Evidence for the modulation of nociception in mice by central mast cells.

BACKGROUND: Hyperalgesia that develops following nerve ligation corresponds temporally and in magnitude with the number of thalamic mast cells located contralateral to the ligature. We tested the possibility that mast cells modulate nociception centrally, similar to their role in the periphery. METHODS: We examined the central effect of two hyperalgesic compounds that induce mast cell degranulation and of stabilized mast cells using cromolyn. RESULTS: Thermal hyperalgesia (tail flick) induced by nerve growth factor (NGF, a neurotrophic compound) and mechanical hyperalgesia (von Frey) induced by dynorphin A (1-17) (opioid compound) each correlated with the per cent of thalamic mast cells that were degranulated. Degranulation of these mast cells by the central injection of compound 48/80, devoid of neurotrophic or opioid activity, was sufficient to recapitulate thermal hyperalgesia. Stabilization of mast cells by central injections of cromolyn produced no analgesic effect on baseline tail flick or von Frey fibre sensitivity, but inhibited thermal hyperalgesia produced by compound 48/80 and tactile hyperalgesia induced by dynorphin and by Freund's complete adjuvant. Finally, chemical nociception produced by the direct activation of nociceptors by formalin (phase I) was not inhibited by centrally injected cromolyn whereas chemical nociception dependent on central sensitization (formalin-phase II and acetic acid-induced abdominal stretches) was. CONCLUSIONS: These convergent lines of evidence suggest that degranulation of centrally located mast cells sensitizes central nociceptive pathways leading to hyperalgesia and tonic chemical sensitivity. SIGNIFICANCE: Hyperalgesia induced by spinal nerve ligation corresponds temporally and in magnitude with degranulation of thalamic mast cells. Here, we provide evidence that hyperalgesia induced by NGF, formalin and dynorphin also may depend on mast cell degranulation in the CNS whereas cromolyn, a mast cell stabilizer, blocks these effects in mice.

Glucocorticoid negative feedback selectively targets vasopressin transcription in parvocellular neurosecretory neurons.

To identify molecular targets of corticosteroid negative feedback effects on neurosecretory neurons comprising the central limb of the hypothalamo-pituitary-adrenal (HPA) axis, we monitored ether stress effects on corticotropin-releasing factor (CRF) and arginine vasopressin (AVP) heteronuclear RNA (hnRNA) expression in rats that were intact or adrenalectomized (ADX) and replaced with corticosterone (B) at constant levels ranging from nil to peak stress concentrations. Under basal conditions, relative levels of both primary transcripts varied inversely as a function of plasma B titers. In response to stress, the kinetics of CRF hnRNA responses of intact and ADX rats replaced with low B were similar, peaking at 5 min after stress. By contrast, intact rats showed a delayed AVP hnRNA response (peak at 2 hr), the timing of which was markedly advanced in ADX/low B-replaced animals (peak at 5-30 min). Transcription factors implicated in these responses responded similarly. Manipulation of B status did not affect the early (5-15 min) phosphorylation of transcription factor cAMP-response element-binding protein (CREB) but accelerated maximal Fos induction from 2 hr after stress (intact) to 1 hr (ADX). Assays of binding by proteins in hypothalamic extracts of similarly manipulated rats toward consensus CRE and AP-1 response elements supported a role for the stress-induced plasma B increment in antagonizing AP-1, but not CRE, binding. These findings suggest that glucocorticoid negative feedback at the transcriptional levels is exerted selectively on AVP gene expression through a mechanism that likely involves glucocorticoid receptor interactions with immediate-early gene products.

Central autonomic control of the bone marrow: multisynaptic tract tracing by recombinant pseudorabies virus.

Bone marrow is the primary place of hematopoiesis, where the development, survival and release of multipotent stem cells, progenitors, precursors and mature cells are under continuous humoral and neural control. Dense network of nerve fibers, containing various neurotransmitters is found in the bone marrow, however, the central neuronal circuit that regulates the activities of the bone marrow through these fibers remained unexplored. Transsynaptically connected neurons were mapped by virus-based transneuronal tracing technique using two isogenic, genetically engineered pseudorabies viruses, Bartha-DupGreen and Ba-DupLac expressing green fluorescent protein and beta-galactosidase, respectively. Bartha-DupGreen was injected into the femoral bone marrow of male rats and the progression of infection was followed 4-7 days post-inoculation. Virus-labeled cells were revealed in ganglia of the paravertebral chain and in the intermediolateral cell column of the lower thoracic spinal cord. Neurons were retrogradely labeled in the C1, A5, A7 catecholaminergic cell groups and several other nuclei of the ventrolateral and ventromedial medulla, the periaqueductal gray matter, the paraventricular and other hypothalamic nuclei, and in the insular and piriform cortex. Nerve transections and double-virus tracing from the bone marrow and the surrounding muscles were used to confirm the specific spreading of the virus. These results provide anatomical evidence for the CNS control of the bone marrow and identify putative brain areas, which are involved in autonomic regulation of the hematopoiesis, the release of progenitor cells, the blood supply and the immune cell function in the bone marrow.

Atriopeptin inhibits stimulated secretion of adrenocorticotropin in rats: evidence for a pituitary site of action.

The aim of this study was to resolve previous controversies regarding the effect of atriopeptin on the secretion of ACTH in vivo. Male Wistar rats were used throughout. The animals were subjected to lesioning of the hypothalamic paraventricular nucleus (PVN) or sham operation and implanted with indwelling jugular cannulae 5 days later for blood sampling and drug infusion. Two days after the insertion of the cannulae the animals were treated with saline or 103-126 amino acid residue atriopeptin iv: a bolus injection was given (200 or 40 pmol/rat) followed by an infusion (40 or 8 pmol/min) which was maintained for the entire duration of the experiment (70 min). Ten minutes after the bolus of atriopeptin the animals received iv a combination of 1 pmol 41-residue CRF and 10 pmol arginine vasopressin (CRF/AVP) to stimulate ACTH secretion. Serial blood samples (0.1 ml) were obtained at -10 min and immediately before the injection of CRF/AVP and at 5, 10, 20, 30, and 60 min afterwards. Plasma ACTH concentration was measured by RIA. In sham-operated rats CRF/AVP caused a 4-fold increase in plasma ACTH which peaked at 5 min and returned to baseline by 60 min. In sham-operated rats the higher dose of atriopeptin (200 pmol bolus, 40 pmol/min infusion) did not alter the effect of the stimulus between 5 and 30 min, and augmented plasma ACTH at 60 min. The smaller dose of atriopeptin reduced plasma ACTH at 10 and 20 min by 54% and 48%, respectively, and also decreased by 48% the net amount of ACTH released over 30 min in response to CRF/AVP. When given alone, the higher dose of atriopeptin caused a persistent (60 min) 10-13% reduction of mean arterial blood pressure, while the lower dose decreased blood pressure by about 9% for less than 10 min. In parallel, the higher dose of atriopeptin increased plasma ACTH concentration while the lower dose produced no change. In PVN-lesioned rats the CRF/AVP induced ACTH response was similar to that seen in sham-operated controls. Only the higher dose of atriopeptin was tested, and this markedly reduced CRF/AVP stimulated ACTH secretion at 5-60 min after CRF/AVP. Given alone, atriopeptin had no marked effect on plasma ACTH in PVN-lesioned rats, while its hypotensive action was similar to that in sham-operated animals.(ABSTRACT TRUNCATED AT 400 WORDS)

Transient changes in the synthesis of nitric oxide result in long-term as well as short-term changes in acetic acid-induced writhing in mice.

A single injection of nitric oxide (NO) synthase (NOS) inhibitors prevents the development of persistent hyperalgesia induced by various manipulations, suggesting that NO precipitates long-term changes in nociception. We examined the possibility that inhibition of NOS may also be sufficient to produce long-term decreases in nociceptive assays, such as writhing, that are known to be sensitive to the short-term effects of NOS inhibitors. We characterized short- and long-term effects of NOS inhibitors, N(omega)-nitro-L-arginine (L-NAME) or 7-nitro indazole (7-NI) injected intrathecally (i.t.) in mice on acetic acid-induced writhing. Doses of L-NAME that had no effect on hot plate or tail flick latencies inhibited writhing (0. 01-30 nmol) as well as spinal nNOS activity (5 and 100 nmol) when injected i.t. 60-90 min before testing. Anti-nociception was not mimicked by D-NAME but was prevented by co-administration with the NO precursor, L-arginine. Injection i.t. of 7-NI (30 min), a selective inhibitor of neuronal NOS (nNOS), inhibited NOS activity in the spinal cord and produced anti-nociception, confirming that writhing is sensitive to inhibition of nNOS. Although the acute action of both NOS inhibitors dissipated completely by 3-6 h, a delayed and prolonged inhibition of writhing was again observed 24 h after L-NAME (5-100 nmol), a time when spinal NOS activity was no longer inhibited by L-NAME (5 and 100 nmol) or 7-NI (25 nmol). This novel effect appears to be initiated by the transient inhibition of nNOS as delayed anti-nociception was mimicked by 7-NI at doses (10-100 nmol) that no longer inhibited spinal nNOS (25 nmol) at 24 h. Co-administration with L-arginine prevented the delayed (24 h) anti-nociceptive effects of L-NAME (30 nmol). L-Arginine (30 and 100 nmol) was without effect on nociception when administered alone 60 min or 24 h prior to testing. Together these data indicate that brief changes in the activity of nNOS induce both long- as well as short-term changes in nociception.

Zinc in the extracellular area of the central nervous system is necessary for the development of kainic acid-induced persistent hyperalgesia in mice.

Kainic acid produces a persistent hyperalgesia when injected intraperitoneally (i.p.) in the rat or mouse. At higher doses than those needed to influence nociception, kainic acid induces seizures and translocation of histologically reactive zinc in the hippocampus. We tested the hypothesis that zinc, localized in a population of small diameter primary afferent neurons, plays a role in kainic acid-induced hyperalgesia similar to that in the hippocampus where zinc translocation accompanies kainic acid-induced seizures. The importance of zinc in the extracellular area was assessed by the influence of compounds that chelate divalent cations (disodium calcium ethylene diaminetetraacetate (CaEDTA)) or zinc (dipicolinic acid (DPA)) on kainic acid-induced hyperalgesia. When measured using the tail flick assay, thermal hyperalgesia was blocked by pretreatment intrathecally (i.t.) with either 10 nmol of NaCaEDTA or 1 nmol of DPA, drugs whose distribution is limited to the extracellular area. Injection of 10 ng zinc chloride i.t. had no long-term effect on nociception or on kainic acid-induced hyperalgesia. Whether zinc is translocated in response to a hyperalgesic dose of kainic acid was determined using the zinc-selective dye, N-(6-methoxy-8-quinolyl)-para-toluenensulfonamide (TSQ), which produces a delicate stain in the neuropil of the mouse spinal cord as well as a dense stain in the hippocampus. Injection of a hyperalgesic dose of kainic acid failed to alter TSQ fluorescence in either the spinal cord or hippocampus, in contrast to the distinct bleaching of TSQ in the hippocampus 24 h after a convulsant dose of kainic acid. Together these data suggest that, while not translocated, zinc in the extracellular area is necessary but not sufficient for the development of kainic acid-induced hyperalgesia.

Double activity imaging reveals distinct cellular targets of haloperidol, clozapine and dopamine D(3) receptor selective RGH-1756.

Acute administration of typical (haloperidol) and atypical (clozapine) antipsychotics results in distinct and overlapping regions of immediate-early gene expression in the rat brain. RGH-1756 is a recently developed atypical antipsychotic with high affinity to dopamine D(3) receptors that results in a unique pattern of c-Fos induction. A single injection of either antipsychotic results in c-fos mRNA expression that peaks around 30 min after drug administration, while the maximum of c-Fos protein induction is seen 2 h after challenge. The transient and distinct temporal inducibility of c-fos mRNA and c-Fos protein was exploited to reveal and compare cellular targets of different antipsychotic drugs by concomitant localization of c-fos mRNA and c-Fos immunoreactivity in brain sections of rats that were timely challenged with two different antipsychotics. Double activity imaging revealed that haloperidol, clozapine and RGH-1756 share cellular targets in the nucleus accumbens, where 40% of all labeled neurons displayed both c-fos mRNA and c-Fos protein. Haloperidol activates cells in the caudate putamen, while clozapine-responsive, single labeled neurons were dominant in the prefrontal cortex and major island of Calleja. RGH-1756 targets haloperidol-sensitive cells in the caudate putamen, but cells that are activated by clozapine and RGH-1756 in the major island of Calleja are different.

C-kit ligand (Stem Cell Factor) affects neuronal activity, stimulates pituitary-adrenal axis and prolactin secretion in rats.

Stem Cell Factor (SCF) is a potent growth factor affecting proliferation, differentiation and migration as well as secretory functions of various cells of different origin and function. The effect of SCF on neuronal activity and on neuroendocrine regulation has been studied by injecting SCF i.v. into conscious male rats. Administration of SCF elevated adrenocorticotropin (ACTH), corticosterone and prolactin (PRL) plasma levels in a dose-dependent manner. Adrenocorticotropin and corticosterone secretions were maximal after injecting 10 micrograms SCF, while prolactin secretion only reached a maximum at a dose of 20 micrograms. Hormone secretions were maximal at 15 min (ACTH and PRL) or at 30 min (CORT) and declined to the baseline between 90 and 180 min. The functional anatomical approach, using immediate-early gene product c-Fos as a marker of activated neurones, revealed that systemic administration of SCF activated neurosecretory neurones of the hypothalamus in a time-dependent manner. Somatosensory afferent pathways and extrahypothalamic areas--which are involved in the regulation of hypothalamic neurosecretory cells--including various parts of the lamina terminalis, bed nucleus of stria terminalis, central amygdala, locus coeruleus, parabrachial nucleus, nucleus of the solitary tract and ventrolateral medulla also became Fos-positive. As SCF-induced mediators have been suggested to be involved in brain pathophysiology, and as SCF might have been of potential therapeutic use in certain anaemias and leukaemias, the complex interaction between SCF-induced cell-specific actions and its effect on the neuroendocrine system should also be considered.

Modulation of lipopolysaccharide-induced tumor necrosis factor-alpha production by selective alpha- and beta-adrenergic drugs in mice.

In a previous study we demonstrated that mice pretreated with the highly selective alpha 2-adrenoceptor antagonist CH-38083 showed blunting of the tumor necrosis factor-alpha (TNF-alpha) response induced by bacterial lipopolysaccharide (LPS). In the present study, the effect of a selective block of alpha 2-adrenoreceptors and the role of the sympathetic nervous system (SNS) in the regulation of LPS-induced TNF-alpha production was explored further using different selective adrenoceptor antagonists and agonists. While adrenalectomy did not prevent the effect of CH-38083, the block of the sympathetic transmission by chlorisondamine fully abolished the inhibitory effect of CH-38083 on LPS-induced TNF-alpha production, suggesting that the effect of the alpha 2-adrenoceptor blocking agent is corticosteroid-independent, but it requires intact sympathetic activity. Since the selective block of alpha 2-adrenoceptors results in an increased sympathetic activity and an increase of the release of noradrenaline (NA) in both the central and the peripheral nervous systems, and in our experiments propranolol, a non-selective beta-adrenoceptor antagonist, and atenolol, a selective antagonist of beta 1-adrenoceptors, prevented the effect of alpha 2-adrenoceptor blockade by CH-38083 of the TNF-alpha response induced by LPS, it seems likely that the excessive stimulation by NA of beta 1-adrenoceptors is responsible for this action. The role of beta-adrenoceptors and endogenous catecholamines is further substantiated by the finding that pretreatment of animals with propranolol alone resulted in a dose-dependent increase of the TNF-alpha response induced by LPS, and that isoproterenol, a non-selective beta-adrenoceptor agonist, decreased it.(ABSTRACT TRUNCATED AT 250 WORDS)

GABAergic innervation of corticotropin-releasing hormone (CRH)-secreting parvocellular neurons and its plasticity as demonstrated by quantitative immunoelectron microscopy.

GABA has been identified as an important neurotransmitter in stress-related circuitry mediating inhibitory effects on neurosecretory neurons that comprise the central limb of the hypothalamo-pituitary-adrenocortical axis. Using combinations of pre-embedding immunostaining and postembedding immunogold methods at the ultrastructural level, direct synaptic contacts were revealed between GABA-containing terminals and neurosecretory cells that were immunoreactive for corticotropin-releasing hormone (CRH) in the hypothalamic paraventricular nucleus (PVN). The vast majority of axo-dendritic GABA synapses was symmetric (inhibitory) type, and 46% of all synaptic boutons in the medial parvocellular subdivision of the PVN were immunoreactive to GABA. Using the disector method, an unbiased stereological method on serial ultrathin sections, the total calculated number of synaptic contacts within the medial parvocellular subdivision of the PVN was 55.4 x 10(6)/mm(3). On CRH-positive profiles 20.1 x 10(6) GABAergic synaptic boutons were detected per mm(3) in control, colchicine-treated rats. In the medial parvocellular subdivision, 79% of GABAergic boutons terminated on CRH neurons. Following adrenalectomy, which increases the synthetic and secretory activities of CRH neurons, the number of GABAergic synapses that terminate on CRH-positive profiles was increased by 55%. GABA-containing boutons appeared to be swollen, while the contact surfaces of cellular membranes between GABAergic boutons and CRH-positive profiles were shorter in adrenalectomized animals than in controls. Our data provide ultrastructural evidence for direct inhibitory GABAergic control of stress-related CRH neurons and suggest a pivotal role of GABA-containing inputs in the functional plasticity of parvocellular neurosecretory neurons seen in response to adrenalectomy.

Regulation of stress-induced transcriptional changes in the hypothalamic neurosecretory neurons.

Transcriptional changes in corticotropin-releasing factor (CRF) and arginine vasopressin (AVP) gene expression were studied by in situ hybridization histochemistry using cRNA probes directed against intronic sequences. Acute ether stress resulted in a rapid induction of CRF and a delayed activation of vasopressin heteronuclear (hn)RNA in the parvocellular neurosecretory neurons within the paraventricular nucleus (PVN) of the hypothalamus. To explore possible molecular mechanisms regulating stress-related neuropeptide expression in vivo, the time-courses of stress-induced activation of different transcription factor classes were compared to that of changes in neuropeptide transcription. The peak of CRF transcription was parallel to that of cAMP response-element binding protein (CREB) phosphorylation but preceded the induction of c-fos and NGFI-B mRNAs and Fos protein. In contrast, AVP expression occurred in step with immediate-early gene (IEG) responses, suggesting involvement of different mechanisms underlying stress-induced neuropeptide responses. The interference of glucocorticoid hormones with stress-induced neuropeptide and transcription-factor responses has also been revealed in rats acutely or chronically pretreated with glucocorticoids. Acute dexamethasone injection did not prevent neuropeptide and transcription factor responses to either inhalation, whereas chronic corticosterone administration completely blocked IEG and neuropeptide induction in the stress-related neurosecretory neurons.

Functional neuroanatomy of the parvocellular vasopressinergic system: transcriptional responses to stress and glucocorticoid feedback.

This chapter summarizes the regulation of vasopressin (VP) transcription within the parvocellular neurosecretory cells of the hypothalamic paraventricular nucleus in vivo, with special reference to stress-response and glucocorticoid feedback. VP is commonly held as the first and the most potent among the co-secretagogues that act synergistically with corticotropin-releasing factor (CRF-41) to induce adrenocorticotropin (ACTH) from the anterior pituitary in response to various internal and external stimuli. Cellular levels of the primary transcripts of VP and CRF genes, revealed by in situ hybridization histochemistry using probes complementary to intronic sequences, are increased after acute challenges with different time courses. In contrast to the rapid stress-induced upregulation of CRF gene expression, VP transcription shows a delayed increase suggesting different regulatory mechanisms governing the two main ACTH releasing neuropeptides in the parvocellular neurosecretory neurons. With respect of transcription factors that may mediate these effects, besides rapid phosphorylation of the cAMP-response element-binding protein (CREB), VP activation in the parvocellular neurons requires additional newly synthesized factors such as those encoded by immediate-early genes, like c-fos. In addition, it has recently been revealed that glucocorticoid negative feedback during stress, selectively targets vasopressin transcription in the parvocellular neurons that is likely mediated by interaction of glucocorticoid receptors and immediate-early gene products. These data speak for the emerging consensus that VP is the principal factor that imparts situation-specific drive and represents the regulated variable governing hypothalamo-pituitary-adrenocortical axis during stress.

Protein synthesis blockade differentially affects the stress-induced transcriptional activation of neuropeptide genes in parvocellular neurosecretory neurons.

Corticotropin-releasing factor (CRF) and arginine vasopressin (AVP) are synergistically interacting ACTH secretagogues that are co-expressed by parvocellular neurosecretory neurons of the hypothalamic paraventricular nucleus (PVH). To shed light on the mechanisms that mediate the stress-induced transcriptional activation of these neuropeptide genes, quantitative hybridization histochemical methods were used to assess the effects of systemic treatment with the protein synthesis inhibitor, cycloheximide, on the ether stress-induced upregulation of primary CRF and AVP transcripts, in vivo. Pretreatment with cycloheximide prevented the induction of FOS, but not CREB phosphorylation, normally seen in response to acute ether exposure, and significantly attenuated the stress-induced rise in AVP, but not CRF, heteronuclear RNA expression in the parvocellular division of the PVH. These results support the view that distinct molecular mechanisms govern the expression of the two principal corticotropin-releasing factors, in vivo.

Differential dependence of ACTH secretion induced by various cytokines on the integrity of the paraventricular nucleus.

Effect of different cytokines, human recombinant interleukin-1 alpha and beta (IL-1 alpha, IL-1 beta), interleukin-6 and tumor necrosis factor-alpha (TNF) on adrenocorticotropin (ACTH) secretion was compared in sham-operated rats and those with lesions of the hypothalamic paraventricular nucleus. IL-1 alpha was less active than IL-1 beta in stimulating ACTH in sham-operated rats. Intravenous injection of IL-1 beta in sham-operated animals resulted in a rapid elevation of ACTH secretion. Five days after surgical lesion of the paraventricular nucleus, the main hypothalamic source of hypophysiotropic corticotropin-releasing factor-41, the response to IL-1 beta was attenuated but not abolished. This suggests involvement of extra-paraventricular releasing factors in mediation of ACTH-releasing activity of IL-1 beta, altered responsiveness of pituitary to CRFs, and/or direct action of IL-1 beta on the corticotrope cells. TNF resulted in a biphasic stimulation of ACTH concentration, with peaks at 15 min and 90 min. In paraventricular-lesioned, TNF injected rats both of these ACTH peaks disappeared, suggesting that CRFs from the paraventricular origin mediates ACTH-inducing activity of TNF. IL-6 elevated ACTH secretion much later than the other intravenously injected cytokines, the peak was at 1 h in sham-lesioned rats. Paraventricular lesion completely prevented the increase of ACTH plasma levels after IL-6 injection. These data suggest that: (1) Effect of TNF and IL-6 on hypothalamo-pituitary-adrenal axis is mediated through the hypothalamic paraventricular nucleus and (2) IL-1 beta is able to release ACTH even in the absence of hypothalamic drive.

c-Fos as a transcription factor: a stressful (re)view from a functional map.

This article summarizes the achievements that have been accumulated about the role of c-Fos as a transcription factor and as a functional marker of activated neurons. Since its discovery, more than a decade ago, as an inducible immediate-early gene encoding a transcription factor, or third messenger, involved in stimulus-transcription coupling and mediation of extracellular signals to long-term changes in cellular phenotype, c-fos became the most widely used powerful tool to delineate individual neurons as well as extended circuitries that are responsive to wide variety of external stimuli. There still remain uncertainties as to how general is the c-fos induction in the central neurons, and whether the threshold of c-fos induction is comparable along a certain neuronal circuit. The major limitation of this technology is that c-fos does not mark cells with a net inhibitory synaptic or transcriptional drive, and c-fos induction, as a generic marker of trans-synaptic activation, does not provide evidence for transcriptional activation of specific target genes in a certain cell type of interest. The first part of the review focuses on recent functional data on c-fos as transcription factor, while the second part discusses c-fos as a cellular marker of transcriptional activity in the stress-related circuitry.

GABAergic mechanisms constraining the activity of the hypothalamo-pituitary-adrenocortical axis.

There are two major inhibitory mechanisms that constrain the activity of the hypothalamo-pituitary-adrenocortical axis: the hormonal negative feedback and the neural inhibition including that posed by the GABAergic neurons. This chapter summarizes our recent morphologic and functional findings on the role of gamma-aminobutyric acid (GABA) in the transcriptional regulation of hypophyseotropic neuropeptide genes in the parvocellular neurosecretory cells of the hypothalamic paraventricular nucleus (PVH). We used organotypic hypothalamic slice cultures and in vivo microinjection protocols in combination with in situ histologic and ultrastructural procedures to address the role of local interneurons in the regulation of hypothalamic effector neurons. Under basal conditions, an intrinsic GABAergic mechanism in the PVH microenvironment was revealed that by itself, without limbic contribution, impinged a tonic inhibitory influence on the parvocellular corticotropin-releasing hormone (CRH) neurons in vitro. In vivo, remote inputs were superimposed on the local circuit, allowing differential transcriptional regulation of CRH and arginine vasopressin (AVP) genes in the hypophyseotropic neurons. During stress, GABAergic cells that are known to project to the PVH become activated and are involved in restraining the cellular, transcriptional, and hormonal responses to stress.

Long-term salt loading impairs pituitary responsiveness to ACTH secretagogues and stress in rats.

Male Wistar rats were allowed to drink tap water ad lib (W), 2% saline (S) or 2% saline containing dexamethasone (S + D, 1 mg/l) for 7 days. On the 8th day rats were subjected to a 3-min ether stress. Plasma ACTH, corticosterone and prolactin concentrations were determined before and after ether exposure. Prestress concentrations of plasma ACTH were low and did not vary among the three groups. In response to ether stress W rats exhibited twice as high plasma ACTH concentrations as did S rats. Rats of the S + D group exhibited a small but statistically significant ACTH response. Plasma corticosterone concentration in S rats was increased while in S + D rats was significantly decreased under resting conditions compared to that in W rats. Ether stress caused large increases in plasma corticosterone concentrations in W and S rats while a small but statistically significant increase was observed in S + D rats. Prolactin responses to ether were smaller in groups S and S + D than in group W. To test whether the decreased ACTH response to ether exposure was a result of a decreased sensitivity of corticotrope cells to corticotropin releasing factor (CRF)-41 or arginine vasopressin (AVP), adenohypophysial fragments from W, S and S + D rats were incubated in the presence of different doses of CRF-41 or AVP. Pituitary fragments obtained from W rats secreted larger amounts of ACTH than did pituitaries from S rats in response to either CRF-41 or AVP.(ABSTRACT TRUNCATED AT 250 WORDS)

Corticosterone and dexamethasone act at different brain sites to inhibit adrenalectomy-induced adrenocorticotropin hypersecretion.

To investigate the involvement of different brain sites in the mediation of glucocorticoid feedback action, we implanted dexamethasone or corticosterone containing glass capillaries into the paraventricular and arcuate nuclei of the hypothalamus, into the lateral septum, the dorsal and ventral hippocampus, amygdala and the cerebral cortex of adrenalectomized male rats, and compared the plasma adrenocorticotropin (ACTH) values to those of the sham implanted controls. The ACTH hypersecretion of adrenalectomized (ADX), sham implanted rats (670 fmol/ml) was reduced significantly by dexamethasone implants placed into the paraventricular nucleus (9.97 fmol/ml), arcuate nucleus (20.54 fmol/ml) or lateral septum (44.15 fmol/ml). Corticosterone was effective only when placed into the dorsal hippocampus, but normal ACTH levels were not restored (219.67 fmol/ml). All other implants at other sites had no effect on ACTH secretion. Our results suggest that corticosterone and dexamethasone possess different feedback potencies and act at different sites in the brain to normalize the ADX-induced ACTH secretion.

Distribution of glucocorticoid receptor-like immunoreactivity in the brain, and its relation to CRF and ACTH immunoreactivity in the hypothalamus of the japanese quail, Coturnix coturnix japonica.

Monoclonal antibody (MAb49) against the rat liver glucocorticoid receptor was used to evaluate glucocorticoid receptor (GR) immunoreactive structures in the brain of the japanese quail, Coturnix coturnix japonica. Using the avidin-biotin technique, the immunoreaction was present in the nerve cell nuclei in intact male birds. High density of glucocorticoid receptor-like immunoreactivity was found in the tubero-infundibular area, nucleus paraventricularis, posteromedialis and lateralis hypothalami, lateral septum and in some brainstem nuclei. Cerebellar cortex was also immunopositive. In contrast to mammals, no immunoreactive cell nuclei were found in the hippocampal region. The glucocorticoid receptors were colocalized with adrenocorticotropin (ACTH) immunoreactivity in the tubero-infundibular region, while corticotropin releasing factor (CRF) positive cells in the paraventricular nucleus did not contain glucocorticoid receptor-like immunoreactivity in their cell nuclei.

Effect of intrahippocampal dexamethasone on the levels of amino acid transmitters and neuronal excitability.

Direct effect of type-II corticosteroid receptor agonist dexamethasone on extracellular amino acid levels and neuronal excitability in the hippocampus was studied by simultaneous application of in vivo microdialysis and recording hippocampal evoked responses in freely moving male rats. Microdialysis probes and hippocampal recording electrodes were implanted to the CA1-CA3 regions of dorsal hippocampus. Local dexamethasone infusion via microdialysis resulted in a transient increase in glutamate level at 30 min, while glutamine decreased by 30-40% throughout the 180-min sampling period. Taurine increased by 50% and remained elevated up to 180 min. No significant changes were detected in extracellular concentration of asparagine, arginine, glycine, threonine, alanine and serine. In contrast, dexamethasone infusion to the striatum had no effect on the extracellular levels of amino acid transmitters. Effect of dexamethasone injected via microdialysis on the neural activity elicited by perforant path stimulation was a decrease in population spikes after 60 min starting dexamethasone infusion. Steroid effect on neural excitability was reversible. Our data indicate that local infusion of type-II receptor agonist dexamethasone has a complex effect in the hippocampus, starts with a change in extracellular glutamate and glutamine concentration and followed by a reduced synaptic excitability.