Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P61278 (somatostatin)
22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Previous studies from this and other laboratories demonstrated that many embryonic sensory ganglion cells in the rat transiently express the catecholamine synthesizing enzyme tyrosine hydroxylase (TH), a trait not expressed by most mature sensory neurons. We, therefore, sought to determine whether transient expression was uniquely associated with catecholaminergic traits, or, alternatively, whether embryonic ganglion cells transiently expressed peptidergic properties as well. Of the four peptides examined (somatostatin [somatotropin release inhibiting factor] (SRIF), galanin (Gal), calcitonin gene-related peptide (CGRP), and substance P (SP)), only SRIF was found to be transiently expressed during early stages of sensory gangliogenesis. Surprisingly, SRIF immunoreactivity was observed in virtually all cranial and spinal sensory ganglion cells on embryonic day (E) 12.5. In addition to perikaryal labeling, intense SRIF immunoreactivity was also observed in the central and peripheral processes of E12.5 sensory neurons, suggesting the peptide may be released from nerve endings. The time course of SRIF appearance in cranial ganglion cells paralleled that previously described for TH, and double-labeling studies revealed extensive co-localization of these two phenotypes. By E16.5, however, the number of neurons expressing SRIF had diminished markedly, indicating that SRIF is only transiently expressed by most sensory neurons during early stages of ganglion development. An unexpected finding was that transient expression of SRIF is also a prominent feature of sympathetic ganglion cells; however, the temporal pattern of staining in the sympathetic and sensory ganglia differed substantially. Whereas virtually no SRIF staining was observed in E12.5 sympathetics, the vast majority of cells in the E16.5 superior cervical ganglion (SCG) were labeled. This contrasted sharply with the adult SCG, in which only low levels of SRIF expression were found. These findings demonstrate that SRIF peptide is transiently expressed at high levels in peripheral sensory and sympathetic neurons during embryogenesis. The time course and widespread distribution of SRIF expression indicates that the peptide may play a role in early stages of ganglion cell growth and development. Moreover, these data, in conjunction with previous studies demonstrating SRIF immunoreactivity in developing central neurons, suggest that transient expression of this peptide is a common property of diverse neuronal cell types.
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PMID:Transient expression of somatostatin peptide is a widespread feature of developing sensory and sympathetic neurons in the embryonic rat. 135 5

Levels of somatostatin-like immunoreactivity (SLI) were measured in the rat retina by radioimmunoassay during prenatal and postnatal development. SLI-containing cells were visualized by immunocytochemistry throughout this time period. SLI is present as early as embryonic day 15 (E15) and by E16 at concentrations 10-fold (4.4 +/- 1.4 pg/micrograms protein) higher than the adult retina, and the SLI is confined to cells in the inner neuroblastic layer. As the inner plexiform layer (IPL) develops (E17-18), the level of SLI falls (2.0 pg/micrograms protein) and distinct SLI neurites are seen throughout the inner neuroblastic layer. At birth (P0), the SLI level continues to decline at a time when cells are migrating. Few immunoreactive cells are seen in the developing ganglion cell layer (GCL), presumably as a result of this migration. At postnatal day 4 (P4), the amount of SLI continues to decline, and very few immunoreactive cells are noted. At P8, distinct cells contain SLI both in the GCL and inner nuclear layer (INL). SLI then increases as the retina matures postnatally. After eye opening, the amount of SLI approaches adult levels and the immunocytochemical pattern is similar to that reported for the adult rat retina; i.e. SLI is confined to two subpopulations of cells, one in the INL and one in the GCL. The early prenatal appearance of SLI suggests that it may play a role in retinal development.
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PMID:Development of somatostatin immunoreactive neurons in rat retina. 288 60

The survival and cellular and connective organization of intracephalic transplants of developing, freeze-stored rat hippocampal tissue were examined. Blocks of tissue containing the hippocampus and fascia dentata were obtained from late embryonic (E16-E22) and early postnatal rats (P0-P4) and immersed in a tissue culture medium with 10% of the cryoprotective agent DMSO, frozen at a cooling rate of approximately 1 degree C/minute, and stored for 1-226 days in liquid nitrogen. After quick thawing and washing out of the DMSO the tissue blocks were transplanted to the brain of adult rats. From 2 weeks to 3 months later the recipient brains were processed histologically. The cellular and connective organization of the transplants and their interaction with the host brains were analyzed after thionin cell staining, Timm's staining for hippocampal and dentate afferents, immunohistochemical staining for enkephalin-, CCK-, and somatostatin-reactive neurons and afferents, AChE staining for cholinergic afferents, and silver stains for fiber architectonics and tracing of connections by anterograde axonal degeneration. Freeze-storage narrowed the range of donor ages with good transplant survival. The best surviving hippocampal and dentate transplants thus came from 17-21-day-old embryos. There was no correlation between the length of storage and survival. Structurally the transplants of stored tissue were more frequently fragmented than the transplants of fresh tissue when located outside the brain parenchyma in the brain ventricles. This was in accordance with the results of a previous study of grafts of freeze-stored and fresh hippocampal tissue placed in the anterior eye chamber. Despite the decrease in survival and the tendency for fragmentation many well-structured and organotypically organized hippocampal and dentate transplants were recovered corresponding to the donor ages E19-E21. In addition to the main cell types (granule cells and pyramidal cells) the freeze-stored transplants also contained peptidergic nerve cells reacting for CCK, somatostatin, and enkephalin. The organization of the intrinsic nerve connections and the exchange of connections with the host brain were similar for transplants of stored and fresh tissue. Besides the consistent innervation of the hippocampal and dentate transplants by host cholinergic afferents monitored by AChE staining, several appropriately located dentate transplants thus sent mossy fibers to the host CA3. Others received host perforant path projections. A CA3-associated transplant projection to the denervated perforant path zones in the host fascia dentata was also observed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Intracephalic transplants of freeze-stored rat hippocampal tissue. 378 12

With hybridization histochemistry, somatostatin (SRIF) mRNA was detected in several neuronal populations of the basal diencephalon (anterior and posterior) and basal telencephalon (lateral) for the first time on the 14th day of gestation (E14). On E16, a large increase of the extent of expression was found in these populations. In addition, cells in the medial telencephalon and a few cells in the future allocortex also contained SRIF mRNA for the first time. In the prenatal period, the expression in the above populations continued to mature and individual nuclei with SRIF mRNA began to be recognizable. At birth, the overall pattern of SRIF gene expression was established but the ventral portions (hypothalamus, amygdala, allocortical areas) had higher levels of expression than the more dorsal ones (striatum and neocortex). Over the first 2 wk of life, this difference decreased and an adult-like pattern was found at postnatal day 21. We demonstrate that most of SRIF gene expression development takes place before birth. This description may serve as a basis for studies on the putative functions of SRIF during brain ontogeny.
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PMID:Ontogeny of somatostatin gene expression in rat forebrain. 791 43

Cyclic AMP (cAMP) mediates the hormonal stimulation of a number of eukaryotic genes by directing the protein kinase A (PK-A)-dependent phosphorylation of the transcription factor CREB. Somatostatin is one such gene known to be transcriptionally activated by cAMP via CREB. In view of the role somatostatin plays in the regulation of neocortical development, we examined the early expression of CREB mRNA and protein (from E10 to E14) in the rat neocortex by in situ hybridization and immunocytochemistry. mRNA for CREB was detected in all layers of the developing neocortex from E10 to E14. CREB immunoreactivity (CREB-IR) was also observed in most cortical cells by E10. However, the number of CREB-immunoreactive nuclei decreased thereafter, and on E14 there were immunoreactive cells only in the preplate. A moderate amount of somatostatin mRNA was observed on E16 in layer I, which is produced from the preplate. This stage specific expression of the CREB protein in the developing neuroepithelium suggests that by regulating transcription of some peptides including somatostatin, CREB plays a role in cortical development.
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PMID:A developmental study of cyclic AMP-response element binding protein (CREB) by in situ hybridization histochemistry and immunocytochemistry in the rat neocortex. 792 74

Cells displaying highly condensed pyknotic nuclei, the most characteristic feature of apoptosis, are considered as dead cells in neural tissue. The present study aimed to devise methods that could allow the neurogenetic and phenotypic characterization of dying pyknotic cells. In the first set of experiments, pregnant mice were labeled at embryonic days E10-E16 with pulses of 5'-bromodeoxyuridine visualization of BrdU after an immunoperoxidase reaction. In addition to normal, healthy immunopositive nuclei, these preparations displayed a number of pyknotic nuclei that were immunoreactive for BrdU. Both the regional and the temporal distribution of BrdU-positive pyknotic cells were coincidental with the peaks of dead cells in neural tissue. For example, pulses of BrdU at E10-E11 resulted in the visualization of immunoreactive pyknotic cells in the subplate and white matter of the cerebral cortex in early postnatal (P) animals. Thus, the times of generation (birthdates) of cells subjected to degenerative processes can be unequivocally identified. In the second set of experiments, brain sections from unlabeled littermates were immunostained for a variety of neural and glial markers and counterstained with bisbenzimide, to find antigens which, by being present in degenerate pyknotic cells, could indicate the phenotype of such cells. Although no pyknotic cells were positively immunostained for neurofilaments, neuropeptide Y, somatostatin, vasoactive intestinal polypeptide, or vimentin, a number of pyknotic cells were found to be immunoreactive for microtubule-associated protein 2, gamma-aminobutyric acid, calbindin 28KD, and glial fibrillary acidic protein. The percentage of pyknotic cells labeled with neural antigens accounted for more than 20% of the total number of pyknotic cells in a given brain region. In contrast, GFAP-positive pyknotic cells represented up to 50% of the total pyknotic cell population. The method shown here has enabled us to determine that both neurons and glial cells undergo degeneration during normal development.
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PMID:Characterization of the phenotype and birthdates of pyknotic dead cells in the nervous system by a combination of DNA staining and immunohistochemistry for 5'-bromodeoxyuridine and neural antigens. 831 74

The neuropeptide somatostatin (SRIF) exerts several important physiological actions in the adult CNS through interactions with membrane-bound receptors. SRIF expression is developmentally regulated and this regulation is most apparent in the cerebellum, where SRIF immunoreactivity is expressed at early postnatal ages and then disappears toward adulthood. The transitory nature of SRIF expression at a time of major changes in cerebellum suggests that this peptide may have a role in cerebellar development. To further investigate the role of the SRIF transmitter system during development, we have examined the levels of expression of SRIF receptors in the developing rat brain by immunoblotting using antiserum selective for a 60-kDa brain SRIF receptor. In whole rat brain, SRIF receptor immunoreactivity first appears at embryonic day 13 (E13), is elevated at E16, increases at birth, peaks at early postnatal ages, and then gradually declines with age. No apparent changes in size of the receptor occur with age. No consistent changes in levels of SRIF receptor immunoreactivity are detected from early postnatal ages to adulthood in the hippocampus, cerebral cortex, and striatum, but levels gradually decline in the hypothalamus. In contrast, SRIF receptor immunoreactivity is expressed transiently in cerebellum. SRIF receptor immunoreactivity is detectable in cerebellum at E16, increases in levels at birth, is apparent from postnatal day 3 to postnatal day 8, and then disappears. The transitory nature of SRIF receptor expression in cerebellum is unique and parallels the expression of SRIF immunoreactivity in this brain region. These findings support the hypothesis that SRIF has a role in cerebellar development.
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PMID:Developmental changes in expression of a 60-kDa somatostatin receptor immunoreactivity in the rat brain. 847 2

Somatostatin (SST) is one of the major peptide transmitters in the mammalian central nervous system and also seems to exert specific functions during brain development. In contrast to ligand binding experiments, by which two pharmacologically different binding sites were characterized, molecular cloning techniques have led to the identification of at least five different receptor subtypes (SSTR1-5), which according to RNA blot analyses seem to be differentially distributed and regulated in the developing brain. In order to provide more precise data on the distribution of SSTR1 during ontogenesis, we have performed an in situ hybridization analysis, using a 35S-labelled RNA probe, in the developing rat cortex between embryonic day (E)12 and adulthood. Within the cortical plate, expression of SSTR1 gene was first detected in parallel with the establishment of the deep laminae V/VI at E16, thereby following the characteristic morphogenetic gradients of cortical plate construction. Thus, with the subsequent addition of cells along the radial dimension, e.g. the deposition of the supragranular neurons beyond E18, the hybridization signal spreads as an uniform homogenous band through the entire cortical plate, whereby silver grains reach their peak density around birth. Similar developmental gradients were observed along the lateromedial and frontooccipital dimension, whereby SSTR1 transcripts were detected near the frontal pole and the lateral cortical areas roughly 2 days before they appeared in the occipital and medial cortical anlage, respectively. From the initially homogenous distribution, two distinct SSTR1 mRNA-positive bands coextensive with laminae V/VI and II/III, respectively, and sparing lamina IV evolved during the first postnatal week, the grain density of which decreased during further postnatal development. Within the hippocampal formation, SSTR1 transcripts were initially observed at E18 in the subicular complex, and after birth also extending into the neighboring CA1 region. During the 1st and 2nd postnatal week, silver grains were observed over the pyramidal cell layer of CA2 and CA3 and as a faint supragranular band in the dentate gyrus. Similar to the isocortex, grain density decreased thereafter. Hypothetically, the pronounced temporospatial regulation of SSTR1 gene expression during brain development can be correlated with (1) the establishment and eventual reduction of transient cortical SSTergic neuron populations described for late pregnancy and early postnatal development and (2) a receptor subtype exchange during maturation as evidenced by the late (from postnatal day 7 onward) appearance of e.g. SSTR3.
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PMID:Distribution of somatostatin receptor subtype 1 mRNA in the developing cerebral hemispheres of the rat. 857 44

It has been suggested that members of the neuropeptide Y (NPY) family of regulatory peptides [NPY, peptide YY (PYY) and pancreatic polypeptide (PP)] play an important role in the development of the endocrine pancreas. The development of rat endocrine pancreas from embryonic (E) day 12 until 30 days postpartum (P) was studied with emphasis on NPY, PYY and PP and their co-existence with insulin, glucagon and somatostatin using single and double immunostaining and in situ hybridization. Already at E12, PYY was detectable in small endocrine cell clusters and found to be co-localised with both insulin and glucagon, which at this stage occurred in the same cells. At E16 most of the insulin-immunoreactive (IR) cells were distinct from the glucagon/PYY-IR cells. Interestingly, at E16 NPY mRNA, and at E17 NPY immunoreactivity appeared in a few, scattered endocrine cells. Virtually all NPY-IR endocrine cells were insulin-producing beta cells. At E18 the endocrine cells started to form typical islets with centrally located insulin/NPY-IR cells surrounded by glucagon/PYY-IR cells. AT E20-E21, the vast majority of insulin-producing cells also expressed NPY. However, at birth (day 0) islet cell NPY mRNA was lacking. Postnatally the number and immunostaining intensity of NPY-IR islet cells rapidly declined, being non-detectable at P5. Cells containing PP immunoreactivity and PP mRNA were first detected at E21. The adult pattern of islet peptide distribution, with NPY confined to neuronal elements. PYY and PP exclusively in endocrine cells, was established at P5. The beta cell expression of NPY during the latter part of embryogenesis coincides with the prepartal glucocorticoid surge and with rapid islet cell replication and differentiation. This is compatible with steroid induction of NPY expression and with a role for NPY in the maturation of beta cells and their hormone release, which occurs in the immediate neonatal period.
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PMID:Developmental expression of NPY, PYY and PP in the rat pancreas and their coexistence with islet hormones. 910 Feb 83

We study the neurogenesis of a distinct subclass of rat striatum gamma-aminobutyric acid (GABA)ergic interneurons marked by the calcium-binding protein parvalbumin (PV). Timed pregnant rats are given an intraperitoneal injection of bromodeoxyuridine (BrdU), a marker of cell proliferation, on designated days between embryonic day (E) 11 and E22. Birthdate of PV neurons is determined in the adult neostriatum and nucleus accumbens by using a BrdU-PV double-labeling immunohistochemical technique. PV-immunoreactive interneurons of the neostriatum show maximum birthrates (>10% double-labeling) between E14-E17, whereas PV-immunoreactive interneurons of the nucleus accumbens show maximum double-labeling between E16-E19. In the neostriatum, caudal PV-immunoreactive neurons are born before those at rostral levels, and lateral PV-immunoreactive neurons become postmitotic before medial neurons. In the postcommissural striatum, ventral PV-immunoreactive neurons become postmitotic before dorsal neurons. In the precommissural striatum, ventral neurons are born before dorsal neurons laterally, but a dorsoventral gradient is seen medially. At corresponding coronal levels, PV-immunoreactive neurons of the nucleus accumbens are born shortly after PV neurons of the neostriatum. Analysis of BrdU labeling intensity in the nucleus accumbens shows that medium spiny projection neurons of the shell become postmitotic before neurons of the core. Similarly, PV-immunoreactive interneurons of the nucleus accumbens shell are born before PV interneurons of the core. Compared with cholinergic interneurons of the neostriatum, PV-immunoreactive interneurons are born later, but neurogenetic gradients are similar. The period of striatum PV interneuron genesis encompasses the period for somatostatin interneurons, although the latter neurons do not show neurogenetic gradients, possibly due to heterogeneous subtypes. Consideration of basal telencephalon neurogenesis suggests that subpopulations of striatum interneurons may share common neurogenetic features with phenotypically similar populations in the basal forebrain, with final morphology and connectivity depending on local cues provided by the host environment.
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PMID:Neurogenesis in the mammalian neostriatum and nucleus accumbens: parvalbumin-immunoreactive GABAergic interneurons. 941 16


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