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)

This review describes the neuropathology and pathophysiology of interneurons in dorsal hippocampus of the adult rat subjected to transient global cerebral ischemia. The object is to verify if the interneurons die or survive after an ischemic insult, and study if ischemia changes GABA inhibition in the period preceding delayed CA1 pyramidal cell death. The findings are discussed from the point of the hypothesis that loss of GABA inhibition may result in excitatory hyperactivity (possibly epilepsy) and excitotoxic glutamate release. Thereby, early ischemic damage to interneurons may exacerbate the ischemic process resulting in the major and delayed CA1 cell death in hippocampus. Interneurons, located in dentate hilus, and a small number of interneurons located in the mossy fiber layer are selectively lost after ischemia. These interneurons contain somatostatin and neuropeptide Y, but the inhibitory or excitatory nature of them is unknown. However, counts of all hippocampal cells immunoreactive for glutamic acid decarboxylase showed that the GABA interneurons survive ischemia. It is therefore suggested that the vulnerable interneurons in hilus and the mossy fiber layer do not contain GABA. As the GABA interneurons, other hippocampal interneurons also survive ischemia. Among these, the CA1 and CA3 interneurons containing neuropeptide Y demonstrate permanently reduced immunoreactivity for neuropeptide Y, evident 1-2 days after ischemia. Another subpopulation transiently shows a decrease in immunoreactivity for parvalbumin approximately 4 days after ischemia. These results are in contrast to the finding that protein synthesis in hippocampal interneurons returns to preischemic levels 9 hours after ischemia. The integrity between excitation and inhibition in CA1 is unchanged in hippocampal slices taken from animals 1-2 days after ischemia. Furthermore, GABA can readily be released upon potassium stimulation in the period preceding CA1 pyramidal cell death. Binding to hippocampal benzodiazepine sites, however, declines prior to ischemic CA1 pyramidal cell death. It is demonstrated that administration of diazepam and GABA uptake inhibitors during this period offers postischemic neuron protection in CA1. There is no conclusive evidence of excitatory hyperactivity preceding ischemic CA1 pyramidal cell death. On the contrary, results from Chang et al. (1) suggest that ischemic loss of interneurons in the dentate hilus is associated with an increase in inhibition. However, it is suggested that GABA inhibition is insufficient to counterbalance the detrimental process during normal or even reduced postischemic excitation, since drugs believed to increase GABA inhibition reduce ischemic cell death. The early and permanent reduction in neuropeptide Y immunoreactivity may reflect a reduced capacity of these interneurons to release neuropeptide Y and thereby reduce presynaptic glutamate release.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Interneurons in rat hippocampus after cerebral ischemia. Morphometric, functional, and therapeutic investigations. 790 56

Light and electron microscopic immunocytochemical techniques were used to study the interneuron population staining for somatostatin (SRIF) in cultured slices of rat hippocampus. The SRIF immunoreactive somata were most dense in stratum oriens of areas CA1 and CA3, and in the dentate hilus. Somatostatin immunoreactive cells in areas CA1 and CA3 were characteristically fusiform in shape, with dendrites that extended both parallel to and into the alveus. The axonal plexus in areas CA1 and CA3 was most dense in stratum lacunosum-moleculare and in stratum pyramidale. Electron microscopic analysis of this area revealed that the largest number of symmetric synaptic contacts from SRIF immunoreactive axons were onto pyramidal cell somata and onto dendrites in stratum lacunosum-molecular. In the dentate gyrus, SRIF somata and dendrites were localized in the hilus. Hilar SRIF immunoreactive neurons were fusiform in shape and similar in size to those seen in CA1 and CA3. Axon collaterals coursed throughout the hilus, projected between the granule cells and into the outer molecular layer. The highest number of SRIF synaptic contacts in the dentate gyrus were seen on granule cell dendrites in the outer molecular layer. Synaptic contacts were also observed on hilar neurons and granular cell somata. SRIF synaptic profiles were seen on somata and dendrites of interneurons in all regions. The morphology and synaptic connectivity of SRIF neurons in hippocampal slice cultures appeared generally similar to intact hippocampus.
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PMID:Somatostatin-containing neurons in rat organotypic hippocampal slice cultures: light and electron microscopic immunocytochemistry. 795 90

The hippocampi of species commonly used for in vitro physiologic studies were examined to determine if there were species-specific and regional differences in somatostatin immunoreactivity. The distributions of somatostatin-immunoreactive somata and fiber plexuses were determined, and the concentration of somatostatin along the septotemporal axis of the hippocampus was measured using a radioimmunoassay. There are many similarities in the patterns of somatostatin immunoreactivity in the hippocampi of mice, rats, guinea pigs, and rabbits. All species had a relatively even distribution of somatostatin-positive perikarya across three fields of the hippocampus (dentate gyrus, CA3, and CA1-2), a similar distribution of somatostatin-immunoreactive perikarya across the strata of the CA1-2 field and the dentate gyrus; and more somatostatin-positive cells in temporal than in septal hippocampus. However, there are species-specific differences in the distribution of somatostatin-immunoreactive perikarya across the strata of CA3. In addition, unlike the other species examined, mice appeared not to have a somatostatin-immunoreactive fiber plexus in the molecular layer of the dentate gyrus. The functional significance of these differences remains to be determined.
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PMID:Somatostatin-immunoreactivity in the hippocampus of mouse, rat, guinea pig, and rabbit. 795 91

The effects of a very short ischemic insult on hilar somatostatin (SS) neurons were investigated in the gerbil hippocampus by means of immunocytochemistry and in situ hybridization histochemistry. A selective and significant loss of 40% of hilar SS neurons took place after 1 day, and a 60% loss after 7 days following 2 min of ischemia, while no SS neurons were lost during recirculation after 1 min of ischemia. Repeated 2-min periods of ischemia, which induced ischemic tolerance by vulnerable CA1 neurons, caused almost complete loss of hilar SS neurons. This study clearly demonstrates that hilar SS neurons are more vulnerable to ischemic insult than CA1 pyramidal neurons. Ischemic tolerance may be induced during the progressive loss of SS neurons in the hilus by changes in their synaptic connections to CA1 pyramidal neurons.
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PMID:Hilar somatostatin neurons are more vulnerable to an ischemic insult than CA1 pyramidal neurons. 809 19

According to electrophysiological studies, the subcortically denervated hippocampus has been suggested as a model for limbic epilepsy. We investigated a) whether fimbrial lesioning leads to any biochemical or morphological changes in the rat hippocampus, b) if these changes give any explanation to the previously indicated hyperexcitability, and c) if the changes are in line with the findings in other experimental models and human epilepsy. The fimbria-fornix transection was done by aspiration. Four months later, spontaneous EEG activities were recorded, and the hippocampal formation was processed for histology. In addition, a separate group of lesioned rats was used for hippocampal amino acid analysis. Hyperexcitable functioning of the hippocampus was seen as frequent and rhythmic spiking activity in 25% of the fimbria-fornix-lesioned rats, although the rest of them had spikes occasionally. The amino acids analysis revealed a notable decrease in the concentration of GABA but no significant changes in the amount of excitatory amino acids. This suggests impaired GABAergic functioning but does not exclude possible abnormalities in the release of both excitatory and inhibitory amino acids. The number of somatostatin-immunoreactive (SOM-IR) neurons, a subpopulation of GABAergic neurons, was decreased in all the areas of the hippocampus (CA3 > CA1 > hilus), but this was statistically significant only in the CA3 area. Interestingly, it is the region from which interictal spiking activity in the subcortically denervated rat presumable originates. Immunostaining for synaptophysin showed a dense band of granules in the inner molecular layer of the dentate gyrus, indicating probable synaptic reorganization of associational afferents.
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PMID:Biochemical and morphological changes in the rat hippocampus following transection of the fimbria-fornix. 809 58

The physiological characteristics and significance of long-term potentiation in the hippocampus were summarized. In particular, it was pointed out that different mechanisms are involved in the production of hippocampal LTP between the mossy fiber-CA3 system and other systems such as Schaffer collateral-CA1, fimbrial fiber-CA3 and commissural/associational fiber-CA3. Furthermore, the epsilon-subspecies of protein kinase C (PKC) was demonstrated to be exclusively located at the presynaptic terminals in the hippocampus and activated by arachidonic acid, and this enzyme is suggested to be involved in the production of LTP through a phosphorylation of GAP-43, while the gamma-subspecies of PKC may be postsynaptically involved in LTP through an activation of NMDAR1. The production of LTP in the hippocampus is facilitated by many factors such as epidermal growth factor, fibroblast growth factors, somatostatin, M1 receptor agonists and many drugs like anirasetam, bifemelane, idebenone, indeloxazine and vinpocetine, but inhibited by M2-receptor agonists, scopolamine and midazolam. In addition to electrophysiological methods, LTP-like phenomena in 2-deoxyglucose uptake and leucine incorporation can be detected. These LTP phenomena in several animal models will be useful as indices for evaluating facilitatory actions of various compounds on learning/memory functions.
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PMID:[Pharmacology of long-term potentiation]. 810 51

The expression of muscarinic acetylcholine receptors (mAChRs) in glutamic acid decarboxylase (GAD)-positive cells in the different strata of CA1, CA3, and the dentate gyrus (DG) of the dorsal hippocampus is examined by way of quantitative immunofluorescent double labeling employing M35, the monoclonal antibody raised against purified mAChR protein. Of all GAD-positive neurons, 97.5% express mAChRs. Conversely, 92.9% of the muscarinic cholinoceptive nonpyramidal neurons express GAD. These results indicate that the vast majority of the gamma-aminobutyric acid (GABA)ergic neurons express mAChRs. In addition to GAD, parvalbumin (PARV) and somatostatin (SOM) are two neurochemical substances notably expressed in GABAergic neurons. In order to examine whether the entire muscarinic cholinoceptive nonpyramidal cell group can be characterized by these three GABAergic markers, a cocktail of GAD, PARV, and SOM was used in a fluorescent double-labeling experiment with M35. These results show that 97.2% of all muscarinic cholinoceptive nonpyramidal neurons can be neurochemically characterized by the content of GAD, PARV, and SOM. In conclusion, nearly all GABAergic cells express mAChRs and, conversely, virtually the entire muscarinic cholinoceptive nonpyramidal cell group belongs to the GABAergic cell population. This study, therefore, provides anatomical evidence for an extensive neuronal connectivity of the hippocampal muscarinic cholinoceptive nonpyramidal system and the inhibitory GABAergic circuitry.
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PMID:GABAergic neurons of the rat dorsal hippocampus express muscarinic acetylcholine receptors. 822 Nov 58

Intracerebral or intraperitoneal injections of kainic acid, an agonist at a class of glutamate receptors, have been extensively used to model temporal lobe epilepsy. In the present study we compared the types and distributions of selectively vulnerable neurons in the ipsi- and contralateral hippocampi following unilateral kainate injections into the CA3 subfield in order to examine whether "proximal" or "distant" neuronal damage resembled the pathology, and possibly also the mechanism, of human temporal lobe epilepsy. The degeneration of principal cells in the different hippocampal subfields was visualized by silver impregnation, and the loss of various types of non-principal cells was studied by immunostaining for the calcium binding proteins parvalbumin, calbindin-D28k and calretinin, as well as for somatostatin. In the first series of experiments various concentrations (ranging from 0.1 to 1 mg/ml) and volumes (0.5-2 microliters) of kainate were tested to induce reproducible damage in the contralateral hippocampus. The optimal dose, employed in the subsequent vulnerability studies, was found to be 3 x 0.5-microliter injections (over a period of 10 min) of a concentration of 0.33 mg/ml under ether anaesthesia, which was discontinued immediately after injection. Anaesthesia with equithesin was found to prevent contralateral cell death. Most if not all pyramidal cells in the CA3 region degenerated on the ipsilateral side, whereas the dentate granule cells, and the majority of CA1 pyramidal cells were resistant. A strikingly different pattern was found on the contralateral side, where CA1 pyramidal cells were almost completely lost, but the CA3 region (with the exception of CA3c) and the dentate gyrus remained intact. Three subpopulations of non-principal cells were found to be vulnerable in both hemispheres, the hilar somatostatin cells, spiny calretinin cells and mossy cells, as well as the spiny calretinin cells in stratum lucidum of CA3. The other subpopulations were resistant, except for those within the effective injection site. We propose that the "distant" (contralateral) damage resembles the pattern, and probably also the mechanism, of cell death in human temporal lobe epilepsy, whereas the ipsilateral damage does not.
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PMID:Selective neuronal death in the contralateral hippocampus following unilateral kainate injections into the CA3 subfield. 824 63

The mechanism of delayed death of pyramidal cells in the hippocampal CA1 region and the acute death of various types of hilar neurons after ischemia is still unknown. Excitotoxicity may play a role in ischemic cell death, a prerequisite of which is the development of increased excitability or an enhanced excitatory transmission in the selectively vulnerable subfields of the hippocampus. Such changes may take place upon the loss or malfunction of local inhibitory neurons in the early postischemic period. In the present study we examined the vulnerability of non-pyramidal neurons containing a recently discovered calcium binding protein, calretinin, in the rat hippocampus following 15 min ischemia induced by four-vessel occlusion. Immunostaining for calretinin enabled us to visualize a new type of spiny non-pyramidal cell in the hippocampus specifically associated with the mossy fiber system. This cell type is present exclusively in regions where mossy fiber terminals occur, i.e. in the hilus of the dentate gyrus and in stratum lucidum of the CA3 subfield. A selective loss of immunoreactivity in these neurons was already observed at 12-24 h after ischemia, when the pyramidal cells in the CA1 region showed no signs of damage. At a survival time of two to three days, most if not all spiny calretinin-immunoreactive cells had disappeared from the hippocampus. Other types of calretinin-containing GABAergic neurons were also reduced in number, but only at a time when CA1 pyramidal cells also started to degenerate, i.e. two to three days after ischemia. We speculate that the early loss of spiny calretinin-containing cells, together with other non-pyramidal cells associated with the mossy fiber system (somatostatin-containing neurons and mossy cells of the hilus), may result in pathological network activity in the hippocampus, which may ultimately lead to an increased excitatory transmission and delayed pyramidal cell death in the CA1 region.
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PMID:Early degeneration of calretinin-containing neurons in the rat hippocampus after ischemia. 825 22

Much of the work on forebrain ischemia in the hippocampus has focused on the phenomenon of delayed neuronal death in CA1. It is established that dentate granule cells and CA3 pyramidal cells are resistant to ischemia. However, much less is known about interneuronal involvement in CA3 or ischemic injury in the dentate hilus other than the fact that somatostatin neurons in the latter lose their immunoreactivity. We combined two sensitive methods--heat-shock protein (HSP72) immunocytochemistry and a newly developed Gallyas silver stain for demonstrating impaired cytoskeletal elements--to investigate the extent of ischemic damage to CA3 and the dentate hilus using the four-vessel-occlusion model for inducing forebrain ischemia. HSP72-like immunoreactivity was induced in neuronal populations previously shown to be vulnerable to ischemia. In addition, a distinct subset of interneurons in CA3 was also extremely sensitive to ischemia, even more so than the CA1 pyramidal cells. These neurons are located in the stratum lucidum of CA3 and possess a very high density of dendritic spines. In silver preparations, they were among the first to be impregnated as "dark" neurons, before CA1 pyramidal cells; microglial reaction was also initiated first in the stratum lucidum of CA3. Whereas CA1 damage was most prominent in the septal half of the hippocampus, hilar and CA3 interneuronal damage had a more extensive dorsoventral distribution. Our results also show a far greater extent of damage in hilar neurons than previously reported. At least four hilar cell types were consistently compromised: mossy cells, spiny fusiform cells, sparsely spiny fusiform cells, and long-spined multipolar cells. A common denominator of the injured neurons in CA3 and the hilus was the presence of spines on their dendrites, which in large part accounted for the far greater number of mossy fiber terminals they receive than their non-spiny neighbors. We suggest that the differential vulnerability of neuronal subtypes in these two regions may be attributed to their extremely dense innervation by the mossy fibers and/or the presence of non-NMDA receptor subtypes that are highly permeable to calcium. In addition, early impairment of these spiny CA3 cells and hilar neurons after ischemia may be causal to delayed neuronal death in the CA1 pyramidal cells.
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PMID:Vulnerability of mossy fiber targets in the rat hippocampus to forebrain ischemia. 836 55


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