Continuous administration of leuprolide acetate improves urinary function in male rats with severe thoracic spinal cord injury.

AIMS: To determine if a continuous administration of leuprolide acetate (LA), a synthetic agonist for the gonadotrophin-releasing hormone receptor, facilitates the recovery of urinary function in spinal cord injured male rats. MAIN METHODS: Male Wistar rats were randomized into spinal cord injury (SCI; n = 7), SCI with continuous administration of LA for two weeks via implantation of a subcutaneous osmotic pump (SCI + LA; n = 7), Sham SCI (SH-SCI; n = 6) or no surgery (Intact; n = 6) groups. Micturition, hind-limb nociception and locomotor behaviors were analyzed before and after surgical procedures on days 7, 14, 21 and 28. After behavioral studies, electromyography of the external urethral sphincter (EUS-EMG) and cystometric (CMG) studies were performed in all groups. KEY FINDINGS: SCI significantly decreased frequency of voids and CMG parameters (p < 0.001), abolished the bursting activity of the EUS during CMG, significantly increased hind limb sensory threshold and decreased locomotor performance in comparison to the other groups (p < 0.001). Continuous LA treatment significantly increased the frequency of voids and improved CMG parameters (p < 0.001), exhibiting bursting EUS activity during CMGs, and enhanced locomotor performance in comparison to SCI rats (p < 0.001). SIGNIFICANCE: SCI severely affected behavioral and functional micturition processes, including sensory and locomotor functions. Systemic and uninterrupted treatment with LA improves the recovery of micturition behavior and the synergistic function of the EUS. Furthermore, sensory and locomotor responses were also improved in SCI rats. This procedure may have a therapeutic potential to facilitate urinary function recovery in patients with SCI.

Expression of BAFF and BAFF receptors in primary Sjögren's syndrome patients with ectopic germinal center-like structures.

B cell-activating factor (BAFF) is an essential cytokine in primary Sjögren's syndrome (pSS) physiopathology. It has been reported that pSS patients develop germinal center-like (GC-like) structures in their minor salivary glands (MSGs). BAFF, BAFF-R, TACI, and BCMA expression was analyzed in MSGs from 29 subjects (nonspecific chronic sialadenitis and focal lymphocytic sialadenitis with the presence [pSS-GC(+)] or absence [pSS-GC(-)] of GC-like structures). Twenty-four percent of patients showed ectopic GC-like structures and a high focus score [p < 0.001 vs pSS-GC(-)]. BAFF serum levels (sBAFF) were high in pSS patients (p = 0.025 vs healthy subjects). However, the pSS-GC(-) group showed higher sBAFF levels than pSS-GC(+) patients. BAFF and BAFF-R glandular expression levels were higher in pSS-GC(+) patients, without significant differences compared to pSS-GC(-) patients. Soluble levels of BAFF correlated with anti-La/SSB antibodies and disease duration. Our results showed that BAFF could contribute to focal lymphocytic infiltration. The role of BAFF-binding receptors in MSGs is proposed as a mechanism for the possible establishment of ectopic GC-like structures and disease progression in some patients. In conclusion, this study supports previous evidence that considers the active BAFF system role in the pathogenesis of pSS and the need for strong biomarkers in this disease.

BDNF and AMPA receptors in the cNTS modulate the hyperglycemic reflex after local carotid body NaCN stimulation.

The application of sodium cyanide (NaCN) to the carotid body receptors (CBR) (CBR stimulation) induces rapid blood hyperglycemia and an increase in brain glucose retention. The commissural nucleus tractus solitarius (cNTS) is an essential relay nucleus in this hyperglycemic reflex; it receives glutamatergic afferents (that also release brain derived neurotrophic factor, BDNF) from the nodose-petrosal ganglia that relays CBR information. Previous work showed that AMPA in NTS blocks hyperglycemia and brain glucose retention after CBR stimulation. In contrast, BDNF, which attenuates glutamatergic AMPA currents in NTS, enhances these glycemic responses. Here we investigated the combined effects of BDNF and AMPA (and their antagonists) in NTS on the glycemic responses to CBR stimulation. Microinjections of BDNF plus AMPA into the cNTS before CBR stimulation in anesthetized rats, induced blood hyperglycemia and an increase in brain arteriovenous (a-v) of blood glucose concentration difference, which we infer is due to increased brain glucose retention. By contrast, the microinjection of the TrkB antagonist K252a plus AMPA abolished the glycemic responses to CBR stimulation similar to what is observed after AMPA pretreatments. In BDNF plus AMPA microinjections preceding CBR stimulation, the number of c-fos immunoreactive cNTS neurons increased. In contrast, in the rats microinjected with K252a plus AMPA in NTS, before CBR stimulation, c-fos expression in cNTS decreased. The expression of AMPA receptors GluR2/3 did not change in any of the studied groups. These results indicate that BDNF in cNTS plays a key role in the modulation of the hyperglycemic reflex initiated by CBR stimulation.

Glutamatergic Receptor Activation in the Commisural Nucleus Tractus Solitarii (cNTS) Mediates Brain Glucose Retention (BGR) Response to Anoxic Carotid Chemoreceptor (CChr) Stimulation in Rats.

Glutamate, released from central terminals of glossopharyngeal nerve, is a major excitatory neurotransmitter of commissural nucleus tractus solitarii (cNTS) afferent terminals, and brain derived neurotrophic factor (BDNF) has been shown to attenuate glutamatergic AMPA currents in NTS neurons. To test the hypothesis that AMPA contributes to glucose regulation in vivo modulating the hyperglycemic reflex with brain glucose retention (BGR), we microinjected AMPA and NBQX (AMPA antagonist) into the cNTS before carotid chemoreceptor stimulation in anesthetized normal Wistar rats, while hyperglycemic reflex an brain glucose retention (BGR) were analyzed. To investigate the underlying mechanisms, GluR2/3 receptor and c-Fos protein expressions in cNTS neurons were determined. We showed that AMPA in the cNTS before CChr stimulation inhibited BGR observed in aCSF group. In contrast, NBQX in similar conditions, did not modify the effects on glucose variables observed in aCSF control group. These experiments suggest that glutamatergic pathways, via AMPA receptors, in the cNTS may play a role in glucose homeostasis.

Responses of glial cells to stress and glucocorticoids.

A growing body of evidence suggests that glial cells are involved in practically all aspects of neural function. Glial cells regulate the homeostasis of the brain, influence the development of the nervous system, modulate synaptic activity, and carry out the immune response inside the brain. In addition, they play an important role in the restoration of the nervous system after damage, and they also participate in various neurodegenerative disorders. In a similar way, the importance of stress and glucocorticoids (GCs) on brain function is being increasingly recognized. Within the brain, stress hormones target both neurons and glial cells. Through their actions on these cells, glucocorticoids exert organizational functions on various processes of the developing brain and contribute to neuronal plasticity in the adult brain. Moreover, stress and glucocorticoids have become especially attractive in the study of a number of neurodegenerative disorders. However, studies on the mechanisms behind glucocorticoid-induced regulation of brain function have been classically focused on their effects on neurons. In this review, we start by describing the main functions of glial cells and then proceed to present data highlighting the effects of stress and GCs on brain function. We conclude the review by presenting recent evidence linking stress and glucocorticoids to glial cell function.

Nitric oxide in the solitary tract nucleus (STn) modulates glucose homeostasis and FOS-ir expression after carotid chemoreceptor stimulation.

We evaluate in rats the role of NO in the solitary tract nucleus (STn) after an anoxic stimulus to carotid body chemoreceptor cells (CChrc) with cyanide (NaCN), on the hyperglycemic reflex with glucose retention by the brain (BGR) and FOS expression (FOS-ir) in the STn. The results suggest that nitroxidergic pathways in the STn may play an important role in glucose homeostasis. A NO donor such as sodium nitroprusside (NPS) in the STn before CChrc stimulation increased arterial glucose level and significantly decreased BGR. NPS also induced a higher FOS-ir expression in STn neurons when compared to neurons in control rats that only received artificial cerebrospinal fluid (aCSF) before CChrc stimulation. In contrast, a selective NOS inhibitor such as Nomega-nitro-L-arginine methyl ester (L-NAME) in the STn before CChrc stimulation resulted in an increase of both, systemic glucose and BGR above control values. In this case, the number of FOS-ir positive neurons in the STn decreased when compared to control or to NPS experiments. FOS-ir expression in brainstem cells suggests that CChrc stimulation activates nitroxidergic pathways in the STn to regulate peripheral and central glucose homeostasis. The study of these functionally defined cells will be important to understand brain glucose homeostasis.

Increased lipid peroxidation and neuron specific enolase in treatment refractory schizophrenics.

It is well-known that increased lipid peroxidation and failure of antioxidant mechanisms leads to neuronal damage in schizophrenic patients. However, this neurodegenerative mechanism has not been studied in treatment refractory schizophrenics (TRS). Therefore, the main purpose of this study was to determine neuronal damage in TRS in comparison to non-refractory schizophrenics (NRS) by means of quantitative analysis of lipid peroxidation and neuron specific enolase (NSE) related to the psychopathology severity. Two groups of paranoid schizophrenics, TRS and NRS, and a group of healthy controls (CO) were assembled (n=13). Lipid peroxidation was analyzed through spectrophotometry for quantification of malonaldehyde (MDA) and 4-hydroxynonenal (4-HNE) serum concentrations. As well, serum NSE was quantified by radioimmunoassay (ELSA). Psychopathology was evaluated using the brief psychiatric rating scale (BPRS) and the positive and negative symptoms scale (PANSS). TRS showed significant higher concentrations of lipoperoxides by-products and NSE, than NRS and CO. Clinical scores also revealed a more severe pathology in TRS, than in NRS. Raised lipoperoxidation correlated with higher delusions and emotional withdrawal symptoms, and increased NSE correlated with a lower flow of the conversation and lack of spontaneity. All these results together suggest that TRS patients suffer a greater lipid peroxidation and neuronal damage than NRS, apparently related to worsening of some of the psychiatric symptoms.

[The effects of the social environment on the brain]. / Efectos cerebrales del medio ambiente social.

AIMS: This work analyses the main studies dealing with the mechanisms by which the brain is altered by chronic stress and the impact of social stimuli on the activation of these mechanisms, which can lead to behavioural disorders and cognitive impairment in communities of mammals. DEVELOPMENT: The physiological and hormonal responses triggered as a response to stress are linked to alterations in certain areas of the brain and more particularly in the hippocampus. These mechanisms include hyperactivity of the hypothalamus-pituitary-adrenal axis, raised levels of corticosteroids and excitatory amino acids, neurotoxicity due to intracellular accumulation of calcium, apoptosis and a number of factors having to do with the immunological system. Most of these studies have involved the exogenous application of supraphysiological levels of corticosteroids or challenging the individual with stimuli that do not properly belong to their natural surroundings. Nevertheless, it is also possible that these mechanisms are triggered by aversive social stimuli from the natural environment, such as confrontation, establishing hierarchies, neglect and social evaluation. It has been proved that social stress has important effects on conduct and health, especially with regard to the structural and functional integrity of the brain. CONCLUSIONS: Social stress can trigger important alterations in the nervous system of individuals exposed to it and these changes can manifest themselves as varying types of disorders affecting conduct and the cognitive skills. Nevertheless, not all natural surroundings give rise to these adverse effects, as balanced communities offer their members support, protection and a series of other advantages.

Efectos cerebrales del medio ambiente social / The effects of the social environment on the brain

Objetivo. El presente trabajo analiza los principales estudios sobre los mecanismos de alteración cerebral resultantes del estrés crónico y el impacto de los estímulos de tipo social sobre la activación de estos mecanismos, de lo que pueden resultar alteraciones conductuales y déficit cognitivos en las comunidades de mamíferos. Desarrollo. Las respuestas hormonal y fisiológica frente al estrés están vinculadas con alteraciones de algunas áreas cerebrales, especialmente el hipocampo. Entre estos mecanismos están: hiperactividad del eje hipotálamo-hipófisis-adrenal, elevación de la concentración de los corticosteroides y los aminoácidos excitatorios, neurotoxicidad por acumulación intracelular de calcio, apoptosis y algunos factores del sistema inmunológico. La mayoría de estos estudios han utilizado la aplicación exógena de concentraciones suprafisiológicas de corticosteroides o la confrontación del individuo con estímulos ajenos a su ambiente natural. Sin embargo, posiblemente, esos mecanismos también pueden activarse por la estimulación social aversiva del medio natural, como confrontación, establecimiento de jerarquías, abandono y evaluación social. Se ha demostrado que el estrés social tiene efectos importantes sobre el comportamiento y la salud, especialmente sobre la integridad estructural y funcional cerebral. Conclusiones. El estrés social provoca alteraciones importantes en el sistema nervioso de los individuos expuestos y estos cambios pueden manifestarse por trastornos variables del comportamiento y las habilidades cognitivas; sin embargo, no siempre resultan efectos adversos de todos los ambientes naturales, ya que las comunidades equilibradas brindan apoyo, protección y numerosas ventajas a los individuos (AU)

Aims. This work analyses the main studies dealing with the mechanisms by which the brain is altered by chronic stress and the impact of social stimuli on the activation of these mechanisms, which can lead to behavioural disorders and cognitive impairment in communities of mammals. Development. The physiological and hormonal responses triggered as a response to stress are linked to alterations in certain areas of the brain and more particularly in the hippocampus. These mechanisms include hyperactivity of the hypothalamus-pituitary-adrenal axis, raised levels of corticosteroids and excitatory amino acids, neurotoxicity due to intracellular accumulation of calcium, apoptosis and a number of factors having to do with the immunological system. Most of these studies have involved the exogenous application of supraphysiological levels of corticosteroids or challenging the individual with stimuli that do not properly belong to their natural surroundings. Nevertheless, it is also possible that these mechanisms are triggered by aversive social stimuli from the natural environment, such as confrontation, establishing hierarchies, neglect and social evaluation. It has been proved that social stress has important effects on conduct and health, especially with regard to the structural and functional integrity of the brain. Conclusions. Social stress can trigger important alterations in the nervous system of individuals exposed to it and these changes can manifest themselves as varying types of disorders affecting conduct and the cognitive skills. Nevertheless, not all natural surroundings give rise to these adverse effects, as balanced communities offer their members support, protection and a series of other advantages (AU)

Beneficial effects of alpha-lipoic acid plus vitamin E on neurological deficit, reactive gliosis and neuronal remodeling in the penumbra of the ischemic rat brain.

During cerebral ischemia-reperfusion, the enhanced production of oxygen-derived free radicals contributes to neuronal death. The antioxidants alpha-lipoic acid and vitamin E have shown synergistic effects against lipid peroxidation by oxidant radicals in several pathological conditions. A thromboembolic stroke model in rats was used to analyze the effects of this mixture under two oral treatments: intensive and prophylactic. Neurological functions, glial reactivity and neuronal remodeling were assessed after experimental infarction. Neurological recovery was only found in the prophylactic group, and both antioxidant schemes produced down-regulation of astrocytic and microglial reactivity, as well as higher neuronal remodeling in the penumbra area, as compared with controls. The beneficial effects of this antioxidant mixture suggest that it may be valuable for the treatment of cerebral ischemia in humans.

Astrocytic and microglia cells reactivity induced by neonatal administration of glutamate in cerebral cortex of the adult rats.

Recent studies confirm that astrocytes and neurons are associated with the synaptic transmission, particularly with the regulation of glutamate (Glu) levels. Therefore, they have the capacity to modulate the Glu released from neurons into the extracellular space. It has also been demonstrated an intense astrocytic and microglia response to physical or chemical lesions of the central nervous system. However, the persistence of the response of the glial cells in adult brain had not been previously reported, after the excitotoxic damage caused by neonatal dosage of monosodium glutamate (MSG) to newborn rats. In this study, 4 mg/g body weight of MSG were administered to newborn rats at 1, 3, 5, and 7 days after birth, at the age of 60 days the astrocytes and the microglia cells were analyzed with immunohistochemical methods in the fronto-parietal cortex. Double labeling to glial fibrillary acidic protein (GFAP) and BrdU, or isolectin-B(4) and BrdU identified astrocytes or microglia cells that proliferated; immunoblotting and immunoreactivity to vimentin served for assess immaturity of astrocytic intermediate filaments. The results show that the neonatal administration of MSG-induced reactivity of astrocytes and microglia cells in the fronto-parietal cortex, which was characterized by hyperplasia; an increased number of astrocytes and microglia cells that proliferated, hypertrophy; increased complexity of the cytoplasm extension of both glial cells and expression of RNAm to vimentin, with the presence of vimentin-positive astrocytes. This glial response to neuroexcitotoxic stimulus of Glu on the immature brain, which persisted to adulthood, suggests that the neurotransmitter Glu could trigger neuro-degenerative illnesses.

Utilización de prótesis de quitosana y silicona en la regeneración del nervio ciático axotomizado de ratas / Quitosan and silicon protesis of the axiotomized cyatic nerve in rats

Para la tubulización de nervios lesionados se ha utilizado silicona con buenos resultados en defectos menores de 3 cm. La silicona es considerada como un material inerte, pero tiene como inconveniente que no es absorbible y es necesaria una segunda cirugía para retirarla. Recientemente, se ha centrado el interés en la utilización de compuestos bioactivos, tales como, la quitosana, homopolímero de estructura lineal con enlaces1-4, N acetilglucosamina, obtenida de la desacetilación de la quitina. La quitosana es absorbible, hipoalergénica, inmunoestimulante y puede actuar como vehículo para liberación prolongada de compuestos. En este trabajo, fue usada para tubulizar el nervio ciático de ratas, para ello se compararon los efectos de ambas prótesis (silicona y quitosana), se analizó la supervivencia neuronal en el dominio medular del nervio ciático y la recuperación locomotriz por medio del índice funcional del nervio ciático. En ninguno de los grupos de animales tubulizados con quitosana o silicona se encontraron indicios de degeneración neuronal en el dominio medular correspondiente. Los animales tubulizados con prótesis de quitosana presentaron una mejor recuperación funcional, esto indica que las prótesis de quitosana produjeron efectos similares a los que resultaron con silicona. Una de las ventajas inmediatas por el uso de quitosana fue evitar una segunda cirugía para retirar la prótesis; sin embargo, este biomaterial posee muchas otras cualidades que facilitan la recuperación de nervios seccionados, mismas que deberán estudiarse utilizando otras técnicas.

Prednisone induces anxiety and glial cerebral changes in rats.

OBJECTIVE: To assess whether prednisone (PDN) produces anxiety and/or cerebral glial changes in rats. METHODS: Male Wistar rats were studied and 3 groups were formed (8 rats per group). The moderate-dose group received 5 mg/kg/day PDN released from a subcutaneous implant. In the high-dose group, implants containing PDN equivalent to 60 mg/kg/day were applied. In the control group implants contained no PDN. Anxiety was assessed using an open field and elevated plus-maze devices. The number of cells and cytoplasmic transformation of astrocytes and microglia cells were assessed by immunohistochemical analyses. RESULTS: Anxiety was documented in both groups of PDN treated rats compared with controls. The magnitude of transformation of the microglia assessed by the number of intersections was significantly higher in the PDN groups than in controls in the prefrontal cortex (moderate-dose, 24.1; high-dose, 23.6; controls 18.7; p < 0.01) and striatum (moderate-dose 25.6; high-dose 26.3; controls 18.9; p < 0.01), but not in hippocampus. The number of stained microglia cells was significantly higher in the PDN treated groups in the prefrontal cortex than in controls (moderate-dose, 29.1; high-dose, 28.4; control, 17.7 cells per field; p < 0.01). Stained microglia cells were significantly more numerous striatum and hippocampus in the high-dose group compared to controls. CONCLUSION: Subacute exposure to PDN induced anxiety and reactivity of microglia. The relevance of these features for patients using PDN remains to be elucidated.

Dehydroepiandrosterone, pregnenolone and sex steroids down-regulate reactive astroglia in the male rat brain after a penetrating brain injury.

Astrocytes are a target for steroid hormones and for steroids produced by the nervous system (neurosteroids). The effect of gonadal hormones and several neurosteroids in the formation of gliotic tissue has been assessed in adult male rats after a penetrating wound of the cerebral cortex and the hippocampal formation. The hormones testosterone, 17beta-estradiol and progesterone and the neurosteroids dehydroepiandrosterone, pregnenolone and pregnenolone sulfate resulted in a significant decrease in the accumulation of astrocytes in the proximity of the wound and in a decreased bromodeoxyuridine incorporation in reactive astrocytes. Of all steroids tested, dehydroepiandrosterone was the most potent inhibitor of gliotic tissue formation. These findings suggest that neurosteroids and sex steroids may affect brain repair by down-regulating gliotic tissue.

Synaptic remodeling in the arcuate nucleus during the estrous cycle is induced by estrogen and precedes the preovulatory gonadotropin surge.

We have shown that the ovarian cycle is accompanied by a fall in the axosomatic synapses on randomly selected neurons of the arcuate nucleus by the morning of estrus, with a return to the preovulatory levels by the morning of metestrus, indicating a possible role in positive feedback. However, it remains to be proven that the circulating estradiol is the actual regulator of this physiological synaptic plasticity, or that estrogen-induced synaptic retraction precedes in the surge of gonadotropins at midcycle. To resolve these questions, we used an estradiol-immunoneutralization protocol and studied arcuate nucleus axosomatic synapses during the critical points of the estrous cycle. In addition to blocking positive feedback, estrogen immunoneutralization abolished synaptic retraction in the arcuate nucleus. As a positive control, the nonbinding estrogen diethylstilbestrol maintained the gonadotropin surge and synaptic retraction in the antiestradiol-treated animals. Furthermore, in the diluent-treated cycling control females, the synaptic retraction was found to precede the preovulatory LH surge. We demonstrated that the midcycle synaptic retraction of arcuate nucleus synapses is induced by the preovulatory estradiol surge, and that these morphological events precede the preovulatory gonadotropin surge. Taken together, these observations strongly suggest that the hypothalamic mechanism underlying the physiological disinhibition of gonadotropins at midcycle (positive feedback) requires estrogen-induced synaptic retraction in the arcuate nucleus.

Expression of the beta 1 and beta 2(AMOG) subunits of the Na,K-ATPase in neural tissues: cellular and developmental distribution patterns.

We have used isoform-specific antisera against the Na,K-ATPase beta 1 (SpETb1) and beta 2(AMOG) (SpETb2) subunit isoforms in order to establish their specific cellular and subcellular localization in several developmental stages of the rat central nervous system. Immunocytochemical preparations revealed beta 1 Isoform protein in most neural cells, being predominantly located in the soma of neurons and astrocytes, with no appreciable developmental variations. In the newborn rat, beta 2(AMOG) immunoreactivity was present in cellular processes of astroglia and in the somas of neurons and decreasing in intensity with maturation until adulthood, where no beta 2 isoform was detected in neurons. The differential location of these isoforms, both developmentally and at the cellular level suggest a complex regulation of their genes expression and mechanisms of subcellular distribution, as well as functional differences.

Gonadal hormone regulation of insulin-like growth factor-I-like immunoreactivity in hypothalamic astroglia of developing and adult rats.

The influence of gonadal steroids on insulin-like growth factor I (IGF-I)-like immunoreactivity was assessed in the rat arcuate nucleus, an area of the hypothalamus that regulates pituitary secretion. IGF-I-like immunoreactivity was observed in hypothalamic cells with the morphological aspects of tanycytes and astrocytes. The surface density of IGF-I-like immunoreactive glia increased with puberty in the arcuate nucleus of male and female rats, while decreasing with age in other brain areas. Gender differences in the surface density of IGF-I-like immunoreactive glia were detected in adult animals, with males and androgenized females having significantly higher values than normal females. In the latter, the surface density of IGF-I-like immunoreactive glia was increased in the afternoon of proestrus and in the morning of estrus compared to the morning of proestrus, diestrus and metestrus. In addition, IGF-I-like immunoreactivity showed a dose-dependent increase in ovariectomized rats injected with 17 beta-estradiol, but not in those receiving 17 alpha-estradiol. The effect of 17 beta-estradiol was blocked by simultaneous administration of progesterone, while this hormone alone had no effect. These results indicate that IGF-I-like immunoreactivity in arcuate glial cells is affected by the hormonal environment and suggest that IGF-I-like immunoreactive glia may be involved in neuroendocrine events within the hypothalamus.

Gonadal hormone regulation of glial fibrillary acidic protein immunoreactivity and glial ultrastructure in the rat neuroendocrine hypothalamus.

The influence of gonadal steroids on the ultrastructure of glial cells and on the immunoreactivity for the specific astrocytic marker glial fibrillary acidic protein (GFAP) has been assessed in the neuroendocrine hypothalamus. The following parameters were analyzed in the arcuate nucleus of adult female rats: the number and the surface density of cells immunoreactive for GFAP, the number of glial profiles showing bundles of glial filaments, the size of the bundles of glial filaments, and the proportion of neuronal perikaryal membrane apposed by glial processes. These parameters were studied during the different phases of the estrous cycle, after ovariectomy, and after the administration of estradiol or progesterone to ovariectomized rats. No significant differences were detected in the number of GFAP-immunoreactive cells among the different experimental groups. The surface density of GFAP-immunoreactive material, the number of glial profiles in the neuropil, and the proportion of neuronal perikaryal membrane covered by glia were increased in the afternoon of proestrus and in the morning of estrus compared with other phases of the estrous cycle or to ovariectomized rats and showed a rapid (5 h) and reversible increase in ovariectomized rats injected with 17 beta estradiol, with a maximal effect by 24 h after the administration of the hormone. In contrast, the size of the bundles of glial filaments was decreased in the afternoon of proestrus, in the morning of estrus, and by the administration of estradiol to ovariectomized rats. The parameters studied were not affected by the administration of progesterone. However, progesterone (300 micrograms/rat) blocked the effects of 17 beta estradiol (1, 10, and 300 micrograms). The results suggest that glial cells may be actively involved in the modulation of neuroendocrine events by the hypothalamus.

Gonadal hormones down-regulate reactive gliosis and astrocyte proliferation after a penetrating brain injury.

Astrocytes are a target for gonadal steroids in the normal brain. The putative modulation by gonadal hormones of the astrocytic reaction to brain injury was assessed in this study. Male and female adult Wistar albino rats were gonadectomized and, one month later, their brains were lesioned by a longitudinal incision crossing the parietal cerebral cortex, the CA1 field of the dorsal hippocampus and the dentate gyrus. Males were injected either with testosterone (20 micrograms/rat) or vehicle immediately after surgery. Females were injected either with 17 beta estradiol (250 micrograms/rat), progesterone (500 micrograms/rat) or vehicle. Hormonal injections were repeated 24 and 48 h after brain injury. All animals received injections of 5'-bromodeoxyuridine (BrdU) to label proliferating cells. Histological sections from the brain of animals killed 72 h after surgery were used for the double immunohistochemical localization of BrdU and glial fibrillary acidic protein (GFAP). The number of GFAP-immunoreactive astrocytes and the number of double labelled astrocytes (GFAP + BrdU) were recorded as a function of the distance to the lesion site in the parietal cerebral cortex, the CA1 field of the hippocampus and the dentate gyrus. Testosterone, estradiol and progesterone treatments resulted in a significant decrease in the number of GFAP-immunolabeled reactive astrocytes in the vicinity of the wound. The number of double labelled cells and the labelling index (proportion of GFAP-immunoreactive astrocytes labelled with BrdU) varied according to the cerebral area, the distance to the wound and the sex of the animals, and were significantly decreased by gonadal steroids in all the areas examined.(ABSTRACT TRUNCATED AT 250 WORDS)