Dose-dependent action of corticosteroids on brain serotonin content and passive avoidance behavior.

Corticosterone, 1.0 and 5.0 mg/kg, improved passive avoidance behavior based on fear versus thirst-conflict situation. Corticosterone, 1.0 mg/kg, increased the serotonin (5-HT) content in the hypothalamus and mesencephalon; 5.0 mg/kg of corticosterone had no effect. Plasma corticosterone level increased in a dosedependent manner after corticosterone treatment. dl-Parachlorophenylalanine (PCPA) impaired passive avoidance behavior and decreased the hypothalamic and mesencephalic 5-HT level. After PCPA treatment, the plasma corticosterone level was slightly increased. PCPA pretreatment was able to prevent the action of 1.0 and 5.0 mg/kg of corticosterone on behavior as well as on brain 5-HT level. Corticosterone, 10.0 mg/kg, impaired passive avoidance behavior, decreased the hypothalamic and mesencephalic 5-HT content, and increased the plasma corticosterone level.Monoamine oxidase inhibitor (nialamide) treatment improved the passive avoidance behavior and increased the 5-HT level in the hypothalamus and mesencephalon. The plasma corticosterone level did not change significantly. Nialamide pretreatment abolished the behavioral action of 10.0 mg/kg of corticosterone as well as its action on brain 5-HT level. A large dose of corticosterone (25.0 mg/kg) and 2.5 mg/kg of 6-dehydro-16-methylenhydrocortisone (6DH) had a similar action on passive avoidance behavior and on brain serotonin level as 10.0 mg/kg of corticosterone; however, the plasma corticosterone level was increased only in corticosterone-treated animals and was significantly decreased after 6DH. 11-Deoxycorticosterone (DOC) at a dose of 25.0 mg/kg was ineffective on passive avoidance behavior and on brain serotonin content, whereas it slightly decreased the plasma corticosterone level. Data suggest that the corticosterone has dosedependent dual action on passive avoidance behavior, and its action is, at least partly, mediated via changed brain serotonin metabolism. The action seems to be a glucocorticoid-specific one since mineralocorticoid (DOC) is ineffective on this behavioral pattern.     

Links in the histamine metabolism in the brain of rats with sequential exposure to low- and high-pressure oxygen

Histamine content and diamine oxidase activity in rat brain under hyperbaric oxygenation have been studied. Under 0,3 MPa histamine level decreases in brain of more sensitive rats, but it does not change in brain of more resistant animals in comparison with the control ones. High oxygen pressure (0,7 MPa) causes a significant increase of histamine concentration. Diamine oxidase activity decreases under hyperoxia. Under the consequent action of high and low pressure (0,3 MPa during 1 h and 0,7 MPa) convulsions in rats begin later and alterations of histamine content in brain are less than under 0,7 MPa oxygen action only. The role of histamine at compensate reaction and cause of increasing resistance of animals to hyperoxia are discussed.     

Ex vivo and in vivo neuroprotection induced by argon when given after an excitotoxic or ischemic insult

In vitro studies have well established the neuroprotective action of the noble gas argon. However, only limited data from in vivo models are available, and particularly whether postexcitotoxic or postischemic argon can provide neuroprotection in vivo still remains to be demonstrated. Here, we investigated the possible neuroprotective effect of postexcitotoxic-postischemic argon both ex vivo in acute brain slices subjected to ischemia in the form of oxygen and glucose deprivation (OGD), and in vivo in rats subjected to an intrastriatal injection of N-methyl-D-aspartate (NMDA) or to the occlusion of middle-cerebral artery (MCAO). We show that postexcitotoxic-postischemic argon reduces OGD-induced cell injury in brain slices, and further reduces NMDA-induced brain damage and MCAO-induced cortical brain damage in rats. Contrasting with its beneficial effect at the cortical level, we show that postischemic argon increases MCAO-induced subcortical brain damage and provides no improvement of neurologic outcome as compared to control animals. These results extend previous data on the neuroprotective action of argon. Particularly, taken together with previous in vivo data that have shown that intraischemic argon has neuroprotective action at both the cortical and subcortical level, our findings on postischemic argon suggest that this noble gas could be administered during but not after ischemia, i.e. before but not after reperfusion has occurred, in order to provide cortical neuroprotection and to avoid increasing subcortical brain damage. Also, the effects of argon are discussed as regards to the oxygen-like chemical, pharmacological, and physical properties of argon.     

Purinergic effect of ethymisole

A study was made of the mechanism of action of ethimizole, a drug synthesized as central stimulant in terms of structural similarity to caffeine but possessing some antagonistic pharmacological effects as regards caffeine action. Experiments on rats given intraperitoneal injections of ethimizole demonstrated a considerable increase in adenylate cyclase activity of the brain and in the ATP level. Caffeine was found to prevent the stimulant action of ethimizole on energy metabolism and adenylate cyclase activity, while adenosine to potentiate this action. The possibility of ethimizole action on brain adenosine receptors is analyzed.     

Alterations in serum and brain trace element levels after antidepressant treatment. Part II. Copper

We have studied the effect of chronic treatment with imipramine, citalopram, and electroconvulsive shock (ECS) on serum and brain copper levels in rats. Chronic treatment with citalopram and imipramine (but not ECS) significantly (approx 14%) decreased the serum copper level. Chronic treatment with both drugs did not alter the brain copper level. However, chronic ECS induced a significant increase (by 36%) in the copper level in the hippocampus and also in the cerebellum (by 16%). In contrast to the zinc, where both pharmacologic and ECS treatment increased its hippocampal concentration, these two antidepressant therapy (drugs versus ECS) differ in their effect on brain copper level. These findings suggest that the mechanism by which copper is involved in ECS differs from that of any involvement in the action of the drugs studied.     

The functional role of neurospecific protein S-100 in memory processes]

Elaboration of alimentary conditioned reflex in rats is accompanied by an increase of the level of protein S-100 in the left and right cerebral hemispheres. Amnestic factor M-cholinolytic atropine disturbs the elaborated habit and simultaneously decreases the quantity of protein S-100 up to the level of unlearned animals. The elaboration of conditioned reflex of passive avoidance does not change the content of protein S-100 in the rats brain. Intracisternal injection of antiserum to protein S-100 has an expressed amnestic action. Intracisternal injection of protein S-100 against the background of amnestic action of cholinolytic does not lead to restoration of memory. The cholinolytic and antiserum to protein S-100 mutually potentiate the amnestic effect.     

Effects of some anticonvulsant drugs on brain GABA level and GAD and GABA-T activities

The effect of anticonvulsant drugs was examined on brain GABA levels and GAD and GABA-T activities. The level of GABA was increased by the treatment with diphenylhydantoin. The drug had no effect on GABA-T activity, whereas GAD activity was inhibited. Carbamazepine increased the GABA level but did not effect GAD and GABA-T activities. Diazepam had no effect on GABA level and GAD activity, whereas it caused a slight inhibition of GABA-T activity. Phenobarbital administration decreased GABA level only at the higher concentration. Clonazepam effected only GAD activity. Some anticonvulsant drugs generally increase brain GABA level; however the lack of correlation with an effect on the GAD and GABA-T activities indicate that other factors than metabolism, such as membrane transport processes, are involved in the mechanism of action of anticonvulsant drugs.     

Psychopharmacologic spectrum of melanostatin

Experiments on cats revealed an emotiotropic action of melanostatin on the original spectrum of emotional reactivity, similar to the effects of L-DOPA and amantadin. The drug does not possess an antidepressant action proper but activates the aggressive-defensive behaviour in experimental reserpine depression and reduces the provocation-induced aggressive behaviour in experimental haloperidol depression. In reserpinized mice, it antagonizes reserpine hypothermia, increases muscle tone and eliminates ptosis. It decreases haloperidol-induced catalepsia. Melanostatin increases the brain level of dopamine and its metabolite, homovanilic acid.     

吸氧预处理对大鼠脑缺血再灌注损伤的保护作用

目的探讨吸氧预处理对大鼠脑缺血再灌注损伤的保护作用。方法通过大鼠局灶脑缺血再灌注损伤模型,采用SOD、MDA测定、电镜及神经行为学检查的方法,观察吸氧预处理对大鼠脑缺血再灌注损伤后SOD、MDA、神经行为学评分及脑组织病理变化。结果吸氧预处理组SOD活力高于对照组(P<0.05),MDA含量、神经行为学评分均低于对照组(P<0.05),脑组织超微结构损伤均减轻。结论吸氧预处理对大鼠脑缺血再灌注损伤有保护作用。     

Phosphorylation processes mediate rapid changes of brain aromatase activity

The enzyme aromatase (also called estrogen synthase) that catalyzes the transformation of testosterone (T) into estradiol plays a key limiting role in the action of T on many aspects of reproduction. The distribution and regulation of aromatase in the quail brain has been studied by radioenzyme assays on microdissected brain areas, immunocytochemistry, RT-PCR and in situ hybridization. High levels of aromatase activity (AA) characterize the sexually dimorphic, steroid-sensitive medial preoptic nucleus (POM), a critical site of T action and aromatization for the activation of male sexual behavior. The boundaries of the POM are clearly outlined by a dense population of aromatase-containing cells as visualized by both immunocytochemistry and in situ hybridization histochemistry. Aromatase synthesis in the POM is controlled by T and its metabolite estradiol, but estradiol receptors alpha (ER) are not normally co-localized with aromatase in this brain area. Estradiol receptor beta (ERβ) has been recently cloned in quail and localized in POM but we do not yet know whether ERβ occurs in aromatase cells. It is therefore not known whether estrogens regulate aromatase synthesis directly or by affecting different inputs to aromatase cells as is the case with the gonadotropin releasing hormone neurons. The presence of aromatase in presynaptic boutons suggests that locally formed estrogens may exert part of their effects by non-genomic mechanisms at the membrane level. Rapid effects of estrogens in the brain that presumably take place at the neuronal membrane level have been described in other species. If fast transduction mechanisms for estrogen are available at the membrane level, this will not necessarily result in rapid changes in brain function if the availability of the ligand does not also change rapidly. We demonstrate here that AA in hypothalamic homogenates is rapidly down-regulated by exposure to conditions that enhance protein phosphorylation (addition of Ca²⁺, Mg²⁺, ATP). This inhibition is blocked by kinase inhibitors which supports the notion that phosphorylation processes are involved. A rapid (within minutes) and reversible regulation of AA is also observed in hypothalamic explants incubated in vitro and exposed to high Ca²⁺ levels (K⁺-induced depolarization, treatment by thapsigargin, by kainate, AMPA or NMDA). The local production and availability of estrogens in the brain can therefore be rapidly changed by Ca²⁺ based on variation in neurotransmitter activity. Locally-produced estrogens are as a consequence available for non-genomic regulation of neuronal physiology in a manner more akin to the action of a neuropeptide/neurotransmitter than previously thought.     

Correlation between the functional status of brain structures and the degree of coherence of their potentials during food-getting behavior in the dog

By means of the cited formula, integral indices of potential coherence of the following pairs of brain structures were calculated: hippocampus--frontal cortex, amygdala--frontal cortex, hippocampus--amygdala. In food-procuring behavior of dogs, the values of these indices increase simultaneously with the increase of the level of functional state of the brain structures. The values become higher under the action of a signal with a greater informational significance for alimentary need satisfaction than under the action of a signal with lesser informational significance.     

Effect of scopolamine on formation and fixation of temporary connections in rats with altered brain serotonin levels

The influence of scopolamine on elaboration and maintenance of conditioned reflexes of two-way avoidance was studied in rats under conditions of excess and deficit of serotonin in the brain. Administration of scopolamine to intact rats accelerated conditioning and did not prevent fixation of the reflex. Administration of scopolamine to animals with a lowered level of serotonin in the brain (by means of para-chlorophenylalanine) impaired conditioning and induced amnesia. In animals with ablated raphe nuclei, the same dose of scopolamine did not prevent elaboration and maintenance of conditioned reflexes. Accumulation of scopolamine in the brain by means of 5-oxytryptophan abolished acceleration of conditioning, which is specific for scopolamine, and affected the preservation of the reflexes. Against the background of the action of iprozid, scopolamine impaired the conditioning and tended to deteriorate the maintenance of conditioned reflexes. It is assumed that the serotoninergic system exerts a modulating influence on the activity of the brain cholinergic and cholinoreactive mechanisms.     

Mechanisms of the regulation of membrane receptor activity by synthetic antioxidants of the screened phenol class

The influence of synthetic water-soluble phenol antioxidants, phenosan and the potassium salt of phenosan (phenosan-K), on the signal processing in some membrane receptor systems of the rat brain has been studied. It was demonstrated that these compounds act at the level transmembrane signal processing rather than at the level of ligand-receptor complex formation. The influence of phenosan and phenosan-K on the activity of brain receptors being due to antioxidants interaction with a hydrophobic moiety of these receptors or the action of antioxidants on the second messengers system. It is proposed that this in vitro action of phenol antioxidants, at concentrations exceeding 10 mcM, is a result of the antioxidant's non-specific interaction with cell plasma membranes and alteration of physicochemical properties of membrane lipids caused by these inhibitors of free radical reactions.     

Influence of changes in glutathione concentration on body temperature and tolerance to cerebral ischemia

Two compounds that deplete glutathione (buthionine sulfoximine and diethyl maleate) with different mechanisms of action decrease body temperature and increase tolerance to complete global cerebral ischemia, both correlating closely with the glutathione concentration decrease. Glutathione apparently participates in the regulations of these functional parameters. GSH diethyl ester does not influence the latter, though it increases moderately the GSH concentration. Injection of GSH ester into the cerebral ventricles or subcutaneously selectively increases the GSH level in the brain and liver. An influence of the brain on the glutathione system in the liver was revealed. Diethyl maleate and GSH ester increase the activity of glutathione metabolizing enzymes under certain conditions.     

THE EFFECT OF AMINO-OXYACETIC ACID ON BRAIN CATECHOLAMINES

Abstract— —Administration of amino-oxyacetic acid (AOAA) to rats induced a pronounced decrease of midbrain norepinephrine (NE) and adrenal epinephrine (E) after 30 min, at which time the GABA level of midbrain had increased to 117 per cent of the initial value. The concentrations of NE in the pons-medulla and of dopamine (DA) in the cerebral hemispheres were not changed.
Further increases in brain GABA were accompanied by a rise of NE in midbrain and pons-medulla beginning 1 hr after AOAA administration. A rise of cerebral DA level was observed only after 4 hr. Six hours after AOAA administration the levels of both NE and DA in brain were reduced.
From the results of these and other studies, where administration of small amounts of GABA were shown to affect brain NE and serotonin levels, it is suggested that monoamines may be involved in the physiological action of GABA in the brain.     

Absence of direct action of insulin on metabolism of the isolated perfused rat brain

The ability of insulin to influence directly the metabolism of the mammalian brain has been evaluated with an isolated, perfused rat brain preparation. Insulin was added to the perfusion fluid or was injected into the rat from which the isolated brain preparation was subsequently made. The spontaneous electrical activity of the brain, the rate of cerebral glucose consumption and the rate of efflux of K⁺ from the brain were not affected by insulin. We conclude that insulin either does not act directly on the brain or that its action is very small and/or very slow in comparison with its action on other tissues. We suggest that the effects on brain metabolism reported to occur after administering insulin and glucose to the intact animal may be secondary to the large stimulation of the metabolism of the liver and/or other organs.     

c-fos mRNA in mouse brain after MPTP treatment.

The neurotoxin, MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) induces a transient increase of mRNA for the immediate-early gene c-fos in the mouse brain. The c-fos mRNA level is MPTP dose-dependent and is evident in all brain regions tested including striatum, hypothalamus, cortex, hippocampus, cerebellum and midbrain. There are regional differences in the time-course for the rise of c-fos mRNA. Pretreatment with deprenyl, a selective monoamine oxidase B inhibitor, pargyline, a nonselective monoamine oxidase inhibitor, or mazindol, a dopamine uptake transport inhibitor, does not prevent the c-fos mRNA increase, suggesting that the elevation is due to the action of MPTP and not its neurotoxic metabolite MPP+.     

The effects of vasopressin and catecholamines on cyclic AMP in homogenates of rat brain

Vasopressin is known to mediate its action on the kidney through increasing the concentrations of cyclic AMP. As vasopressin is widely distributed in many extra hypothalamic areas of the brain and can be shown to act centrally, we have investigated the effect of vasopressin on cyclic AMP levels in homogenates of the striatal and locus coeruleus areas. In contrast with the effect obtained on the kidney, vasopressin did not stimulate adenyl cyclase activity in rat brain homogenates in a dose-related manner. The stimulation of cyclic AMP observed with dopamine or noradrenaline in these brain areas and the hippocampus was not affected by the presence of vasopressin. These observations suggest that the action of vasopressin on the brain is not mediated through cyclic AMP.     

Effect of chronic administration of phenytoin on regional monoamine levels in rat brain

Phenytoin (DPH) is a widely used anticonvulsant drug but a conclusive mode of action is not yet clear. This study was undertaken to assess the effects of chronic administration of DPH on monoamine levels. DPH (50 mg/kg body weight) was administered to adult male Wistar rats by intraperitoneal injections for 45 days and the regional brain levels of norepinephrine (NE), dopamine (DA) and serotonin (5-HT) were assayed using high performance liquid chromatographic (HPLC) method. The experimental rats revealed no behavioral deficits of any kind nor body and brain weight deficits were observed. Increased NE levels were observed after DPH administration in motor cortex (P<0.05), striatum-accumbens (P<0.01) and hippocampus (P<0.01), whereas, NE level was decreased in brain stem (P<0.05). DA levels were increased in striatum-accumbens (P<0.05), hypothalamus (P<0.001) and cerebellum (P<0.001) but decreased in brainstem (P<0.01). In DPH treated rats, 5-HT levels were increased in motor cortex (P<0.001) but decreased in cerebellum (P<0.001) when compared to control group of rats. The present study suggest that chronic administration of DPH induces alterations in monoamine levels in specific brain regions. DPH seems to mediate, its anticonvulsant action by selectively altering the monoamine levels in different brain regions.