Glucagon-related peptides in the rat hypothalamus

Summary Immunohistochemically, nerve fibers and terminals reacting with anti-N-terminal-specific but not with anti-C-terminal-specific glucagon antiserum were observed in the following rat hypothalamic regions: paraventricular nucleus, supraoptic nucleus, anterior hypothalamus, arcuate nucleus, ventromedial hypothalamic nucleus and median eminence. Few fibers and terminals were demonstrated in the lateral hypothalamic area and dorsomedial hypothalamic nucleus. Radioimmunoassay data indicated that the concentration of gut glucagon-like immunoreactivity was higher in the ventromedial nucleus than in the lateral hypothalamic area. In food-deprived conditions, this concentration increased in both these parts. This was also verified in immunostained preparations in which a marked enhancement of gut glucagon-like immunoreactivity-containing fibers and terminals was observed in many hypothalamic regions. Several immunoreactive cell bodies were found in the ventromedial and arcuate nuclei of starved rats. Both biochemical and morphological data suggest that glucagon-related peptides may act as neurotransmitters or neuromodulators in the hypothalamus and may be involved in the central regulatory mechanism related to feeding behavior and energy metabolism.     

Electron-microscopic cytochemistry of the catecholaminergic innervation of TRH neurons in the rat hypothalamus

Summary The catecholaminergic innervation of thyrotropin-releasing hormone (TRH) neurons was examined by use of a combined method of 5-hydroxydopamine (5-OHDA) uptake or autoradiography after intraventricular injection of ³H-noradrenaline (³H-NA) and immunocytochemistry for TRH in the same tissue sections at the electron-microscopic level.TRH-like immunoreactive nerve cell bodies were distributed abundantly in the parvocellular part of the paraventricular nucleus (PVN), in the suprachiasmatic preoptic nucleus and in the dorsomedial nucleus of the rat hypothalamus. In the PVN, a large number of immunonegative axon terminals were found to make synaptic contact with TRH-like immunoreactive cell bodies and fibers. In the combined autoradiography or 5-OHDA labeling with immunocytochemistry, axon terminals labeled with ³H-NA or 5-OHDA were found to form synaptic contacts with the TRH immunoreactive nerve cell bodies and fibers. These findings suggest that catecholamine-containing neurons, probably noradrenergic, may innervate TRH neurons to regulate TRH secretion via synapses with other unknown neurons in the rat PVN.This study was supported by grants from the Ministry of Education, Science and Culture, Japan     

Evidence for pyroglutamyl peptidase I and prolyl endopeptidase activities in the rat insulinoma cell line RINm 5F: lack of relationship with TRH metabolism

Thyrotropin-R eleasing hormone (TRH)-degrading pyroglutamyl peptidase I(PGP I) and prolyl endopeptidase (PE) activities have been demonstrated in rat insulinoma RINm 5F cell line. These two enzymes catalyze the conversion of TRH to Histydyl-Proline-Diketopiperazine and to acid TRH respectively.After cell fractionation, we found all the PGP I and PE activities in the cytosolic fraction. The membranebound PGP II activity is not detectable in the RINm 5F cells. Further investigations on these two cytosolic enzymes show that pyroglutamyl- and proline-containing peptides are inhibitors of each TRH-degrading enzyme.Gelfiltration chromatography on Sephadex G100 shows that PGP I and PE activity have an apparent molecular mass of about 18 kDa and 57 kDa, respectively. Kinetic analysis with TRH as substrate, gives a Km of 44 µM and 235 µM, and a Vmax of 1.49 and 8.80 pmoUmin/µg protein for PGP I and PE, respectively. Immunoreactive TRH, His-Pro-Diketopiperazine and acid TRH levels in the cell line extracts are 2.2 ± 0.9, 22.5 ± 11.1 and 28.7 ± 14.6pg/10⁶ cells, respectively. When cells have been incubated for 2 to 72 hours with a P. E. inhibitor (Z-Gly-Pro-CHN₂) at 5 × 10^–7M, both cell PGP I and PE activities are inhibited. No change in the cellular content of immunoreactive TRH, His-Pro-Diketopiperazine and acid TRH have been observed in treated cells.These data suggest that TRH is not degraded by cytosolic, unspecific PGP I and PE enzymes in RINm 5F. The finding that these cells contain 10 and 13 times more His-Pro-Diketopiperazine and acid TRH than TRH may be an indirect evidence for the existence of another precursor than TRH for these two peptides or of the possibility that TRH can be degraded by other peptidases.Abbreviations TRH Thyrotropin-Releasing Hormone or Thyroliberin - His-Pro-DKP Histidyl-ProlineDiketopiperazine - TRH-OH acid TRH or deamidated TRH - LH-RH Luteinizing Hormone-Releasing Hormone - Z-Gly-Pro-CHN₂ N-benzyloxycarboxyl-Gly-Pro-diazomethylketone - PGP Pyroglutamyl Peptidase, PGP I (EC 3.4.19.3) and PGP II (EC 3.4.19.-) - PE Prolyl Endopeptidase or post-proline cleaving enzyme (EC 3.4.21.26)     

Presence of dynorphin-like immunoreactivity in rat pituitary gland and hypothalamus

Using a highly specific and sensitive radioimmunoassay for dynorphin(1-13), dynorphin-like immunoreactivity (dynorphin-LI) was detected in rat pituitary and hypothalamus. Gel chromatographic studies on Sephadex G-50 revealed three components of dynorphin-LI with molecular weights of approximately 7500-9500 (big dynorphin), 3500-5500 (intermediate dynorphin) and 1600-1900 (small dynorphin), the latter of which eluted at the same position as authentic dynorphin contamination in porcine ACTH extracts (Sigma). Dynorphin-LI in rat anterior pituitary existed mainly as big dynorphin, whereas dynorphin-LI in rat intermediate-posterior pituitary and hypothalamus eluted mainly at the position of authentic small dynorphin.     

A novel substance P binding site in rat brain regions modulates TRH receptor binding

Binding sites for thyrotropin-releasing hormone (TRH) were labelled with [³H](2-Me-His³)TRH ([³H]MeTRH) on membranes from rat brain regions at 0°C for 5 h. Amygdaloid membranes bound [³H]MeTRH with high-affinity (K _d=3.1±0.5 nM (n=4)). Five TRH analogs competed for this binding with the same rank order and with affinities that matched the pharmacological specificity of pituitary TRH receptors. Substance P (SP) and its C-terminal fragments reduced amygdaloid TRH receptor binding in a concentration dependent manner (IC₅₀ for SP=65 M). The rank order of potency of SP analogs at inhibiting TRH receptor binding was: SP>nonapeptide (3–11)>hexapeptide (6–11)>heptapeptide (5–11)>pentapeptide (7–11). However, other tachykinins were inactive in this system. SP was a potent inhibitor of [³H]MeTRH binding in hippocampus> spinal cord>retina>n. accumbens>hypothalamus>amygdaloid>olfactory bulb pituitary>pons/medulla in parallel assays. In amygdaloid membranes SP (50 M) reduced the apparent maximum receptor density by 39% (p<0.01) without altering the binding affinity, and 100 M SP induced a biphasic dissociation of [³H]MeTRH with kinetics faster than those induced by both TRH (10 M) and serotonin (100 M). In contrast, other neuropeptides such as neurotensin, proctolin, angiotensin II, bombesin and luteinizing hormone releasing hormone did not significantly inhibit [³H]MeTRH binding to amydaloid membranes. Thus, the SP site with low affinity in the rat brain is not like any of the previously described tachykinin/neurokinin binding sites but resembles the site found on neuroblastoma cells (108CC15) and on adrenal chromaffin cells that modulate cation permeability and nicotinic receptors respectively. The physiological role of these atypical SP sites in the rat brain remains to be determined.A preliminary account of these studies has been presented to the British Pharmacological Society (9).     

Effects of TRH on cell proliferation of rat pituitary cells (GH3)

Summary Chronic treatment (more than 3 d) of GH₃ cells, cloned rat pituitary cells producing prolactin, with 100 nM TRH resulted in a 41% reduction in the rate of cell growth in a medium containing 0.5% fetal bovine serum. These effects of TRH appeared both in the medium containing a higher concentration of serum and in that containing six growth factors, i.e. insulin, transferrin, parathyroid hormone, fibroblast growth factor, triiodothyronine, and multiplication-stimulating activity (MSA) instead of serum. TRH stimulated prolactin production by GH₃ cells in a dose-dependent manner both in the serum-supplemented and serum-free media. On the other hand, TRH, at 1 nM, elicited a 130% stimulation in the cellular growth, whereas, at concentrations of more than 10 nM, it inhibited the growth significantly. In the defined culture system, it was demonstrated that TRH stimulated prolactin production in the presence or absence of six growth factors, whereas its inhibitory effects on cellular growth appeared only in the presence of MSA regardless of the presence or absence of the other five factors. Furthermore, it was shown that a dose-dependent stimulatory effect of MSA on the growth of GH₃ cells was suppressed by TRH. TRH exhibited only a stimulatory effect on cellular growth in the medium containing the five factors other than MSA. In conclusion, TRH could inhibit cell growth of GH₃ in the presence of MSA in the defined medium or MSA-like factor(s) in the serum-supplemented medium.     

Ultrastructural localization of the receptor for leptin in the rat hypothalamus

Ultrastructural localization of the leptin receptor in the rat hypothalamus was studied by immunocytochemistry. The antiserum against the leptin receptor which was used specifically recognized the carboxy terminal of the cytoplasmic domain. Intense leptin receptor immunoreactivity was detected in the arcuate, paraventricular, and ventromedial nuclei of the hypothalamus and in the lateral hypothalamic area. At the ultrastructural level, leptin receptor-like immunoreactivity appeared to be concentrated predominantly in perikarya and dendrites of these areas and strong immunolabeling for the leptin receptor was detected in the plasma membrane, rough endoplasmic reticulum, Golgi apparatus, and cytoplasmic matrix. This study provides the first detailed fine structure of leptin receptor-immunoreactive neurons in the rat hypothalamus. It may help to provide better understanding of the functions of leptin in the rat hypothalamus.     

Catecholamine-containing neurons in cultures of fetal rat hypothalamus: distribution,morphology, and maturation

The distribution, morphology, and maturation of catecholamine (CA) neurons have been studied in hypothalamic explants from late-gestation rats. CA-containing neurons were identified using the glyoxylic acid technique. CA-containing processes were present from all hypothalamic areas except the preoptic region. Several fiber types were identified. CA neurons in vitro resemble CA neurons in adult hypothalamus. This tissue culture system may be useful in the study of a number of properties of hypothalamic CA neurons.     

Ultrastructural localization of radiolabelled L-dopa in the endocrine hypothalamus of the rat

Summary Light and electron microscopic autoradiography has been employed to define the neuroanatomical patterns of uptake and binding of radiolabelled L-dopa in the endocrine hypothalamus of the rat. A dorsomedial continuum of arcuate and periventricular neurons selectively sequester ³H L-dopa 20 min following its intraventricular infusion. By 40 and 60 min following the infusion labelling of neurons is minimal and supports the notion of rapid degradation. Other cell compartments such as tanycytes demonstrate uptake of ³H L-dopa. The ultrastructural localization and distribution of radiolabelled L-dopa (or its metabolites) in the rodent hypothalamus is discussed with respect to mechanisms and cell compartments involved in neuroendocrine regulatory processes.Supported by USPHS Program Project Grant NS-11642-04 (DES) and RR-05403Career Development Awardee RO4GM-70001     

Immunohistochemical localization of TRH in rat CNS: comparison with RIA studies

The localization of thyrotropin releasing hormone (TRH) in rat brain determined by use of avidin-biotin immunoperoxidase histochemistry was compared with the distribution and quantitation by radioimmunoassay (RIA). Male Sprague-Dawley rats received intracisternal injections of 100 micrograms of colchicine or saline and were sacrificed 24 hours later. Brains were either perfused with lysine-periodate fixative and processed for TRH immunohistochemistry or were dissected into 9 brain regions for TRH RIA. In colchicine pretreated rats. TRH immunoreactive perikarya were observed only in nuclei of the hypothalamus and brain stem. No cell body staining was observable in non-colchicine treated rats. With the exception of the olfactory bulb, brain regions exhibiting dense TRH staining contained high concentrations of TRH as measured by RIA. Colchicine pretreatment did not alter the concentration of TRH in most brain regions, however, there was a significant increase in brain stem TRH content 24 hours following colchicine administration. These findings indicate that immunohistochemical localization of TRH corresponds well with endogenous concentrations of TRH determined by RIA.     

Effect of TRH (thyrotropin-releasing hormone) on the fine structure and replication of TSH and prolactin cells in the rat

Summary In intact male rats after TRH administration for 7 and 14 days, TSH cells showed similar morphological changes to those observed after thyroidectomy. These changes were paralleled by small numerical increases in TSH cell counts. After 34 days of TRH treatment, however, most of the TSH cells had a normal appearance and the number of TSH cells also had returned to normal. TRH treatment for 7, 14 and 34 days caused morphological changes in Prolactin cells similar to those obtained after a suckling stimulus. In the three groups these changes were also paralleled by small numerical increases in Prolactin cell counts. The cell replication after TRH for 7 and 14 days, as measured by incorporation of tritiated thymidine to obtain a labeling index, was slightly but significantly increased.This work was supported by grants MA-552 and MT-2701 from the Medical Research Council of Canada. The authors wish to thank Dr. D.A.J. Ives, Connaught Medical Research Laboratories, Toronto, for providing the TRH, and Mr. G. Penz for technical assistance.Fellow of the Medical Research Council of Canada.     

Molecular diversity and conformity of neurohormonal peptides: clues to an adaptive role in evolution

Peptide regulators are probably the most widely distributed signalling agents in the animal kingdom. They are found in both invertebrates and vertebrates where they are produced in endocrine, neuroendocrine and neuronal tissues. As more of these ubiquitous messengers have been characterized it has become evident that they may be grouped into families with clearly defined relationships. Amino acid sequences of the mature, final product indicate relationships between for example cholecystokinin (CCK) and gastrin. More detailed examination of peptide precursors can give further insights into family trees and in the case of the secretin-vasoactive intestinal polypeptide family result in the identification of a novel co-coded peptide. Such dual coding has led to the hypothesis of gene-duplication in peptide evolution, a phenomenon admirably exemplified by the glucagon family and the opioid family. A further example of peptide diversity is evident when mRNA processing is examined. Here a single gene encoding two (or more) structural sequences can produce multiple mRNAs, each encoding a unique peptide sequence. The mRNA produced varies according to the tissue site. The calcitonin and Tachykinin family are fine examples with different peptides produced in neurones and endocrine tissues. A remarkable conservatism of peptide sequences is found in the insulin family where distinct relationships are evident between insulin, insulin-related growth factors (IGF) and insect prothoracicotrophic hormone. Such relationships are supported by examination of the genes for insulin and IGF. Peptide regulators do not evolve in isolation and it is clear that their receptors are also exposed to adaptive pressures. Receptor classes for the Tachykinin family are well characterized, with receptors being identified as falling into two categories, SP-P type and SP-E type. Similar situations obtain for the opioids. Much of this information is based on mammalian studies, however recent work on gastrin/CCK receptors in a range of vertebrates indicates a phylogenetic diversity between brain and gut receptors.     

Isolation and characterization of VGF peptides in rat brain. Role of PC1/3 and PC2 in the maturation of VGF precursor

The neurotrophin responsive gene vgf is widely expressed in central and peripheral neurones, and in certain neuroendocrine cell populations. Its encoded VGF precursor protein (proVGF1: 617 amino acids in rat, 615 in man, > 85% homology) gives rise to several low molecular weight species. We studied a range of neuroendocrine and neuronal cells, in which VGF-processing products were prominent with an apparent molecular weight of 20 and 10 kDa (VGF20 and VGF10, respectively). Such peptides were recognized by antibodies specific for the C-terminal rat VGF nonapeptide, thus indicating that they included the C-terminus of proVGF. Ectopic expression of the neuroendocrine-specific prohormone convertases PC1/3 or PC2 in GH3 cells showed that both could generate VGF20, while VGF10 was preferentially produced by PC1/3. Site-directed mutagenesis was used to identify the KRKRKK(488) motif as the target within VGF sequence which leads to the production of VGF20. Molecular characterization of rat VGF10, on the other hand, revealed that this peptide is produced by cleavage at the RPR(555) site. By the combined use of high-resolution separation techniques, matrix-assisted laser desorption/ionization time of flight (MALDI-ToF) mass spectrometry and manual Edman degradation we identified in rat brain a VGF fragment analogous to bovine peptide V and two novel peptides also derived from the C-terminal region of proVGF.     

Ontogenetic development of thyrotropin-releasing hormone (TRH)-immunoreactive structures in the brain of the mallard embryo

Summary Developmental changes of thyrotropin-releasing hormone (TRH)-immunoreactive structures in the brain of mallard embryos were studied by means of immunocytochemistry (PAP technique). The primary antibody was generated against synthetic TRH. Immunoreactive neurons were first detected in the hypothalamus of 14-day-old embryos. By day 20, increasing numbers of immunoreactive perikarya were observed in the paraventricular nucleus, anterior preoptic region and supraoptic region. Immunoreactive fiber projections were seen in the median eminence as early as embryonic day 20; they occurred also in some extrahypothalamic regions (lateral septum, accumbens nucleus). The number and staining intensity of the cell bodies increased up to hatching, and continued to increase during the first week after hatching.     

Thyroidectomy cells and their response to thyrotrophin releasing hormone (TRH) in the rat

Summary Thyroidectomy cells of the rat pituitary gland were studied by the peroxidase-antibody labeling procedure and by electron microscopy. Secretory granules accumulated in these cells in response to a short-term treatment with thyroxine, and the cells were then reactive to the peroxidase-antibody labeling procedure. An intravenous injection of synthetic thyrotrophin releasing hormone (TRH) to thyroxine-treated, thyroidectomized rats provoked an acute and active extrusion of secretory granules from the thyroidectomy cells. The secretory granules in these cells were mostly haloed after primary fixation in osmium tetroxide. It is concluded that TRH causes thyroidectomy cells to release their secretory granules, and presumably TSH, by the usual process of exocytosis or granule extrusion.This study was supported by USPHS Grant AM 12583.     

下丘脑局部损毁对大鼠双侧催产素神经元爆发放电的影响

为探究授乳大鼠双侧下丘脑巨细胞催产素神经元同步化射乳反射爆发放电的中枢所中,我们采用双微电极细胞外记录技术,观察了选择性脑切割损毁后的大鼠双侧视上核内催们素神经元在仔鼠吸吮刺激下射乳反射爆发放电。结果显示：在腹侧这画以上横向民单侧中脑中部,不同能阻断双侧催产素神经元的同步化爆发放 单侧下丘脑中间内侧部横切则可阻断这种经爆发放电。这些结果表明;中脑中部至一丘脑中部这一脑区在双侧视上核内催产素神经元的     

A retinal projection to the lateral hypothalamus in the rat

Summary This study presents evidence for a retinal projection to neurons in the lateral hypothalamic area (LHA) of the albino rat. In Golgi-Kopsch material dendrites from LHA-neurons are observed to extend through the supraoptic commissures into the optic tract. The presence of dendrites in the optic tract is confirmed by electron microscopy. Numerous axon terminals are observed forming asymmetric synaptic contacts with these dendritic profiles. Following bilateral enucleation, many of the preterminal axons and terminals in synaptic contact with dendrites in the optic tract demonstrate dark degeneration. After intraocular injection of horseradish peroxidase, there is marked labeling of preterminal axons and terminals in the optic tract. These observations indicate that LHA neurons receive a direct retinal projection from terminals making synaptic contact with dendrites of LHA-neurons extending into the optic tract.     

TRH: Cardiovascular and sympathetic modulation in brain nuclei of the rat

The cardiovascular and sympathetic effects of TRH in discrete cardiovascular-related brain nuclei were studied. Microinjections of TRH were made into the nucleus preopticus medialis (POM) of conscious rats and the nucleus tractus solitarius (NTS) of pentobarbitone-anesthetized, artificially respired rats. POM injections (1 μl, 0.8–80 nM) elicited dose dependent pressor and tachycardic responses which were accompanied by increased levels of norepinephrine (NE) and epinephrine (EPI) in the plasma. These pressor/tachycardic effects of TRH were also elicited in adrenal demedullated (ADM-x) rats, but completely abolished in ADM-x rats pretreated with bretylium (30 mg/kg, IA). NTS injections (0.1 μl, 30 and 150 nM) had a short depressor effect on blood pressure (BP) and a delayed increase in heart rate (HR). From these findings we suggest that the POM, a central nucleus in the AV3V region, may be an important forebrain site for autonomic regulation by TRH, mediated through the sympathetic nervous system.     

Characteristics of thyrotropin releasing hormone (TRH) receptors in rat brain

Characteristics of TRH-receptors were studied in the rat central nervous system (CNS). Ion species, pH and temperature importantly influenced TRH-receptor binding. Subcellular distribution of TRH-receptor binding revealed that synaptic membranes had the greatest percentage of total sites. Scatchard analysis suggested that the rat CNS had two distinct TRH binding sites with apparent dissociation constants (Kd) of 5 X 10(09) M and 13 X 10(-8) M. Receptor activity is sensitive to trypsin and phospholipase A digestion, suggesting that protein and phospholipid moieties are essential for the binding of [3H]TRH. Thiol reagents reduced the binding activity of the receptor, suggesting that an intrachain disulfide bond may form an important constituent of the binding site for TRH. The TRH-receptor in the rat brain was successfully solubilized with non-ionic detergent Triton X-100. On gel chromatography with Sepharose 6B column, the solubilized TRH-receptor molecule eluted at the fraction corresponding to an apparent molecular weight of 300,000 daltons, with Stokes' radius of 5.8 nm. The regional distribution of TRH-receptor binding was examined to clarify the site of TRH action. The highest level of binding was in the hypothalamus, cerebral cortex and hippocampus, indicating that TRH affects the CNS function mainly through the limbic system, cerebral cortex and hypothalamus. Moreover, tricyclic anti-depressants and Li+ decreased the binding of [3H]TRH. These findings suggest that endogenous TRH and TRH receptor may play the role of a neurotransmission modulator in the brain to control emotional and mental functions.     

Immunocytochemical location of thyrotropin-releasing hormone (TRH) in the B-cells of adult hypothyroid rat pancreas

Thyrotropin-releasing hormone (TRH) is present in small quantities in the rat adult pancreas. As hypothyroidism increases dramatically the pancreatic content of this peptide, this model was used to localize TRH in the gland by immunocytochemistry. Immunocytochemical staining of semithin (0.5–1.0 μm) and thin (golden) sections was performed as well as antibody and method controls to check the specificity of the immunoperoxidase staining. At the light microscope level, a very faint TRH-like immunoreactivity was apparent in the pancreas of normal untreated animals. In hypothyroid rats, a strong TRH immunostaining was observed in the central portion of the islets of Langerhans. On the contrary, in previously hypothyroid rats made euthyroid, no TRH-like immunoreactivity was found. Serial sections alternately labelled with TRH and insulin antisera revealed the simultaneous occurrence of both immunoreactivities. In addition, the TRH immunoreactive cells were distinct from glucagon- or somatostatin-containing cells. At the electron microscope level, immunoreactive TRH was found over the secretory granules of insulin-containing cells. Hypothyroid animals offer therefore a suitable model for the study of TRH in the pancreas.