LPA1 receptor-deficient mice have phenotypic changes observed in psychiatric disease.

Several psychiatric diseases, including schizophrenia, are thought to have a developmental aetiology, but to date no clear link has been made between psychiatric disease and a specific developmental process. LPA(1) is a G(i)-coupled seven transmembrane receptor with high affinity for lysophosphatidic acid. Although LPA(1) is expressed in several peripheral tissues, in the nervous system it shows relatively restricted temporal expression to neuroepithelia during CNS development and to myelinating glia in the adult. We report the detailed neurological and behavioural analysis of mice homozygous for a targeted deletion at the lpa(1) locus. Our observations reveal a marked deficit in prepulse inhibition, widespread changes in the levels and turnover of the neurotransmitter 5-HT, a brain region-specific alteration in levels of amino acids, and a craniofacial dysmorphism in these mice. We suggest that the loss of LPA(1) receptor generates defects resembling those found in psychiatric disease.

The distribution of the orphan bombesin receptor subtype-3 in the rat CNS.

Bombesin receptor subtype 3 (BRS-3) is an orphan G-protein coupled receptor that shares between 47 and 51% homology with other known bombesin receptors. The natural ligand for BRS-3 is currently unknown and little is known about the mechanisms regulating BRS-3 gene expression. Unlike other mammalian bombesin receptors that have been shown to be predominantly expressed in the CNS and gastrointestinal tract, expression of the BRS-3 receptor in the rat brain has previously not been observed. To gain further understanding of the biology of BRS-3, we have studied the distribution of BRS-3 mRNA and protein in the rat CNS. The mRNA expression pattern was studied using reverse transcription followed by quantitative polymerase chain reaction. Using immunohistological techniques, the distribution of BRS-3 protein in the rat brain was investigated using a rabbit affinity-purified polyclonal antiserum raised against an N-terminal peptide. The BRS-3 receptor was found to be widely expressed in the rat brain at both mRNA and protein levels. Particularly strong immunosignals were observed in the cerebral cortex, hippocampal formation, hypothalamus and thalamus. Other regions of the brain such as the basal ganglia, midbrain and reticular formation were also immunopositive for BRS-3. In conclusion, our neuroanatomical data provide evidence that BRS-3 is as widely expressed in the rat brain as other bombesin-like peptide receptors and suggest that this receptor may also have important roles in the CNS, mediating the functions of a so far unidentified ligand.

Growth hormone secretagogue receptors in rat and human gastrointestinal tract and the effects of ghrelin.

The peptide hormone ghrelin is known to be present within stomach and, to a lesser extent, elsewhere in gut. Although reports suggest that gastric function may be modulated by ghrelin acting via the vagus nerve, the gastrointestinal distribution and functions of its receptor, the growth hormone secretagogue receptor (GHS-R), are not clear and may show signs of species-dependency. This study sought to determine the cellular localisation and distribution of GHS-R-immunoreactivity (-Ir) using immunofluorescent histochemistry and explore the function of ghrelin in both human and rat isolated gastric and/or colonic circular muscle preparations in which nerve-mediated responses were evoked by electrical field stimulation. The expression of GHS-R-Ir differed to a greater extent between species than between gut regions of the same species. Both the human and rat gastric and colonic preparations (n=3 each) expressed GHS-R-Ir within neuronal cell bodies and fibres, cells associated with gastric glands and putative entero-endocrine and/or mast cells. Smooth muscle cells and epithelia were devoid of GHS-R-Ir and only rat preparations expressed GHS-R-Ir on nerve fibres associated with the muscle layers. GHS-R-Ir was fully competed in all cases in pre-adsorption studies and antiserum specificity was confirmed using a cell line transiently expressing the rat GHS-R. In rat isolated forestomach circular muscle, ghrelin 0.1-10 microM had no effect on smooth muscle tension but concentration-dependently facilitated the amplitude of contractions evoked by excitatory nerve stimulation (n=4-7; P<0.05 for each concentration versus vehicle; n=18). When examined under similar conditions, in both rat distal colon (n=4-6, P>0.05 each) and human ascending (n=3) and sigmoid (n=1) colon, these concentrations of ghrelin were without effect (P>0.05 each). The data suggest that ghrelin has the potential to profoundly affect gastrointestinal functions in both species and at least one of these functions is to exert a gastric prokinetic activity. Moreover, we suggest that this activity of ghrelin is mediated via the enteric nervous system, in addition to known vagus nerve-dependent mechanisms.

Effect of direct injection of melanin-concentrating hormone into the paraventricular nucleus: further evidence for a stimulatory role in the adrenal axis via SLC-1.

Melanin-concentrating hormone (MCH) is implicated in the control of a number of hormonal axes including the hypothalamic-pituitary adrenal (HPA) axis. Previous studies have shown that there is evidence for both a stimulatory and an inhibitory action on the HPA axis; therefore, we attempted to further characterize the effects of MCH on this axis. Intracerebroventricular injection of MCH increased circulating adrenocorticotropic hormone (ACTH) at 10 min post injection. Injection of MCH directly into the paraventricular nucleus (PVN) was found to increase both circulating ACTH and corticosterone 10 min after injection. Additionally, MCH was found to increase corticotropin-releasing factor (CRF) release from hypothalamic explants, and this effect was abolished by the specific SLC-1 antagonist SB-568849. Neuropeptide EI, a peptide from the same precursor as MCH was also found to increase CRF release from explants. These results suggest that MCH has a stimulatory role in the HPA axis via SLC-1, and that MCH exerts its effects predominantly through the PVN CRF neuronal populations

Protein distribution of the orexin-2 receptor in the rat central nervous system.

Orexin-A and -B are neuropeptides mainly expressed in the lateral hypothalamic area (LHA). A role for orexins was first demonstrated in the regulation of feeding behaviour. Subsequently, the peptides have been implicated in the control of arousal. To date, two receptors for orexins have been characterised: orexin-1 and -2 receptors (OX-R1 and OX-R2). Both receptor genes are widely expressed within the rat brain. Particularly high expression of both receptor genes in certain hypothalamic and pons nuclei could be responsible for the orexigenic and arousal properties of the peptides. It is, however, presently unclear if one given receptor subtype or both subtypes may mediate a specific biological effect of orexins such as an increase in food intake. We have recently reported the distribution of the OX-R1 protein in the rat nervous system. In this study, we report the distribution of the OX-R2 protein in the rat brain and spinal cord using specific anti-peptide antisera raised against the OX-R2 protein. We also assess the expression profile of the OX-R2 gene in different brain regions. Immunolabelling for the OX-R2 protein was observed in brain regions that exhibited OX-R1-like immunoreactivity (cerebral neocortex, basal ganglia, hippocampal formation, and many other regions in the hypothalamus, thalamus, midbrain and reticular formation). Differences in the OX-R1 and OX-R2 distribution were, however, noticed in the hippocampus, hypothalamus and dorso-lateral pons.

Distribution and expression of TREK-1, a two-pore-domain potassium channel, in the adult rat CNS.

TREK-1 is a member of the two-pore-domain potassium channel family which is expressed predominantly in the CNS. Using an anti-peptide polyclonal antiserum, we have determined the distribution of TREK-1 in the brain and spinal cord of adult rats. Specificity of the antiserum was tested using a TREK-1-transfected cell line and confirmed with c-myc-tagged TREK-1. In thin tissue sections, immunoreactivity was widespread throughout the rat brain and spinal cord. TREK-1-like signals were observed in the cerebral cortex, basal ganglia, hippocampus, and various other subcortical nuclei in the hypothalamus, thalamus, mesencephalon and rhombencephalon. TREK-1 labelling appeared to be over the entire cell membrane, including the cell body and processes. Cells that morphologically resembled projection neurones and interneurones but not glial cells were labelled. As interneurones and known GABAergic projection neurones were the predominant population labelled, we investigated the possibility that TREK-1 is expressed in GABA-containing neurones using a specific anti-GABA antiserum. Expression of TREK-1 in GABA-containing neurones was observed in a number of areas, including the isocortex, hippocampus and thalamus. Thus, TREK-1 expression defines a unique and specific subset of interneurones and principal cells. These studies indicate a widespread distribution of TREK-1 potassium channels throughout the rat brain and spinal cord, with expression in a number of areas being demonstrated to be present on GABA-containing neurones.

Gene expression and protein distribution of the orexin-1 receptor in the rat brain and spinal cord.

Orexins-A and -B are neuropeptides derived from a single precursor prepro-orexin. The mature peptides are mainly expressed in the lateral hypothalamic and perifornical areas. The orexins have been implicated in the control of arousal and appear to be important messengers in the regulation of food intake. Two receptors for orexins have been characterised so far: orexin-1 and -2 receptors. To gain a further understanding of the biology of orexins, we studied the distribution of the orexin-1 receptor messenger RNA and protein in the rat nervous system. We first assessed the expression profile of the orexin-1 receptor gene (ox-r1) in different regions by using quantitative reverse transcription followed by polymerase chain reaction. Using immunohistochemical techniques, we investigated the distribution of orexin-1 receptor protein in the rat brain using a rabbit affinity-purified polyclonal antiserum raised against an N-terminal peptide. The orexin-1 receptor was widely and strongly expressed in the brain. Thus, immunosignals were observed in the cerebral cortex, basal ganglia, hippocampal formation, and various other subcortical nuclei in the hypothalamus, thalamus, midbrain and reticular formation. In particular, robust immunosignals were present in many hypothalamic and thalamic nuclei, as well as in the locus coeruleus. The distribution of the receptor protein was generally in agreement with the distribution of the receptor messenger RNA in the brain as reported previously by others and confirmed in the present study. In addition, we present in situ hybridisation and immunohistochemical data showing the presence of orexin-1 receptor messenger RNA and protein in the spinal cord and the dorsal root ganglia. Finally, due to the shared anatomical and functional similarities between orexins and melanin-concentrating hormone, we present a comparison between the neuroanatomical distribution of the orexin-1 receptor and melanin-concentrating hormone receptor protein-like immunoreactivities in the rat central nervous system, and discuss some functional implications. In conclusion, our neuroanatomical data are consistent with the biological effects of orexins on food intake and regulation of arousal. In addition, the data suggest other physiological roles for orexins mediated through the orexin-1 receptor.

The expression of GABA(B1) and GABA(B2) receptor subunits in the cNS differs from that in peripheral tissues.

GABA(B) receptors are G-protein-coupled receptors that mediate the slow and prolonged synaptic actions of GABA in the CNS via the modulation of ion channels. Unusually, GABA(B) receptors form functional heterodimers composed of GABA(B1) and GABA(B2) subunits. The GABA(B1) subunit is essential for ligand binding, whereas the GABA(B2) subunit is essential for functional expression of the receptor dimer at the cell surface. We have used real-time reverse transcriptase-polymerase chain reaction to analyse expression levels of these subunits, and their associated splice variants, in the CNS and peripheral tissues of human and rat. GABA(B1) subunit splice variants were expressed throughout the CNS and peripheral tissues, whereas surprisingly GABA(B2) subunit splice variants were neural specific. Using novel antisera specific to individual GABA(B) receptor subunits, we have confirmed these findings at the protein level. Analysis by immunoblotting demonstrated the presence of the GABA(B1) subunit, but not the GABA(B2) subunit, in uterus and spleen. Furthermore, we have shown the first immunocytochemical analysis of the GABA(B2) subunit in the brain and spinal cord using a GABA(B2)-specific antibody. We have, therefore, identified areas of non-overlap between GABA(B1) and GABA(B2) subunit expression in tissues known to contain functional GABA(B) receptors. Such areas are of interest as they may well contain novel GABA(B) receptor subunit isoforms, expression of which would enable the GABA(B1) subunit to reach the cell surface and form functional GABA(B) receptors.

Expression of melanin-concentrating hormone receptors in insulin-producing cells: MCH stimulates insulin release in RINm5F and CRI-G1 cell-lines.

Melanin-concentrating hormone (MCH) is a hypothalamic orexigenic peptide. Recently, an orphan G-protein-coupled receptor (SLC-1) was identified that binds MCH with high affinity. Here, we demonstrate the mRNA expression of this receptor in insulin-producing cells including CRI-G1 and RINm5F cells, and in rat islets of Langerhans. Immunofluorescence studies in CRI-G1 and RINm5F cell-lines demonstrated cell-surface expression of the receptor. Rat MCH significantly stimulated insulin secretion in both cell-lines. The potency and the efficacy of MCH were significantly increased in the simultaneous presence of forskolin, suggesting that MCH may amplify the insulinotropic effect of cyclic AMP elevating stimuli. Salmon MCH, which differs from rat/human MCH by six amino acids, was less efficacious than rat/human MCH in stimulating insulin release. The data provide evidence for the expression of MCH receptors in insulin producing cells. The insulinotropic effect of MCH may contribute to the regulation of metabolism and energy balance by this peptide.

The distribution of the mRNA and protein products of the melanin-concentrating hormone (MCH) receptor gene, slc-1, in the central nervous system of the rat.

Melanin-concentrating hormone (MCH), a 19 amino acid cyclic peptide, is largely expressed in the hypothalamus. It is implicated in the control of general arousal and goal-orientated behaviours in mammals, and appears to be a key messenger in the regulation of food intake. An understanding of the biological actions of MCH has been so far hampered by the lack of information about its receptor(s) and their location in the brain. We recently identified the orphan G-protein-coupled receptor SLC-1 as a receptor for the neuropeptide MCH. We used in situ hybridization histochemistry and immunohistochemistry to determine the distribution of SLC-1 mRNA and its protein product in the rat brain and spinal cord. SLC-1 mRNA and protein were found to be widely and strongly expressed throughout the brain. Immunoreactivity was observed in areas that largely overlapped with regions mapping positive for mRNA. SLC-1 signals were observed in the cerebral cortex, caudate-putamen, hippocampal formation, amygdala, hypothalamus and thalamus, as well as in various nuclei of the mesencephalon and rhombencephalon. The distribution of the receptor mRNA and immunolabelling was in good general agreement with the previously reported distribution of MCH itself. Our data are consistent with the known biological effects of MCH in the brain, e.g. modulation of the stress response, sexual behaviour, anxiety, learning, seizure production, grooming and sensory gating, and with a role for SLC-1 in mediating these physiological actions.

A G protein-coupled receptor for UDP-glucose.

Uridine 5'-diphosphoglucose (UDP-glucose) has a well established biochemical role as a glycosyl donor in the enzymatic biosynthesis of carbohydrates. It is less well known that UDP-glucose may possess pharmacological activity, suggesting that a receptor for this molecule may exist. Here, we show that UDP-glucose, and some closely related molecules, potently activate the orphan G protein-coupled receptor KIAA0001 heterologously expressed in yeast or mammalian cells. Nucleotides known to activate P2Y receptors were inactive, indicating the distinctly novel pharmacology of this receptor. The receptor is expressed in a wide variety of human tissues, including many regions of the brain. These data suggest that some sugar-nucleotides may serve important physiological roles as extracellular signaling molecules in addition to their familiar role in intermediary metabolism.

Visualisation of somatostatin receptor sst(3) in the rat central nervous system.

Somatostatin actions are mediated through G-protein coupled receptors named sst(1) to sst(5). We used an affinity-purified polyclonal antibody AS-69, directed against a specific N-terminal peptide sequence of sst(3) to determine the immunohistochemical distribution of the sst(3) receptor in the rat and human brain. The specificity of the antibody was shown by Western blotting experiments using an N-terminal sst(3) fusion protein. Enzymatic deglycosylation experiments were combined to blotting experiments on a sst(3)-transfected cell line and rat brain membrane proteins and with immunocytochemistry on the sst(3)-transfected cell line. These studies showed that the antibody detected the deglycosylated sst(3) receptor protein. Immunohistochemical staining showed that sst(3) immunoreactivity recognised by this N-terminal antiserum was widely distributed throughout the brain with cells and processes labelled in the cerebral cortex, regions of the limbic system (including the hippocampal formation, some amygdaloid regions, some basal ganglia nuclei and regions from the nucleus basalis complex), the habenula, the hypothalamus, the thalamus, different mesencephalic structures (substantia nigra, zona incerta, superior colliculus), the reticular formation, the cerebellum. The distribution of immunoreactivity was in good general agreement with that predicted from the localisation of sst(3) mRNA and radio-ligand binding studies; however, due to the preference of AS-69 towards the deglycosylated receptor, it appears that the sst(3) immunoreactivity detected may correspond largely to the deglycosylated receptor. This study on the immunohistochemical distribution of the sst(3) receptor in the brain may provide a better understanding of the central actions of somatotropin release-inhibiting factor (SRIF).

Melanin-concentrating hormone is the cognate ligand for the orphan G-protein-coupled receptor SLC-1.

The underlying causes of obesity are poorly understood but probably involve complex interactions between many neurotransmitter and neuropeptide systems involved in the regulation of food intake and energy balance. Three pieces of evidence indicate that the neuropeptide melanin-concentrating hormone (MCH) is an important component of this system. First, MCH stimulates feeding when injected directly into rat brains; second, the messenger RNA for the MCH precursor is upregulated in the hypothalamus of genetically obese mice and in fasted animals; and third, mice lacking MCH eat less and are lean. MCH antagonists might, therefore, provide a treatment for obesity. However, the development of such molecules has been hampered because the identity of the MCH receptor has been unknown until now. Here we show that the 353-amino-acid human orphan G-protein-coupled receptor SLC-1 expressed in HEK293 cells binds MCH with sub-nanomolar affinity, and is stimulated by MCH to mobilize intracellular Ca2+ and reduce forskolin-elevated cyclic AMP levels. We also show that SLC-1 messenger RNA and protein is expressed in the ventromedial and dorsomedial nuclei of the hypothalamus, consistent with a role for SLC-1 in mediating the effects of MCH on feeding.

Cellular localization and role of prohormone convertases in the processing of pro-melanin concentrating hormone in mammals.

Melanin concentrating hormone (MCH) and neuropeptide EI (NEI) are two peptides produced from the same precursor in mammals, by cleavage at the Arg145-Arg146 site and the Lys129-Arg130 site, respectively. We performed co-localization studies to reveal simultaneously the expression of MCH mRNA and proconvertases (PCs) such as PC1/3 or PC2. In the rat hypothalamus, PC2 was present in all MCH neurons, and PC1/3 was present in about 15-20% of these cells. PC1/3 or PC2 was not found in MCH-positive cells in the spleen. In GH4C1 cells co-infected with vaccinia virus (VV):pro-MCH along with VV:furin, PACE4, PC1/3, PC2, PC5/6A, PC5/6B, or PC7, we observed only efficient cleavage at the Arg145-Arg146 site to generate mature MCH. Co-expression of pro-MCH together with PC2 and 7B2 resulted in very weak processing to NEI. Comparison of pro-MCH processing patterns in PC1/3- or PC2-transfected PC12 cells showed that PC2 but not PC1/3 generated NEI. Finally, we analyzed the pattern of pro-MCH processing in PC2 null mice. In the brain of homozygotic mutants, the production of mature NEI was dramatically reduced. In contrast, MCH content was increased in the hypothalamus of PC2 null mice. In the spleen, a single large MCH-containing peptide was identified in both wild type and PC2 null mice. Together, our data suggest that pro-MCH is processed differently in the brain and in peripheral organs of mammals. PC2 is the key enzyme that produces NEI, whereas several PCs may cleave at the Arg145-Arg146 site to generate MCH in neuronal cell types.

Distribution of somatostatin receptor subtypes in rat lumbar spinal cord examined with gold-labelled somatostatin and anti-receptor antibodies.

Using gold-labelled somatostatin, somatostatin binding sites were predominantly found in laminae I-III, X and on motorneurones of the rat lumbar spinal cord. A comparison with immunohistochemical staining using antisera against somatostatin receptor sequences revealed that the marked binding in laminae I-III coincided with the presence of somatostatin receptor-like immunoreactivity for the receptor subtypes 1, 2 and 3. Binding sites on motorneurones were only paralleled by an immunoreaction for subtype 3. In lamina X, however, the lack of a positive immunoreaction indicates that in this part other subtypes may be present.

Visualisation of non-glycosylated somatostatin receptor two (ngsst2) immunoreactivity in the rat central nervous system.

The biological actions of the neuropeptides somatostatin-14 and -28 are receptor-mediated. To date, five G protein-coupled receptors sst1 to sst5 have been characterised pharmacologically and their genes have been cloned. In this study, we used an affinity-purified polyclonal antibody (AS-68) raised against a specific N-terminal peptide sequence of sst2 to localise N-terminal sst2-immunoreactive regions in the rat brain and the cervical spinal cord. The specificity of the antiserum was demonstrated by Western and slot blotting experiments using a N-terminal sst2 fusion protein. Further blotting experiments with a sst2(A)-transfected cell line and rat CNS membrane proteins showed that the antibody detected the non-glycosylated and/or non-sialated receptor. A strong signal using an sst2(A)-transfected CHO-K1 cell line was obtained only if the cells had been treated with N-Glycosidase F prior to the immunochemical detection. Two variants of sst2 (sst2(A) and sst2(B)) have been identified by cloning procedures and gene expression studies in the rodents. They differ in their carboxy-termini: AS-68 would, however, be able to recognise the non-glycosylated form of both these variants. We present here the central nervous system distribution of non-glycosylated sst2-immunoreactivity in the rat using this N-terminal antibody. The sst2 non-glycosylated N-terminal like immunoreactivity was distributed throughout the brain with cells and processes labelled in the cerebral cortex and the basal ganglia (neostriatum, substantia nigra), in the limbic system (hippocampal formation, amygdala), in the diencephalon (epithalamus, thalamus, hypothalamus), the superior colliculus, the periaqueductal grey matter and some of the reticular formation nuclei. The distribution of the non-glycosylated sst2-like immunoreactivity detected here was consistent with that predicted from the localisation of sst2 mRNA and SRIF-ligand binding studies.

The localization of somatostatin receptor 1 (sst1) immunoreactivity in the rat brain using an N-terminal specific antibody.

The biological actions of somatostatin are mediated via a family of G protein-coupled receptors named sst1 to sst5. We used an affinity-purified polyclonal antibody AS-65, directed against a specific N-terminal peptide sequence of sst1 to determine the immunohistochemical distribution of N-terminal sst1 immunoreactivity in the rat brain. The specificity of the antibody was shown by western blotting experiments using an N-terminal sst1 fusion protein. Enzymatic deglycosylation experiments were combined with blotting experiments on a sst1-transfected cell line and rat brain membrane proteins and with immunocytochemistry on an sst1-transfected cell line. These studies showed that the antibody detected the deglycosylated sst1 receptor protein. Immunohistochemical staining showed that sst1 immunoreactivity (presumably the deglycosylated receptor) recognised by this N-terminal antiserum was widely distributed throughout the brain with cells and processes labelled in the cerebral cortex, regions of the limbic system (including the hippocampal formation and some basal ganglia nuclei), the epithalamus, the thalamus, different subthalamic structures (subthalamic nucleus, zona incerta), the colliculi, the hypothalamus, the reticular formation, the cerebellum and regions of the trigeminal nerve complex. The distribution of immunoreactivity was in good general agreement with that predicted from the localization of sst1 messenger RNA and radioligand binding studies. This study on the immunohistochemical distribution of the sst1 receptor in the brain will provide a better understanding of the central actions of somatostatin at its receptor types.

Developmental and stage-dependent expression of melanin-concentrating hormone in mammalian germ cells.

Melanin-concentrating hormone (MCH) is a cyclic peptide predominantly expressed in the hypothalamus of mammals. This peptide modulates the stress response and regulates many goal-oriented behaviors in the rat brain. MCH mRNA and peptides generated from the precursor, namely MCH and neuropeptide (N) glutamic acid (E) isoleucine (I) amide (NEI), were also found in rodent peripheral tissues including those in adult testis. In the present study, we first examined the cellular distribution and content of MCH gene products and peptide in the testes of adult rats. Using reverse-transcription polymerase chain reaction with MCH gene primers and in situ hybridization with specific 33P-labeled oligoprobes, we characterized the MCH RNA species. Pro-MCH products were revealed through use of immunoperoxidase detection and an RIA with specific MCH and NEI antisera. Both MCH gene transcripts and MCH peptide were found within germ cells at the periphery of some of the seminiferous tubules of adult rats. We further investigated temporal expression of MCH in 7-microns sections of testes from adult rats and mice. MCH was predominantly found in nuclei of spermatogonia at stages II-IV of spermatogenesis and in nuclei of leptotene and zygotene spermatocytes (at stages IX- XIII). MCH was markedly absent in preleptotene spermatocytes at the stage VII-VIII, and MCH immunoreactivity was no longer detectable as spermatocytes underwent the pachytene step. MCH immunoreactivity was also found in some peritubular cells, mainly at stages II-IV. Finally, we studied MCH expression during puberty in the rat, in sterile mutant mice, and in one adult man. We found predominant staining with MCH antiserum over nuclei of immature germ cells as early as 10 days postpartum in the rat and further confirmed the absence of staining except for that in spermatogonia and early spermatocytes during rat postnatal development. MCH distribution was found to be similar in normal and sterile mutant mice, suggesting that MCH expression is not dependent upon the early steps of spermiogenesis. MCH immunoreactivity was found to be confined to the nuclei of spermatogonia and early spermatocytes in the adult man. Our results indicate that MCH is present predominantly within nuclei of spermatogonia and primary spermatocytes in three mammalian species and that its expression is under strong stage-specific and developmental regulation. This peptide may play a role during stem cell renewal and/or differentiation of early spermatocytes.

Similarities in cellular expression and functions of melanin-concentrating hormone and atrial natriuretic factor in the rat digestive tract.

Melanin-concentrating hormone (MCH) is a cyclic peptide isolated first from salmon brain, then from rat and human hypothalamus. We have recently found expression of MCH messenger RNA and encoded peptides, e.g. MCH and neuropeptide-glutamic acid-isoleucine, within the rat gastrointestinal (GI) tract, but their cellular origin was unclear. Furthermore, similarities in the localization of rat atrial natriuretic factor (ANF) and rat MCH immunoreactivities within intestine suggested functional convergence. In the present study we determined first the presence and distribution of MCH messenger RNA and encoded peptides in the GI tract by combining in situ hybridization and immunohistochemical analysis. Our data revealed numerous MCH-containing cells located in the lamina propria and submucosa at both duodenal and colonic levels. Second, the localisation of MCH- and arginine vasopressin- or ANF-containing cells appears similar at the duodenal and colonic levels, respectively. Colocalization of MCH/neuropeptide-glutamic acid-isoleucine immunoreactivity (-IR) and catecholamine indicated that MCH-expressing cells are probably antigen-presenting cells forming part of the enterochromaffin cell system. Third, we performed reverse phase HPLC coupled to RIA to characterize MCH-like materials in different portions of the rat gut. Crude acidic extracts of rat intestine contained about 2-3 pmol/g tissue of MCH-IR, close to the values found in brain extracts. Reverse phase HPLC of MCH-IR in the GI tract revealed that only 10-30% of the immunoreactivity corresponded to mature MCH, whereas the rat brain contained 94% mature peptide. Finally, we compared the effect of MCH and ANF on water and electrolyte secretions at different levels of the GI tract by using the in situ ligated loop technique. Similar effects were noted for ANF and MCH; both stimulated water, Na, and K fluxes at the proximal colon level and increased Na and K fluxes in the duodenum. However, only ANF increased water and Cl fluxes in the duodenum and decreased bicarbonate secretion in the ileum, whereas MCH increased bicarbonate absorption in the jejunum. The dose required was 10 nmol/100 g.h for MCH, i.e. 10 times more than for the ANF. These studies strongly suggest that MCH produced by antigen-presenting cells of the lamina propria may have an important role, similar to that of ANF at the colonic level, in the physiology of the GI tract.

Pro-melanin concentrating hormone messenger ribonucleic acid and peptides expression in peripheral tissues of the rat.

Melanin-concentrating hormone (MCH) is a cyclic peptide which is predominantly synthetized in the hypothalamus of fish and mammalian brains. In the present paper we examined the expression of MCH mRNA and pro-MCH-derived peptides, i.e. MCH and neuropeptide-(N)-glutamic acid (E) isoleucine (I) amide (NEI), in peripheral tissues of adult rodents. By means of polymerase chain reaction (PCR) of reverse-transcribed RNA, low levels of MCH gene transcripts were detected reliably in testis, stomach, and intestine of Sprague-Dawley and Wistar rats, whereas strong expression was found in hypothalamus. Subsequent sequence analysis of the PCR products verified the authenticity of MCH mRNA found in hypothalamus and stomach. The length of MCH RNA species was measured by Northern blot and multiple MCH RNA species were detected in both rat species. Shortest polyadenylated tails were found in MCH RNAs isolated from the peripheral organs by comparison with hypothalamus MCH RNAs of Wistar rats. In order to localize MCH expression in gastrointestinal and genital tracts of Wistar rats we performed in situ hybridization with specific 33P-labeled oligoprobes joined to immunocytochemical studies with rat MCH or NEI antisera. In testis, the MCH transcripts and pro-MCH-derived peptide immunoreactivities were found at the periphery of the seminiferous tubules, suggesting expression in Sertoli cells. Studies with MCH oligoprobes and antisera directed towards MCH, NEI and alpha A-inhibin revealed similar pattern of expression in isolated Sertoli cells from Swiss mice, indicating that MCH RNA species were actually synthesized and translated in these cells. In the gastrointestinal (GI) tract, the cells expressing MCH RNA species and pro-MCH-derived peptides were predominantly expressed in the antral portion of the stomach and duodenum. Strikingly, distinct oligoprobes, recognizing antisense MCH transcript, revealed a pattern of hybridization in the GI tract similar to this observed with oligoprobes revealing the mature MCH mRNA. Furthermore, total RNA from the pyloric junction, duodenum, jejunum, ileum and hypothalamus as well appeared to contain RNA complementary to MCH mRNA suggesting therefore that antisense MCH RNA species may play a general role in regulation of MCH synthesis. Taken together, our present and previous data indicate that authentic MCH RNA species and translational products are expressed in various rodent tissues at the periphery. The cellular location suggests that MCH and associated peptides may play a role in spermatogenesis and in digestive processes.