Regulatory effects of reboxetine treatment alone, or following paroxetine treatment, on brain noradrenergic and serotonergic systems

When patients do not respond to an initial antidepressant, one clinical approach is to switch to an agent in a different pharmacological class. However, few studies have examined the neurochemical consequences of this practice. To study this, we examined changes in binding sites in rat brain for norepinephrine (NET) and serotonin transporters (SERT), alpha1, alpha2, and beta1 adrenergic receptors after chronic administration of paroxetine (PRX), reboxetine (RBX), or PRX followed by RBX. We also examined the effects of these treatments on mRNA expression for tyrosine hydroxylase (TH). RBX treatment for 3 weeks reduced NET binding significantly, by approximately 40% in terminal field areas, and 6 weeks of RBX reduced it even more, by approximately 60%. RBX treatment for 3 and 6 weeks reduced beta1 adrenergic receptor-binding sites equally, by 50-60%. At no time did RBX treatment reduce SERT-binding sites. PRX treatment had no effect on beta1 adrenergic or NET-binding sites, but reduced SERT-binding sites by 75-80%. Neither treatment altered mRNA for TH, alpha1, or alpha2 adrenergic receptor-binding sites. When 3 weeks of RBX treatment followed 3 weeks of PRX treatment, NET-binding sites were reduced to the same extent as measured after 6 weeks of RBX treatment alone, indicating that PRX pretreatment may have 'primed' the subsequent regulatory effect of RBX on the NET. Thus, pretreatment of rats with PRX actually enhanced at least one regulatory effect of RBX treatment on the noradrenergic system, and did not interfere with any other pharmacological effect caused by RBX treatment.

Interactions of norepinephrine and galanin in the central amygdala and lateral bed nucleus of the stria terminalis modulate the behavioral response to acute stress

Many aspects of drug abuse and addiction share neurobiological substrates with the modulatory processes underlying the response and adaptation to acute stress. In particular, the ascending noradrenergic system has been implicated in facilitating the response to stress, and in stress-induced reinstatement of drug seeking behavior. Thus, to better understand the link between stress and addictive behaviors, it would be informative to understand better the modulatory function of the ascending noradrenergic system, and its interaction with other neurotransmitters with which it is closely associated or co-localized, such as the neuropeptide galanin. In this paper, we review a series of studies investigating the functional interactions of norepinephrine and galanin in modulating the behavioral response to acute stress in two components of the extended amygdala, the central nucleus of the amygdala and the lateral bed nucleus of the stria terminalis. We showed that norepinephrine facilitates behavioral reactivity to stress on the elevated plus-maze and social interaction tests. However, when stress-induced activation of the noradrenergic system was enhanced by blocking inhibitory adrenergic autoreceptors, galanin release was recruited in the central amygdala, acting to attenuate the behavioral response to stress. By contrast, stress-induced galanin release in the lateral bed nucleus appeared to be independent of enhanced noradrenergic activation, and unlike the central amygdala, both galanin and norepinephrine facilitated behavioral stress reactivity in the bed nucleus. The different modes of interaction and differential region- and response-specificity of galanin and norepinephrine suggest that a complex neural circuit interconnecting these two regions is involved in the modulatory effects of norepinephrine and galanin on the behavioral response to stress. Such complexity may allow for flexibility and plasticity in stress adaptation, and may also contribute to behavioral changes induced by chronic drug administration. Thus, the interaction of galanin and norepinephrine may be a viable target for the future development of novel therapeutic strategies for treating behavioral disorders related to stress or drug abuse.

Chronic cold stress sensitizes brain noradrenergic reactivity and noradrenergic facilitation of the HPA stress response in Wistar Kyoto rats

Many psychiatric disorders, including depression, post-traumatic stress disorder and other anxiety disorders, result from an interaction between genetic factors and exposure to a sufficiently sensitizing environmental stressor. The inbred Wistar Kyoto (WKY) rat strain has been proposed as a model of stress vulnerability, exhibiting an exaggerated hypothalamic-pituitary-adrenal (HPA) response to stress and susceptibility to gastric ulceration. Previously, we showed that stress-activation of the brain noradrenergic system was deficient in WKY rats, and they lacked noradrenergic facilitation of the HPA response in the lateral bed nucleus of the stria terminalis (BSTL), compared to outbred Sprague-Dawley (SD) controls. Deficient modulatory function of the noradrenergic system may contribute to the stress susceptibility of WKY rats. Thus, we investigated the influence of a sensitizing stimulus, chronic intermittent cold exposure, on neuroendocrine and noradrenergic stress reactivity, and on noradrenergic facilitation of the HPA response in these two strains. Chronic cold exposure (7 days, 4 h/day, 4 degrees C) potentiated activation of the HPA axis by acute immobilization stress, assessed by measuring plasma adrenocorticotropic hormone (ACTH), in both strains, although to a greater extent in WKY rats, and enhanced stress-induced norepinephrine (NE) release in BSTL of WKY but not SD rats. We then compared the influence of chronic cold exposure on noradrenergic modulation of the HPA stress response in BSTL, by measuring changes in acute stress-induced elevation of plasma ACTH after microinjecting the alpha(1)-adrenoreceptor antagonist benoxathian into the BSTL. As shown previously, benoxathian attenuated stress-induced ACTH secretion in control SD but not control WKY rats. After chronic cold, the ACTH response to acute stress was attenuated by benoxathian administration into BSTL of both strains, such that the WKY response was not different from that of SD rats. Thus, chronic cold not only sensitized the release of NE in BSTL of WKY rats, but also restored noradrenergic facilitation of their already-elevated HPA response. Such functional sensitization of a previously-deficient facilitatory system may be one mechanism whereby exposure to repeated or severe stress may induce pathologic dysregulation of the stress response in susceptible individuals, resulting in psychiatric illness.

Stress reactivity of the brain noradrenergic system in three rat strains differing in their neuroendocrine and behavioral responses to stress: implications for susceptibility to stress-related neuropsychiatric disorders

The brain noradrenergic system is activated by stress, modulating the activity of forebrain regions involved in behavioral and neuroendocrine responses to stress. In this study, we characterized brain noradrenergic reactivity to acute immobilization stress in three rat strains that differ in their neuroendocrine stress response: the inbred Lewis (Lew) and Wistar-Kyoto (WKY) rats, and outbred Sprague-Dawley (SD) rats. Noradrenergic reactivity was assessed by measuring tyrosine hydroxylase mRNA expression in locus coeruleus, and norepinephrine release in the lateral bed nucleus of the stria terminalis. Behavioral measures of arousal and acute stress responsivity included locomotion in a novel environment, fear-potentiated startle, and stress-induced reductions in social interaction and open-arm exploration on the elevated-plus maze. Neuroendocrine responses were assessed by plasma adrenocorticotropic hormone. Compared to SD, adrenocorticotropic hormone responses of Lew rats were blunted, whereas those of WKY were enhanced. The behavioral effects of stress were similar in Lew and SD rats, despite baseline differences. Lew had similar elevations of tyrosine hydroxylase mRNA, and initially greater norepinephrine release in the lateral bed nucleus of the stria terminalis during stress, although both noradrenergic responses returned toward baseline more rapidly than in SD rats. WKY rats showed depressed baseline startle and lower baseline exploratory and social behavior than SD. However, unlike the Lew or SD rats, WKY exhibited a lack both of fear potentiation of the startle response and of stress-induced reductions in exploratory and social behavior, indicating attenuated stress responsivity. Acute noradrenergic reactivity to stress, measured by either tyrosine hydroxylase mRNA levels or norepinephrine release, was also attenuated in WKY rats. Thus, reduced arousal and behavioral responsivity in WKY rats may be related to deficient brain noradrenergic reactivity. This deficit may alter their ability to cope with stress, resulting in the exaggerated neuroendocrine responses and increased susceptibility to stress-related pathology exhibited by this strain.

Modulatory effects of norepinephrine, acting on alpha 1 receptors in the central nucleus of the amygdala, on behavioral and neuroendocrine responses to acute immobilization stress

The central nucleus of the amygdala (CeA) is a component of the limbic fear-anxiety circuit, and has also been implicated in regulation of the hypothalamic-pituitary-adrenal (HPA) stress axis. The CeA receives dense noradrenergic innervation, and is rich in expression of alpha(1)-adrenergic receptors. We hypothesized that norepinephrine (NE), acting on alpha(1) receptors in CeA, may modulate stress-induced anxiety-like behavioral responses and HPA activation. To investigate the role of alpha(1) adrenergic receptors in CeA on stress-induced behavioral reactivity, the alpha(1) antagonist benoxathian was microinjected bilaterally into CeA of male Sprague-Dawley rats, and anxiety-like behavioral responses to acute immobilization stress were measured on the Social Interaction (SI) test and on the Elevated Plus-maze (EPMZ). Benoxathian dose dependently blocked the reduction in SI time induced by immobilization stress, whereas beta-receptor antagonists had no effect, consistent with an absence of beta-receptors in CeA. By contrast, in separate experiments, benoxathian had no effect on stress-induced reduction in open-arm exploratory behavior on the EPMZ, nor on stress-induced plasma ACTH secretion. These results confirm that the SI test and EPMZ measure different aspects of behavioral stress reactivity that can be modulated independently, and likewise, that noradrenergic modulation of behavioral stress reactivity can occur independently of modulation of the HPA axis.

Modulatory effects of norepinephrine in the lateral bed nucleus of the stria terminalis on behavioral and neuroendocrine responses to acute stress

The brain noradrenergic system is activated by stress, and modulates the activity of forebrain regions involved in behavioral and neuroendocrine responses to stress, such as the lateral bed nucleus of the stria terminalis (BSTL). This region of the limbic forebrain receives dense noradrenergic innervation, and has been implicated in both anxiety and regulation of the hypothalamic-pituitary-adrenal axis. We hypothesized that stress-induced release of norepinephrine in the BSTL modulates anxiety-like behavioral responses to stress and activation of the hypothalamic-pituitary-adrenal stress axis. Using microdialysis, we showed that release of norepinephrine was increased in the BSTL of male Sprague-Dawley rats during immobilization stress. In the next experiment, we then microinjected noradrenergic antagonists into the BSTL immediately prior to acute immobilization stress to examine noradrenergic modulation of behavioral stress reactivity. Either the alpha(1)-receptor antagonist benoxathian, or a cocktail of beta(1)- and beta(2)-receptor antagonists (betaxolol+ICI 118,551) blocked the anxiety-like reduction in open-arm exploration on the elevated plus-maze, but not the reduction in social behavior induced in the social interaction test. In a third experiment, benoxathian reduced plasma levels of adrenocorticotropic hormone following stress, but beta-receptor antagonists had no effect. From these results we suggest that stress-induced norepinephrine release acts on both alpha(1)- and beta-receptors in the BSTL to facilitate anxiety-like behavioral responses on the plus-maze but not the social interaction test, and modulates hypothalamic-pituitary-adrenal axis activation via alpha(1)-receptors only. Together with previous results in which adrenergic antagonists in central amygdala attenuated behavioral responses on the social interaction test but not the plus-maze, these observations suggest the two behavioral tests measure different dimensions of stress reactivity, and that norepinephrine facilitates different components of the stress response by region- and receptor-specific mechanisms.

Modulatory effects of galanin in the lateral bed nucleus of the stria terminalis on behavioral and neuroendocrine responses to acute stress

The neuropeptide galanin has been identified as a possible neurotransmitter/neuromodulator within the central nervous system. In the present study, a potential role for galanin in the lateral bed nucleus of the stria terminalis (BSTL) in modulating behavioral and neuroendocrine responses to an acute stress was investigated. In the first experiment, acute immobilization stress induced anxiety-like behavioral responses in rats, measured on the social interaction and elevated plus-maze tests. Immobilization stress decreased both social interaction time and open arm exploratory behavior on the elevated plus-maze. Bilateral administration of the galanin antagonist M40 (1.0 nmole/0.2 microl) into BSTL immediately prior to stress exposure attenuated the anxiogenic-like effects of immobilization stress, restoring both social interaction time and exploration of open arms to control levels. Administration of the antagonist alone had no effect on baseline behavior of unstressed control rats in either test, suggesting that the modulatory effect of galanin elicited during stress is not exerted tonically in unstressed animals. In the second experiment, immobilization stress produced an increase in plasma adrenocorticotropic hormone (ACTH) that was also attenuated by bilateral administration of M40 into BSTL prior to stress. These results suggest that during stress, the neuropeptide galanin exerts a modulatory effect in the BSTL, facilitating behavioral and neuroendocrine components of the acute stress response.

Behavioral reactivity to stress: amplification of stress-induced noradrenergic activation elicits a galanin-mediated anxiolytic effect in central amygdala

Brain norepinephrine (NE) modulates many aspects of the stress response. The interaction between NE and neuropeptides such as galanin, with which it is closely associated and which may be released from noradrenergic terminals under conditions of high activity, has not been well studied. We therefore investigated the modulatory effects of galanin in the central nucleus of the amygdala (CeA) on behavioral responsivity to stress when activation of the noradrenergic system was amplified using the adrenergic autoreceptor antagonist yohimbine (2.5 mg/kg ip). Either immobilization stress or yohimbine alone had anxiogenic effects on rat behavior in the elevated plus maze. However, yohimbine pretreatment before stress produced a paradoxical anxiolytic response, which we hypothesized was attributable to galanin release in CeA. Microdialysis verified that yohimbine amplified NE release in CeA during immobilization stress, and also showed that whereas there was no detectable change in galanin release in CeA during stress alone, there was an increase during immobilization stress after yohimbine pretreatment. Bilateral administration of the galanin antagonist M40 into CeA before stress blocked the anxiolytic influence of yohimbine pretreatment. Exogenous galanin mimicked the anxiolytic effect of yohimbine pretreatment, and this too was blocked by M40. These results suggest that amplifying the noradrenergic response to stress can recruit galanin release in CeA, which buffers the anxiety-like behavioral response to acute stress. The balance between noradrenergic and peptidergic neurotransmission may be modified by prior stress, drug treatment or genetic variability, and may represent a novel target for treatment of stress-related neuropsychiatric disorders.

Effects of acute restraint stress on tyrosine hydroxylase mRNA expression in locus coeruleus of Wistar and Wistar-Kyoto rats

Norepinephrine (NE) is thought to play a role in the stress response, and may be involved in stress-related psychopathological conditions such as depression or anxiety. Heterogeneity in individual responses to the same stressor suggest that a genetic susceptibility to the effects of stress may contribute to such pathology. To address possible mechanisms underlying this genetic aspect of the stress response, we examined acute stress-induced changes in mRNA expression for several components of the NE system in the locus coeruleus (LC) and adrenal medullae of stress-susceptible Wistar-Kyoto (WKY) rats and their parent Wistar (W) strain. Expression of tyrosine hydroxylase (TH), NE transporter (NET) and alpha(2A) receptor mRNA were measured in the LC by in situ hybridization 30 min and 2 h after the onset of 30 min restraint stress. Adrenal TH mRNA was measured by slot blots. No basal differences were observed for any measure, but in the LC, expression of TH mRNA increased by 40% in W rats at 30 min (n=8, p<0.05) and returned toward baseline by 2 h, while WKY rats showed only a non-significant 29% increase at 2 h. In contrast, adrenal TH mRNA expression increased in WKY rats at 2 h (n=3, p<0.05), with no significant change in W rats. NET and alpha(2A) mRNA were unaltered by restraint stress in both strains. Differences in the stress-reactivity of TH gene expression in the central and peripheral noradrenergic systems may be related to differences in behavioral coping strategies and autonomic responsivity to stress in these strains, and suggest that differences in noradrenergic reactivity may contribute to genetic susceptibility to stress-related pathology.

Changes in tyrosine hydroxylase mRNA expression in the rat locus coeruleus following acute or chronic treatment with valproic acid

Valproate has proven effective in treating bipolar disorder. Though some biochemical effects of valproate are rapid, mood-stabilizing effects can take weeks, suggesting that regulatory changes in gene expression in brain neurotransmitter systems may be involved. Given a presumed role for norepinephrine (NE) in bipolar disorder, as well as the actions of mood-stabilizing drugs, we examined changes in mRNA expression for tyrosine hydroxylase (TH), the NE transporter (NET) and alpha 2A autoreceptor in the rat locus coeruleus after valproate treatment. TH mRNA increased slightly (16%) following acute treatment, and more so after chronic valproate treatment (26%), while neither NET nor alpha 2A mRNA expression changed. Further, chronic valproate treatment attenuated the elevation in TH mRNA expression induced in the LC in response to acute restraint stress. Both acute and chronic valproate treatment attenuated restraint stress-induced elevations in plasma ACTH secretion. These observations suggest that the therapeutic effects of valproate may involve regulatory alterations in TH message expression in the brain, and attenuation of stress-reactivity of the central noradrenergic system and the hypothalamic-pituitary-adrenal axis.

Effects of chronic antidepressant treatments on serotonin transporter function, density, and mRNA level

To investigate functional changes in the brain serotonin transporter (SERT) after chronic antidepressant treatment, several techniques were used to assess SERT activity, density, or its mRNA content. Rats were treated by osmotic minipump for 21 d with the selective serotonin reuptake inhibitors (SSRIs) paroxetine or sertraline, the selective norepinephrine reuptake inhibitor desipramine (DMI), or the monoamine oxidase inhibitor phenelzine. High-speed in vivo electrochemical recordings were used to assess the ability of the SSRI fluvoxamine to modulate the clearance of locally applied serotonin in the CA3 region of hippocampus in drug- or vehicle-treated rats. Fluvoxamine decreased the clearance of serotonin in rats treated with vehicle, DMI, or phenelzine but had no effect on the clearance of serotonin in SSRI-treated rats. SERT density in the CA3 region of the hippocampus of the same rats, assessed by quantitative autoradiography with tritiated cyanoimipramine ([(3)H]CN-IMI), was decreased by 80-90% in SSRI-treated rats but not in those treated with phenelzine or DMI. The serotonin content of the hippocampus was unaffected by paroxetine or sertraline treatment, ruling out neurotoxicity as a possible explanation for the SSRI-induced decrease in SERT binding and alteration in 5-HT clearance. Levels of mRNA for the SERT in the raphe nucleus were also unaltered by chronic paroxetine treatment. Based on these results, it appears that the SERT is downregulated by chronic administration of SSRIs but not other types of antidepressants; furthermore, the downregulation is not caused by decreases in SERT gene expression.

Expression of alpha1D adrenergic receptor messenger RNA in oxytocin- and corticotropin-releasing hormone-synthesizing neurons in the rat paraventricular nucleus

The paraventricular nucleus of the hypothalamus contains a number of intermingled populations of neuroendocrine cell groups involved in the hormonal stress response, including cells synthesizing corticotropin-releasing hormone and oxytocin. Ascending noradrenergic afferents to the paraventricular nucleus, acting through alpha1 adrenergic receptors, are thought to play a role in stress-induced activation of the hypothalamic-pituitary-adrenal axis. We have previously demonstrated that, of the three known alpha1 adrenergic receptor subtypes, messenger RNA for the alpha1D subtype is the most prominently expressed in the paraventricular nucleus. Thus, regulation of the expression of this receptor may be important in modulation of the stress response. It is currently unknown, however, which populations of stress-related neuroendocrine cells in the paraventricular nucleus express alpha1 receptors, or whether the excitatory influence of norepinephrine in stress is exerted directly on neurons expressing oxytocin or corticotropin-releasing hormone. Thus, in the present study, we used dual in situ hybridization, combining a digoxigenin-labeled riboprobe encoding the rat alpha1D adrenergic receptor with radiolabeled riboprobes for oxytocin or corticotropin-releasing hormone, to determine the degree to which these neurons in the paraventricular nucleus express alpha1D adrenergic receptors. In sections through the rostral and mid-level paraventricular nucleus, nearly all (>95%) oxytocin neurons also expressed alpha1D messenger RNA. In contrast, the populations of corticotropin-releasing hormone- and alpha1D-expressing cells overlapped only partially, with most alpha1D expression situated more laterally. A subset (37%) of the neurons expressing corticotropin-releasing hormone also expressed alpha1D messenger RNA, and these were found almost entirely within the region of overlap in the lateral aspect of the medial parvocellular region. These observations support a direct role for alpha1 receptors in regulation of oxytocin secretion. Expression of alpha1D messenger RNA in distinct subsets of cells synthesizing corticotropin-releasing hormone may also help to clarify contradictory and inconsistent observations in the literature regarding the role of norepinephrine in the stress response, and may account for a presumed stressor-specific role for norepinephrine in activation of the hypothalamic-pituitary-adrenal axis.

Reduced noradrenergic tone to the hypothalamic paraventricular nucleus contributes to the stress hyporesponsiveness of lactation

Lactation in mammals is accompanied by a marked decrease in stress responsiveness that we previously attributed, in part, to a reduction in noradrenergic (NA) innervation of hypothalamic paraventricular nucleus (PVN) neurons controlling neuroendocrine stress responses. In the present study, we compared in-vivo PVN catecholamine secretion by microdialysis between nonlactating and lactating females and tested the effects of NA alpha-1 and alpha-2 receptor antagonists (corynanthine and idazoxan, respectively) on the acute stress response of lactating and virgin female rats. To determine if PVN alpha-adrenoreceptor density, affinity, or synthesis, changes as a function of lactation, we performed receptor autoradiography, Scatchard analysis and in situ hybridization of alpha-adrenoreceptors. Densitometric analysis of the alpha-adrenoreceptors in the supraoptic nucleus (SON) was used to evaluate changes in magnocellular neurons. Endogenous PVN norepinephrine release under basal conditions was lower in lactating females than in females who had their pups removed for 2 days, and microdialysate concentrations of adrenaline and MHPG were attenuated in lactating females. Alpha-2 adrenoreceptor density in the PVN showed a significant decrease from lactation day 3 to lactation days 10-12 and a reduction to 40% of virgin controls on days 10-20 of lactation. A similar pattern was observed for the SON. The affinity of hypothalamic alpha-2 adrenoreceptors was reduced as a function of lactation. Alpha-1 adrenoreceptor density in the PVN and in the hypothalamus rose as a function of lactation, although the affinity of these receptors was not altered. In contrast, alpha-1D adrenoreceptor subtype mRNA expression in the PVN decreased in middle lactating females (day 10) compared to virgins. Intracerebroventricular (i.c.v.) application of idazoxan, significantly increased the ACTH response to swim stress in virgin females, but had the opposite effect in lactating females. In contrast, i.c.v. corynanthine treatment significantly decreased the ACTH response in virgins, but not in lactating females. Overall, these data suggest that the secretion of NA in the PVN is reduced during lactation, and that the ability of PVN parvocellular neurons to respond to changes in synaptic NA levels (i.e. after stress) is also altered.

Distribution of alpha1A adrenergic receptor mRNA in the rat brain visualized by in situ hybridization

Norepinephrine has been implicated in a number of physiological, behavioral, and cellular modulatory processes in the brain, and many of these modulatory effects are attributable to alpha1 adrenergic receptors. At least three alpha1 receptor subtypes have been identified by molecular criteria, designated alpha1A, alpha1B, and beta1D. The distributions of alpha1B and alpha1D receptor mRNA expression in rat brain have been described previously, but the cDNA for the rat alpha1A receptor has only recently been cloned and characterized. In the present study, we used a radiolabelled riboprobe derived from the rat alpha1A receptor cDNA to describe the distribution of alpha1A message expression in the rat brain. The highest levels of alpha1A adrenergic receptor mRNA expression were seen in the olfactory bulb, tenia tectae, horizontal diagonal band/magnocellular preoptic area, zona incerta, ventromedial hypothalamus, lateral mammillary nuclei, ventral dentate gyrus, piriform cortex, medial and cortical amygdala, magnocellular red nuclei, pontine nuclei, superior and lateral vestibular nuclei, brainstem reticular nuclei, and several cranial nerve motor nuclei. Dual in situ hybridization combining a radioactive riboprobe for choline acetyltransferase mRNA with a digoxigenin-labeled alpha1A riboprobe in the fifth and seventh cranial nerve motor nuclei showed that the alpha1A mRNA is expressed in cholinergic motor neurons. Prominent alpha1A hybridization signal was also seen in the neocortex, claustrum, lateral amygdala, ventral cochlear nucleus, raphe magnus, and in the ventral horn of thoracic spinal cord. This overall pattern of expression, considered in comparison with that previously described for the other alpha1 adrenergic receptor subtypes, may shed light on the different roles of the alpha1 receptors in mediating the neuromodulatory effects of norepinephrine in processes such as arousal, neuroendocrine control, sensorimotor regulation, and the stress response.

alpha1B adrenoceptors in rat paraventricular nucleus overlap with, but do not mediate, the induction of c-Fos expression by osmotic or restraint stress

A role has been suggested for hypothalamic alpha1 adrenoceptors in the acute stress-induced activation of the hypothalamic-pituitary-adrenal axis. Using a polyclonal antiserum against the rat alpha1B adrenergic receptor protein, we have demonstrated alpha1B receptor immunoreactivity in neurons and especially in punctate cell processes in the rat paraventricular nucleus. The distribution of alpha1B receptor immunoreactivity overlapped in part with the distributions of c-Fos immunoreactivity induced in the paraventricular nucleus by either restraint stress or hypertonic saline administration. However, intraperitoneal pretreatment with the alpha1 receptor antagonist prazosin (0.5 or 5.0 mg/kg) failed to attenuate stress-induced c-Fos expression in the paraventricular nucleus. Prazosin also failed to attenuate the secretion of corticosterone following restraint stress. Thus, we conclude that neither acute secretory activity nor activation of gene transcriptional responses mediated by c-Fos in the hypothalamic pituitary adrenal axis following these stressors are dependent upon hypothalamic alpha1 adrenergic receptors.

Co-localization of alpha1D adrenergic receptor mRNA with mineralocorticoid and glucocorticoid receptor mRNA in rat hippocampus

Many adaptive changes occur in response to chronic or repeated stress, involving complex regulatory interactions between central stress-related afferents and the central components of the hypothalamo-pituitary-adrenal (HPA) axis. One change associated with chronic stress is an attenuation of corticosteroid receptor-mediated feedback inhibition of the HPA axis, a process thought to involve corticosteroid receptors in the hippocampus. A prominent stress-related central afferent that innervates the hippocampus and that may participate in the regulation of the HPA axis is the central noradrenergic system. Previous evidence suggests that alpha1 adrenergic receptors may down-regulate hippocampal corticosteroid receptors, and may thus contribute to stress-induced facilitation of HPA responses. In the present study, we used combined nonisotopic and radioisotopic in situ hybridization to examine the overlapping expression and co-localization of mRNA encoding the post-synaptic alpha1D adrenergic receptor subtype, the major alpha1 subtype expressed in hippocampus, with mRNA for the two corticosteroid receptor subtypes, type I (mineralocorticoid receptor, MR) and type II (glucocorticoid receptor, GR) in rat hippocampal neurons. We observed overlapping distributions and an extensive degree of co-localization of alpha1D receptor mRNA with both corticosteroid receptor subtype messages, establishing an anatomical substrate by which these two receptor systems may directly regulate each other. The potential interaction between co-localized adrenergic and corticosteroid receptors in hippocampus may contribute to stress-induced alterations in the HPA response to subsequent stress.

Neurons expressing 5-HT2 receptors in the rat brain: neurochemical identification of cell types by immunocytochemistry

The serotonin2 (5-HT2) receptor has been implicated in a number of behavioral and physiological processes. It may also play a role in cellular development and differentiation, and represents a site of action of hallucinogens and certain psychotherapeutic drugs. To better understand the functions and regulation of the 5-HT2 receptor, we have undertaken a series of studies in which we attempted to identify the specific cell types that express the receptor. This was accomplished using a variety of double-labeling strategies with an antibody we raised against the rat 5-HT2 receptor protein. In this review, we recount of some of our previously published findings and present some new data in which we identify subpopulations of cholinergic neurons in the brainstem and gamma-aminobutynic acid (GABA)ergic interneurons in the cortex that express 5-HT2 receptor immunoreactivity. Developmentally, the appearance of 5-HT2 receptor immunoreactivity occurs relatively late in teh ontogeny of the cells in which it is expressed, mostly in the early postnatal period. This argues against a significant role for this receptor in early development, though it may participate in some aspect of terminal differentiation. We discuss the significance of the cell-type-specific and temporal expression of the 5-HT2 receptor in the context of current hypotheses of neuropsychiatric disorders such as schizophrenia.

5-HT2 receptor immunoreactivity on cholinergic neurons of the pontomesencephalic tegmentum shown by double immunofluorescence

The serotonin-2 (5-HT2) receptor subtype is implicated in several behavioral and physiological processes, and may be the site of action of hallucinogens and certain psychotherapeutic drugs. To better understand the function and regulation of 5-HT2 receptors, it is necessary to determine the specific brain regions and cell types expressing them. By double immunofluorescence using a polyclonal antibody raised against the rat 5-HT2 receptor in conjunction with an antibody against choline acetyltransferase (ChAT), the synthetic enzyme for acetylcholine, we have shown that cholinergic neurons in the rat laterodorsal and pedunculopontine tegmental nuclei express 5-HT2 receptors. In contrast, there was little co-localization of 5-HT2 and ChAT immunoreactivity in neurons of the basal forebrain or striatum, even though the 5-HT2- and ChAT-positive cells in these regions overlapped extensively. These findings are discussed in relation to the potential interaction between cholinergic and serotonergic systems in sleep regulation, hallucinogenesis and the pathophysiology of neuropsychiatric disorders.

Ontogeny of 5-hydroxytryptamine2 receptor immunoreactivity in the developing rat brain

In this study, we investigated the regional and temporal emergence of 5-hydroxytryptamine2 receptor immunoreactivity in the developing rat brain. In a qualitative immunocytochemical analysis using an antibody against the rat 5-hydroxytryptamine2 receptor protein, we visualized cells expressing the receptor in the pontine tegmentum, caudate nucleus, basal forebrain, hippocampus and neocortex of developing rats. Three potentially important periods in the developmental regulation of 5-hydroxytryptamine2 receptors were identified: the time of onset, a period of accelerated expression and hyper-elaboration, and a period of regression. In general, the onset of 5-hydroxytryptamine2 receptor immunoreactivity occurred relatively late in the ontogeny of cells in these regions, in the late prenatal and early postnatal periods. Following the perinatal onset of receptor expression, there was a rapid increase in the number of immunoreactive neurons during the first week after birth. In neocortex, there appeared to be a relative over-expression of the receptor, with an elevated density and hyper-elaboration of immunopositive neurons relative to the adult, reaching a peak at the end of the second week. There was then a gradual decrease in both the density and morphological complexity of cortical 5-hydroxytryptamine2-labelled neurons, until the adult pattern of expression was achieved at about four weeks of age. In all areas studied, cells positive for the 5-hydroxytryptamine2 receptor were first detected within the regions in which they would ultimately reside, and after the known periods of cell proliferation for these regions. These observations would argue against a role for the 5-hydroxytryptamine2 receptor as a transducer of the early developmental influences of serotonin in the central nervous system, but leave open the possibility that the receptor may participate in regulating some aspect of terminal differentiation or late maturation of the neurons on which it is found. The identification of important developmental periods in the ontogeny of 5-hydroxytryptamine2 receptors suggests time-points at which events that disrupt the normal ontogenetic pattern of expression could produce long-lasting effects on central serotonergic neurotransmission.

Production and characterization of a specific 5-HT2 receptor antibody

A synthetic peptide was used to generate antibodies against the rat serotonin-2 (5-HT2) receptor. The peptide corresponds to a unique sequence from the N-terminal extracellular portion of the receptor protein (antibody = Ab 5HT2-N). This peptide was chosen based on its theoretical antigenic index and for specificity to the 5-HT2 receptor. In dot blot analysis, antisera detected 2 ng-2 micrograms of synthetic peptide at dilutions of 1/200-1/20,000. COS-7 cells transiently transfected with a eukaryotic expression vector containing the 5-HT2 cDNA displayed intense immunoreactivity with crude and affinity-purified Ab 5HT2-N. In contrast, no immunoreactivity was seen in control experiments when: (1) non-transfected or vector transfected COS-7 cells were used; (2) pre-immune sera was substituted for primary antisera; (3) primary antisera was omitted; or (4) antiserum was pre-adsorbed to 10 microM synthetic peptide. Immunohistochemical analysis of sections of perfused rat brain revealed intense immunolabelling of a subset of neurons in regions of the ventral forebrain, dorsal hippocampus, striatum, cerebral cortex, and laterodorsal tegmental nucleus (LDT). An especially dense band of small cells was seen in layer 2 of pyriform cortex. There was a very high concentration of labelled cells in the laterodorsal tegmental nucleus. In situ hybridization histochemistry with a 5-HT2 antisense cRNA riboprobe showed a pattern of hybridization in forebrain similar to the pattern of immunolabelling with Ab 5HT2-N. Western blot analysis of proteins extracted from the LDT revealed a single protein species reacting with the antibody. This reactivity is not present in the pre-immune sera and is blocked by the synthetic antigen.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunocytochemical localization and description of neurons expressing serotonin2 receptors in the rat brain

Serotonin2 receptors have been implicated in a variety of behavioral and physiological processes, as well as a number of neuropsychiatric disorders. To specify the brain regions and specific cell types possessing serotonin2 receptors, we conducted an immunocytochemical study of the rat brain using a polyclonal serotonin2 receptor antibody. Perfusion-fixed rat brain sections were processed for immunocytochemistry and reactivity was visualized using an immunoperoxidase reaction. Numerous small, round neurons were heavily labeled in the granular and periglomerular regions of the olfactory bulb. Heavy labeling of medium-sized multipolar and bipolar neurons was also seen in olfactory regions of the ventral forebrain, including the anterior olfactory nucleus and olfactory tubercle. Other regions of the basal forebrain exhibiting high levels of immunoreactivity were the nucleus accumbens, ventral pallidum, Islands of Calleja, fundus striatum and endopyriform nucleus. Immunoreactive neurons were also seen in the lateral amygdala. A dense band of small, round cells was stained in layer 2 of pyriform cortex. In neocortex, a very sparse and even distribution of bipolar and multipolar neurons was seen throughout layers II-VI. A much more faintly labeled population of oval cells was observed in the deep layer of retrosplenial and posterior cingulate cortex, and in the granular layer of somatosensory frontoparietal cortex. A moderate number of medium bipolar and multipolar cells were scattered throughout the neostriatum, and a moderate number of pyramidal and pyramidal-like cells were seen in the CA fields of the hippocampus. Diencephalic areas showing immunolabeling included the medial habenula and anterior pretectal nucleus, with less labeling in the ventral lateral geniculate. In the hindbrain, two dense populations of large multipolar cells were heavily labeled in the pedunculopontine and laterodorsal tegmental nuclei, with lesser labeling in the periaqueductal gray, superior colliculus, spinal trigeminal nucleus and nucleus of the solitary tract. Based on the distribution, localization and morphology of immunoreactive neurons in these regions, we hypothesize that subpopulations of serotonin2 containing cells may be GABAergic interneurons or cholinergic neurons. Further, the observed distribution suggests that the physiological effects of serotonin acting through serotonin2 receptors are mediated by a relatively small number of cells in the brain. These observations may have strong functional implications for the pharmacological treatment of certain neuropsychiatric disorders.

Endogenous opioids tonically inhibit the depressor neurones in the caudal ventrolateral medulla of rabbits: mediation through delta- and kappa-receptors

In the present studies, an attempt was made to elucidate the role of endogenous opioid inputs to the depressor region of the caudal ventrolateral medulla in the tonic regulation of arterial pressure and to examine the subtype(s) of receptor underlying any observed effects by use of receptor-specific antagonists. The depressor region of the caudal ventrolateral medulla in chloralose-anesthetized, artificially ventilated rabbits was functionally identified by injection of l-glutamate (5 nmol). Bilateral injection of the non-selective opioid antagonist naloxone (0.3, 5 and 20 nmol) into the caudal ventrolateral medulla produced a dose-dependent depressor response, accompanied by a bradycardia, suggesting a tonically active inhibitory opioid input to this region. Bilateral injection of the selective delta-receptor antagonist ICI 174,864 (0.3 nmol) or of the kappa-receptor antagonist nor-binaltorphimine (1 nmol), also markedly reduced both arterial pressure and heart rate. In contrast, injection of the mu-selective antagonist beta-funaltrexamine (0.3-0.6 nmol) produced no effect on arterial pressure or heart rate. These data support the hypothesis that tonically active endogenous opioid inputs, possibly enkephalinergic and/or dynorphinergic, inhibit the depressor neurones of the caudal ventrolateral medulla in the rabbit through activation of delta- and kappa-receptors. Surprisingly, injection of the opioid agonists leu-enkephalin (1 nmol) or dynorphin 1-13 (0.1 nmol), but not the selective mu-receptor agonist DAGO (1 nmol), in the depressor area of the caudal ventrolateral medulla also induced naloxone-sensitive (5 mg/kg, i.v.) decreases in both arterial pressure and heart rate.(ABSTRACT TRUNCATED AT 250 WORDS)

Opioid innervation of the caudal ventrolateral medulla is not critical for the expression of the aortic depressor nerve response in the rabbit

We investigated the influence of endogenous opioids in the caudal ventrolateral medulla (CVLM) on the expression of the baroreflex response induced by the electrical stimulation (50 Hz, 0.2 ms, 11 V, 10 s) of the aortic depressor nerve. We used microinjection of selective opioid antagonists into the functionally identified depressor area of the CVLM in chloralose-anesthetized rabbits. Injection of vehicles or the mu-antagonist beta-funaltrexamine (0.3 nmol) into the CVLM had no effects, while naloxone (20 nmol), ICI 174,864 (delta-antagonist, 0.3 nmol) or nor-binaltorphimine (kappa-antagonist, 1 nmol) abolished the depressor response, but themselves all elicited a tonic depressor effect as well. In contrast, intravenous naloxone (5 mg/kg) induced a small but significant increase in arterial pressure and did not alter the depressor response. Hypotensive hemorrhage induced a decrease in arterial pressure similar to that seen with local injection of naloxone into the CVLM, but did not change the reflex, suggesting that the reflex abolition was not due to the decrease in basal arterial pressure per se. CVLM injection of glutamate (10 nmol) or the GABA-antagonist bicuculline (0.1 nmol), non-opioid agents which activate CVLM and induce a tonic depressor effect, also abolished the depressor response suggesting that the reflex abolition was secondary to general activation or disinhibition of the CVLM. Thus, although the CVLM is tonically inhibited by endogenous opioid inputs acting via delta- and kappa-receptors, our data provide no evidence that opioid neurons which provide input to this region constitute a specific and integral component in mediating the aortic depressor response. However, the more general role that opioids play in tonically influencing the resting level of activity in the CVLM, is nevertheless very important in enabling the normal expression of this baroreflex.

Single-unit and physiological analyses of brain norepinephrine function in behaving animals

In behaving cats, the single-unit activity of locus coeruleus noradrenergic neurons is strongly activated by a variety of challenges (stressors). For example, exposing cats to a dog or to loud white noise, dramatically increases the activity of these neurons and simultaneously produces strong activation of the sympathetic nervous system. Similarly, glucoregulatory, thermoregulatory, and cardiovascular challenges also coactivate noradrenergic neurons and the sympathetic nervous system. A related research program utilized a simple brainstem response (the monosynaptic jaw closure reflex) to explore the physiological significance of this response of brain noradrenergic neurons. Conditions which activate these neurons were also shown to potentiate the elicited jaw closure-reflex response. Importantly, when the noradrenergic input to the motor side of this reflex pathway was destroyed with a neurotoxin, the conditions which previously potentiated the reflex were now ineffective. These data represent the first demonstration that the release of norepinephrine, at a specific site, and under physiological conditions, facilitates behavioral output in the intact organism.

Single-unit responses of serotonergic neurons to vasoactive drug administration in behaving cats

Single-unit activity of serotonergic neurons in the dorsal raphe nucleus (DRN), heart rate (HR), and arterial blood pressure were recorded in freely moving cats during spontaneous behavior and in response to systemic administration of vasoactive drugs. The activity of serotonergic neurons varied in association with behavioral arousal but was unrelated to spontaneous fluctuations in HR and blood pressure. Bolus administration of phenylephrine hydrochloride and sodium nitroprusside (15-20 micrograms/kg iv) produced a rapid transient increase (35 mmHg) and decrease (49 mmHg), respectively, in mean arterial pressure (MAP). Infusion of phenylephrine and sodium nitroprusside (100 micrograms/ml) produced sustained hypertension (avg MAP 166 mmHg) and hypotension (avg MAP 49 mmHg), respectively. The activity of serotonergic neurons was not significantly altered in response to phenylephrine or sodium nitroprusside administration. Furthermore, no significant changes in unit activity were observed after hydralazine administration (1 mg/kg iv) despite prolonged reflex activation of sympathetic outflow. Thus the activity of DRN serotonergic neurons was unrelated to transient alterations in blood pressure and baroreceptor activity. These results suggest that changes in the activity of serotonergic DRN neurons are not involved in physiological mechanisms underlying reflex alterations in sympathetic (and parasympathetic) outflow invoked by hypertension and hypotension.