Global ETD Search

411	Autocrine loop in the purinergic control of airway surface liquid volume : monitoring with a novel side-view imaging technique Dubois, David 03 1900 (has links) La Fibrose Kystique (FK) est une maladie dégénérative qui entraine une dégénération des poumons dû au problème de clairance mucociliaire (CMC). Le volume de surface liquide (SL) couvrant les cellules pulmonaires est essentiel à la clairance de mucus et au combat contre les infections. Les nucléotides extracellulaires jouent un rôle important dans la CMC des voies aériennes, en modifiant le volume de la SL pulmonaire. Cependant, les mécanismes du relâchement de l’ATP et de leurs déplacements à travers la SL, restent inconnus. Des études ultérieures démontrent que l’exocytose d’ATP mécano-sensible et Ca2+-dépendant, dans les cellules A549, est amplifié par les actions synergétiques autocrine/paracrine des cellules avoisinantes. Nous avions comme but de confirmer la présence de la boucle purinergique dans plusieurs modèles de cellules épithéliales et de développer un système nous permettant d’observer directement la SL. Nous avons démontrés que la boucle purinergique est fonctionnelle dans les modèles de cellules épithéliales examinés, mis appart les cellules Calu-3. L’utilisation de modulateur de la signalisation purinergique nous a permis d’observer que le relâchement d’ATP ainsi que l’augmentation du [Ca2+]i suivant un stress hypotonique, sont modulés par le biais de cette boucle purinergique et des récepteurs P2Y. De plus, nous avons développé un système de microscopie qui permet d’observer les changements de volume de SL en temps réel. Notre système permet de contrôler la température et l’humidité de l’environnement où se trouvent les cellules, reproduisant l’environnement pulmonaire humain. Nous avons démontré que notre système peut identifier même les petits changements de volume de SL. / Cystic Fibrosis (CF) patients suffer from respiratory problems associated with pulmonary infections and exacerbations, due to improper mucociliary clearance (MCC). The airway surface liquid (ASL) covering pulmonary epithelial cells plays a pivotal role in MCC and infection control. Extracellular nucleotides control MCC in airway epithelia by modulating ASL volume, ciliary beating and mucin secretion. The mechanism(s) of their release and dispersal within the ASL remain incompletely understood. Studies with A549 cells, a human alveolar type II cell model, have shown that mechanosensitive, Ca2+-dependent ATP secretion is strongly amplified by the synergistic autocrine/paracrine actions of released nucleotides. The aim of this study was to examine whether the autocrine purinergic loop operates in different lung epithelial cell models and to develop an imaging system allowing the direct monitoring of ASL height during purinergic stimulation. We demonstrated that the signaling loop is functional in all epithelial cells tested, with the exception of Calu-3 epithelial cells. With different purinergic signaling modulators, we demonstrated that ATP release and [Ca2+]i elevations evoked by hypotonic stress were strongly amplified by autocrine/paracrine effects in cells expressing the P2Y receptor family. To monitor ASL volume changes in real time, we developed a novel epi-fluorescence, side-view microscopy system to observe ASL height. During experiments, cell cultures grown on permeable filters were mounted in a custom-designed chamber that allows control of the temperature, humidity and air flow above the cell monolayer, mimicking the pulmonary environment. This system detects even small changes in ASL volume following purinergic stimulation. ATP Boucle autocrine purinergique Cellules épithéliales pulmonaires Fibrose Kystique Microscopie Nucléotides extracellulaires Stimulation purinergique Surface liquide épithéliales Transport ionique Cystic Fibrosis Extracellular nucleotides Ionic transport Pulmonary epithelial cells Purinergic stimulation Microscopy
412	Studies of electronic and structural properties of molecular clusters of prebiotic importance Aylward, Nigel Nunn January 2006 (has links) This thesis applies the ab initio techniques of computational chemistry to studies of molecular clusters containing covalent (strong) or van der Waals (weak) bonds formed in chemistry and biochemistry in the temperature range 10-300 K. Van derWaals complexes with an enthalpy of formation from reactants of less than 25 kJ mol-1 and covalent clusters are described in this thesis. The first group of van der Waals complexes involved the molecule carbon monoxide that possesses a small permanent dipole that could lead to dipole - induced dipole interaction and dipole - dipole interaction with another reactant in addition to dispersion. The substrates investigated were methanimine and cyanogen where endergonic unstable molecules were formed, and the clustering of carbon monoxideon a porphin surface leading to the formation of carbon - carbon fragments. TheFaraday effect was invoked to suggest that this was the original method by which thechirality of the D-sugars was selected. Coordination of imino-compounds on thesame surface involving induction and electrostatic interactions could lead to the preferential formation of L-aziridones, hydrolysable to L-amino-acids.The preferred formation of D-ribose, and the more stable D-2-deoxyribose, andnucleotides polymerisable to deoxyribonucleic acids was described. The second group of van der Waals complexes involved the polymerisation of acetylene molecules, to di- and tri-acetylene complexes where the exchange interaction involved the quadrupole moment of the acetylene radical reacting with acetylene or diacetylene. The reaction of carbon monoxide was extended to include its interaction with diacetylene. The entire potential energy surface for the interaction with diacetylene was investigated. The reaction was shown to be endergonic to produce a reactive species, here postulated to rearrange with a reasonable activation energy toform an aldehyde. The energetics of the formation of diacetylene, triacetylene andhigher polymers was briefly investigated. The reactivity of the acetylene polymeraldehydes with other substrates was briefly investigated. This work has apparently laid a firm basis both, qualitative and quantitative, tounderstand some of the weakest interactions in nature involving the simplest ofreactions that have been important in atmospheric chemistry. carbon monoxide azirine-2one aziridine-2one 2 2-bi(cycloazirine-3one) nicotinamide flavin folic acid D-ribose D-2deoxyribose L-amino-acids nucleotides porphin
413	Gene Expression and Profiling of Human Islet Cell Subtypes: A Master’s Thesis Blodgett, David M. 25 July 2012 (has links) Background: The endocrine pancreas contains multiple cell types co-localized into clusters called the Islets of Langerhans. The predominant cell types include alpha and beta cells, which produce glucagon and insulin, respectively. The regulated release of these hormones maintains whole body glucose homeostasis, essential for normal metabolism and to prevent diabetes and complications from the disease. Given the heterogeneous nature of islet composition and absence of unique surface markers, many previous studies have focused on the whole islet. Sorting islet cells by intracellular hormone expression overcomes this limitation and provides pure populations of individual islet cell subsets, specifically alpha and beta cells. This technique provides the framework for characterizing human islet composition and will work towards identifying the genetic changes alpha and beta cells undergo during development, growth, and proliferation. Methods: Human islets obtained from cadaveric donors are dissociated into a single cell suspension, fixed, permeabilized, and labeled with antibodies specific to glucagon, insulin, and somatostatin. Individual alpha, beta, and delta cell populations are simultaneously isolated using fluorescence activated cell sorting. Candidate gene expression and microRNA profiles have been obtained for alpha and beta cell populations using a quantitative nuclease protection assay. Thus far, RNA has been extracted from whole islets and beta cells and subjected to next generation sequencing analysis. Results: The ratio of beta to alpha cells significantly increases with donor age and trends higher in female donors; BMI does not appear to significantly alter the ratio. Further, we have begun to investigate the unique gene expression profiles of alpha and beta cells versus whole islets, and have characterized the microRNA profiles of the two cell subsets. Conclusions: By establishing methods to profile multiple characteristics of alpha and beta cells, we hope to determine how gene, miRNA, and protein expression patterns change under environmental conditions that lead to beta cell failure or promote beta cell development, growth, and proliferation. Islets of Langerhans Gene Expression Profiling Amino Acids, Peptides, and Proteins Cell and Developmental Biology Digestive System Endocrine System Genetic Phenomena Genetics and Genomics
414	The Role of Endoplasmic Reticulum Stress Signaling in Pancreatic Beta Cells: a Dissertation Lipson, Kathryn L. 07 May 2008 (has links) Protein folding in the endoplasmic reticulum (ER) is essential for proper cellular function. However, the sensitive environment in the ER can be perturbed by both pathological processes as well as by physiological processes such as a large biosynthetic load placed on the ER. ER stress is a specific type of intracellular stress caused by the accumulation of immature or abnormal misfolded or unfolded proteins in the ER. Simply defined, ER stress is a disequilibrium between ER load and folding capacity. Cells have an adaptive response that counteracts ER stress called the "Unfolded Protein Response” (UPR). The ability to adapt to physiological levels of ER stress is especially important for maintaining ER homeostasis in secretory cells. This also holds true for pancreatic β-cells, which must fold and process large amounts of the hormone insulin. Pancreatic β-cells minimize abnormal levels of glycemia through adaptive changes in the production and regulated secretion of insulin. This process is highly sensitive, so that small degrees of hypo- or hyperglycemia result in altered insulin release. The frequent fluctuation of blood glucose levels in humans requires that β-cells control proinsulin folding in the ER with exquisite sensitivity. Any imbalance between the load of insulin translation into the ER and the actual capacity of the ER to properly fold and process the insulin negatively affects the homeostasis of β-cells and causes ER stress. In this dissertation, we show that Inositol Requiring 1 (IRE1), an ER-resident kinase/endoribonuclease and a central regulator of ER stress signaling, is essential for maintaining ER homeostasis in pancreatic β-cells. Importantly, IRE1 has a crucial function in the body’s normal production of insulin in response to high glucose. Phosphorylation and subsequent activation of IRE1 by transient exposure to high glucose is coupled to insulin biosynthesis, while inactivation of IRE1 by siRNA or inhibition of IRE1 phosphorylation abolishes insulin biosynthesis. IRE1 signaling under these physiological ER stress conditions utilizes a unique subset of downstream components of IRE1 and has a beneficial effect on pancreatic β-cell homeostasis. In contrast, we show that chronic exposure of β-cells to high glucose causes pathological levels of ER stress and hyperactivation of IRE1, leading to the degradation of insulin mRNA. The term “glucose toxicity” refers to impaired insulin secretion by β-cells in response to chronic stimulation by glucose and is characterized by a sharp decline in insulin gene expression. However, the molecular mechanisms of glucose toxicity are not well understood. We show that hyperactivation of IRE1 caused by chronic high glucose treatment or IRE1 overexpression leads to insulin mRNA degradation in pancreatic β-cells. Inhibition of IRE1 signaling using a dominant negative form of the protein prevents insulin mRNA degradation in β-cells. Additionally, islets from mice heterozygous for IRE1 retain expression of more insulin mRNA after chronic high glucose treatment than do their wild-type littermates. This work suggests that the rapid degradation of insulin mRNA could provide immediate relief for the ER and free up the translocation machinery. Thus, this mechanism may represent an essential element in the adaptation of β-cells to chronic hyperglycemia. This adaptation is crucial for the maintenance of β-cell homeostasis and may explain in part why the β-cells of diabetic patients with chronic hyperglycemia stop producing insulin without simply undergoing apoptosis. This work implies that prolonged activation of IRE1 signaling is involved in the molecular mechanisms underlying glucose toxicity. This work therefore reveals two distinct activities elicited by IRE1 in pancreatic β-cells. IRE1 signaling activated by transient exposure to high glucose enhances proinsulin biosynthesis, while chronic exposure of β-cells to high glucose causes hyperactivation of IRE1, leading to the degradation of insulin mRNA. Physiological IRE1 activation by transient high glucose levels in pancreatic β cells has a beneficial effect on insulin biosynthesis. However, pathological IRE1 activation by chronic high glucose or experimental drugs negatively affects insulin gene expression. In the future, a system to induce a physiological level of IRE1 activation, and/or reduce the pathological level of IRE1 activation could be used to enhance insulin biosynthesis and secretion in people with diabetes, and may lead to the development of new and more effective clinical approaches to the treatment of this disorder. Endoplasmic Reticulum Insulin-Secreting Cells Pancreas Signal Transduction Stress Diabetes Mellitus Membrane Glycoproteins Amino Acids, Peptides, and Proteins Carbohydrates Cells Digestive System Endocrine System Diseases Nutritional and Metabolic Diseases
415	Peptidyltransfer Reaction Catalyzed by the Ribosome and the Ribozyme: a Dissertation Sun, Lele 08 May 2003 (has links) The "RNA world" hypothesis makes two predictions that RNA should have been able both to catalyze RNA replication and to direct protein synthesis. The evolution of RNA-catalyzed protein synthesis should be critical in the transition from the RNA world to the modem biological systems. Peptide bond formation is a fundamental step in modem protein biosynthesis. Although many evidence suggests that the ribosome is a ribozyme, peptide bond formation has not been achieved with ribosomal RNAs only. The goal of this thesis is to investigate whether RNA could catalyze peptide bond formation and how RNA catalyzes peptide bond formation. Two systems have been employed to approach these questions, the ribozyme system and the ribosome system. Ribozymes have been isolated by in vitro selection that can catalyze peptide bond formation using the aminoacyl-adenylate as the substrate. The isolation of such peptide-synthesizing ribozymes suggests that RNA of antiquity might have directed protein synthesis and bolsters the "RNA world" hypothesis. In the other approach, a novel assay has been established to probe the ribosomal peptidyltransferase reaction in the presence of intact ribosome, ribosomal subunit, or ribosomal RNA alone. Several aspects of the peptidyltransfer reaction have been examined in both systems including metal ion requirement, pH dependence and substrate specificity. The coherence between the two systems is discussed and their potential applications are explored. Although the ribozyme system might not be a reminiscence of the ribosome catalysis, it is still unique in other studies. The newly established assay for ribosomal peptidyltransferase reaction provides a good system to investigate the mechanism of ribosomal reaction and may have potential application in drug screening to search for the specific peptidyltransferase inhibitors. Evolution Molecular RNA Catalytic RNA Ribosomal Protein Binding Peptide Biosynthesis Ribosomes Peptidyl Transferases Biological Assay Amino Acids, Peptides, and Proteins Cells Pharmaceutical Preparations Therapeutics
416	Understanding Assembly of AGO2 RISC: the RNAi enzyme: a Dissertation Matranga, Christian B. 17 September 2007 (has links) In 1990, Richard Jorgensen’s lab initiated a study to test if they could create a more vivid color petunia (Napoli et al. 1990). Their plan was to transform plants with the chalcone synthase transgene––the predicted rate limiting factor in the production of purple pigmentation. Much to their surprise, the transgenic plants, as well as their progeny, displayed a great reduction in pigmentation. This loss of endogenous function was termed “cosuppression” and it was thought that sequence-specific repression resulted from over-expression of the homologous transgene sequence. In 1998, Andrew Fire and Craig Mello described a phenomenon in which double stranded RNA (dsRNA) can trigger silencing of cognate sequences when injected into the nematode, Caenorhabditis elegans (Fire et al. 1998). This data explained observations seen years earlier by other worm researchers, and suggested that repression of pigmentation in plants was caused by a dsRNA-intermediate (Guo and Kemphues 1995; Napoli et al. 1990). The phenomenon––which soon after was coined RNA interference (RNAi)––was soon discovered to be a post-transcriptional surveillance system in plants and animals to remove foreign nucleic acids. RNA Interference MicroRNAs RNA Small Interfering Drosophila Proteins Methyltransferases RNA-Induced Silencing Complex RNA 3' End Processing Plants RNA Helicases RNA-Binding Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Enzymes and Coenzymes
417	piRNA Function and Biogenesis in the <em>Drosophila</em> Female Germline: A Dissertation Klattenhoff, Carla Andrea 20 November 2008 (has links) The studies presented in this thesis addressed mainly two aspects of Piwi-interacting RNA (piRNA) biology in the Drosophilagermline. We investigated the role of the piRNA pathway in embryonic axis specification. piRNAs mediate silencing of retrotransposons and the Stellate locus. Mutations in the Drosophila piRNA pathway genes armitage and aubergine disrupt embryonic axis specification, triggering defects in microtubule polarization and asymmetric localization of mRNA and protein determinants in the developing oocyte. Mutations in the ATR/Chk2 DNA damage signal transduction pathway dramatically suppress these axis specification defects, but do not restore retrotransposon or Stellatesilencing. Furthermore, piRNA pathway mutations lead to germline-specific accumulation of γ-H2Av foci characteristic of DNA damage. We conclude that piRNA based gene silencing is not required for axis specification, and that the critical developmental function for this pathway is to suppress DNA damage signaling in the germline. We have also identified a new member of the piRNA pathway. We show that mutations in rhino, which encodes a rapidly evolving Heterochromatin Protein 1 (HP1) chromo box protein, lead to germline specific DNA break accumulation, trigger Chk2 kinase dependent defects in axis specification, and disrupt germline localization of Piwi proteins. Mutations in rhino and the piRNA pathway gene armitage disrupt silencing of all major transposon families, but do not alter expression of euchromatic or heterochromatic protein coding genes. Deep sequencing studies show that rhino mutations significantly reduce or eliminate anti-sense piRNAs derived from the majority of transposable elements in the Drosophila genome, and lead to a dramatic reduction in piRNAs derived from major piRNA production clusters on chromosomes 2R and 4. Rhino protein localizes to distinct nuclear foci, and associates with the chromosome 2R and 4 clusters by chromatin immunoprecipitation. The Rhino HP1 homologue is therefore required for piRNA biogenesis, transposon silencing, and maintenance of germline genome integrity. RNA Small Interfering Drosophila Proteins Biogenesis Germ Cells Body Patterning Cell Cycle Proteins Mutation Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Embryonic Structures Genetic Phenomena
418	Os efeitos do ácido cafeico e do éster fenetil do ácido cafeico sobre as atividades da acetilcolinesterase e das ecto-nucleotidases em ratos / THE EFFECTS OF CAFFEIC ACID AND CAFFEIC ACID PHENETHYL ESTER ON THE ACTIVITIES OF ACETYLCHOLINESTERASE AND ECTO-NUCLEOTIDASES IN RATS Anwar, Javed 21 January 2013 (has links) Conselho Nacional de Desenvolvimento Científico e Tecnológico / Phenolic compouds and their derivatives constitute a leading family of natural compounds. Caffeic acid (CA) and caffeic acid phenethyl ester (CAPE) are the important members of phenolic compound, sharing several biological applications; antioxidant, neuroprotective, anti-inflammatory, antiproliferative, antibacterial, antiviral, antiatherosclerotic and anticancer properties. In spite of these, literature reportes some of its pro-oxidants activity depending on cellular environment. These pathophysiolocal properties increased the interest to evaluate the effect of CA and CAPE on the enzyme evolved in the purines salvage and the acetylcholine hydrolyzing enzyme the acetylcholineterase (AChE); in both PNS and CNS, since the essential constituent of our dietary items. Previously, our research group has reported that phenolic compound altered the activities of these enzymes. The AChE rapidly hydrolyzes the acetylcholine in neuronal and non neuronal tissues, mediating several neurodegenerative diseases. Beside the ACh, ATP (as co-neurotramittors) and adenosine are important signaling molecules, communicating cells in both PNS and CNS. In the extracellular signalling pathways; the adenine nucleotides, their derivative and the coupling of these molecules with specific receptor have a crucial role in nervous, vascular and immune systems. Once released, these molecules are hydrolyzed by a cascade of enzymes including ectonucleoside triphosphate diphosphohydrolase (NTPDase; E.C. 3.6.1.5, CD39), 5 -nucleotidase (E.C 3.1.3.5, CD73), ectonucleotide pyrophosphatase/phosphodiesterase (E-NPP), modulating crucially the signaling pathways in the normal functioning of nervous, vascular and immune systems. Next, adenosine deaminase (ADA) and xanthin oxidase (XO) degrade the adenosine and xanthine respectively which further control the functioning mechanisms in cellular events. Found in the neuronal and non neuronal (in both PNS and CNS) the AChE, NTPDase, 5'-nucleotidase, E-NPP, and ADA regulate several events including neurotransmission, inflammation, and thrombogenic process. We hypothesized to evaluate first the in vitro effects of CA on AChE activity in peripheral and central cholinergic system of rats. The results showed that CA significantly modulated the cholinergic system in vitro. By modulating the cholinergic system in vitro, apparently CA (e.g. phenolic structure) has proper role in neurotransmission. Therefore we hypothesizes to evaluate the in vivo effects of CA on AChE, NTPDase, E-NPP, 5'-nucleotidase, platelets aggregation and (ADA) in different tissues/cell from rats. The animals were treated during 30 days and killed after behavioral test. The results showed that caffeic acid increased significantly the AChE activity in hippocampus, hyphothalmus, pon and lymphocytes while that in cortex, cerebellum and striatum the AChE was inhibited. CA improves step-down latencies in the inhibitory avoidance. Investigating the in vivo effects of CA in purinergic system, caffecid acid increased the ATP and AMP hydrolysis in synaptosomes. However, in the synaptosomes no alterations were observed in the ADA activity in the groups evaluated in this study. CA increased the ATP and AMP hydrolysis, while the ADP hydrolysis was decreased in platelets. In the present findings caffeic acid decreased the platelets aggregation induced by ADP agonist. Treatment with CA also increased the NTPDase and ADA activities in lymphocytes of rats. Considering the dual function of caffeic acid in vitro and in vivo, the present study was extended to CAPE followed by acute treatment model (ip) in order to elucidate the effect of another phenolic structure on the same parameters. In this line the animals were treated (ip) with CAPE and killed after 40 minutes. In platelets, the results showed that the effect of CAPE increased the NTPDase, E-NPP, 5 -nucleotidase activities, while ADA activities did not change significantly. In synaptosomes CAPE significantly inhibited the NTPDase, and 5 -nucleotidase activity. CAPE induced no significant changes in ADA in synaptosomes but reduced XO in whole brain. Finaly we investigated the activity of AChE in cortex, cerebellum, striatum, hippocampus, hyphotalamus, pon, lymphocytes and muscules of rats treated with CAPE. The results showed that CAPE significantly decreased the AChE activity in cortex cerebellum and striatum. CAPE significantly increased the AChE activity in hippocampus hypothalamus, pons, muscle and lymphocytes. In cholinergic system our results clearly demonstrating that both compound with dual functions.These findings demonstrated that the AChE activities and the cascade of ecto-enzymes was alter in different tissues after treatment with CA and CAPE in rats, suggesting that these compound should be considered a potentially therapeutic agent in immune, vascular and neurological disorders related with the cholinergic purinergic system. / Os compostos fenólicos e seus derivados constituem uma importante família de compostos naturais. O ácido cafeico (AC) e o éster fenetil do ácido cafeico (CAPE) são membros importantes dessa família e compartilham algumas aplicações biológicas, tais como: antioxidante, neuroprotetor, antiinflamatório, antiproliferativo, antibacteriano, antiviral, antiaterosclerótico e anticancerígeno. Entretanto, a literatura relata algumas atividades pró-oxidantes, dependendo do ambiente celular. Devido a estas propriedades patofisiológicas, aumentou o interesse com o objetivo de avaliar o efeito de CA e CAPE sob as atividades das enzimas purinérgicas e da acetilcolinesterase (AChE), tanto no Sistema Nervoso Periférico (SNP) como no Sistema Nervoso Central (SNC). Previamente, nosso grupo de pesquisa relatou que o composto fenólico tem a capacidade de alterar as atividades dessas enzimas. A AChE rapidamente hidrolisa a acetilcolina (ACh) em tecidos neuronais e não neuronais, mediando algumas doenças neurodegenerativas. Ao lado da ACh, o ATP (como coneurotransmissor) e adenosina são importantes moléculas sinalizadoras, comunicando as células em ambos os SNP e do SNC. Nas vias de sinalização extracelulares, os nucleotídeos de adenina e seus derivados podem ser acoplados a receptores específicos e desse modo ter um papel crucial no sistema nervoso, sistema vascular e imune. Uma vez liberadas, estas moléculas são hidrolisadas por uma cascata de enzimas incluindo a ectonucleosídeo trifosfato difosfoidrolase (NTPDase; EC 3.6.1.5, CD39), 5'- nucleotidase (EC 3.1.3.5, CD73), ectonucleotideo pirofosfatase/fosfodiesterase (E-NPP), modulando definitivamente as vias de sinalização do funcionamento normal do sistema nervoso, sistema vascular e imune. Além disso, a adenosina deaminase (ADA) e a xantina oxidase (XO) degradam a adenosina e a xantina, respectivamente, as quais controlam o funcionamento de mecanismos em eventos celulares. As enzimas encontradas em tecidos neuronais e não neuronais como a AChE, a NTPDase, a 5'-nucleotidase, a E-NPP e a ADA regulam eventos celulares incluindo a neurotransmissão, inflamação e processos trombogênicos. Com essas informações, nós introduzimos a hipótese de avaliar primeiramente os efeitos in vitro de CA na atividade da AChE periférica e no sistema central colinérgico de ratos. Os resultados demonstraram que o CA modula significativamente o sistema colinérgico no estudo in vitro. Essa modulação demonstra aparentemente que o CA (estrutura fenólica) possui propriedades de ação que altera a neurotransmissão. Portanto, a hipótese de se avaliar os efeitos in vivo de CA na atividade da AChE, NTPDase, E-NPP, 5'-nucleotidase, ADA e da agregação de plaquetas em diferentes tecidos de ratos tornou-se evidente. Para esse estudo, os animais foram tratados durante 30 dias e sacrificados após o teste comportamental. Os resultados do experimento demonstraram que o CA aumentou significativamente a atividade da AChE em hipocampo, hipotálamo, ponte e nos linfócitos, enquanto que no córtex cerebral, cerebelo e estriado a AChE foi inibida. No teste comportamental o CA teve evolução de melhora na latência de passos da esquiva inibitória. A investigação dos efeitos in vivo do CA no sistema purinérgico demonstrou aumento na hidrólise de ATP e AMP em sinaptossomas. Entretanto, não foram observadas alterações significativas na atividade da ADA em sinaptossomas dos grupos avaliados neste estudo. Em plaquetas, o CA aumentou significativamente a hidrólise de ATP e AMP, enquanto que a hidrólise de ADP foi diminuída nesse tecido. No presente estudo o CA reduziu significativamente a agregação de plaquetas induzida pelo agonista ADP. Além disso, o tratamento com CA aumentou significativamente as atividades da NTPDase e da ADA em linfócitos de ratos. Considerando a dupla função de CA, in vitro e in vivo, o presente estudo foi estendido para CAPE seguindo o modelo de tratamento agudo pela via intraperitoneal (ip) com o objetivo de elucidar o efeito de uma segunda estrutura fenólica sobre os mesmos parâmetros. Nesta linha de pesquisa, os animais foram tratados ip com CAPE e eutanasiados após 40 minutos. Em plaquetas, os resultados demonstraram que o CAPE aumentou significativamente a atividade da NTPDase, E-NPP e 5'-nucleotidase, enquanto que a atividade da ADA não foi alterada significativamente. Em sinaptossomas, o CAPE inibiu significativamente a atividade da NTPDase e da 5'-nucleotidase. O CAPE não induziu alterações significativas na atividade da ADA em sinaptossomas, mas reduziu significativamente a atividade da XO em todo o cérebro. Finalmente, nós investigamos a atividade da AChE no córtex cerebral, cerebelo, estriado, hipocampo, hipotálamo, ponte, linfócitos e músculos de ratos tratados com CAPE. Os resultados demonstraram que CAPE diminuiu significativamente a atividade da AChE em córtex cerebral, cerebelo e estriado. O CAPE aumentou significativamente a atividade da AChE em hipotálamo, hipocampo, ponte, músculo e linfócitos. No sistema colinérgico, nossos resultados demonstram claramente que ambos os compostos possuem dupla função. Estes resultados demonstram que as atividades da AChE e da cascata das ecto-enzimas foram alteradas em diferentes tecidos após o tratamento com CA ou CAPE em ratos, sugerindo que estes compostos devem ser considerados agentes com potencial terapêutico em doenças imunes, vasculares e neurológicas relacionadas com o sistema colinérgico e purinérgico. Acetilcolinesterase Acetilcolina Nucleotídeo de adenina Ectonucleotidases Purinoreceptores Ácido cafeico Éster fenetil do ácido cafeico Actylcholinesterase Actylcholine Adenin nucleotides Ecto-nucleotidases Purinoreceptors Caffeic acid Caffeic acid phenethyl ester CNPQ::CIENCIAS BIOLOGICAS::BIOQUIMICA
419	CIS/SOCS Proteins in Growth Hormone Action: A Dissertation Du, Ling 01 October 2000 (has links) CIS/SOCS (cytokine-inducible SH2 protein/suppressor of cytokine signaling) are a family of proteins that are thought to act as negative regulators of signaling by erythropoetin, interleukin-6 and other cytokines whose receptors are related to the growth hormone receptor (GHR), and like growth hormone (GH), signal through the JAK/STAT pathway. We examined the possibility that CIS/SOCS proteins may also be involved in GH signaling, in particular, in termination of the transient insulin-like effects of GH. mRNAs for CIS, SOCS3, and to a lesser extent SOCS1 were detectable by Northern blot analysis of rat adipocyte total RNA, and the expression of CIS and SOCS3 was markedly increased 30 min after incubation with 500 ng/ml hGH. Both CIS and SOCS3 were detected in adipocyte extracts by immunoprecipitation and immunoblotting with their corresponding antisera. GH stimulated the tyrosine phosphorylation of a 120 kDa protein (p120) that was co-precipitated from adipocyte extracts along with αCIS and detected in Western blots with phospho-tyrosine antibodies. However, no tyrosine phosphorylated proteins in these cell extracts were immunoprecipitated with antibodies to CIS3/SOCS3. p120 was later identified as the GHR based on the observations that two GHR antibodies recognized p120 in scale-up experiments and that p120 and the GHR share several characteristics, including their molecular weights, tyrosine phosphorylation upon GH stimulation, interaction with CIS, similar extent of glycosylation as judged by electrophoretic mobility shift after Endo F digestion, comparable mobility shifts upon thrombin digestion, and N-terminal histidine-tagging. The findings, however, do not rule out the possibility that there might be other tyrosine phosphorylated 120 kDa protein(s) that interact with CIS and contribute to the p120 signal, as well as the GHR. Further studies of the association of CIS with the GHR revealed that CIS might selectively interact with multiply tyrosine phosphorylated forms of the GHR, and these tyrosines are likely located near the carboxyl end of the GHR. Overexpression of CIS partially inhibited GH-induced STAT5 phosphorylation in CHO cells. Studies in freshly isolated and GH-deprived (sensitive) adipocytes revealed that the abundance of CIS does not correlate with the termination of the insulin-like effects of GH or the emergence of refractoriness. Neither the association of CIS with the GHR nor the tyrosine phosphorylation status of the GHR, JAK2 and STAT5 appear responsible for refractoriness in adipocytes. These data imply that some negative regulators other than CIS might contribute to the termination of GH-induced insulin-like effects in adipocytes. Immediate-Early Proteins Human Growth Hormone Human Growth Hormone Cytokines Amino Acids, Peptides, and Proteins Animal Experimentation and Research Biological Factors Cells
420	Regulation of Contractility by Adenosine A<sub>1</sub> and A<sub>2A</sub> Receptors in the Murine Heart: Role of Protein Phosphatase 2A: A Dissertation Tikh, Eugene I. 21 June 2006 (has links) Adenosine is a nucleoside that plays an important role in the regulation of contractility in the heart. Adenosine receptors are G-protein coupled and those implicated in regulation of contractility are presumed to act via modulating the activity of adenylyl cyclase and cAMP content of cardiomyocytes. Adenosine A1 receptors (A1R) reduce the contractile response of the myocardium to β-adrenergic stimulation. This is known as anti adrenergic action. The A2A adenosine receptor (A2AR) has the opposite effect of increasing contractile responsiveness of the myocardium. The A2AR also appears to attenuate the effects of A1R. The effects of these receptors have been primarily studied in the rat heart and with the utilization of cardiomyocyte preparations. With the increasing use of receptor knockout murine models and murine models of various pathological states, it is of importance to comprehensively study the effects of adenosine receptors on regulation of contractility in the murine heart. The following studies examine the adenosinergic regulation of myocardial contractility in isolated murine hearts. In addition, adenosinergic control of contractility is examined in hearts isolated from A2AR knockout animals. Responses to adenosinergic stimulation in murine isolated hearts are found to be comparable to those observed in the rat, with A1R exhibiting an anti adrenergic action and A2AR conversely enhancing contractility. A significant part of the A2AR effect was found to occur via inhibition of the A1R antiadrenergic action. A part of the anti adrenergic action of A1R has previously been shown to be the result of protein phosphatase 2A activation and localization to membranes. Additional experiments in the present study examine the effect of adenosinergic signaling on PP2A in myocardial extracts from wild type and A2AR knockout hearts. A2AR activation was found to decrease the activity of PP2A and enhance localization of the active enzyme to the cytosol; away from its presumed sites of action. In the A2AR knockout the response to A1R activation was enhanced compared with the wild type and basal PP2A activity was reduced. It is concluded that A2AR modulation of PP2A activity may account for the attenuation of the A1R effect by A2AR observed in the contractile studies. Myocardial Contraction Receptor Adenosine A1 Receptor Adenosine A2A Adenosine Phosphoprotein Phosphatase Heart Mice Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cardiovascular System Circulatory and Respiratory Physiology Heterocyclic Compounds Physiology

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