Homovanillic acid levels in corpus striatum, limbic system and diencephalon of male and female rats

The HVA levels in corpus striatum, limbic system and diencephalon in male and female rats during the postnatal period have been measured. The HVA levels in corpus striatum and diencephalon differed significantly when both sexes wee compared, whereas in limbic system significant differences were not found. A decrease in the levels of HVA in all areas studied was observed.     

Acetylcholinesterase activity in brain slices of rats subjected to cooling

The acetylcholinesterase (AChE) activity is studied in rat slices of the cerebral cortex, corpus striatum, hypothalamus and medulla oblongata of rats during hypothermia (20 degrees C) and also 1 and 7 days after the posthypothermal period. Cooling of animals down to 20 degrees C is accompanied by an increase in the AChE activity in the brain both under incubation temperature of 20 degrees and 37 degrees C. Under prolonged hypothermia the AChE activity in the investigated brain regions, except for corpus striatum, returns to the control level. By the 7th day of posthypothermal period the AChE activity in corpus striatum, hypothalamus and medulla oblongata does not restore completely. The most substantial changes in the AChE activity both under hypothermia and posthypothermal period occur in corpus striatum, which obviously reflects its complicated functional role.     

Prolonged effect of stress at weaning on the brain serotonin metabolism and sexuality of female rats.

Weanling female rats were stressed (by water and food deprivation for two days) and three months later the following indexes were studied: 5-HT and 5-HIAA levels in five brain regions, blood plasma and cerebrospinal fluid (CSF), sexual activity and nocistatin level of the plasma and CSF. The 5-HIAA content of hypothalamus and brainstem was significantly decreased (in the brainstem with one third) and in the striatum significantly increased. Plasma nocistatin level was significantly increased. Meyerson index and lordosis quotient were similar to control, but the estrus frequency almost doubled in the stressed animals. Much more defense reactions were observed in the stressed females during trials of mating. The results demonstrate that, 1) the perinatal period is not only sensitive to the remote-effects of stress but later could also be stress-sensitive critical periods, and 2) the continuously differentiating (e.g. bone marrow) cells are sensitive to late imprinting by stress, as well as to the brain and the sexual system.     

Systemic administration of kainic acid produces elevations in TRH in rat central nervous system

Several studies have suggested that the concentration of thyrotropin releasing hormone (TRH) in the central nervous system (CNS) is influenced by the level of CNS activation. Hibernation in the ground squirrel and estivation in the lungfish result in region-specific decreases in TRH concentrations. Repeated electroconvulsive shock (ECS) and amygdaloid kindling have been shown to result in elevations of TRH in limbic brain regions. In the present study, limbic seizures induced by systemic administration of kainic acid resulted in substantial increases in the TRH content of posterior cortex and of dorsal and ventral hippocampus, and in moderate elevations in anterior cortex, amygdala/piriform cortex and corpus striatum. Maximal elevations in TRH were observed 2-4 days after kainic acid administration, and by 14 days TRH levels were similar to control values, with the exception of the dorsal hippocampus, which exhibited more prolonged elevations in TRH levels. Prior exposure to limbic seizure activity attenuated the magnitude of TRH elevation in response to a second administration of kainic acid in the posterior cortex but in no other region. These results indicate that seizure-related processes or events influence TRH systems in the CNS. Neuronal populations involved in limbic seizure induced damage may be involved in the modulation of posterior cortical TRH levels.     

Direct activation of the ventral striatum in anticipation of aversive stimuli

The brain "reward" system, centered on the limbic ventral striatum, plays a critical role in the response to pleasure and pain. The ventral striatum is activated in animal and human studies during anticipation of appetitive/pleasurable events, but its role in aversive/painful events is less clear. Here we present data from three human fMRI studies based on aversive conditioning using unpleasant cutaneous electrical stimulation and show that the ventral striatum is reliably activated. This activation is observed during anticipation and is not a consequence of relief after the aversive event. Further, the ventral striatum is activated in anticipation regardless of whether there is an opportunity to avoid the aversive stimulus or not. Our data suggest that the ventral striatum, a crucial element of the brain "reward" system, is directly activated in anticipation of aversive stimuli.     

Changes in the activity of enzymes of renin-angiotensin and kinin systems in the rat brain after adrenalectomy and administration of hydrocortisone

It is shown that the activity of enzymes participating in renin-angiotensin and brain kinin systems' metabolism depends on functional state of hypothalamo-pituitary-adrenocortical system. Under experimental hypocorticism the activity of angiotensin-converting enzyme and kininase I in the hypothalamus, hippocamp, corpus striatum and rat pituitary decreases; the renin-like enzyme activity decreases in the corpus striatum but increases in the hypothalamus and hippocamp. After hydrocortisone administration to adrenalectomized rats the angiotensin-converting enzyme activity of the hippocamp and pituitary is shown to be normalized as well as renin-like enzyme and kininase I of the hippocamp and corpus striatum. The activity of the studied enzymes in the hypothalamus decreases in this case.     

Effects on striatal and mesolimbic dopamine systems of a new potential antipsychotic drug -mezilamine- with weak cataleptogenic properties.

Mezilamine (2-methylamino-4-N-methylpiperazino-5-methylthio-6-chloropyrimidine) inhibits dopamine-sensitive adenylate cyclase in rat nucleus accumbens and striatum both in vitro and in vivo. After parenteral administration, mezilamine produces a dose dependent increase in homovanillic acid in rat and rabbit brain. As with clozapine, this increase is more marked in the limbic system than in the striatum of rabbit brain whereas the reverse holds true in the rat. However, in rats pretreated with probenecid, mezilamine and clozapine produce a greater activity in the limbic system while that of chlorpromazine is more pronounced in the striatum. In both regions mezilamine is more active than chlorpromazine. After chronic treatment (15 days), the activity of mezilamine decreases in the striatum but not in the limbic system. The low cataleptogenic activity of mezilamine cannot be explained by anticholinergic properties, neither can it be related to GABA-mimetic properties. Among the hypotheses discussed that attributing α-adrenergic properties to mezilamine is supported by the catalepsy-inducing effect observed in the rat when associating mezilamine and phenoxybenzamine.     

The role of neonatal NMDA receptor activation in defeminization and masculinization of sex behavior in the rat

Normal development of the male rat brain involves two distinct processes, masculinization and defeminization, that occur during a critical period of brain sexual differentiation. Masculinization allows for the capacity to express male sex behavior in adulthood, and defeminization eliminates or suppresses the capacity to express female sex behavior in adulthood. Despite being separate processes, both masculinization and defeminization are induced by neonatal estradiol exposure. Though the mechanisms underlying estradiol-mediated masculinization of behavior during development have been identified, the mechanisms underlying defeminization are still unknown. We sought to determine whether neonatal activation of glutamate NMDA receptors is a necessary component of estradiol-induced defeminization of behavior. We report here that antagonizing glutamate receptors during the critical period of sexual differentiation blocks estradiol-induced defeminization but not masculinization of behavior in adulthood. However, enhancing NMDA receptor activation during the same critical period mimics estradiol to permanently induce both defeminization and masculinization of sexual behavior.     

The role of neonatal NMDA receptor activation in defeminization and masculinization of sex behavior in the rat

Normal development of the male rat brain involves two distinct processes, masculinization and defeminization, that occur during a critical period of brain sexual differentiation. Masculinization allows for the capacity to express male sex behavior in adulthood, and defeminization eliminates or suppresses the capacity to express female sex behavior in adulthood. Despite being separate processes, both masculinization and defeminization are induced by neonatal estradiol exposure. Though the mechanisms underlying estradiol-mediated masculinization of behavior during development have been identified, the mechanisms underlying defeminization are still unknown. We sought to determine whether neonatal activation of glutamate NMDA receptors is a necessary component of estradiol-induced defeminization of behavior. We report here that antagonizing glutamate receptors during the critical period of sexual differentiation blocks estradiol-induced defeminization but not masculinization of behavior in adulthood. However, enhancing NMDA receptor activation during the same critical period mimics estradiol to permanently induce both defeminization and masculinization of sexual behavior.     

Glutamate (mGluR-5) gene expression in brain regions of streptozotocin induced diabetic rats as a function of age: role in regulation of calcium release from the pancreatic islets in vitro

Metabotrophic glutamate receptors (mGluRs) modulate cellular activities involved in the processes of differentiation and degeneration. In this study, we have analysed the expression pattern of group-I metabotropic glutamate receptor (mGlu-5) in cerebral cortex, corpus striatum, brainstem and hippocampus of streptozotocin induced and insulin treated diabetic rats (D+I) as a function of age. Also, the functional role of glutamate receptors in intra cellular calcium release from the pancreatic islets was studied in vitro. The gene expression studies showed that mGlu-5 mRNA in the cerebral cortex increased siginficantly in 7 weeks old diabetic rats whereas decreased expression was observed in brainstem, corpus striatum and hippocampus when compared to control. 90 weeks old diabetic rats showed decreased expression in cerebral cortex, corpus striatum and hippocampus whereas in brainstem the expression increased significantly compared to their respective controls. In 7 weeks old D+I group, mGlu-5 mRNA expression was significantly decreased in cerebral cortex and corpus striatum whereas the expression increased significantly in brainstem and hippocampus. 90 weeks old D+I group showed an increased expression in cerebral cortex, while it was decreased significantly in corpus striatum, brainstem and hippocampus compared to their respective controls. In vitro studies showed that glutamate at lower concentration (10^-7 M) stimulated calcium release from the pancreatic islets. Our results suggest that mGlu-5 receptors have differential expression in brain regions of diabetes and D+I groups as a function of age. This will have clinical significance in management of degeneration in brain function and memory enhancement through glutamate receptors. Also, the regulatory role of glutamate receptors in calcium release has immense therapeutic application in insulin secretion and function.     

Neonatal inhalatory anesthetic exposure: reproductive changes in male rats

We investigated the effects of an inhalatory anesthetic (ethyl ether) during the neonatal period of brain sexual differentiation on the later fertility and sexual behavior of male rats. Animals were exposed to ethyl ether immediately after birth. At adulthood, body weight, testes wet weight, and plasma testosterone levels were not affected; however, neonatal exposure to ether showed alterations on male fertility: a decrease in the number of spermatids and spermatozoa, an increase in the transit time of cauda epididymal spermatozoa and a decrease in daily sperm production. An alteration of sexual behavior was also observed: decreased male sexual behavior and appearance of homosexual behavior when the male rats were castrated and pretreated with exogenous estrogen. Probably, the ether delayed or reduced the testosterone peak of the sexual differentiation period, altering the processes of masculinization and defeminization of the hypothalamus. Our results indicate that perinatal exposure to ethyl ether during the critical period of male brain sexual differentiation, acting as endocrine disruptors, has a long-term effect on the fertility and sexual behavior of male rats, suggesting endocrine disruption through incomplete masculinization and defeminization of the central nervous system.     

Lack of effect of prolactin on the dopaminergic receptor sensitivity in striatal and limbic areas after experimentally-induced alterations in its peripheral levels.

Although it had been suggested that prolactin (PRL) modulates the dopaminergic receptor sensitivity in extrahypothalamic areas, recent studies have questioned this role. We studied the effects of PRL on the receptor sensitivity in the striatum and the limbic forebrain, analyzing the number of D1 and D2 receptors and the amount of their second messenger, cyclic-adenosine monophosphate (cAMP). Tyrosine hydroxylase (TH) activity and dopamine (DA) and L-3,4-dihydroxyphenylacetic acid (DOPAC) content were also measured as indices of presynaptic activity. The study was carried out in male rats submitted to either acute (PRL injection) or chronic (pituitary grafts or diethylstilbestrol (DES)-induced pituitary tumors) rises of plasma PRL levels. The results showed a common lack of effect of PRL on the dopaminergic receptor sensitivity in both brain areas and, only some few effects on presynaptic activity in the striatum. Thus, grafted rats showed a slight decrease in DA content in the striatum, but neither D1 and D2 receptor number and cAMP content nor DOPAC content and TH activity, were modified, whereas DES animals exhibited no changes in all the parameters studied. A single injection of ovine PRL caused a decrease in DOPAC content and an increase in TH activity in the striatum. In the case of the limbic area, both chronic and acute hyperprolactinemia failed to alter any of the indices studied. In summary, we cannot support the view that PRL plays a role as modulator of dopaminergic receptor sensitivity. The only effects were always produced at the presynaptic level on the striatum, and after acute treatment, which supports the possible development of tolerance after chronic changes in peripheral PRL levels.     

Sex Differences in Glutamic Acid Decarboxylase mRNA in Neonatal Rat Brain: Implications for Sexual Differentiation

Sexual differentiation of rodent brain is dependent upon hormonal exposure during a “critical period” beginning in late gestation and ending in early neonatal life. Steroid hormone action at this time results in anatomical and physiological sexual dimorphisms in adult brain, but the mechanism mediating these changes is essentially unknown. The inhibitory neurotransmitter, GABA, is involved in regulation of sexually dimorphic patterns of behavior and gonadotropin secretion in the adult. Recent evidence suggests that during development GABA is excitatory and provides critical neurotrophic and neuromodulatory influences. We hypothesized that steroid-induced changes in GABAergic neurotransmission during this critical period are important mediators of sexual differentiation in brain. Therefore, we quantified levels of mRNA for GAD, the rate-limiting enzyme in GABA synthesis. On Postnatal Day 1, males had significantly higher levels of GAD mRNA in the dorsomedial nucleus, arcuate nucleus, and CA1 region of hippocampus. On Postnatal Day 15, after the critical period for sexual differentiation has ended, these differences were no longer present. We examined the role of gonadal steroids in regulating GAD by removing testes of males and administering testosterone to females at birth. Exposure to testosterone was correlated with increased GAD mRNA in the dorsomedial nucleus. A sex difference in GAD mRNA was also observed in the medial preoptic area, but the influence of testosterone was inconclusive. We conclude that sex differences in the GABAergic system during development are partially hormonally mediated, and that these differences may contribute to the development of sexually dimorphic characteristics in adult brain.     

Enhancement of anandamide formation in the limbic forebrain and reduction of endocannabinoid contents in the striatum of delta9-tetrahydrocannabinol-tolerant rats

Recent studies have shown that the pharmacological tolerance observed after prolonged exposure to synthetic or plant-derived cannabinoids in adult rats is accompanied by down-regulation/desensitization of brain cannabinoid receptors. However, no evidence exists on possible changes in the contents of the endogenous ligands of cannabinoid receptors in the brain of cannabinoid-tolerant rats. The present study was designed to elucidate this possibility by measuring, by means of isotope dilution gas chromatography/mass spectrometry, the contents of both anandamide (arachidonoylethanolamide; AEA) and its biosynthetic precursor, N-arachidonoylphosphatidylethanolamine (NArPE), and 2-arachidonoylglycerol (2-AG) in several brain regions of adult male rats treated daily with delta9-tetrahydrocannabinol (delta9-THC) for a period of 8 days. The areas analyzed included cerebellum, striatum, limbic forebrain, hippocampus, cerebral cortex, and brainstem. The same regions were also analyzed for cannabinoid receptor binding and WIN-55,212-2-stimulated guanylyl-5'-O-(gamma-[35S]thio)-triphosphate ([35S]GTPgammaS) binding to test the development of the well known down-regulation/desensitization phenomenon. Results were as follows: As expected, cannabinoid receptor binding and WIN-55,212-2-stimulated [35S]GTPgammaS binding decreased in most of the brain areas of delta9-THC-tolerant rats. The only region exhibiting no changes in both parameters was the limbic forebrain. This same region exhibited a marked (almost fourfold) increase in the content of AEA after 8 days of delta9-THC treatment. By contrast, the striatum exhibited a decrease in AEA contents, whereas no changes were found in the brainstem, hippocampus, cerebellum, or cerebral cortex. The increase in AEA contents observed in the limbic forebrain was accompanied by a tendency of NArPE levels to decrease, whereas in the striatum, no significant change in NArPE contents was found. The contents of 2-AG were unchanged in brain regions from delta9-THC-tolerant rats, except for the striatum where they dropped significantly. In summary, the present results show that prolonged activation of cannabinoid receptors leads to decreased endocannabinoid contents and signaling in the striatum and to increased AEA formation in the limbic forebrain. The pathophysiological implications of these findings are discussed in view of the proposed roles of endocannabinoids in the control of motor behavior and emotional states.     

Behavioral reactions of rats and the contents of neurospecific proteins in their brain after single X-ray irradiation

We studied the behavior of rats in an open-field test and the contents of neurospecific proteins [neural cell adhesion molecule (NCAM) and glial fibrillary acidic protein (GFAP)] in the brain cortex, hippocampus, striatum, midbrain, cerebellum, andpons Varolii 1, 12, 24, 120, and 168 h after a single X-ray irradiation session (dose of 0.25 Gy). Within the postirradiation period, manifestations of the behavioral activity of the animals were mostly suppressed, and the parameters related to the emotional state of the animals were influenced to a greater extent. The dynamics of the NCAM and GFAP contents were complex and dissimilar in the brain structures under study, but it was possible to observe some general regularities. Within early periods of time, 12 h after irradiation, the NCAM content increased in the cortex, hippocampus, and cerebellum. In these structures, it reached approximately 220, 170, and 150%, respectively, as compared with the control, while it dropped to about 40% in thepons Varolii. Changes in the GFAP content reached their maximum 24 h after irradiation; this index dropped to 29, 44, 34, and 67% in the striatum,pons Varolii, midbrain, and cerebellum, respectively, while it increased to 380% in the hippocampus. Later time intervals were characterized by smoother changes in the contents of the above neurospecific proteins. Seven days after irradiation, the NCAM content did not differ from initial values in the striatum and cerebellum and was higher than the control in the neocortex, hippocampus, and midbrain. Within this period, the GFAP level in the cerebellum and midbrain was relatively normalized, but it increased in the hippocampus and decreased in the pons and striatum. Therefore, the greatest postirradiation shifts in the NCAM and GFAP levels were observed in the structures of the limbic system, and this can be correlated with the data on testing the rats in an open field.     

Localization of estrogen receptor-alpha and -betamRNA in brain areas controlling sexual behavior in Japanese quail

Two estrogen receptors (ERs), denoted ERalpha and ERbeta, have been identified in humans and various animal species, including the Japanese quail. Estrogens play a key role in sexual differentiation and in activation of sexual behavior in Japanese quail. The distribution of ERalpha in the brain of male and female adult quail has previously been studied using immunohistochemistry, whereas in situ hybridization has been employed to study the distribution of ERbeta mRNA in males only. In this article, we used in situ hybridization to study the distribution of mRNAs for both ERalpha and ERbeta in brain areas controlling sexual behavior of Japanese quail. Our results show that both ERalpha mRNA and ERbeta mRNA are localized in areas important for sexual behavior, such as the preoptic area and associated limbic areas, in both males and females. Moreover, we found differences in distribution of mRNA for the two receptors in these areas. The results of this article support previously reported data and provide novel data on localization of ER mRNAs in adult quail brain of both sexes.     

Brain tyrosine hydroxylase activity in behavior-selected silver foxes

In two groups of silver foxes--i.e. selected by the domestic type of behaviour and aggressive ones--studies have been made on the activity of the key enzyme in biosynthesis of catecholamines--i.e. tyrosine hydroxylase from the brain. Domesticated animals exhibited higher enzymic activity in the locus coeruleus, hypothalamus and cortex. Animals from both groups did not differ with respect to the level of tyrosine hydroxylase activity in the corpus striatum. The enzymic reactions of homogenates from locus coeruleus region of the brain in both groups of animals, as well as homogenates from the corpus striatum of the brain of aggressive animals exhibited low and approximately equal values of Michaelis constant for tyrosine. The value of KM was 3 times higher in the hypothalamus in both groups of foxes and in the corpus striatum of tame animals. Presumably, selection of silver foxes for the domestic type of behaviour resulted in the increase of biosynthesis of catecholamines in the brain due to the increase in the number of enzyme molecules. The increase in the activity of tyrosine hydroxylase in noradrenaline system of the brain may be associated with changes in the behavioural pattern of animals resulting from selection.     

Steroid-induced sexual differentiation of the developing brain: multiple pathways, one goal

Hormone exposure, including testosterone and its metabolite estradiol, induces a myriad of effects during a critical period of brain development that are necessary for brain sexual differentiation. Nuclear volume, neuronal morphology, and astrocyte complexity are examples of the wide range of effects by which testosterone and estradiol can induce permanent changes in the function of neurons for the purpose of reproduction in adulthood. This review will examine the multitude of mechanisms by which steroid hormones induce these permanent changes in brain structure and function. Elucidating how steroids alter brain development sheds light on how individual variation in neuronal phenotype is established during a critical period.     

Mechanisms of self-regulation and interaction of the central nervous system and of the hypophyseal-sexual system

Literary review on the problem of regulation of the sexual glands functions by the central nervous system and the effect of the sex and tropine hormones on the brain formation activity is given. In experiments on rabbits and rats sexual steroid hormones have been shown to alter the bioelectric activity mainly in the structures of the Nauta septo-hypothalamo-hippocampal circle and the amygdalar circle of the limbic system. The data obtained suggested the steroid hormones participation in the processes of self-regulation of the cerebral reticulo-hypothalamo-limbic complex's functions by means of involving the limbic system circles into the process of reverberation.