Interleukin-1[beta] effects on somatostatin release in vitro /

Tittle, Angela M.,

January 1998

Thesis (M.Sc.), Memorial University of Newfoundland, Faculty of Medicine,1999. / Typescript. Bibliography: leaves 100-118.

Regulatory mechanisms in glucagon-like peptide-1-and somatostatin-producing cells

Adriaenssens, A. Elizabeth

January 2014

No description available.

612

Glucagon-like peptide 1 ; Somatostatin

Charakterisierung von Somatostatinrezeptor-Subtyp 4 interagierenden Proteinen in der Ratte (Rattus norvegicus) / Characterisation of somatostatin receptor subtype 4 interacting proteins in the rat (Rattus norvegicus)

Christenn, Marcus

January 2005

Somatostatin ist ein regulatorisches Peptid, das eine Vielzahl von biologischen Prozessen innerhalb des Körpers beeinflußt. Die Wirkung von Somatostatin wird auf zellulärer Ebene über eine Familie von fünf G-Protein-gekoppelten Rezeptoren vermittelt, die entweder in G Protein-abhängiger Weise oder vermutlich auch über andere interagierende intrazelluläre Proteine auf nachgeschaltete Signaltransduktionswege wirken. Der Somatostatinrezeptor Subtyp 4 (SSTR4) wird hauptsächlich im Gehirn exprimiert und wirkt dort inhibierend auf die exzitatorische Signalweiterleitung. Es sind aber auch stimulierende Effekte des SSTR4 bekannt. Um das subtypspezifische Signalverhalten des SSTR4 weiter zu untersuchen, wurden im Rahmen dieser Arbeit Proteine gesucht, die intrazellulär mit dem SSTR4 interagieren und so seine physiologischen Effekte beeinflussen. In einem ersten Ansatz konnten drei mögli-che Interaktionspartner mit Hilfe des Hefe-Zwei-Hybrid-Systems identifiziert werden, die aber in nachfolgenden Untersuchungen als unpezifisch eingestuft wurden. Mit Hilfe einer Affinitätschromatografie wurden dann zwei Proteine identifiziert, die spezifisch mit dem SSTR4 interagieren. Sowohl PSD-95 als auch PSD-93 (Postsynaptic density protein of 95 kDa bzw. 93kDa) wurden mit einem immobilisierten Peptid präzipitiert, das die neun C-terminalen Aminosäuren des SSTR4 enthält. Die Interaktion des SSTR4 mit PSD 95 wurde im Weiteren näher charakterisiert. In einem Bindungsexperiment mit rekombinaten Proteinen konnte gezeigt werden, dass die Interaktion durch die 1. und 2. PDZ-Domäne von PSD-95 vermittelt wird. In humanen embryonalen Nieren-Zellen (HEK293), die den SSTR4 stabil exprimieren, konnte PSD-95 mit dem Rezeptor koimmunpräzipitiert werden. Nach Koexpression von PSD-95 und SSTR4 findet man eine partielle Kolokalisierung beider Proteine an der Zellmembran, wobei aber der Großteil des PSD-95 weiterhin eine diffuse zytoplasmatische Verteilung zeigt. Die Interaktion wurde in vivo sowohl immunhistochemisch in kultivierten Hippocampus-Neuronen als auch durch Koimmunpräzipitation beider Proteine aus Rattengehirn-Lysaten nachgewiesen. Die Interaktion von PSD-95 mit dem SSTR4 beeinflußt weder die Agonisten-induzierte Internalisierung des Rezeptors in HEK293-Zellen, noch die Kopplung des Rezeptors an einen G-Protein-gekoppelten einwärtsgleichrichtenden Kaliumkanal in Oozyten des afrikanischen Krallenfrosches Xenopus laevis. Durch die Interaktion mit PSD-95 wird der SSTR4 in physikalische Nähe zu bestimmten Zielproteinen gebracht, über die nachfolgend die Somatostatineffekte weitervermittelt werden. So ermöglicht die Interaktion vermutlich eine Integration des SSTR4 in den postsynaptischen Komplex aus PSD-95 und Glutamatrezeptoren, wo der SSTR4 die bereits beschrieben regulatorischen Effekte auf die Glutamat-vermittelte exzitatorische Signaltransduktion ausüben kann. / Somatostatin is a regulatory peptid, which affects a multiplicity of biological processes within the body. The effects of Somatostatin are mediated by a family of five G-protein-coupled receptors, which act on several downstream signaltransduction pathways either in a G-protein-dependent way or probably in a G-protein-independent manner via intracellular interacting proteins. The somatostatin receptor subtype 4 (SSTR4) is mainly expressed in brain, where it inhibits the excitatory neurotransmission. In addition, excitatory effects of SSTR4 have also been published. In order to examine the subtype specific signalling of SSTR4, I tried to identify intracellular proteins which interact directly with the SSTR4 and affect its physiological effects. Using the yeast two-hybrid system I identified three possible interaction partners for SSTR4, which were however classified as non-specific in subsequent experiments. In a second approach two proteins which interact with SSTR4 could be identified by affinity-chromatography. Both proteins PSD-95 and PSD-93 (Postsynaptic density protein of 95 kDa and 93kDa) were precipitated specifically with an immobilized peptid that contains the nine C-terminal amino acids of SSTR4. The interaction of the SSTR4 with PSD-95 was further characterized. In a binding experiment with recombinant proteins I could show that the interaction is mediated by the 1st and 2nd PDZ-domain of PSD-95. In human embryonic kidney cells (HEK293) which stably express SSTR4, PSD-95 could be coprecipitated with the receptor. After coexpression of PSD-95 and SSTR4 both proteins are partially colocalized at the plasma membrane. The majority of the PSD-95 however shows a diffuse cytoplasmic distribution. The in vivo interaction was proven by immunohistochemistry on cultivated hippocampal neurons and by coimmunoprecipitation of both proteins from rat brain lysates. The interaction of PSD-95 with SSTR4 affected neither the agonist induced internalisation of the receptor in HEK293 cells, nor the coupling of the receptor to a G-protein-coupled inwardly-rectifying potassium channel in oocytes obtained from the african clawed frog Xenopus laevis. By the interaction with PSD-95, SSTR4 is brought into physical proximity to certain target proteins which mediate the effects of somatostatin. Thus the interaction probably allows an integration of SSTR4 into the postsynaptic complex of PSD-95 and glutamergic receptors, where SSTR4 could regulate the glutamat-mediated excitatory signaltransduction.

Ratte

Somatostatin

G-Proteine

Rezeptor

ddc:540

"Marcação do peptídeo Dota-TYR3-Octreotato com radioiodo e estudo da biodistribuição e afinidade por células de carcinoma pancreático" / LABELING OF THE PEPTIDE DOTA-TYR3-OCTREOTATE WITH RADIOIODINE AND BIODISTRIBUTION AND AR42J NEUROENDOCRINE TUMOR AFFINITY STUDY IN MICE

Nagamati, Lucio Takeshi

19 December 2006

Os tumores neuroendócrinos são raros, ocorrem principalmente no trato gastrointestinal, mas outros sistemas são acometidos como pele, pulmões e sistema nervoso. São ricos em receptores de somatostatina (SM) do tipo 2 (SSTR2) e podem secretar hormônios em excesso. Peptídeos análogos sintéticos da SM são de grande utilidade por possuírem meia vida maior do que a SM e, assim, podem ser utilizados para melhora clínica destes pacientes devido sua ação inibitória tumoral. A marcação destes peptídeos com radioisótopos permite a obtenção de imagens, de boa relação custo-eficácia comprovada, e realização de terapia. O peptídeo utilizado, DOTA-Tyr3-octreotato (DOTATATO), possui afinidade ao receptor SSTR2 muito maior do que o utilizado comercialmente hoje, é facilmente radioiodado e possui biodistribuição favorável para diagnóstico e terapia devido à presença do quelante DOTA. Estudamos a influência de vários fatores na pureza radioquímica do composto marcado além da estabilidade da marcação e biodistribuição em camundongos Swiss e Nude, normais e com tumor de células AR42J, além da estimativa de dose absorvida. Observamos fácil e estável radioiodação do peptídeo à razão molar peptídeo/radioiodo (131I) de 2,73, que gerou espécie radioquímica com tempo de retenção de 22,7 minutos na cromatografia líquida de alta eficiência e que apresentou biodistribuição e dosimentria favoráveis para a realização de imagens e terapia dos pacientes com tumores neuroendócrinos, ao contrário do que dados antigos da literatura mostravam nos compostos radioativos sem quelante associado. Outras razões molares não se mostraram eficientes, com outras espécies radioquímicas e biodistribuição desfavorável. Um estudo dosimétrico em pacientes com tumores neuroendócrinos pode ser realizado num futuro próximo. / Neuroendocrine tumors are rare and affect mainly the gastrointestinal tract but other systems are also affected like the skin, lungs and the nervous system. They are rich in type 2 somatostatin (SM) receptors (SSTR2) and may secrete hormones in excess. Synthetic SM derivative peptides are of great utility because presented bigger half life when compared to SM and can be used to clinical improvement of these patients due to its tumoral inhibitory action. The labeling of these peptides with radioisotopes allowed the acquisition of images with favourable cost-efficiency relationship and use in therapy. The peptide, DOTATyr3- octreotate (DOTATATE), has much more affinnity for the SSTR2 receptor than the peptide commercially used nowadays, is easily radioiodinated and has a favourable biodistribution for diagnosis and treatment due to the presence of the chelator DOTA. We have studied the influence of various factors on the radiochemical purity of the labeled compound as labeling stability, absorbed dose estimation and biodistribution in normal and AR42J cell tumor-bearing Swiss and Nude mice. We observed easy and stable peptide radioiodination at peptide/radioiodine (131I) ratio of 2.73 that produced a radiochemical species with retention time of 22.7 minutes at high performance liquid chromatography and presented a favourable biodistribution and dosimetry for imaging and therapy of patients with neuroendocrine tumors, just the opposite result observed the radioiodinated compounds without a chelator as described in the literature. Other molar peptide/radioiodine ratios did not showed good results, with various radiochemical species and unfavourable biodistribution. A possible dosimetric study in patients with neuroendocrine tumors may be carried out in the near future.

Neuroendocrine

neuroendocrino

octreotate

octreotato

somatostatin

somatostatina

The effects of neurosteroids and neuropeptides on anxiety-related behavior

Engin, Elif

11 1900

Anxiety disorders are the most prevalent of all psychiatric conditions. However, current pharmacological treatments for anxiety disorders are characterized by one or more of the following deficiencies: 1) unwanted side effects, 2) partial efficacy, 3) addictive potential, and 4) delayed onset of therapeutic effects. These therapeutic liabilities motivate the search for better pharmacological treatments. This research effort has been concentrated in three broad, neuropharmacological domains: 1) Sub-unit specific GABAA receptor agonists, 2) Neurosteroids, and 3) Neuropeptides. The general purpose of this thesis was to advance our understanding of the putative anxiolytic potential of neurosteroids and neuropeptides, and their neural mechanisms of action, as revealed by intracerebral infusion studies in animal models of anxiety. Chapter 1 of this thesis will provide a systematic review of what is now known about the behavioral effects of intra-cerebrally infused agonists and antagonists of anxiolytic compounds in animal models of anxiety. A theoretical context in which to view the empirical work is also outlined. Chapter 2 will provide a brief introduction to neurosteroids and neuropeptides, and their potential as anxiolytic drugs as suggested by the current literature. In Chapter 3, the anxiolytic-like effects of the neurosteroid allopregnanolone were examined in the amygdala, the hippocampus or the medial prefrontal cortex. Allopregnanolone had site- and test-specific anxiolytic effects, causing anxiolysis following infusion into the amygdala and the medial prefrontal cortex. In Chapter 4, the anxiety-related effects of two receptor antagonists of the neuropeptide arginine vasopressin were investigated in the hippocampus. Anxiolytic effects were specific to both receptor sub-type and by infusion site. In chapter 5, the putative anxiolytic and antidepressant effects of the neuropeptide somatostatin were investigated. Intracerebroventricular microinfusion of somatostatin produced anxiolytic-like and antidepressant-like signatures in distinct domains. In chapter 6, selective agonists for each of the 5 G-protein coupled somatostatin receptors were administered to rats. Intracerebroventricular administration of an sst2 agonist produced anxiolytic-like effects, whereas an antidepressant-like effect was observed following the administration of both sst2 and sst3 agonists. In summary, the present thesis provides important clues to the neurochemical correlates of anxiety, and its potential treatment with alternative compounds such as neuropeptides.

anxiety

vasopressin

somatostatin

allopregnanolone

neuroscience

hippocampus

Regulation of Synapse Development by Activity Dependent Transcription in Inhibitory Neurons

Mardinly, Alan Robert

07 June 2014

Neuronal activity and subsequent calcium influx activates a signaling cascade that causes transcription factors in the nucleus to rapidly induce an early-response program of gene expression. This early-response program is composed of transcriptional regulators that in turn induce transcription of late-response genes, which are enriched for regulators of synaptic development and plasticity that act locally at the synapse.

Neurosciences

Activity

Inhibition

Npas4

somatostatin

synapse development

The effects of neurosteroids and neuropeptides on anxiety-related behavior

Engin, Elif

Unknown Date

No description available.

anxiety

vasopressin

somatostatin

allopregnanolone

neuroscience

hippocampus

Somatostatin receptor expression and biological functions in endocrine pancreatic cells /

Ludvigsen, Eva,

January 2006

Diss. (sammanfattning) Uppsala : Uppsala universitet, 2006. / Härtill 4 uppsatser.

Functional relationship between forebrain cholinergic projections and somatostatin neurons in the rat /

Perry, Theresa Fried,

January 1990

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1990. / Vita. Abstract. Includes bibliographical references (leaves 72-87). Also available via the Internet.

"Marcação do peptídeo Dota-TYR3-Octreotato com radioiodo e estudo da biodistribuição e afinidade por células de carcinoma pancreático" / LABELING OF THE PEPTIDE DOTA-TYR3-OCTREOTATE WITH RADIOIODINE AND BIODISTRIBUTION AND AR42J NEUROENDOCRINE TUMOR AFFINITY STUDY IN MICE

Lucio Takeshi Nagamati

19 December 2006

Os tumores neuroendócrinos são raros, ocorrem principalmente no trato gastrointestinal, mas outros sistemas são acometidos como pele, pulmões e sistema nervoso. São ricos em receptores de somatostatina (SM) do tipo 2 (SSTR2) e podem secretar hormônios em excesso. Peptídeos análogos sintéticos da SM são de grande utilidade por possuírem meia vida maior do que a SM e, assim, podem ser utilizados para melhora clínica destes pacientes devido sua ação inibitória tumoral. A marcação destes peptídeos com radioisótopos permite a obtenção de imagens, de boa relação custo-eficácia comprovada, e realização de terapia. O peptídeo utilizado, DOTA-Tyr3-octreotato (DOTATATO), possui afinidade ao receptor SSTR2 muito maior do que o utilizado comercialmente hoje, é facilmente radioiodado e possui biodistribuição favorável para diagnóstico e terapia devido à presença do quelante DOTA. Estudamos a influência de vários fatores na pureza radioquímica do composto marcado além da estabilidade da marcação e biodistribuição em camundongos Swiss e Nude, normais e com tumor de células AR42J, além da estimativa de dose absorvida. Observamos fácil e estável radioiodação do peptídeo à razão molar peptídeo/radioiodo (131I) de 2,73, que gerou espécie radioquímica com tempo de retenção de 22,7 minutos na cromatografia líquida de alta eficiência e que apresentou biodistribuição e dosimentria favoráveis para a realização de imagens e terapia dos pacientes com tumores neuroendócrinos, ao contrário do que dados antigos da literatura mostravam nos compostos radioativos sem quelante associado. Outras razões molares não se mostraram eficientes, com outras espécies radioquímicas e biodistribuição desfavorável. Um estudo dosimétrico em pacientes com tumores neuroendócrinos pode ser realizado num futuro próximo. / Neuroendocrine tumors are rare and affect mainly the gastrointestinal tract but other systems are also affected like the skin, lungs and the nervous system. They are rich in type 2 somatostatin (SM) receptors (SSTR2) and may secrete hormones in excess. Synthetic SM derivative peptides are of great utility because presented bigger half life when compared to SM and can be used to clinical improvement of these patients due to its tumoral inhibitory action. The labeling of these peptides with radioisotopes allowed the acquisition of images with favourable cost-efficiency relationship and use in therapy. The peptide, DOTATyr3- octreotate (DOTATATE), has much more affinnity for the SSTR2 receptor than the peptide commercially used nowadays, is easily radioiodinated and has a favourable biodistribution for diagnosis and treatment due to the presence of the chelator DOTA. We have studied the influence of various factors on the radiochemical purity of the labeled compound as labeling stability, absorbed dose estimation and biodistribution in normal and AR42J cell tumor-bearing Swiss and Nude mice. We observed easy and stable peptide radioiodination at peptide/radioiodine (131I) ratio of 2.73 that produced a radiochemical species with retention time of 22.7 minutes at high performance liquid chromatography and presented a favourable biodistribution and dosimetry for imaging and therapy of patients with neuroendocrine tumors, just the opposite result observed the radioiodinated compounds without a chelator as described in the literature. Other molar peptide/radioiodine ratios did not showed good results, with various radiochemical species and unfavourable biodistribution. A possible dosimetric study in patients with neuroendocrine tumors may be carried out in the near future.

neuroendocrino

octreotato

somatostatina

Neuroendocrine

octreotate

somatostatin