMP levels. Serotonin increased cyclic GMP levels 60% and decreased cyclic AMP levels 36%. Calcium- and magnesium-free media inhibited the norepinephrine-induced levels of cyclic GMP and cyclic AMP respectively.     

Formation of guanosine 3′,5′-cyclic monophosphate by thyroliberlin in cultured rat pituitary cells a possible role in stimulation of prolactin synthesis

In a clonal strain of rat pituitary tumour cells (GH₄C₁ cells), thyroliberin stimulated prolactin secretion and synthesis: effects that could be demonstrated after 5 min and 4–5 h of treatment, respectively. Within 0.5–5 min after addition of thyroliberin, maximal increases (2–4 hold) in cellular cyclic GMP concentrations were observed, and this rise preceded or occurred simultaneously with that of cyclic AMP. After 60 min of treatment the concentrations of the cyclic nucleotides had returned to control values. Half maximal and maximal stimulation of cyclic GMP elevations were obtained with approx. 2·10⁹ and approx. 27·10^?9 thyroliberin, respectively. Aminophylline increased both cyclic GMP and cyclic AMP, and potentiated the stimulatory effects of thyroliberin on both cyclic nucleotides. The dibutyryl derivative of cyclic GMP (10^?4–10^?6 M) stimulated prolactin synthesis, but not hormone release. Prostaglandin E₂ (3·10^?7 M) stimulated cellular cyclic AMP concentrations, but did not affect cyclic GMP levels. We conclude that thyroliberin in the GH₄C₁ ccell strain stimulates cyclic GMP formation, in addition to elevate cyclic AMP concentrations. The stimulatory effect on cyclic GMP is probably not secondary to the rise in cyclic AMP concentration, since prostaglandin E₂ elevates only cyclic GMP is involved in the action of thyroliberin on prolactin, the present results suggest a role on hormone synthesis.     

Separation of cyclic AMP and cyclic GMP from thymidine,electrolytes and polyvalent nucleotides in tissue samples

Cyclic AMP and cyclic GMP can be separated from thymidine and its possible metabolites, electrolytes, and polyvalent nucleotides using columns of acidic alumina. Electrolytes and thymidine are not adsorbed on acidic alumina at pH 4.4 while cyclic nucleotides and polyvalent nucleotides are adsorbed at this pH. Cyclic AMP and cyclic GMP are eluted together from acidic alumina with 0.2 M ammonium formate (pH 6.0) and the polyvalent nucleotides remain adsorbed. The cyclic nucleotides are separated by chromatography on Dowex AG 1 X 8 resin. Recovery is 60–64% for cyclic AMP and cyclic GMP isolated from renal tissue samples. This methodology permits the separation of tritiated thymidine from cyclic nucleotides which are present in tissue preparations used in studies on the role of cyclic nucleotides in cellular growth.     

Separation of cyclic AMP and cyclic GMP from thymidine, electrolytes and polyvalent nucleotides in tissue samples.

Cyclic AMP and cyclic GMP can be separated from thymidine and its possible metabolites, electrolytes, and polyvalent nucleotides using columns of acidic alumina. Electrolytes and thymidine are not adsorbed on acidic alumina at pH 4.4 while cyclic nucleotides and polyvalent nucleotides are adsorbed at this pH. Cyclic AMP and cyclic GMP are eluted together from acidic alumina with 0.2 M ammonium formate (pH 6.0) and the polyvalent nucleotides remain adsorbed. The cyclic nucleotides are separated by chromatography on Dowex AG 1 X 8 resin. Recovery is 60--64% for cyclic AMP and cyclic GMP isolated from renal tissue samples. This methodology permits the separation of tritiated thymidine from cyclic nucleotides which are present in tissue preparations used in studies on the role of cyclic nucleotides in cellular growth.     

Effects of parathyroid hormone on cyclic AMP, cyclic GMP, and efflux of calcium in isolated renal tubules.

The effects of parathyroid hormone (PTH) on concentrations of cyclic AMP and cyclic GMP were investigated in isolated renal cortical tubules from hamsters. Efflux of 45Ca from tubules was compared to temporal changes in both cyclic nucleotide concentrations. A rapid increase in cyclic AMP occurred following addition of PTH which was maximal by 1 min but decreased over the next 4 min period. Cyclic GMP concentrations were not significantly altered at 1 min but increased between 1 and 5 min from basal levels. Concentrations of both nucleotides remained significantly elevated from basal levels between 5 and 15 min following PTH. Efflux of 45Ca was increased by PTH with time-course changes closely paralleling changes in cyclic GMP concentrations. Changes in both cyclic AMP and cyclic GMP were related to PTH concentrations of the incubation media and were increased by addition of theophylline. Increasing the calcium concentration from 1 to 3 mM did not significantly alter the effect of PTH on cyclic AMP, however, cyclic GMP concentrations were further increased.     

METABOLITE LEVELS IN BRAIN FOLLOWING EXPERIMENTAL SEIZURES: THE EFFECTS OF ISONIAZID AND SODIUM VALPROATE IN CEREBELLAR AND CEREBRAL CORTICAL LAYERS

Abstract— Levels of glucose, lactate, GABA and cyclic nucleotides were examined in discrete layers of the cerebellum and cerebral cortex of mice following treatment with the anticonvulsant, sodium valproate, and/or the convulsant, isoniazid. The concentrations of the metabolites were essentially uniform among the layers of each region, whether from control or from drug-treated mice. Metabolite concentrations in the isoniazid-treated mice were determined either 30 min after administration (preconvulsive state), or immediatley after the onset of seizures. Glucose and lactate, two markers of energy status in the brain, were only minimally affected by drug treatment. However, the levels of GABA and cyclic nucleotides were markedly different from control values in the drug-treated animals. In the preconvulsive state, GABA levels in cerebellar layers were depressed and the cyclic nucleotides were elevated in most layers of both regions. At the onset of seizures, the reduction of GABA and the elevation of cyclic AMP in both regions was more pronounced than during the preconvulsive state. While the concentration of cyclic GMP remained elevated in the cerebellar layers at the onset of seizures, the level in the cerebral cortex returned to control values. Valproate elevated GABA in all the layers of both regions and decreased the cyclic GMP in the cerebellar layers. Generally, when valproate was administered in combination with isoniazid, it dampened the isoniazid induced changes in the metabolites. The events leading up to a seizure as well as those that sustain it may be reflected by the disparate responses of the metabolites in the cerebellum and cerebral cortex.     

Amylase secretion by rabbit parotid gland. Role of cyclic AMP and cyclic GMP.

Amylase secretion and changes in the levels of cyclic AMP and GMP were studied in rabbit parotid gland slices incubated in vitro with a variety of neurohumoral transmitters, their analogs and inhibitors. Cyclic GMP levels increased 8-fold 5 min after exposure to carbachol (10(-4) M), without a change in cyclic AMP levels; amylase output also rose. These effects were completely inhibited by muscarinic blockade with atropine, but were unaffected by alpha-adrenergic blockade with phenoxybenzamine. Epinephrine (4 - 10(-5) M) produced a rapid increase in the levels of both cyclic nucleotides and in amylase release. The increase in cyclic GMP level was inhibited by previous exposure of the slices to phenoxybenzamine, while the cyclic AMP rise was prevented by the beta-blocking agent, propranolol. Pure alpha-adrenergic stimulation with methoxamine (4 - 10(-4) M) produced modest elevations in cyclic GMP content and amylase output, effects blocked by pre-treatment of slices with either atropine or phenoxybenzamine. At a concentration of 4 - 10(-6) M, isoproterenol (a beta-agonist) failed to affect cyclic GMP levels, but promptly stimulated increases in cyclic AMP levels, and after a short lag, amylase secretion. At a higher dose (4 - 10(-5) M) isoproterenol produced elevations in the levels of both nucleotides. The carbachol-induced effects on cyclic GMP content and amylase release were greatly potentiated by the addition of isoproterenol (4 - 10(-6) M). These data strongly suggest that cholinergic muscarinic agonists and alpha-adrenergic agonists stimulate amylase output in rabit parotid gland by mechanisms involving cyclic GMP. The atropine-sensitive intracellular events effected by alpha-stimulation may be dependent upon endogenous generation of acetylcholine. Both cyclic nucleotides seem to be required for the early rapid secretion of amylase. The unique responses achieved by the combination of carbachol and isoproterenol suggest that isoproterenol may increase the sensitivity of this tissue to the effects of cholinergic stimuli.     

Cyclic nucleotides in stroke and related cerebrovascular disorders

Evidence has steadily accumulated to indicate that the rapid fluctuations in cyclic nucleotides during primary and secondary stroke are more than epiphenomena of the disease. During acute phases of ischemia, anoxia or hypoxia cyclic AMP rapidly accumulates in cerebral tissue, cerebrospinal fluid (CSF) and venous plasma, while cyclic GMP either remains unchanged or declines. The massive release of transmitters (catecholamines and adenosine) or ionic fluxes (Na+ and K+) may account for these observations. If reflow is established through a previously occluded vessel cyclic AMP content rises even higher in conjunction with a sharp rise in cyclic GMP. It is during this reflow period subsequent to longer term stroke (30-60 min) that the synaptic membrane enzyme, adenylate cyclase, is especially vulnerable. Presumably the cause of injury to cell membrane systems results from excess lactic acid accumulation and/or Ca++ entry through the damaged blood-brain barrier. The latter initiates breakdown of membrane phospholipids with resultant synthesis of vasoactive prostaglandins and formation of free radicals causing further insult to membrane phospholipids. Thus drugs acting to inhibit formation of prostaglandins, scavenge free radicals, reduce lactate formation, inhibit Ca++ entry or stabilize cell membranes have been shown to possess varying degrees of protective action toward adenylate cyclase. Moreover, cyclic AMP has been found to reverse stroke-induced vasospasm in central vessels. Reduced cyclic AMP content in CSF has been used to monitor the severity of coma, whereas clinical improvement was associated with predictable increases in the cyclic nucleotide. Therefore, cyclic nucleotides and related membrane enzyme systems might be used as target molecules in which to develop future therapeutic strategies for prevention or treatment of stroke.     

The content of cyclic nucleotides in an organ culture of normal and atherosclerosis-affected human aorta

Cyclic AMP and cyclic GMP content was measured in intima media of unaffected and atherosclerotic areas of human aorta in a short-term organ culture. It was demonstrated that during short-term cultivation the content of both cyclic nucleotides in tissues is constant. The cyclic AMP content in fatty streaks and atherosclerotic plaques is significantly (2 to 7-fold) lower than in unaffected intima. The cyclic GMP level in atherosclerotic lesions is 1.5 to 3-fold higher than in normal. The content of both cyclic nucleotides in the media underlying fatty streaks and atherosclerotic plaques is the same as in the normal tissue. The obtained data indicate serious disorders in the system of cyclic nucleotides during atherosclerosis.     

The accumulation of cyclic AMP and cyclic GMP in guinea pig brain slices: Effect of calcium ions,norepinephrine and adenosine

The effect of Ca²⁺ and putative neurotransmitters on formation of cyclic AMP and cyclic GMP has been studied in incubated slices of brain tissue. Cyclic AMP levels in cerebellar slices after about 90 min of incubation ranged from 10 pmol/mg protein in rabbit, to 25 in guinea pig, to 50 in mouse and 200 in rat. Cyclic GMP levels in the same four species showed no correlation with cyclic AMP levels and were, respectively, 1.3, 20, 5 and 30 pmol/mg protein. The absence of calcium during the prolonged incubation of cerebellar slices had little effect on final levels of cyclic AMP, while markedly decreasing final levels of cyclic GMP. Reintroduction of Ca²⁺ resulted in a rapid increase in cerebellar levels of cyclic GMP which was most pronounced for guinea pig where levels increased nearly 7-fold within 5 min. Prolonged incubation of guinea pig cerebral cortical slices in calcium-free medium greatly elevated cyclic AMP levels apparently through enhanced formation of adenosine, while having little effect on final levels of cyclic GMP. Norepinephrine and adenosine elicited accumulations of cyclic AMP and cyclic GMP in both guinea pig cerebral cortical and cerebellar slices. Glutamate, γ-aminobutyrate, glycine, carbachol, and phenylephrine at concentrations of 1 mM or less had little or noe effect on cyclic nucleotide levels in guinea pig cerebellar slices. Prostaglandin E₁ and histamine slightly increased cerebellar levels of cyclic AMP. Isoproterenol increased both cyclic AMP and cyclic GMP. The accumulation of cyclic AMP and cyclic GMP elicited by norepinephrine in cerebellar slices appeared, baed on dose vs. response curves, agonist-antaganonist relationships and calcium dependency, to involve in both cases activation of a similar set of ß-adrenergic receptors. In cerebellar slices accumulations of cyclic AMP and cyclic GMP elicted by norepinephrine and by a depolarizing agent, veratridine, were strongly dependent on the presence of calcium. The stimulatory effects of adenosine on cyclic AMP and cyclic GMP formation were antagonized by theophylline. The lack of correlations between levels of cyclic AMP and cyclic GMP under the various conditions suggested independent activation of cyclic AMP- and cyclic GMP-generating systems in guinea pig cerebellar slices by interactions with Ca²⁺, norephinephrine and adenosine.     

Cerebral ischemia: Changes in monoamines are independent of energy metabolism

The relationship of neurotransmitters and neuroeffectors to the energy state of the brain was examined in the gerbil model of ischemia after 5 and 15 min of bilateral common carotid artery occlusion only or with 1 hr of reperfusion. The gerbil brains were fixed by microwave irradiation and a total of 15 metabolites were measured from a single piece of tissue from either the hippocampus or the striatum. The rapid alterations in energy-related compounds and cyclic nucleotides appeared to be directly related both to the loss of oxygen and glucose during ischemia and the resupply of these nutrients during reflow. Significant reduction in the level of monoamines occurred prinicipally during reflow, at a time when the energy-related metabolites were restored. It is proposed that the changes in monoamines were triggered by other ischemic-induced events unrelated to energy depletion.Presented in part at the Nineteenth Annual Meeting of the American Society for Neurochemistry, 1988     

METABOLITE LEVELS IN BRAIN FOLLOWING EXPERIMENTAL SEIZURES: THE EFFECTS OF MAXIMAL ELECTROSHOCK AND PHENYTOIN IN CEREBELLAR LAYERS

Abstract— The effects of maximal electroshock (MES) and phenytoin on metabolites and cyclic nucleotides in layers of frozen-dried cerebellum have been investigated. The four layers (molecular, Purkinje-cell rich, granular and white matter) had remarkably homogeneous distributions of P-creatine, ATP, glucose, glycogen, lactate, GABA and the cyclic nucleotides. MES caused dramatic decreases in P-creatine, ATP, and glucose at 10 s after treatment, followed by a decrease in glycogen at 30 s. Lactate levels were elevated, and GABA was unchanged. Cyclic AMP concentrations were increased at 10s and cyclic GMP at 30 s. Phenytoin modified most of the MES induced changes in all the layers, although white matter was less affected by MES and/or phenytoin. Lactate concentrations were increased by MES and these effects were not altered when phenytoin was administered. The most dramatic effects of phenytoin were on the changes in cyclic nucleotides. Cyclic AMP concentrations were elevated after MES but the values returned to normal more rapidly when phenytoin was present. The drug almost obliterated the MES induced changes in cyclic GMP. The possible relationship of cyclic nucleotide concentrations and the modulation of seizure activity is discussed.