Sexually dimorphic distribution of sst2A receptors on growth hormone-releasing hormone neurones in mice: modulation by gonadal steroids

The ultradian pulsatile pattern of growth hormone (GH) secretion is markedly sexually dimorphic in rodents as in primates, but the neuroanatomical mechanisms of this phenomenon are not clear. In the arcuate nucleus of the hypothalamus, GH-releasing hormone (GHRH) neurones receive somatostatinergic inputs through the sst2A receptor (sst2A-R) and the percentage of GHRH neurones bearing sst2A-R is higher in female than in male GHRH-enhanced green fluorescent protein (eGFP) mice. In the present study, we hypothesised that sst2A-R expression on GHRH neurones is modulated by gonadal steroids and constitutes a mechanism for sexually differentiated GH secretion. The distribution of sst2A-R on GHRH neurones was evaluated by immunohistochemistry in adult GHRH-eGFP mice gonadectomised and treated for 3 weeks with oestradiol or testosterone implants. In gonadectomised females supplemented with testosterone, sst2A-R distribution on GHRH neurones was reduced to the level seen in intact males, whereas oestradiol implants were ineffective. Conversely, orchidectomy induced a female 'sst2A phenotype', which was reversed by testosterone supplementation. Changes in the hepatic expression of GH-dependent genes for major urinary protein-3 and the prolactin receptor reflected the altered steroid influence on GH pulsatile secretion. In the ventromedial-arcuate region, GHRH and sst2-R, as well as GHRH and somatostatin expression as measured by the real-time polymerase chain reaction, were positively correlated in both sexes. By contrast, the positive correlation between ventromedial-arcuate GHRH and periventricular somatostatin expression in males was reversed to a negative one in females. Moreover, the positive correlation between periventricular somatostatin and ventromedial-arcuate sst2-R expressions in males was lost in females. These results suggest that, in the adult mouse, testosterone is a major modulator of sst2A distribution on GHRH neurones. This marked sex difference in sst2A-R distribution may constitute a key element in the genesis of the sexually differentiated pattern of GH secretion, possibly through testosterone-modulated changes in somatostatin inputs from hypophysiotrophic periventricular neurones.     

Anatomically specific changes in the expression of somatostatin, growth hormone-releasing hormone and growth hormone receptor mRNA in diabetic rats

Growth hormone (GH) secretion is altered in poorly controlled diabetic animals. However, modifications in the hypothalamic neuropeptides that control GH secretion, somatostatin and GH-releasing hormone (GHRH), as well as changes in the sensitivity of the hypothalamus and pituitary to the feedback effects of GH, are less clear. We have used RNase protection assays and in-situ hybridization to address whether the mRNA expression of GH, somatostatin and GHRH, as well as of the GH receptor (GHR) in the hypothalamus and anterior pituitary, are altered in streptozotocin-induced diabetic rats. After induction of diabetes, rats were treated with insulin twice daily for 3 weeks to obtain either poorly controlled (mean plasma glucose >300 mg/dl) or well-controlled diabetic rats. Although no significant change in pituitary GH mRNA expression was found, the hypothalamic expression of GHRH and somatostatin mRNA was reduced in poorly-controlled diabetic rats and returned to control values with normalisation of plasma glucose concentrations (P<0.0001 and P<0.002, respectively). Somatostatin mRNA expression was reduced only in the central portion of the periventricular nucleus, with no change being seen in the other areas of the periventricular nucleus or in the arcuate, suprachiasmatic or paraventricular nuclei. A significant decline in GHRH mRNA expression was observed in both the arcuate nucleus and ventromedial hypothalamus. Anterior pituitary GHR mRNA expression was significantly reduced in both well and poorly-controlled diabetic rats, while there was no change in the hypothalamus. To examine whether the evolution time of the diabetes influences these parameters, in a subsequent experiment, diabetic rats received no insulin for 2 months. A significant decline in GHRH and somatostatin mRNA expression was also observed in these rats. In addition, pituitary GH mRNA expression declined significantly in long-term diabetic rats. These results demonstrate that: (1) the expression of both GHRH and somatostatin declines specifically in anatomical areas involved in anterior pituitary hormone control; (2) GHR mRNA expression is decreased in the pituitary of diabetic rats, but not in the hypothalamus, and does not return to control values with normalisation of mean blood glucose concentrations; and (3) the evolution time of the diabetes is important for detecting some changes, including the decrease in pituitary GH mRNA expression.     

Somatostatin dramatically stimulates growth hormone release from primate somatotrophs acting at low doses via somatostatin receptor 5 and cyclic AMP

Somatostatin and cortistatin have been shown to act directly on pituitary somatotrophs to inhibit growth hormone (GH) release. However, previous results from nonprimate species indicate that these peptides can also directly stimulate GH secretion, at low concentrations. The relevance of this phenomenon in a nonhuman primate model was investigated in the present study by testing the impact of somatostatin/cortistatin on GH release in primary pituitary cell cultures from baboons. High doses (> 10(-10) m) of somatostatin/cortistatin did not alter basal GH secretion but blocked GH-releasing hormone (GHRH)- and ghrelin-induced GH release. However, at low concentrations (10(-17)-10(-13) m), somatostatin/cortistatin dramatically stimulated GH release to levels comparable to those evoked by GHRH or ghrelin. Use of somatostatin receptor (sst) specific agonists/antagonists, and signal transduction blockers indicated that sst2 and sst1 activation via intact adenylate cylcase and mitogen-activated protein kinase systems mediated the inhibitory actions of high-concentration somatostatin. By contrast, the stimulatory actions of low-dose somatostatin on GH release were mediated by sst5 signalling through adenylate cylcase/cAMP/protein kinase A and intracellular Ca(2+) pathways, and were additive with ghrelin (not GHRH). Notably, low-concentrations of somatostatin, similar to sst5-agonists, inhibited prolactin release. These results clearly demonstrate that the ultimate impact of somatostatin/cortistatin on hormone release is dose-dependent, cell type-selective and receptor-specific, where the stimulatory effects of low-concentration somatostatin/cortistatin on GH release extend to primates, thereby supporting the notion that this action is relevant in regulating GH secretion in humans.     

Involvement of sst2 somatostatin receptor in locomotor, exploratory activity and emotional reactivity in mice

Somatostatin (SRIF) controls many physiological and pathological processes in the central nervous system but the respective roles of the five receptor isotypes (sst1-5) that mediate its effects are yet to be defined. In the present study, we attempted to identify functions of the sst2 receptor using mice with no functional copy of this gene (sst2 KO mice). In contrast with control 129Sv/C57Bl6 mice, sst2 mRNA was no longer detectable in the brain of sst2 KO mice; 125I-labeled Tyr0DTrp8-SRIF14 binding was also greatly reduced in almost all brain structures except for the hippocampal CA1 area, demonstrating that sst2 accounts for most SRIF binding in mouse brain. Invalidation of this subtype generated an increased anxiety-related behaviour in a number of behavioural paradigms, while locomotor and exploratory activity was decreased in stress-inducing situations. No major motor defects could be detected. sst2 KO mice also displayed increased release of pituitary ACTH, a main regulator of the stress response. Thus, somatostatin, via sst2 receptor isotype pathways, appears involved in the modulation of locomotor, exploratory and emotional reactivity in mice.     

Immunohistochemical localization of the somatostatin receptor subtype 2 (sst2) in the central nervous system of the golden hamster (Mesocricetus auratus)

The many actions of somatostatin in the central nervous system are mediated through specific membrane receptors of which five have been cloned. In this study, we have investigated the distribution of one of these receptors, the sst2 subtype, in the brain and spinal cord of the golden hamster (Mesocricetus auratus). Immunohistochemistry was carried out by using polyclonal antibodies raised against the C-terminal part of the human sst2 receptor. sst2 immunoreactivity was found in the forebrain, brainstem, cerebellum, and spinal cord. In the forebrain, strong immunoreactivity was observed in the deep layers of the neocortex as well as in the endopiriform cortex, claustrum, and basolateral amygdaloid nucleus. Immunoreactivity was also found in the CA1 area of the hippocampus and in the subiculum. In the diencephalon, staining was observed in the periventricular area, the dorsomedial and arcuate nuclei of the hypothalamus, and the medial habenular nucleus. Other areas such as the thalamus, striatum, and globus pallidus were almost devoid of staining. In the brainstem, strong immunoreactivity was observed in the locus coeruleus and the parabrachial nucleus. In addition, immunostaining was observed in the cortex of the cerebellum. In the spinal cord, intense immunoreactivity was seen in lamina I and II of the dorsal horn. Finally, immunoreactive cells were widely distributed in the anterior pituitary. The localization of the sst2 receptor in many brain regions suggests that this receptor subtype is involved in different neuromodulatory actions of somatostatin such as somatosensory, motor, memory, and neuroendocrine functions.     

NPY neurons express somatostatin receptor subtype 1 in the arcuate nucleus

The regulation of growth hormone (GH) secretion involves hypothalamic somatostatin and its specific receptors (sst1-sst5). sst1 is highly expressed in the arcuate nucleus (AN), and several data suggest that sst1 receptors are preferentially involved in the somatotropic hypothalamic network. Neuropeptide Y (NPY)-containing neurons function as direct transducers for GH feedback. Interestingly, there is an overlap in the distribution of NPY and sst1 containing cells in the AN. To determine whether these NPY cells are target for somatostatin we used a double label in situ hybridization histochemistry. Image analysis revealed that approximately 7% of NPY-hybridizing neurons coexpressed sst1 mRNA. These results further support the evidence for the direct interactions between the somatotropic axis and the neuroendocrine regulatory loops of energy homeostasis.     

Distribution of Somatostatin Receptors 1, 2 and 3 mRNA in Rat Brain and Pituitary

In this study sequence-specific antisense oligonucleotide probes have been used to investigate the distribution of the mRNAs coding for the somatostatin receptor subtypes termed somatostatin receptor 1, somatostatin receptor 2 and somatostatin receptor 3 in the rat brain and pituitary using in situ hybridization techniques. The three receptor subtype mRNAs were found to be widely distributed in the brain with different patterns of expression, but with some overlap. Somatostatin receptor 1 mRNA was particularly concentrated in the cerebral and piriform cortex, magnocellular preoptic nucleus, hypothalamus, amygdala, hippocampus, and several nuclei of the brainstem. Somatostatin receptor 3 mRNA was very abundant in the cerebellum and pituitary (in contrast to somatostatin receptor 1), but it was also found in hippocampus, amygdala, hypothalamus and in motor nuclei of the brainstem. Somatostatin receptor 2 mRNA levels were very low relative to the other two mRNAs evaluated. Receptor 2 mRNA was observed in the anterior pituitary, and in the brain it was found in the medial habenular nucleus, claustrum, endopiriform nucleus, hippocampus, some amygdala nuclei, cerebral cortex and hypothalamus. None of the three somatostatin receptor mRNAs studied here was found in the caudate nucleus. Northern analysis revealed distinct sizes of mRNAs for each subtype, and displacement experiments showed that each probe sequence was subtype-specific.     

Differential expression of sst1, sst2A, and sst3 somatostatin receptor proteins in low-grade and high-grade astrocytomas

We have previously reported that sst2A somatostatin receptors are frequently overexpressed in human meningiomas. Initial clinical observations suggest that somatostatin analogues may also be of value for imaging and treatment of other human intracranial tumors, including astrocytomas. However, contradictory results have been reported regarding the expression of somatostatin receptors in low-grade and high-grade astrocytomas. Therefore, we determined the precise pattern of somatostatin receptor protein expression in 8 diffuse astrocytoma (DA), 10 anaplastic astrocytomas (AA), and 32 glioblastoma multiforme (GBM) using immunohistochemistry and Western blot analysis. sst1 and sst2A somatostatin receptors were not present in DA and only occasionally detected in AA. In GBM, sst1 was present in 66%, and sst2A was found in 44% of the tumors. sst3 receptors were present in 38% of DA, 40% of AA, and 84% of GBM. Thus, loss of differentiation was significantly associated with increased expression of sst1, sst2A, and sst3 somatostatin receptors. In contrast, sst4 and sst5 receptors were found in 80% and 25% of all cases, respectively, in a manner independent of histological grade. No significant correlation was found between somatostatin receptor expression and the proliferation rate of the tumors as determined by MIB-I immunostaining. Furthermore, the presence or absence of the 5 somatostatin receptor subtypes did not significantly influence survival time in 14 GBM patients.     

Hypothalamic Distribution of Somatostatin mRNA Expressing Neurones Relative to Pubertal and Adult Changes in Pulsatile Growth Hormone Secretion in Mice

The age‐associated decline in growth hormone (GH) secretion may be a consequence of the reduction in the number of GH‐releasing hormone (GHRH) positive neurones. However, it remains unclear whether an alteration in the number or distribution of somatostatin (SST) neurones contributes to this change. In the present study, we characterised the role of SST in modulating the change in pulsatile GH secretion in male C57Bl/6J mice throughout puberty and into early adulthood. We assessed pulsatile GH secretion in mice at 4, 8 and 16 weeks of age. These ages correspond to early pubertal, early adulthood and adulthood, respectively. We show an elevation in peak, total and pulsatile GH secretion coinciding with periods of rapid linear growth. Using in situ hybridisation and morphometric methods, we mapped the distribution of Sst mRNA expression within the mouse brain relative to this change in pulsatile GH secretion. The results obtained show that altered pulsatile GH secretion in male mice from 4–16 weeks of age does not coincide with a significant change in the number of Sst mRNA expressing neurones or an abundance of Sst mRNA expression throughout the arcuate nucleus (ARC) and periventricular nucleus (PeV). Rather, we observed a progressive decline in Sst mRNA expressing neurones within subnuclei of the paraventricular nucleus at this time. We conclude that structural changes in Sst expression within the PeV and ARC may not reflect the observed decline in pulsatile GH secretion in mice from puberty into early adulthood.     

谷氨酸单钠对大鼠下丘脑生长抑素神经元性差别的影响

本实验用原位杂室组化方法研究了谷氨酸单钠对大鼠下丘脑室周核生长抑素神经元性差别的影响。结果证明对照组下丘脑室周核生长抑素神经元在基因转录水平表现出明显的性别差异，谷氨酸单钠损伤下丘脑弓状核神经元后这种性别差异不再存在。这些结果提示下丘脑室周核生长抑素神经元在基因转录水平所表现出的性别差异可能是通过下丘脑弓状核神经元间接地受性激素的调节。     

Electrical Stimulation of the Rat Periventricular Nucleus Influences the Activity of Hypothalamic Arcuate Neurones

In rats, the release of growth hormone (GH) is inhibited during electrical stimulation of the periventricular nucleus but after the end of stimulation, there is a rebound ‘hypersecretion’ of GH. We examined the responses of arcuate neurones in pentobarbitone-anaesthetized male rats, following electrical stimulation of the periventricular nucleus to test the hypothesis that the effects of periventricular nucleus stimulation on GH secretion are mediated via effects upon GH-releasing hormone (GRF) neurones in the arcuate nucleus. The electrical activity of 2 groups of arcuate neurones were analysed before, during and after periventricular nucleus stimulation (10 Hz, 5 min, 0.5 mA biphasic, 0.5/1.0 ms): a) putative neurosecretory cells which were antidromically identified (AD) as projecting to the median eminence (n = 53) and b) non-neurosecretory cells, identified by their spontaneous ‘bursting’ pattern of activity (n = 29). During stimulation predominantly inhibitory responses were observed in both AD and bursting cell groups. Of the 39 AD cells which were spontaneously active, 25 were inhibited during the periventricular nucleus stimulation, and 10 of these showed a rebound hyperactivation following the end of stimulation. Fifteen bursting cells were inhibited during stimulation and 4 of these displayed a rebound hyperactivation following the end of stimulation. Additional evidence was sought for the identity of these cells by testing their response to electrical stimulation of the basolateral amygdala (which has previously been shown to increase plasma GH concentration without influencing the release of other pituitary hormones). Six of the 10 AD cells which displayed the inhibition/rebound response to periventricular nucleus stimulation were also excited following electrical stimulation of the basolateral amygdala. We conclude that 1) electrical stimulation of the periventricular nucleus and the basolateral amygdala exert predominantly inhibitory and excitatory effects respectively upon the activity of arcuate neurones but for neither site were the effects of stimulation exclusively upon GRF neurones, and 2) the rebound hypersecretion of GH following PeN stimulation is likely to involve the rebound activation of arcuate neurones.     

Anatomic relationships between aromatase and androgen receptor mRNA expression in the hypothalamus and amygdala of adult male cynomolgus monkeys

This study mapped the regional locations of cells expressing cytochrome P450 aromatase (P450AROM) and androgen receptor (AR) mRNAs in the adult male macaque hypothalamus and amygdala by in situ hybridization histochemistry using monkey-specific cRNA probes. High densities of P450AROM and AR mRNA-containing neurons were observed in discrete hypothalamic areas involved in the regulation of gonadotropin secretion and reproductive behavior. P450AROM mRNA-containing neurons were most abundant in the medial preoptic nucleus, bed nucleus of the stria terminalis, and anterior hypothalamic area, whereas AR mRNA-containing neurons were most numerous in the ventromedial nucleus, arcuate nucleus, and tuberomamillary nucleus. Moderate to heavily labeled P450AROM mRNA-containing cells were present in the cortical and medial amygdaloid nuclei, which are known to have strong reciprocal inputs with the hypothalamus. Heavily labeled P450AROM mRNA-containing cells were found in the accessory basal amygdala nucleus, which projects to the cingulate cortex and hippocampus, areas that are important in the expression of emotional behaviors and memory processing. In contrast to P450AROM, the highest density of AR mRNA labeling in the temporal lobe was associated with the cortical amygdaloid nucleus and the pyramidal cells of the hippocampus. All areas that contained P450AROM mRNA-expressing cells also contained AR mRNA-expressing cells, but there were areas in which AR mRNA was expressed but not P450AROM mRNA. The apparent relative differences in the expression of P450AROM and AR mRNA-containing neurons within the monkey brain suggests that T acts through different signaling pathways in specific brain areas or within different cells from the same region.     

Guipi decoction effects on brain somatostatin levels and receptor mRNA expression in rats with spleen deficiency*☆

BACKGROUND： Somatostatin is abundant in the hypothalamus, cerebral cortex, limbic system, and mesencephalon. Somatostatin mRNA expression in the brain of rats with spleen deficiency is noticeably reduced, as well as attenuation of cognitive function. OBJECTIVE： To observe the interventional effect of Guipi decoction on somatostatin level and somatostatin receptor 1 （SSTRl） mRNA expression in different encephalic regions of rats with spleen deficiency, and to compare the interventional effects of Guipi decoction, Chaihu Shugan powder, and Tianwang Buxin pellet. DESIGN： A randomized controlled observation.
SETTING： Basic Medical College, Beijing University of Traditional Chinese Medicine.
MATERIALS： Fifty adult Wistar male rats, of clean grade, weighing （160 ± 10） g, were provided by Beijing Weitong Lihua Laboratory Animal Technology Co., Ltd. The protocol was performed in accordance with ethical guidelines for the use and care of animals. Somatostatin 1 polyclonal anti-rabbit antibody and SSTRl in situ hybridization kit were provided by Department of Neuroanatomy, Shanghai Second Military Medical University of Chinese PLA. The drug for developing rat models of spleen deficiency was composed of Dahuang, Houpu and Zhishi, and prepared at 2：1：1. Guipi decoction, Chaihu Shugan powder, and Tianwang Buxin pellet recipes were made according to previous studies. METHODS： This study was performed at the Basic Medical College, Beijing University of Traditional Chinese Medicine from March 2002 to March 2005. The rats were randomly divided into 5 groups, with 10 rats in each group： normal, model, Guipi decoction, Chaihu Shugan powd.er, and Tianwang Buxin pellet groups. Rat models of the latter 4 groups were developed by methods of purgation with bitter and cold nature drugs, improper diet, and overstrain. The rats received 7.5 g/kg of the drugs each morning and were fasted every other day, but were allowed free access to water at all times. The rats were forced to swim in 25 ℃ water until fati     

The Nonpeptide Growth Hormone Secretagogue,MK-0677, Activates Hypothalamic Arcuate Nucleus Neurons in vivo

There is accumulating evidence that the hypothalamic arcuate nucleus plays an important role in mediating the effects of growth hormone secretagogues on growth hormone (GH) release from the anterior pituitary gland. One such nonpeptidyl secretagogue, MK-0677, has been shown to directly stimulate growth hormone release from isolated pituitary cells but its central actions remain to be established. Therefore, in the present study, we have employed both immunocytochemical and in vivo electrophysiological techniques to examine the effects of MK-0677 within the hypothalamic arcuate nucleus of the male rat. In conscious male rats, both central and systemic injection of MK-0677 induced fos-like immunoreactivity specifically within the arcuate nucleus indicating selective neuronal activation of neurons within this region. MK-0677 induced-activation was generally confined close to the wall of the third ventricle, whereas systemic injection of the peptide secretagogue, GHRP-6, also induced fos-like immunoreactivity in more lateral regions of the nucleus. In urethane anaesthetized rats, intravenous injection of MK-0677 increased the electrical activity of a population of antidromically identified (i.e. neuroendocrine) arcuate neurons with a similar electrophysiological profile to cells excited by GHRP-6. The activity of neuroendocrine arcuate neurons excited by MK-0677 injection could be attenuated by a subsequent systemic injection of somatostatin. However, the activity of neuroendocrine arcuate neurons unaffected by MK-0677 injection and the activity of non-neuroendocrine arcuate neurons was unaltered by somatostatin injection. Taken together, the immunocytochemical and electrophysiological results suggest that systemic and central administration of MK-0677 activates a population of neurons in the arcuate nucleus. Furthermore, the inhibitory effects of somatostatin on MK-0677-induced excitation of these neuroendocrine cells is consistent with an action of neurons involved in the regulation of GH release.