Crh receptor priming in the bed nucleus of the stria terminalis (BNST) induces tph2 gene expression in the dorsomedial dorsal raphe nucleus and chronic anxiety (original) (raw)
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Basic and Clinical Neuroscience (BCN), 2022
Stress is a reaction to unwanted events disturbing body homeostasis and its pathways and target areas. Stress affects the brain through the lateral hypothalamic area (LHA), the orexinergic system that mediates the effect of corticotropin-releasing hormone (CRH) through CRH Receptor Type 1 (CRHr1). Therefore, this study explores the outcome of stress exposure on anxiety development and the involvement of the LHA through LHA-CRHr1. Methods: Male Wistar rats (220-250 g) implanted with a cannula on either side of the LHA received acute or chronic stress. Subsequently, exploratory behavior was examined using the Open Field (OF), and anxiety was tested by Elevated Plus Maze (EPM). Before sacrifice, the cerebrospinal fluid (CSF) and the blood were sampled. Nissl stain was performed on fixed brain tissues. Results: Acute stress reduced exploration in of and increased anxiety in EPM. LHA-CRHr1 inhibition reversed the variables to increase the exploration and decrease anxiety. In contrast, chronic stress did not show any effect on anxiety-related behaviors. Chronic stress decreased the cell population in the LHA, which was prevented by the CRHr1 inhibition. However, the CRHr1 inhibition could not reverse the chronic stress-induced increase in the CSF orexin level. Furthermore, plasma corticosterone levels increased through acute or chronic stress, impeded by the inhibition of CRHr1. Conclusion: Our results recognize LHA-CRHr1 as a capable candidate that modulates acute stress-induced anxiety development and chronic stress-induced changes in the cellular population of the region.
Stress-induced behaviors require the corticotropin-releasing hormone (CRH) receptor, but not CRH
Proceedings of the National Academy of Sciences, 1999
Corticotropin-releasing hormone (CRH) is a central regulator of the hormonal stress response, causing stimulation of corticotropin and glucocorticoid secretion. CRH is also widely believed to mediate stress-induced behaviors, implying a broader, integrative role for the hormone in the psychological stress response. Mice lacking the CRH gene exhibit normal stress-induced behavior that is specifically blocked by a CRH type 1 receptor antagonist. The other known mammalian ligand for CRH receptors is urocortin. Normal and CRHdeficient mice have an identical distribution of urocortin mRNA, which is confined to the region of the Edinger-Westphal nucleus, and is absent from regions known to mediate stress-related behaviors. Since the Edinger-Westphal nucleus is not known to project to any brain regions believed to play a role in anxiety-like behavior, an entirely different pathway must be postulated for urocortin in the Edinger-Westphal nucleus to mediate these behaviors in CRH-deficient mice. Alternatively, an unidentified CRH-like molecule other than CRH or urocortin, acting through the CRH receptors in brain regions believed to mediate stressinduced behaviors, may mediate the behavioral response to stress, either alone or in concert with CRH.
Behavioural Brain Research, 2003
The behavioral consequences of uncontrollable stress that are collectively called learned helplessness (LH) are mediated in part by increased levels of serotonin (5-HT) activity in the dorsal raphe nucleus (DRN) and it's projection regions. Recently, corticotropin-releasing hormone (CRH) within the DRN has been implicated in the development of LH because intra-DRN CRH produces LH at very high doses, and because intra-DRN antagonists for the CRH 2 receptor (CRHR2) block LH. Since these behavioral effects are mediated by both 5-HT excitation and CRHR2 activation, we have suggested that CRHR2 mediates excitation of DRN 5-HT neurons. However, CRH has been shown to inhibit DRN 5-HT neurons at low doses that are expected to bind to CRHR1. Since CRHR1 antagonists were ineffective in blocking LH, we have further suggested that CRHR1 might mediate the inhibition of DRN 5-HT neurons. In support of this hypothesis, although low doses of CRH that preferentially bind CRHR1 inhibit DRN 5-HT activity, higher doses at which CRH would be expected to bind both receptor subtypes no longer inhibit DRN 5-HT. In addition, high doses of CRH are required to produce LH, which is known to be mediated by 5-HT excitation, and the CRHR2 agonist urocortin II (UCN II) produces LH at much lower doses than does CRH. The present studies show that intra-DRN CRH microinjection blocks the behavioral effects produced by DRN UCN II, but only at doses that have been shown to inhibit DRN 5-HT activity. Indeed, a higher dose of CRH that has been shown to no longer inhibit DRN 5-HT activity did not affect the behavioral consequences of DRN UCN II. In a separate experiment, the effective dose of CRH blocked the usual behavioral consequences of uncontrollable stress.
Biological Psychiatry, 2013
BACKGROUND-STEP is a brain-specific protein tyrosine phosphatase that opposes the development of synaptic strengthening and the consolidation of fear memories. In contrast, stress facilitates fear memory formation, potentially by activating corticotrophin releasing factor (CRF) neurons in the anterolateral cell group of the bed nucleus of the stria terminalis (BNST ALG). METHODS-Here, using dual-immunofluorescence, single-cell RT-PCR, quantitative RT-PCR, Western blot, and whole cell patch-clamp electrophysiology, we examined the expression and role of STEP in regulating synaptic plasticity in rat BNST ALG neurons, and its modulation by stress. RESULTS-STEP was selectively expressed in CRF neurons in the oval nucleus of the BNST ALG. Following repeated restraint stress (RRS), animals displayed a significant increase in anxiety-like behavior, which was associated with a down-regulation of STEP mRNA and protein expression in the BNST ALG as well as selectively enhanced magnitude of long-term potentiation (LTP) induced in Type III, putative CRF neurons. To determine if the changes in STEP expression following RRS were mechanistically related to the facilitation of synaptic strengthening, we examined the effects of intracellular application of STEP on the induction of LTP. STEP completely blocked the RRS-induced facilitation of LTP in BNST ALG neurons. CONCLUSIONS-Hence, STEP acts to buffer CRF neurons against excessive activation, while down-regulation of STEP after chronic stress may result in pathological activation of CRF neurons in the BNST ALG and contribute to prolonged states of anxiety. Thus, targeted manipulations of STEP activity might represent a novel treatment strategy for stress-induced anxiety disorders.
Brain corticotropin releasing hormone and stress reactivity
Integrative Physiology, 2021
The hypothalamic-pituitary-adrenocortical axis is one of the main components of stress adaptation. Corticotropin-releasing hormone (CRH) coming from the nucleus paraventricularis hypothalami (PVN) is the canonical central regulator of the axis. This CRH acts on the CRH-R1 receptors of the pituitary, and, through adrenocorticotropin, stimulates glucocorticoid release from the adrenal cortex. However, it may be synthetized in other parts of the brain as well, and may act both on CRH-R1 and CRH-R2 receptors. These areas form the central CRH network. Many of them are also stress reactive and participate in physical and psychological stress response. The central nucleus of the amygdala and bed nucleus of stria terminalis are two areas best known for their role in emotions, while hippocampus is mostly involved in glucocorticoid feedback as well as memory formation, all heavily connected to stress adaptation. Among others, the brainstem raphe nuclei get dense CRHergic innervation that, through CRH-R1 receptors, may influence the serotoninergic tone of the brain. Both stress and serotonin are strongly implicated in depression, therefore, it is not surprising that CRH-R1 antagonists were developed as therapeutic tools that extensively act on the brain CRH system. Our review suggests a general role of brain CRH network in stress adaptation which is not restricted to PVN.
Science Bulletin, 2020
The bed nucleus of the stria terminalis (BNST) plays a critical role in regulating anxiety, yet the involved specific cell types and their connections functioning in anxiety-related behaviors remains elusive. Here we identified two cell subpopulations-corticotropin-releasing hormone-positive (CRH+) and protein kinase C-d-positive (PKC-d+) neurons-each displayed discrete emotionally valenced behaviors in the anterior-dorsal BNST (adBNST). Using whole-cell patch-clamp recordings and virus-assisted circuit tracing techniques, we delineated the local and long-range connectivity networks in a cell-type-specific manner. The results show that the CRH+ and PKC-d+ neurons received inputs from similar brain regions and exhibited significant differences in the downstream projection density. In addition, in vivo calcium imaging as well as gain-and loss-of-function studies characterized the physiological response properties and the functional heterogeneities in modulating anxiety, further suggesting the similarity and individuality between the two adBNST cell types. These results provide novel insights into the circuit architecture of adBNST neurons underlying the functionally specific neural pathways that relate to anxiety disorders.
Brain Research, 1999
The central administration of corticotropin-releasing hormone CRH to experimental animals sets into motion a coordinated series of physiological and behavioral events that promote survival during threatening situation. A large body of evidence suggest that CRH in the Ž. central nucleus of the amygdala CEA induces fear-related behaviors and is essential to fear conditioning; however, evidence of CRH-mediated activation of the amygdala under physiological situation is still limited. We report here a study of the impact of a psychological stressor on hypothalamic and amygdala CRH systems in the rat. Non-footshocked rats placed in a floored compartment surrounded by footshocked rats were defined as the psychological stress group. Rats were exposed to psychological stress for 15 min, and then sacrificed 1.5 and 3 h after cessation of stress. We found that our psychological stressor induced an increase in both CRH mRNA levels, as assessed by in situ hybridization histochemistry, and CRH content, as assessed by micropunch RIA, in the CEA. Exposure to the psychological stressor also caused a significant increase in CRH mRNA levels with a trend for an increase in CRH content in the Ž. dorsolateral subdivision of the bed nucleus of the stria terminalis BNST which is anatomically associated with the CEA. In contrast, Ž. psychological stress induced a small, but significant increase in type-1 CRH receptor CRHR-1 mRNA in the hypothalamic Ž. paraventricular nucleus PVN , while it failed to elevate either PVN CRH mRNA levels or content, CRH content in the median eminence Ž. Ž. ME , or levels of plasma ACTH or corticosterone CORT. Thus, in the context of a psychological stressor, the activation of the amygdala CRH system can occur without robust activation of the hypothalamic CRH system. In the light of previous data that the psychological stress-induced loss of sleep was reversed by the central administration of a CRH antagonist, these data suggest that CRH in the CEA may contribute to the psychological stress-evoked fear-related behavior such as hyperarousal. These data also indicate that in response to a psychological stressor, the amygdala CRH system is much more sensitive than is the CRH system emanating from the PVN.
The role of CRH in behavioral responses to stress
Peptides, 2001
Corticotropin-releasing hormone (CRH) and urocortin in the central nervous system affect behavior and can enhance behavioral responses to stressors. The action of CRH-related peptides is mediated through multiple receptors that differ markedly in their pharmacological profiles and anatomical distribution. Comparative pharmacology of CRH receptor agonists suggests that CRH, urocortin, sauvagine and urotensin consistently mimic, and CRH receptor antagonists consistently lessen, functional consequences of stressor exposure. Recently, important advances have been made in understanding the CRH system and its role in behavioral responses to stress by the development of specific CRH receptor antagonists, application of antisense oligonucleotides and development of transgenic mice lacking peptides and functional receptors. This review summarizes recent findings with respect to components of the CRH system and their role in stress-induced behavioral responses.
Journal of Neuroendocrinology, 1996
The role of afferent innervation to the hypothalamic paraventricular nucleus (PVN) on CRH mRNA and CRH receptor mRNA levels was studied in control and stressed rats. Groups of rats were subjected to unilateral transection of the stria terminalis (ST), the medial forebrain bundle at the rostra1 hypothalamic level (RMFB), or the lower brainstem through the medulla oblongata between the obex and the locus coeruleus (CBs). Twelve days after surgery, each group of rats was further divided into controls (basal conditions) and stressed (1 h immobilization), before collecting brains for mRNA analysis by in situ hybridization histochemistry. While ST and RMFB cuts had no effect on basal CRH mRNA levels in the PVN, CBs cut decreased CRH mRNA in the PVN ipsilaterally to the knife cut but it was without effect on the contralateral side (-40% and -37% vs contralateral and sham-operated, respectively, P<O.Ol). Acute stress (rats were killed 3 h after immobilization) increased CRH mRNA levels by about 30% bilaterally, an effect which was unchanged by any of the three hemisections.