Somatostatin Neurons Research Articles

Mechanically evoked reflex electrogenic chloride secretion in rat distal colon is triggered by endogenous nucleotides acting at P2Y1, P2Y2, and P2Y4 receptors.

Mechanical activation of the mucosal lining of the colon by brush stroking elicits an intestinal neural reflex and an increase in short circuit current (Isc) indicative of electrogenic chloride ion transport. We tested whether endogenous nucleotides are physiologic regulators of mucosal reflexes that control ion transport. The brush stroking-evoked Isc response in mucosa and submucosa preparations (M-SMP) of rat colon was reduced by the P2Y1 receptor (R) antagonist 2'deoxy-N6-methyl adenosine 3',5'-diphosphate diammonium salt (MRS 2179) and further blocked by tetrodotoxin (TTX). M-SMP Isc responses to serosal application of the P2Y1 R agonist 2-methylthioadenosine-diphosphate (2MeSADP) or the P2Y2/P2Y4 R agonist 5'uridine-triphosphate (UTP) were reduced but not abolished by TTX. The potency profile of nucleotides for increasing Isc was 5'adenosine-triphosphate (ATP; effective concentration at half maximal response [EC50] 0.65 x 10(4) M) congruent with UTP (EC50 1.0 x 10(-4) M) congruent with 2MeSADP (EC50 = 1.60 x 10(-4) M). Mucosal touch and distention-induced Ca2+ transients in submucous neurons were reduced by apyrase and prevented by blocking the P2Y1 R with MRS 2179 and TTX; denervation of the mucosa. It did not occur by touching a ganglion directly. 2MeSADP Ca2+ responses occurred in subsets of neurons with or without substance P (SP) responses. The potency profile of nucleotides on the neural Ca2+ response was 2MeSADP (5 x 10(-7) M) > UTP (6 x 10(-6) M) > ATP (9 x 10(-5) M). The expression of P2Y R immunoreactivity (ir) in nerve cell bodies was in the order of P2Y1 R > P2Y4 R >> P2Y2 R. P2Y1R ir occurred in the cell somas of more than 90% of neuronal nitric oxide synthase, vasoactive intestinal peptide (VIP), calretinin, or neuropeptide Y (NPY)-ir neurons, 78% of somatostatin neurons, but not in calbindin or SP neurons. P2Y2 R ir was expressed in a minority of SP, VIP, NPY, vesicular acetylcholine transporter, and calcitonin gene-related peptide-ir varicose fibers (5-20%) and those surrounding calbindin (5-20%) neurons. P2Y4 ir occurred mainly in the cell somas of 93% of NPY neurons. Reverse transcriptase polymerase chain reaction of the submucosa demonstrated mRNA for P2Y1R, P2Y2, P2Y4, P2Y6, and P2Y12 Rs. Expression of P2Y1, P2Y2, and P2Y4 protein was confirmed by western blots. In conclusion, endogenous nucleotides acting at P2YRs transduce mechanically evoked reflex chloride ion transport in rat distal colon. Nucleotides evoke reflexes by acting primarily at postsynaptic P2Y1 Rs and P2Y4 R on VIP+/NPY+ secretomotor neurons, at P2Y2 Rs on no more than 2% of VIP+ secretomotor neurons, and 2Y2 Rs mainly of extrinsic varicose fibers surrounding putative intrinsic primary afferent and secretomotor neurons. During mucosal mechanical reflexes, it is postulated that P2Y1 R, P2Y2 R, and P2Y4 R are activated by endogenous ATP, UTP, and 5'uridine-diphosphate.

The somatostatin receptor (sst 1) modulates the release of somatostatin in rat retina

The aim of this study was to examine the ability of somatostatin receptor (sst 1) to regulate the release of somatostatin in rat retina. Immunohistochemistry studies were performed to locate the somatostatin neurons, and radioligand binding to ascertain the presence of sst 1. The neuronal release of somatostatin was examined ex vivo in rat retinal explants in the presence of KCl (50 and 100 mM), and absence of Ca ++ (EGTA; 10 mM). Somatostatin levels, quantified by radioimmunoassay, were increased in the presence of KCl (100 mM, 151%) and attenuated in the absence of Ca ++ (31%). CH275 (sst 1 agonist) reduced the somatostatin levels in a concentration-dependent manner (10 −5–10 −7 M), and this effect was reversed by NVP-SRA 880 (sst 1 antagonist;10 −5 M). MK678 (sst 2 agonist; 10 −5 M) had no effect. These data suggest an autoreceptor role for sst 1 in retina.

Distinct GABAergic Targets of Feedforward and Feedback Connections Between Lower and Higher Areas of Rat Visual Cortex

Processing of visual information is performed in different cortical areas that are interconnected by feedforward (FF) and feedback (FB) pathways. Although FF and FB inputs are excitatory, their influences on pyramidal neurons also depend on the outputs of GABAergic neurons, which receive FF and FB inputs. Rat visual cortex contains at least three different families of GABAergic neurons that express parvalbumin (PV), calretinin (CR), and somatostatin (SOM) (Gonchar and Burkhalter, 1997). To examine whether pathway-specific inhibition (Shao and Burkhalter, 1996) is attributable to distinct connections with GABAergic neurons, we traced FF and FB inputs to PV, CR, and SOM neurons in layers 1-2/3 of area 17 and the secondary lateromedial area in rat visual cortex. We found that in layer 2/3 maximally 2% of FF and FB inputs go to CR and SOM neurons. This contrasts with 12-13% of FF and FB inputs onto layer 2/3 PV neurons. Unlike inputs to layer 2/3, connections to layer 1, which contains CR but lacks SOM and PV somata, are pathway-specific: 21% of FB inputs go to CR neurons, whereas FF inputs to layer 1 and its CR neurons are absent. These findings suggest that FF and FB influences on layer 2/3 pyramidal neurons mainly involve disynaptic connections via PV neurons that control the spike outputs to axons and proximal dendrites. Unlike FF input, FB input in addition makes a disynaptic link via CR neurons, which may influence the excitability of distal pyramidal cell dendrites in layer 1.

Identification of the Downstream Targets of SIM1 and ARNT2, a Pair of Transcription Factors Essential for Neuroendocrine Cell Differentiation

SIM1 and ARNT2 are two basic helix-loop-helix/PAS (Per-Arnt-Sim) transcription factors that control the differentiation of neuroendocrine lineages in the mouse hypothalamus. Heterozygous Sim1 mice also develop early onset obesity, possibly due to hypodevelopment of the hypothalamus. Although SIM1 and ARNT2 form heterodimers to direct the same molecular pathway, knowledge of this pathway is limited. To facilitate the identification of their downstream genes, we combined an inducible gene expression system in a neuronal cell line with microarray analysis to screen for their transcriptional targets. This method identified 268 potential target genes of SIM1/ARNT2 that displayed >1.7-fold induced expression. 15 of these genes were subjected to Northern analysis, and a high percentage of them were confirmed to be up-regulated. In vivo, several of these genes showed neuroendocrine hypothalamic expression correlating with that of Sim1. Furthermore, we found that expression of two of these potential targets, the Jak2 and thyroid hormone receptor beta2 genes, was lost in the neuroendocrine hypothalamus of the Sim1 mutant. The expression and predicted functions of many of these genes provide new insight into both the Sim1/Arnt2 action in neuroendocrine hypothalamus development and the molecular basis for the Sim1 haplo-insufficient obesity phenotype.

Somatostatin-14 neurons in the ovine hypothalamus: colocalization with estrogen receptor alpha and somatostatin-28(1-12) immunoreactivity, and activation in response to estradiol.

Pituitary gland growth hormone (GH) secretion is influenced by two hypothalamic neuropeptides: growth hormone-releasing hormone (GHRH) and somatostatin. Recent data also suggest that estrogen modulates GH release, particularly at the time of the preovulatory luteinizing hormone surge, when a coincident surge of GH is observed in sheep. The GHRH neurons do not possess estrogen receptor alpha (ERalpha), suggesting that estrogen does not act directly on GHRH neurons. Similarly, few somatotropes express ERalpha, suggesting a weak pituitary effect of estradiol on GH. It was hypothesized, therefore, that estradiol may affect somatostatin neurons to modulate GH release from the pituitary. Using immunocytochemical approaches, the present study revealed that although somatostatin neurons were located in several hypothalamic sites, only those in the arcuate nucleus (13% +/- 2%) and ventromedial nucleus (VMN; 29% +/- 1%) expressed ERalpha. In addition, we found that all neurons immunoreactive for somatostatin-14 were also immunoreactive for somatostatin-28(1-12). To determine whether increased GH secretion in response to estradiol is through modulation of GHRH and/or somatostatin neuronal activity, a final study investigated whether c-fos expression increased in somatostatin- and GHRH-immunoreactive cells at the time of the estradiol-induced LH surge in intact anestrous ewes. Estradiol significantly (P < 0.05) increased the percentage of GHRH (estradiol, 75% +/- 3%; no estradiol, 19% +/- 2%) neurons expressing c-fos in the hypothalamus. The percentage of somatostatin-immunoreactive neurons coexpressing c-fos in the estradiol-treated animals was significantly (P < 0.05) higher (periventricular, 44% +/- 3%; arcuate, 72% +/- 5%; VMN, 81% +/- 5%) than in the control animals (periventricular, 22% +/- 1%; arcuate, 29% +/- 3%; VMN, 31% +/- 3%). The present study suggests that estradiol modulates the activity of GHRH and somatostatin neurons but that this effect is most likely mediated through an indirect interneuronal pathway.

Hypothalamic Somatostatin and Growth Hormone-Releasing Hormone mRNA Expression Depend upon GABAA Receptor Expression in the Developing Mouse

Gonadal steroids exert an important regulatory influence upon the biosynthetic and secretory activity of the somatostatin and growth hormone-releasing hormone (GHRH) neurons controlling the release of growth hormone. It is hypothesized that some of these effects occur in an indirect transsynaptic manner through the steroid regulation of GAGAergic inputs to these cells. Using GABA_A receptor γ₂ subunit knockout mice (γ₂^–/–), which exhibit marked deficiencies in GABA_A receptor functioning, we have examined here whether signaling through the GABA_A receptor has any role in maintaining normal levels of somatostatin and GHRH mRNA expression in vivo. In situ hybridization experiments using ³⁵S-labeled oligonucleotide probes revealed that cellular levels of somatostatin mRNA in the periventricular nucleus were significantly (p < 0.01) reduced by 16% in newborn γ₂^–/– mice compared with wild-type litter mates (γ₂^+/+). Somatostatin mRNA expression in the striatum was not changed. Cellular levels of GHRH mRNA expression in the arcuate nucleus were significantly (p < 0.05) reduced by 30% in γ₂^–/– compared with γ₂^+/+ mice. These results demonstrate that deletion of the γ₂ subunit of the GABA_A receptor reduces somatostatin and GHRH mRNA expression within the hypothalamopituitary axis and indicate that GABA exerts a tonic stimulatory influence upon both somatostatin and GHRH biosynthesis in vivo in the neonatal mouse.

Orexin receptor-1 (OX-R1) immunoreactivity in chemically identified neurons of the hypothalamus: focus on orexin targets involved in control of food and water intake.

The neuropeptides orexin-A and orexin-B are produced in neurons of the lateral hypothalamic area and have been implicated to be involved in the regulation of food/water intake and sleep-wake control. The orexins act at two different G-protein-coupled orexin receptors (OX-R1 and OX-R2) that are derived from separate genes and expressed differentially throughout the central nervous system. In the present study, we have used a polyclonal antipeptide antiserum to analyse in detail the distribution of OX-R1-immunoreactive neurons in the rat hypothalamus. In order to identify the chemical mediators of orexin action in the hypothalamus, the OX-R1-containing neurons were characterized with regard to the content of peptides shown previously to affect ingestive and drinking behaviour. Neurons containing OX-R1 immunoreactivity were widely distributed in the hypothalamus with cell bodies located in the suprachiasmatic, periventricular, paraventricular (both magno- and parvocellular division), supraoptic, arcuate, ventromedial, dorsomedial and tuberomammillary nuclei and the lateral hypothalamic area. In magnocellular neurons of the paraventricular and supraoptic nuclei, OX-R1 immunoreactivity was seen in both vasopressin- and oxytocin-containing neurons. OX-R1 immunoreactivity was demonstrated in vasopressin and vasoactive intestinal polypeptide (VIP) neurons of the suprachiasmatic nucleus, in somatostatin neurons of the periventricular nucleus and in corticotropin-releasing hormone (CRH) neurons of the parvocellular paraventricular nucleus. In the arcuate nucleus, OX-R1 immunoreactivity was present in neuropeptide Y (NPY) and agouti-related peptide (AGRP) neurons of the ventromedial part as well as in proopiomelanocortin (POMC) and cocaine- and amphetamine-regulated transcript (CART) neurons of the ventrolateral division. In the lateral hypothalamic area, OX-R1 immunoreactivity was demonstrated in melanin-concentrating hormone (MCH)- and orexin-containing neurons. In the hypothalamic tuberomammillary nucleus, OX-R1-immunoreactivity was shown in many histamine-containing neurons. The results support the idea that orexins have important actions on hypothalamic neurons that control food intake and fluid balance, but also that orexins may regulate other neuroendocrine systems.

Effects of central infusions of neuropeptide Y on the somatotropic axis in sheep fed on two levels of protein

Effects of infusions of neuropeptide Y (NPY) into 3rd ventricle of growing sheep fed on diets containing restricted (R) or elevated (E) levels of protein on the immunoreactive (ir) somatostatin neurones, ir somatotrophs, growth hormone (GH) concentration in the blood plasma were studied. The long-term restriction of protein in the diet elicited: enhancing irSS content in periventricular perikarya; diminishing irSS stores in the median eminence and elevating the number ir somatotrophs and content of irGH. NPY infusions enhanced the content of irSS in perikarya in sheep fed on E diet and diminished the number of ir somatotrophs and content of irGH of sheep fed on R diet. The R diet as well as NPY infusions caused an increase in GH mean concentrations in the blood plasma. Obtained results suggest that timulatory effect of restricted feeding and/or NPY action on GH secretion can be due to attenuated SS output. Since dietary restrictions and exogenous NPY have similar influence on the activation of GH secretion, we suggest that NPY could be a neuromodulatory link between nutritional cues and somatotropic axis in sheep.

Axo-axonic synapses formed by somatostatin-expressing GABAergic neurons in rat and monkey visual cortex.

In cerebral cortex of rat and monkey, the neuropeptide somatostatin (SOM) marks a population of nonpyramidal cells (McDonald et al. [1982] J. Neurocytol. 11:809-824; Hendry et al. [1984] J. Neurosci. 4:2497:2517; Laemle and Feldman [1985] J. Comp. Neurol. 233:452-462; Meineke and Peters [1986] J. Neurocytol. 15:121-136; DeLima and Morrison [1989] J. Comp. Neurol. 283:212-227) that represent a distinct type of gamma-aminobutyric acid (GABA) -ergic neuron (Gonchar and Burkhalter [1997] Cereb. Cortex 7:347-358; Kawaguchi and Kubota [1997] Cereb. Cortex 7:476-486) whose synaptic connections are incompletely understood. The organization of inhibitory inputs to the axon initial segment are of particular interest because of their role in the suppression of action potentials (Miles et al. [1996] Neuron 16:815:823). Synapses on axon initial segments are morphologically heterogeneous (Peters and Harriman [1990] J. Neurocytol. 19:154-174), and some terminals lack parvalbumin (PV) and contain calbindin (Del Rio and DeFelipe [1997] J. Comp. Neurol. 342:389-408), that is also expressed by many SOM-immunoreactive neurons (Kubota et al. [1994] Brain Res. 649:159-173; Gonchar and Burkhalter [1997] Cereb. Cortex 7:347-358). We studied the innervation of pyramidal neurons by SOM neurons in rat and monkey visual cortex and examined putative contacts by confocal microscopy and determined synaptic connections in the electron microscope. Through the confocal microscope, SOM-positive boutons were observed to form close appositions with somata, dendrites, and spines of intracortically projecting pyramidal neurons of rat area 17 and pyramidal cells in monkey striate cortex. In addition, in rat and monkey, SOM boutons were found to be associated with axon initial segments of pyramidal neurons. SOM axon terminals that were apposed to axon initial segments of pyramidal neurons lacked PV, which was shown previously to label axo-axonic terminals provided by chandelier cells (DeFelipe et al. [1989] Proc. Natl. Acad. Sci. USA 86:2093-2097; Gonchar and Burkhalter [1999a] J. Comp. Neurol. 406:346:360). Electron microscopic examination directly demonstrated that SOM axon terminals form symmetric synapses with the initial segments of pyramidal cells in supragranular layers of rat and monkey primary visual cortex. These SOM synapses differed ultrastructurally from the more numerous unlabeled symmetric synapses found on initial segments. Postembedding immunostaining revealed that all SOM axon terminals contained GABA. Unlike PV-expressing chandelier cell axons that innervate exclusively initial segments of pyramidal cell axons, SOM-immunoreactive neurons innervate somata, dendrites, spines, and initial segments, that are just one of their targets. Thus, SOM neurons may influence synaptic excitation of pyramidal neurons at the level of synaptic inputs to dendrites as well as at the initiation site of action potential output.

Absence of androgen receptor in the growth hormone releasing hormone-containing neurones in the rat mediobasal hypothalamus.

Growth hormone (GH) secretory patterns are influenced by gonadal steroids, at least in part, through modulation of hypothalamic somatostatin and GH releasing hormone (GHRH) secretion. In the adult male rat, testosterone appears to stimulate somatostatin gene expression by acting directly on androgen receptors in somatostatin neurones. The mechanism by which gonadal status influences hypothalamic GHRH gene expression is less clear. Gonadectomy reduces GHRH mRNA expression in rats, and this reduction can be prevented by the administration of testosterone or partly by a nonaromatizable androgen. While these observations suggest that androgen receptors mediate the actions of gonadal steroids on GHRH gene expression, they do not provide any information about the location of the androgen receptors involved in this process. To determine whether GHRH neurones themselves express androgen receptors, we double immunolabelled hypothalamic sections from colchicine-pretreated male rats. Although there was an overlap in the anatomical distribution of GHRH and androgen receptor-containing cell bodies, none of the nearly 900 GHRH immunolabelled cells we examined in each mediobasal hypothalamus appeared to contain androgen receptors. These results suggest that GHRH-expressing neurones are not direct targets for androgens and therefore the effects of testosterone on GHRH gene expression must be produced indirectly by some other neural or endocrine intermediary process.

Somatostatin Inhibits Alpha-2-Adrenergic-Induced Secretion of Growth Hormone-Releasing Hormone

The purpose of this experiment was to determine the role of growth hormone-releasing hormone (GHRH) and somatostatin (SRIH) neurons in mediating α₂-adrenergic receptor-induced stimulation of growth hormone (GH) secretion in cattle. Our first objective was to determine if stimulation of α₂-adrenergic receptors increases activity of GHRH neurons in the arcuate nucleus (ARC) and/or decreases activity of SRIH neurons in periventricular (PeVN) and ARC nuclei. Clonidine (an α₂-adrenergic agonist) or vehicle (saline) were injected i.v. into steers and dual-label immunohistochemistry was performed to quantify the number of GHRH and SRIH neurons expressing Fos and Fos-related antigens (Fos/FRA) as markers of neuronal activity. Clonidine increased concentrations of GH in serum and decreased activity of SRIH neurons in the PeVN, but not in the ARC. Clonidine did not alter activity of GHRH neurons in the ARC. Our second objective was to determine if clonidine decreases secretion of SRIH from perifused slices of hypothalami, which contain perikarya and terminals of GHRH and SRIH neurons, and from explants of hypophysial stalk alone, which contain only terminals of GHRH and SRIH neurons. Clonidine failed to alter release of GHRH or SRIH from hypothalamic slices, but stimulated release of GHRH from explants of hypophysial stalk. Blockade of SRIH receptors enabled clonidine to stimulate release of GHRH from slices of hypothalami, but also stimulated release of SRIH. These results suggest that α₂-adrenergic-induced secretion of GH occurs via a dual mechanism involving inhibition of SRIH neurons in the PeVN and direct stimulation of GHRH release from axon terminals in the median eminence.

Neuroregulation of growth hormone secretion in domestic animals

Growth hormone (GH) is essential for postnatal somatic growth, maintenance of lean tissue at maturity in domestic animals and milk production in cows. This review focuses on neuroregulation of GH secretion in domestic animals. Two hormones principally regulate the secretion of GH: growth hormone-releasing hormone (GHRH) stimulates, while somatostatin (SS) inhibits the secretion of GH. A long-standing hypothesis proposes that alternate secretion of GHRH and SS regulate episodic secretion of GH. However, measurement of GHRH and SS in hypophysial-portal blood of unanesthetized sheep and swine shows that episodic secretion of GHRH and SS do not account for all episodes of GH secreted. Furthermore, the activity of GHRH and SS neurons decreases after steers have eaten a meal offered for a 2-h period each day (meal-feeding) and this corresponds with reduced secretion of GH. Together, these data suggest that other factors also regulate the secretion of GH. Several neurotransmitters have been implicated in this regard. Thyrotropin-releasing hormone, serotonin and γ-aminobutyric acid stimulate the secretion of GH at somatotropes. Growth hormone releasing peptide-6 overcomes feeding-induced refractoriness of somatotropes to GHRH and stimulates the secretion of GHRH. Norepinephrine reduces the activity of SS neurons and stimulates the secretion of GHRH via α 2-adrenergic receptors. N-methyl-d, l-aspartate and leptin stimulate the secretion of GHRH, while neuropeptide Y stimulates the secretion of GHRH and SS. Activation of muscarinic receptors decreases the secretion of SS. Dopamine stimulates the secretion of SS via D 1 receptors and inhibits the secretion of GH from somatotropes via D 2 receptors. Thus, many neuroendocrine factors regulate the secretion of GH in livestock via altering secretion of GHRH and/or SS, communicating between GHRH and SS neurons, or acting independently at somatotropes to coordinate the secretion of GH.

Estrogen receptor (ER)alpha, but not ERbeta, gene is expressed in growth hormone-releasing hormone neurons of the male rat hypothalamus.

GH synthesis and release from pituitary somatotropes is controlled by the opposing actions of the hypothalamic neuropeptides, GH-releasing hormone (GHRH), and somatostatin (SS). There is a striking sex difference in the pattern of GH secretion in rats. Early reports indicate that gonadal steroids have important imprinting effects during the neonatal period. Recently, our laboratory and others have reported that the GH secretory pattern is altered by short-term gonadal steroid treatment in adult rat, suggesting that gonadal steroids are also important determinants of the pattern of GH secretion during adult life. However, the site of action of gonadal steroids in the adult rat hypothalamus is still unknown. In this study, we used in situ hybridization in the adult male rat brain to determine whether GHRH neurons and/or SS neurons coexpress estrogen receptor alpha (ERalpha) and ERss genes. In the medial basal hypothalamus of adult male rat, the ERalpha messenger RNA (mRNA) was located in medial preoptic area (MPA) and arcuate nucleus (ARC), whereas ERss mRNA was detected in MPA, supraoptic nucleus, and paraventricular nucleus. From studies using adjacent sections, the distribution of ERalpha mRNA-containing cells appeared to overlap in part with those of GHRH and SS expressing cells only in the ARC. On the other hand, the distribution of ERss mRNA-containing cells does not appear to overlap with GHRH cells or SS cells. The double label in situ hybridization studies showed that in the ARC, 70% of GHRH neurons contain ERalpha mRNA, whereas less than 5% of SS neurons expressed the ERalpha gene. These results indicated that GHRH neurons are direct target cells for estrogens, and estrogens may act directly on GHRH neurons through ERalpha during adult life to modify GH secretory patterns.

Estrogen Receptor (ER) , But Not ER , Gene Is Expressed in Growth Hormone-Releasing Hormone Neurons of the Male Rat Hypothalamus

GH synthesis and release from pituitary somatotropes is controlled by the opposing actions of the hypothalamic neuropeptides, GH-releasing hormone (GHRH), and somatostatin (SS). There is a striking sex difference in the pattern of GH secretion in rats. Early reports indicate that gonadal steroids have important imprinting effects during the neonatal period. Recently, our laboratory and others have reported that the GH secretory pattern is altered by short-term gonadal steroid treatment in adult rat, suggesting that gonadal steroids are also important determinants of the pattern of GH secretion during adult life. However, the site of action of gonadal steroids in the adult rat hypothalamus is still unknown. In this study, we used in situ hybridization in the adult male rat brain to determine whether GHRH neurons and/or SS neurons coexpress estrogen receptor α (ERα) and ERβ genes. In the medial basal hypothalamus of adult male rat, the ERα messenger RNA (mRNA) was located in medial preoptic area (MPA) and arcuate nucleus (ARC), whereas ERβ mRNA was detected in MPA, supraoptic nucleus, and paraventricular nucleus. From studies using adjacent sections, the distribution of ERα mRNA-containing cells appeared to overlap in part with those of GHRH and SS expressing cells only in the ARC. On the other hand, the distribution of ERβ mRNA-containing cells does not appear to overlap with GHRH cells or SS cells. The double label in situ hybridization studies showed that in the ARC, 70% of GHRH neurons contain ERα mRNA, whereas less than 5% of SS neurons expressed the ERα gene. These results indicated that GHRH neurons are direct target cells for estrogens, and estrogens may act directly on GHRH neurons through ERα during adult life to modify GH secretory patterns.

Role of the gonads in sex differentiation of growth hormone-releasing hormone and somatostatin neurons in the mouse hypothalamus during postnatal development

We clarify the mechanism of sexual dimorphism of growth hormone releasing hormone (GHRH) neurons in the arcuate nucleus (ARC) and somatostatin (SS) neurons in periventricular nucleus (PeN), by studying the role of the gonads during the neonatal period and after puberty using immunohistochemical and morphometric methods. As in our previous works the numbers of ARC GHRH-ir and PeN SS-ir neurons were significantly greater in adult normal male (NM) mice than in adult normal female (NF) mice. Adult female mice that were ovariectomized neonatally (NOF) increased the expression of GHRH-ir neurons to the male pattern, but adult female mice ovariectomized after puberty (APO) did not change. Adult male mice castrated neonatally and after puberty (NCM and APC, respectively) were not significantly different from NM mice. However, NCT male mice, which were castrated neonatally and transplanted with ovary just before puberty, showed a significantly reduced number of GHRH-ir neurons compared with NCM mice, but no significant difference from NM and NF mice. On the other hand, the PeN SS-ir neuron expression in NCM mice and APC mice showed a significant reduction compared with NM mice, but no significant difference from NF mice. The number of PeN SS-ir neurons in NOF increased to match that of NM mice. Our results suggest that the presence of the ovary during postnatal life inhibits the development of ARC GHRH-ir neurons. The presence of the testis during postnatal life may stimulate the development of PeN SS-ir neurons, while the presence of the ovary during neonatal period may inhibit the development of PeN SS-ir neurons; the presence of ovary after puberty does not inhibit.

Effects of intrauterine and early postnatal growth restriction on hypothalamic somatostatin gene expression in the rat.

In the human, intrauterine growth retardation (IUGR) can result in persistent postnatal growth failure, which may be attributable, in part, to abnormal GH secretion. Whether putative alterations in GH secretion are the result of abnormalities intrinsic to the pituitary or reflect changes in the production of GH-releasing hormone or somatostatin (SS) is unknown. We tested the hypothesis that growth failure associated with IUGR or early postnatal food restriction (FR) is caused by a central defect in hypothalamic SS gene expression. Both models displayed persistent growth failure postnatally without any catch-up growth. We measured levels of SS mRNA levels in rats experimentally subjected to IUGR or FR. SS mRNA levels were measured by semiquantitative in situ hybridization throughout development. Levels of SS mRNA in the periventricular nucleus were significantly higher in both male and female IUGR rats in the juvenile and adult stages compared with matched controls (p < or = 0.05). FR was associated with higher SS mRNA levels only in neonatal female rats (p < or = 0.05). These results suggest that intrauterine malnutrition induces a persistent increase in the expression of SS mRNA in the periventricular nucleus, whereas early postnatal FR results in only a transient increase in SS gene expression. Because IGF-I levels were normal in juvenile IUGR and FR rats, central dysregulation of SS neurons does not appear to be the cause of early postnatal growth failure in either model. However, these observations are consistent with the hypothesis that nutritional stress at critical times during development can have persistent and potentially irreversible effects on organ function.

Rapid modifications of somatostatin neuron activity in the periventricular nucleus after acute stress.

We have previously reported that stress induces a rapid increase in hypothalamic somatostatin (SS) release. In the present work, we investigated whether SS synthesis is also affected by this treatment. Male rats were subjected to 15-min immobilization (IMO) stress, and measurements of both SS mRNA levels and SS mRNA-containing cells were analyzed in the periventricular nucleus (PeV) by radioactive and nonradioactive in situ hybridization (ISH), respectively. In addition, SS content and total SS mRNA were measured in the whole hypothalamus by radioimmunoassay (RIA) and northern blot analysis, respectively. ISH was conducted by applying either a radioactive-labeled (35S) or a digoxigenin (DIG)-labeled oligonucleotide probe on histological sections containing the periventricular region of the anterior hypothalamic area (AHA). ISH analysis using radioactive label showed a significant increase in SS mRNA levels in stressed rats. In contrast, stress treatment decreased the number of DIG-labeled cells expressing SS mRNA in this region by 35% as compared to the same histological sections from naive control rats. In addition, a significant decrease in the total SS mRNA DIG-labeled area was observed. Finally, SS content and SS mRNA measured in the whole hypothalamus of stressed rats were markedly inhibited as compared to control rats. Our data show that IMO stress induces a significant and rapid increase in SS mRNA level accompanied by a decrease in the number of cells expressing SS mRNA in the PeV-AHA. The present results suggest that a subset of PeV SS neurons, which became silent at the onset of stress, are regulated independently of the remaining whole mass of PeV neurons. This differential control is in line with the cellular heterogeneity described in periventricular SS-producing neurons and with the multiple hypothalamic and pituitary functions assigned to SS.

Brain-Derived Neurotrophic Factor But Not Neurotrophin-3 Enhances Differentiation of Somatostatin Neurons in Hypothalamic Cultures

The present work investigated whether neurotrophins could differentially affect in vitro growth and maturation of two related subsets of hypothalamic neurons, hypophysiotropic somatostatin (SRIH) neurons projecting from the periventricular area and arcuate SRIH interneurons. For this purpose, the hypothalamus of 17-day-old rat fetuses was sampled and separated into a ventral and a dorsal fragment containing respectively periventricular and arcuate regions. Each fragment was dissociated and seeded separately in defined medium. Brain-derived neurotrophic factor (BDNF) or neurotrophin-3 (NT-3), two important members of the neurotrophin family involved in neuronal differentiation and plasticity, were added to the cultures at seeding time. After 6 or 11 days in vitro, neurons were labeled with an anti-SRIH antiserum and submitted to morphometric analysis. In parallel, SRIH mRNA was estimated by semiquantitative reverse-transcriptase-polymerase chain reaction, and neuronal SRIH content, basal and depolarisation-stimulated releases measured by radioimmunoassay. The response of control, non-labeled neurons was estimated by neuronal counts and by assaying glutamic acid decarboxylase, a marker of a large majority of hypothalamic neurons. BDNF markedly increased the size and the branching number of SRIH periventricular cell bodies. Expression of SRIH mRNA, as well as SRIH content and release into the culture medium, were also stimulated by the neurotrophin. Non-SRIH neurons were not affected by the treatment. Under the same conditions, arcuate neurons exhibited a weak, mostly transient response to BDNF. NT-3 was ineffective on either neuronal subset. Immunoneutralization of Trk receptors provided further evidence for BDNF effect specificity. The results indicate that BDNF is a selective activator of the differentiation of hypophysiotropic SRIH neurons in the periventricular area of the hypothalamus.

Galanin-Like Peptide (GALP) mRNA Expression Is Restricted to Arcuate Nucleus of Hypothalamus in Adult Male Rat Brain

Galanin-like peptide (GALP) is a novel 60-amino acid neuropeptide, isolated from porcine hypothalamus and subsequently identified in rats and humans, which has reported selectivity for the Gal-R2 galanin receptor [Ohtaki T et al: J Biol Chem 1999; 274: 37041–37045]. In the current study, the regional and cellular distribution of GALP mRNA in rat brain has been investigated by in situ hybridization of [³⁵S]-labelled oligonucleotide probes. In a thorough screening of adult male rat brain, GALP mRNA expression was detected only throughout the rostrocaudal extent of the arcuate nucleus (ARC) with the most abundant hybridization signal in the posterior, periventricular zones. GALP mRNA-positive neurons were mostly localized in the ventromedial division of the ARC, with many closely adjacent to the wall of the third ventricle. Smaller numbers of labelled neurons were also found in ventrolateral areas. The distribution of GALP mRNA was somewhat complementary to that for galanin (GAL) mRNA in the ARC, but contrasted with the broad distribution of this transcript throughout the hypothalamus. GAL mRNA was also distributed along the rostrocaudal extent of the ARC, but was most abundant in the anterior to middle levels and in ventrolateral regions. Interestingly, somatostatin mRNA expression appeared to overlap the distribution of GALP mRNA in posterior, ventromedial regions of the ARC. Thus, in adult rat brain GALP mRNA expression was restricted to a discrete subpopulation of neurons in the ARC, with a unique localization pattern unlike GAL or many other known peptide- and transmitter-containing cells in this region. GALP could, however, be co-expressed in sub-populations of other neuronal phenotypes (e.g. somatostatin neurons) or within cells that express Gal-R2 receptors. In view of the established anatomy and function of the ARC and the restricted localization of GALP mRNA, this novel peptide is likely to play a role in regulation of anterior pituitary hormone secretion, or in regulation of other hypothalamic peptide and transmitter systems.

Feeding reduces activity of growth hormone-releasing hormone and somatostatin neurons.

Secretion of growth hormone (GH) is synchronized among castrate male cattle (steers) around feeding when access to feed is restricted to a 2-hr period each day. Typically, concentrations of GH increase before and decrease after feeding. Our objectives were to determine whether i) concentrations of GH decrease in blood after start of feeding; ii) activity of immunoreactive growth hormone-releasing hormone (GHRH-ir) neurons decreases in the arcuate nucleus (ARC) after feeding; iii) activity of immunoreactive somatostatin (SS-ir) neurons in the periventricular nucleus (PeVN) and ARC increase after feeding; and iv) GHRH stimulates release of GH to a similar magnitude at 0900 and at 1300 hr, in steers fed between 1000 and 1200 hr. Blood samples were collected at 20-min intervals from 0700 to 1300 hr. Groups of steers were euthanized at 0700, 0900, 1100, and 1300 hr (n = 5 per group). Dual-label immunohistochemistry was performed on free-floating sections of hypothalami using antibodies directed against Fos and Fos-related antigens (Fos/FRA) as a marker of neuronal activity in immunoreactive GHRH and SS neurons. Concentrations of GH were high before and decreased after feeding. The percentage of SS-ir neurons containing Fos/FRA-ir in the PeVN was 50% lower (P<0.01) at 1100 hr and 36% lower (P<0.05) at 1300 hr than at 0900 hr. There was no change in percentage of SS-ir neurons containing Fos/FRA-ir in the ARC. The percentage of GHRH-ir neurons containing Fos/FRA-ir in the ARC was 66% lower (P<0.05) at 1100 hr and 65% lower (P<0.05) at 1300 hr than at 0700 hr. In contrast, the number of GHRH-ir neurons increased from 0700 to 1300 hr. GHRH-induced release of GH was suppressed at 1300 hr compared with 0900 hr. In conclusion, reduced basal and GHRH-induced secretion of GH after feeding was associated with decreased activity of GHRH neurons in the ARC and decreased activity of SS neurons in the PeVN.