UNIPROT:P61278 - FACTA Search

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

The morphology of somatostatin immunoreactive (SOM-I) neurons in lamina (L) II of the rat spinal cord was determined using a combination of Golgi impregnation and immunohistochemistry. Golgi-impregnated SOM-I neurons that resembled islet, stalked and other cells were observed. Islet cells are considered to be inhibitory interneurons while stalked cells are excitatory and are thought to relay information from primary afferent neurons to L I projection cells. The heterogeneous morphology of SOM-I neurons suggest they have diverse functions.
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PMID:Golgi impregnated somatostatin immunoreactive neurons in lamina II of the rat spinal cord. 135 Jul 50

Light microscopic analysis of adult and 10-14-day-old rat spinal cords suggested that somatostatin-immunoreactive (SOM-I) fibers apposed SOM-I cell bodies in lamina (L) II. Electron microscopic analysis of these relationships at both ages showed the presence of direct appositions between SOM-I fibers and SOM-I cells. However, synapse formation between SOM-I fibers and cells was observed only in the young rat. Similarly, synapses between SOM-I fibers and SOM negative cell bodies were only found in the young animal. Adjacent SOM-I perikarya directly contacted each other, but, again, membrane specializations were evident only in the young rat. Within L I of the adult dorsal horn, a SOM-I fiber directly apposed an unlabeled cell body. Despite analysis of serial sections through the apposition, no synaptic contacts were observed.
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PMID:Anatomical evidence for interactions between somatostatin neurites in lamina II of the rat spinal cord. 135 34

The regional distribution of mRNA coding for the neuropeptide somatostatin has been studied in the human brain by in situ hybridization histochemistry using 32P-labeled oligonucleotides. We show that somatostatin mRNA-containing neurons are widely distributed in a number of nuclei and grey areas of the human brain, including neocortex, putamen, nucleus caudatus, nucleus accumbens, amygdala, midbrain, medulla oblongata, hippocampal formation, reticular nucleus of the thalamus, and posterior nucleus of the hypothalamus. No significant hybridization signal was observed in the substantia nigra, claustrum, globus pallidus, thalamus, and cerebellum. The topographic localization of neurons containing SOM mRNA in the human brain is in agreement with previous studies using immunocytochemical or radioimmunoassay techniques. These results show that in situ hybridization histochemistry with oligonucleotide probes can be used to map the distribution of neurons expressing SOM mRNA in human postmortem materials.
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PMID:Regional distribution of neuropeptide somatostatin gene expression in the human brain. 135 64

The distributions of single- and double-labelled neuropeptide Y- (NPY-) and somatostatin-immunoreactive (SOM-IR) perikarya and processes were determined in the goldfish brain using immunoperoxidase and immunofluorescence techniques, respectively. In double-labelled material, it was evident that although these two peptides showed markedly similar distributions, they were colocalized in very few instances. A high degree of colocalization of NPY and SOM was noted in the neurons of the ventrolateral telencephalon (VI), the entopenduncular nucleus (NE) and, to a lesser extent, in the dorsocentral nucleus of the telencephalon (Dc). In Vl and NE, neurons showing NPY-IR displayed SOM-IR and vice versa. The only other instance of colocalization was that noted in the brainstem, where SOM and NPY were colocalized in the large cell bodies of the medial column of the vagal motor complex. Single-labelled SOM- and NPY-IR neurons shared a very similar distribution in various nuclei in the diencephalon and in the optic tectum. Colocalization was also noted within fibers throughout many nuclei of the telencephalon and within fibers innervating the swim bladder, one of the peripheral organs to which neurons of the medial column of the vagal motor complex project. Processes in the torus semicircularis and vagal lobe showed single-labelled immunoreactivity for both SOM and NPY in distinct laminar patterns. Large single-labelled SOM-IR terminals appeared to form pericellular baskets in the eminentia granularis of the cerebellum. Single-labelled NPY- or SOM-IR fibers were also found in the secondary gustatory nucleus and tract, the facial lobe, descending trigeminal tract, reticular formation and spinal cord. As in mammalian species, select groups of neurons in teleosts colocalize the neuropeptides SOM and NPY.
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PMID:Distributions and colocalization of neuropeptide Y and somatostatin in the goldfish brain. 135 16

An important component of neuronal development is the matching of neurotransmitter expression with the appropriate target cell. We have examined how peptide transmitter expression is controlled in a simple model system, the avian ciliary ganglion (CG). This parasympathetic ganglion contains 2 distinct types of neurons: choroid neurons, which project to vasculature in the eye's choroid layer and use somatostatin as a co-transmitter with ACh, and ciliary neurons, which innervate the ciliary body and iris and use ACh but no known peptide co-transmitter. We have found that the earliest developmental stage in which neurons with somatostatinlike immunoreactivity (SOM-IR) are consistently found in vivo is stage 30 (embryonic day 6.5), a time shortly after the extension of neurites to targets in the eye's choroid layer. In cell culture, CG neurons expressed SOM-IR in co-culture with choroid cells, but not when cultured with striated muscle myotubes or with ganglion non-neuronal cells. No significant differences in neuronal survival or in ChAT activity were observed under these different co-culture conditions, which suggests that somatostatin expression is independently regulated. The stimulation of somatostatin expression was also specific in that other neuropeptides commonly found in autonomic neurons [neuropeptide Y (NPY), substance P (SP), vasoactive intestinal polypeptide (VIP)] were not induced in the presence of choroid cells. The ability to stimulate SOM-IR was not contact dependent because a macromolecule of greater than or equal to 10 kDa in choroid-conditioned medium (ChCM) was found to stimulate somatostatin expression in a dosage-dependent fashion. The somatostatin-stimulating activity induced SOM-IR in more than 90% of CG neurons, as well as in retrogradely labeled ciliary neurons, which would not normally express SOM-IR. Thus, the expression of somatostatin in cultured CG neurons is regulated by a macromolecule produced by cells in the choroid layer, a target normally innervated in vivo by CG neurons expressing somatostatin.
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PMID:Stimulation of somatostatin expression in developing ciliary ganglion neurons by cells of the choroid layer. 167 9

The axonal transport blocker colchicine has been extensively used in immunohistochemical studies to induce accumulation of neuroactive compounds, especially neuropeptides, in neuronal somata and thus improve their visualization. To assess whether colchicine might, in addition, influence the synthesis of such compounds, we have now used in situ hybridization to examine the levels of mRNAs encoding for several neuropeptides (galanin [GAL], cholecystokinin [CCK], somatostatin [SOM], neuropeptide Y [NPY]) and neurotransmitter-synthesizing enzymes (choline acetyltransferase [ChAT], tyrosine hydroxylase [TH], amino acid decarboxylase [AADC], and glutamic acid decarboxylase [GAD]) after intraventricular administration of the drug. The results show that colchicine differentially modifies the levels of several mRNA species in different brain areas. Thus GAL mRNA levels increase in virtually all regions examined, including the basal forebrain, hypothalamus, dorsal raphe nucleus, locus coeruleus, and nucleus tractus solitarii. In addition, after colchicine treatment, GAL mRNA appears to be induced in the ipsilateral hemisphere in regions such as the cortex, hippocampus, striatum, lateral septum, and some nuclei of the thalamus as well as within white matter, where it cannot be detected in control animals. Although GAL mRNA in the vast majority of cases is neuronal, some findings indicate a possible glial localization. In parallel, colchicine depletes ChAT mRNA and increases GAD mRNA in the basal forebrain and striatum and decreases AADC mRNA in the dorsal raphe nucleus and locus coeruleus. In the latter nucleus, NPY and TH mRNA levels are increased by colchicine. In contrast, TH mRNA and also CCK mRNA levels decrease in the substantia nigra. In the cortex, hippocampus, and thalamus ipsilateral to colchicine injection CCK mRNA levels are markedly decreased, whereas SOM mRNA is decreased and NPY mRNA increased in the hippocampus but unchanged in the cortex. The results are discussed with reference to the possible artifacts that the use of colchicine might induce in immunohistochemical mapping studies and in relation to possible neurotoxic actions of colchicine, in some cases perhaps related to impaired retrograde transport of growth factor(s).
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PMID:Differential effects of intracerebroventricular colchicine administration on the expression of mRNAs for neuropeptides and neurotransmitter enzymes, with special emphasis on galanin: an in situ hybridization study. 170 58

Substance P (SP) in the dose range 0.75-1.5 nmol exerts a potent stimulatory effect on ventilation after microinjection into the rat ventrolateral medulla oblongata (VLM; n. reticularis lateralis, n. paragigantocellularis lateralis). A significant but less pronounced effect is also seen in the dorsal medulla (DM; n. tractus solitarius). Somatostatin (0.6-1.8 nmol) inhibited ventilation and induced apnoea after microinjection into the VLM but not the DM. Serial microinjections of the two peptides showed a reciprocal antagonistic action in the VLM but not in the DM. The apnoea-inducing effect of SOM was blunted by SP while SOM reduced the ventilatory stimulation induced by SP. Extracellular single unit recordings were performed following the microiontophoretic application of SP and/or SOM to respiratory-related and non-respiratory-related neurons in the VLM and DM. Although a heterogeneous population of neurons were recorded from, the majority of respiratory-related units in the VLM responded with excitation to SP and inhibitory to SOM. A direct interaction between the peptides was seen in some respiratory-related units. The neurons not responding to either of the peptides were usually non-respiratory. Dorsal to the VLM, the type of response to the two peptides was less likely to be antagonistic and a wider distribution of response types were recorded. The results indicate a direct physiological antagonism between SP and SOM regarding their effects on respiratory regulation elicited in the VLM.
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PMID:Antagonistic effects of somatostatin and substance P on respiratory regulation in the rat ventrolateral medulla oblongata. 171 56

The distribution and the levels of expression of preprosomatostatin (PPSOM) mRNA were examined during pre- and postnatal development of the mouse brain using the in situ hybridization technique. The signal obtained by in situ hybridization of embryonic tissues at day 14 and day 17 of gestation was highest over the neurons of the pyriform cortex, amygdala, and entopeduncular nucleus. The signal was very low over cells of the neocortex and the developing hippocampal formation. The density of grains overlying the neurons of the amygdala and pyriform cortex continued to be high during early postnatal life, but decreased as the animals became adults. A progressive increase of PPSOM mRNA expression was observed in postnatal animals in the stratum oriens and dentate gyrus of the hippocampal formation. In the cerebral cortex and striatum, the number of these neurons became maximal between postnatal weeks 1 and 3. In the diencephalon, the highest densities of grains were found over neurons in the nucleus reticularis thalami and zona incerta at postnatal day 21; these levels declined slightly thereafter. The cells of the periventricular nucleus of the hypothalamus had high densities of grains as early as postnatal week 1 and continued to have high densities of grains in adult animals. These patterns of hybridization density parallelled the distribution of SOM-like immunoreactivity in the mouse brain. When PPSOM mRNA expression was examined in the cerebral cortices of mice that received lesions of the nucleus basalis of Meynert as neonates, a transient increase in the number of cells expressing PPSOM mRNA was observed in the frontoparietal cortex ipsilateral to the lesion at postnatal day 10, but not at postnatal day 30. Importantly, the density of grains over the individual cells was not altered in lesioned animals at these two ages.
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PMID:Developmental expression of somatostatin in mouse brain. II. In situ hybridization. 197 40

In the present work we demonstrate immunohistochemically the presence of both immunoreactive vasoactive intestinal peptide (IR-VIP) and immunoreactive somatostatin (IR-SOM) cells in the thymus of neonatal and adult rats. IR-VIP and IR-SOM from thymic tissue extracts were identified by gel chromatography, HPLC as VIP standard, and somatostatin S-28, respectively. IR-VIP (352.7 pg/thymus) amounts greater than those of IR-SOM (38.7 pg/thymus) detected by radioimmunoassay in the thymus of 3-month-old rats reflected the abundance of IR-VIP positive cells demonstrated by immunohistochemistry. Somatostatin-like immunoreactive cells were identified as epithelial or neuroendocrine-like cells arranged in the thymic cortico-medullary border, whereas IR-VIP positive cells appeared to be large lymphoid cells distributed along the connective tissue trabeculae. Furthermore, IR-VIP lymphoid cells occurred in the periarteriolar lymphoid tissue of the splenic white pulp where lymphoblasts accumulate. The results are discussed with respect to the mutual interactions between the neuroendocrine and immune systems and the possible role played by neuropeptides in these interactions.
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PMID:Demonstration of immunoreactive vasoactive intestinal peptide (IR-VIP) and somatostatin (IR-SOM) in rat thymus. 197 6

In situ hybridization was used to study the expression of prepro-neuropeptide Y (NPY), preprosomatostatin (SOM), preprotachykinin (PPT) and preprocholecystokinin (CCK) mRNA in caudate-putamen and frontoparietal cortex of rat brain with unilateral lesion of midbrain dopamine neurons. Neurons expressing NPY and SOM mRNA showed a similar distribution and the expression of both NPY and SOM appears to be regulated by dopamine in a similar fashion. Following a dopamine deafferentation, the numerical density of both NPY and SOM mRNA producing neurons almost doubled in the lesioned caudate-putamen with no change in the average grain density over positive neurons. Hence, in the intact caudate-putamen dopamine appears to suppress expression of these two neuropeptide genes leading to an activation of both NPY and SOM mRNA expression in many non- or low-expressing neurons when the level of dopamine is decreased. In the fronto-parietal cortex, on the other hand, dopamine appears to stimulate NPY and SOM gene expression. Thus, in the absence of dopamine about half of the NPY positive neurons disappeared. However, for SOM the number of positive neurons did not change, but rather most positive neurons appeared to have down-regulated their SOM mRNA expression. No evidence was found for a change in CCK mRNA expression by the dopamine deafferentation, while PPT mRNA expression decreased in the deafferented caudate-putamen. Consequently, dopamine exerts dissimilar effects on the expression of different neuropeptide genes, that in turn do not respond in the same way in different brain regions.
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PMID:Neuropeptide gene expression in brain is differentially regulated by midbrain dopamine neurons. 238 50

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