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Contributions of TRPM4 and Rho Kinase to Myogenic Tone Development in Cerebral Parenchymal ArteriolesLi, Yao 01 January 2016 (has links)
Cerebral parenchymal arterioles (PAs) play a critical role in assuring appropriate blood flow and perfusion pressure within the brain. PAs are unique in contrast to upstream pial arteries, as defined by their critical roles in neurovascular coupling, distinct sensitivities to vasoconstrictors, and enhanced myogenic responsiveness. Dysfunction of these blood vessels is implicated in numerous cardiovascular diseases. However, treatments are limited due to incomplete understanding of the fundamental control mechanisms at this level of the circulation. One of the key elements within most vascular networks, including the cerebral circulation, is the presence of myogenic tone, an intrinsic process whereby resistance arteries constrict and reduce their diameter in response to elevated arterial pressure. This process is centrally involved in the ability of the brain to maintain nearly constant blood flow over a broad range of systemic blood pressures. The overall goal of this dissertation was to investigate the unique mechanisms of myogenic tone regulation in the cerebral microcirculation. To reveal the contributions of various signaling factors in this process, measurements of diameter, intracellular Ca2+ concentration ([Ca2+]i), membrane potential and ion channel activity were performed. Initial work determined that two purinergic G protein-coupled receptors, P2Y4 and P2Y6 receptors, play a unique role in mediating pressure-induced vasoconstriction of PAs in a ligand-independent manner. Moreover, a particular transient receptor potential (TRP) channel in the melastatin subfamily, i.e. TRPM4, was also identified as a mediator of PA myogenic responses. Notably, the observations that inhibiting TRPM4 channels substantially reduces P2Y receptor-mediated depolarization and vasoconstriction, and that P2Y receptor ligands markedly activate TRPM4 currents provide definitive evidence that this ion channel functions as an important link between mechano-sensitive P2Y receptor activation and the myogenic response in PAs. Next, the signaling cascades that mediate stretch-induced TRPM4 activation in PA myocytes were explored. Interestingly, these experiments determined that the RhoA/Rho kinase signaling pathway is involved in this mechanism by facilitating pressure-induced, P2Y receptor-mediated stimulation of TRPM4 channels, leading to subsequent smooth muscle depolarization, [Ca2+]i increase and contraction. Since Rho kinase is generally accepted as a 'Ca2+-sensitization' mediator, the present, contrasting observations point to an underappreciated role of RhoA/Rho kinase signaling in the excitation-contraction mechanisms within the cerebral microcirculation. Overall, this dissertation provides evidence that myogenic regulation of cerebral PAs is mediated by mechano-sensitive P2Y receptors, which initiate the RhoA/Rho kinase signaling pathway, subsequent TRPM4 channel opening, and concomitant depolarization and contraction of arteriolar smooth muscle cells. Revealing the unique mechanochemical coupling mechanisms in the cerebral microcirculation may lead to development of innovative therapeutic strategies for prevention and treatment of microvascular pathologies in the brain.
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Pharmacological and molecular characterisation of P2Y receptors in endothelial and epithelial cellsD'Souza, Vijay Kenneth January 2007 (has links)
In light of the significant modulation of receptor activity previously shown by a peptide (designated L247), designed to mimic the third extracellular loop of the human P2Y2 receptor, the aim of this study was to use this peptide as an immunogen to generate and fully characterise polyclonal rabbit antibodies to the P2Y2 receptor. Other aims of this study were to characterise epithelial and endothelial cells for a thorough expression profile of P2Y receptor mRNA transcripts in order to provide a rapid screen for the molecular determinants of these receptors in these cells. These studies also aimed to confirm previously published pharmacology, thus, to set the basis for western blot studies using P2Y receptor antibodies. Bovine aortic endothelial cells that co-express P2Y1 and P2Y2 receptors; EAhy926, a human endothelial fusion cell line, that express P2Y2 receptors; and ECV304 human bladder cancer cell line, known to express P2Y2-like and P2Y11-like receptors were used in this study. The dose dependent accumulation of inositol phosphates and cAMP response to potent P2Y11 agonists and RT-PCR studies confirmed the functional expression of both P2Y2 and P2Y11 receptors in ECV304 cells. Likewise, the dose dependent accumulation of inositol phosphates in response to potent P2Y2 and P2Y6 agonists and the presence of mRNA transcripts confirmed the expression of functional P2Y2/4- like and P2Y6- like receptors in EAhy926 cells. Polyclonal antiserum raised against L247 peptide was affinity purified and the purified fractions showed strong immunoreactivity with immobilised immunogenic antigen in ELISA. In western blot analysis L247 rabbit polyclonal anti-P2Y2 antibody detected strong bands in ECV304 and EAhy926 cells. On pre-absorption with the immunogenic peptide these responses were abolished suggesting that this antibody is antigen specific. Agonist induced P2Y2 receptor desentisation studies in ECV304 cells showed that prolonged agonist incubation caused the receptor sequestration. The loss of bands caused by P2Y2 receptor desensitisation and sequestration in membrane enriched fractions of agonist incubated ECV304 cells confirmed the specificity of L247 antibody. This antibody also showed no immunoreactivity in 1321N1 human brain astrocytoma cells devoid of any P2Y receptor subtypes cells. Deglycosylation studies revealed that the P2Y2 receptors are glycosylated in ECV304 cells. The polyclonal rabbit anti-P2Y2 receptor antibodies obtained from commercial sources produced completely different immunoreactive profiles with multiple bands even in 1321N1 cells. Furthermore, in comparison to L247 anti-P2Y2 antibody the commercial antibody showed no difference between normal and agonist incubated cells suggesting that this antibody may not be recognising the P2Y2 receptors in ECV304 cells. Likewise polyclonal rabbit antibodies to other P2Y receptors either showed no response or showed strong immunoreactive profile with multiple bands even in 1321N1 cells suggesting that these antibodies may not have been extensively characterized. Furthermore, immunofluorescence studies with commercial anti-P2Y2 antibodies showed that they may be only recognising non-denatured receptors. These studies suggest that the L247 anti-P2Y2 antibody raised against peptide designed to mimic specific region in the third extracellular loop of human P2Y2 receptor is highly specific and sensitive and provides an important tool to study endogenously expressed P2Y2 receptors in both non-denatured and denatured state. These studies indicate that this strategy of generating antibodies may be used to generate highly specific antibodies to other P2Y receptor subtypes.
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Regulatory Functions of the Juxtaglomerular ApparatusLiu, Ruisheng January 2002 (has links)
<p>The tubuloglomerular feedback mechanism is an important regulator in the juxtaglomerular apparatus and it detects flow dependent alterations in luminal NaCl concentration ([NaCl]) at the macula densa (MD) cell site via a Na+-K+-2Cl cotransporter. Signals are sent by the MD to adjust the afferent arteriole tone and altering release of renin. This signaling mechanism is unclear but MD cell calcium concentration, release of ATP and nitric oxide (NO) might be important.</p><p>In cultured rat glomerular mesangial cells the NO production was measured using confocal microscopy and calcium responses to ATP was measured with fura-2 using imaging techniques. NO from spermine-NONOate and L-arginine could resensitize, desensitized ATP receptors in a cGMP independent way. In mesangial cells from spontaneously hypertensive rats (SHR) less NO effect was found on ATP receptor de/resensitization indicating an impaired NO release or effect.</p><p>The macula densa cells were studied using microperfusion techniques with confocal and video imaging systems. Changes in [Ca2+]i from exposed macula densa plaques were assessed upon addition of agonists added to bath. The order of efficacy of agonists was UTP = ATP >> 2MesATP = ADP. Dose response curve for ATP added in bath showed an EC50 of 15 μM. Macula densa cell volume and NO concentration increased considerably with increasing luminal [NaCl] indicating an important role for NO in the signaling process to counteract a vasoconstrictor response and reset the sensitivity of the tubuloglomerular feedback mechanism. </p><p>In conclusion, the results showed 1). NO can increase the P2Y receptor resensitization in rat glomerular mesangial cells, acting through a cGMP-independent pathway. 2) An impaired NO generation/effect on P2Y receptors in mesangial cells from SHR rats. 3) Macula densa cells possess P2Y2, purinergic receptors on basolateral and that activation of these receptors results in the mobilization of Ca2+. 4) Increased luniinal [NaCl] delivery increased cell volume and the NO productions in the macula densa cells. </p>
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Regulatory Functions of the Juxtaglomerular ApparatusLiu, Ruisheng January 2002 (has links)
The tubuloglomerular feedback mechanism is an important regulator in the juxtaglomerular apparatus and it detects flow dependent alterations in luminal NaCl concentration ([NaCl]) at the macula densa (MD) cell site via a Na+-K+-2Cl cotransporter. Signals are sent by the MD to adjust the afferent arteriole tone and altering release of renin. This signaling mechanism is unclear but MD cell calcium concentration, release of ATP and nitric oxide (NO) might be important. In cultured rat glomerular mesangial cells the NO production was measured using confocal microscopy and calcium responses to ATP was measured with fura-2 using imaging techniques. NO from spermine-NONOate and L-arginine could resensitize, desensitized ATP receptors in a cGMP independent way. In mesangial cells from spontaneously hypertensive rats (SHR) less NO effect was found on ATP receptor de/resensitization indicating an impaired NO release or effect. The macula densa cells were studied using microperfusion techniques with confocal and video imaging systems. Changes in [Ca2+]i from exposed macula densa plaques were assessed upon addition of agonists added to bath. The order of efficacy of agonists was UTP = ATP >> 2MesATP = ADP. Dose response curve for ATP added in bath showed an EC50 of 15 μM. Macula densa cell volume and NO concentration increased considerably with increasing luminal [NaCl] indicating an important role for NO in the signaling process to counteract a vasoconstrictor response and reset the sensitivity of the tubuloglomerular feedback mechanism. In conclusion, the results showed 1). NO can increase the P2Y receptor resensitization in rat glomerular mesangial cells, acting through a cGMP-independent pathway. 2) An impaired NO generation/effect on P2Y receptors in mesangial cells from SHR rats. 3) Macula densa cells possess P2Y2, purinergic receptors on basolateral and that activation of these receptors results in the mobilization of Ca2+. 4) Increased luniinal [NaCl] delivery increased cell volume and the NO productions in the macula densa cells.
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Lipid Signalling Dynamics in Insulin-secreting β-cellsWuttke, Anne January 2013 (has links)
Certain membrane lipids are involved in intracellular signalling processes, among them phosphoinositides and diacylglycerol (DAG). They mediate a variety of functions, including the effects of nutrients and neurohormonal stimuli on insulin secretion from pancreatic β-cells. To ensure specificity of the signal, their concentrations are maintained under tight spatial and temporal control. Here, live-cell imaging techniques were employed to investigate spatio-temporal aspects of lipid signalling in the plasma membrane of insulin-secreting β-cells. The concentration of phosphatidylinositol 4-phosphate [PtdIns(4)P] increased after stimulation with glucose or Gq protein-coupled receptor agonists. The glucose effect was Ca2+-dependent, whereas the receptor response was mediated by isoforms of novel protein kinase C (PKC). The increases in PtdIns(4)P were paralleled by lowerings of the phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] concentration. This relationship was not caused by conversion of PtdIns(4,5)P2 to PtdIns(4)P but rather reflected independent regulation of the two lipids. Stimulation of β-cells with glucose or a high K+ concentration induced pronounced, repetitive increases in plasma-membrane DAG concentration, which were locally restricted and lasted only for a few seconds. This pattern was caused by exocytotic release of ATP, which feedback-activates purinergic P2Y1-receptors and stimulates local phospholipase C-mediated DAG generation. Despite their short durations the DAG spikes triggered local activation of PKC. Novel PKCs were recruited to the plasma membrane both after glucose and muscarinic receptor stimulation. While the glucose-induced translocation was synchronized with DAG spiking, muscarinic stimulation induced sustained elevation of the DAG concentration and stable membrane association of the kinase. Also conventional PKCs translocated to the membrane after glucose and receptor stimulation. The glucose-induced response was complex with sustained membrane association mirroring the cytoplasmic Ca2+ concentration, and superimposed brief recurring translocations caused by DAG. Interruption of the purinergic feedback loop underlying DAG spiking suppressed insulin secretion. Since the DAG spikes reflected exocytosis events, a single-cell secretion assay was established, which allowed continuous recording of secretion dynamics from many cells in parallel over extended periods of time. With this approach it was possible to demonstrate that insulin exerts negative feedback on its own release via a phosphatidylinositol 3,4,5-trisphosphate-dependent mechanism.
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Die Beteiligung von Purinnukleotiden an der Modulation des Angstverhaltens via Stimulation von P2Y1-Rezeptoren bei der Ratte untersucht im elevated plus-maze ModellSchultheis, Nina 13 December 2010 (has links) (PDF)
Die hohe Dichte und breite Verteilung von P2Y-Rezeptoren im Hirn von Säugetieren lässt für diese Rezeptoren eine wichtige Rolle in den Prozessen des zentralen Nervensystems vermuten. Um die Beteiligung von P2Y-Rezeptoren bei der Verarbeitung von Angst zu untersuchen, wurde in dieser Arbeit das P2Y1,11,12,13 -rezeptorspezifische ADP-Analogon Adenosin-5\'-O-2-thiodiphosphat (ADPßS), der P2X1,3-Rezeptoragonist a,b-methylen-ATP (a,bmeATP), der unspezifische P2-Rezeptorantagonist Pyridoxalphosphat-6-azophenyl-2’,4’-disulfonat (PPADS) und der spezifische P2Y1-Rezeptorantagonist N6-methyl-2’-deoxyadenosin-3’:5’bisphosphat (MRS 2179) Ratten intracerebroventrikulär injiziert und die Wirkung in einem Verhaltensversuch im standardisierten Angstmodell des elevated plus-maze untersucht. Die Substanzen wurden zu 0,5 μl verabreicht. ADPßS (50 fmol und 500 fmol) zeigte dabei anxiolytische Wirkung mit vermehrten Eintritten und gesteigerter Aufenthaltszeit der Tiere auf den offenen Armen. Eine Prämedikation mit PPADS (5 pmol) oder MRS 2179 (5 pmol) konnte diesen Effekt vollständig antagonisieren. Auch eine Vorbehandlung durch den unspezifischen NO-Synthase-Inhibitor Nw-nitro-L-arginin-methyl-ester (L-NAME) konnte die ADPβS-Wirkung verhindern. Bei alleiniger Gabe zeigten diese drei Substanzen anxiogene Wirkung mit einer verminderten Aufenthaltszeit und einer geringeren Zahl von Eintritten in die offenen Armen. Der anxiogene Effekt konnte wiederum durch eine Gabe von L-Arginin (500 pmol), einem Substrat der NO-Synthase (NOS), verhindert werden, nicht aber durch das Enantiomer D-Arginin (500 pmol), das kein Substrat der NOS darstellt.
Die doppelte Immunfluoreszenz konnte die Präsenz der P2Y1-Rezeptoren an Neuronen in dorsomedialen Hypothalamus, Amygdala, Hippokampus und zentralen Höhlengrau wie auch die Kolokalisation von P2Y1-Rezeptoren und nNOS nachweisen. Die höchste Dichte an Immunoreaktivität fand sich im dorsomedialen Hypothalamus. Durch die lokale bilaterale Mikroinjektion von ADPßS und MRS 2179 konnten die in den vorausgegangen Versuchen erreichten Ergebnisse reproduziert und bestätigt werden.
Zusammenfassend lässt sich postulieren, dass P2Y1-Rezeptoren maßgeblich an der Verarbeitung von Angst bei männlichen Wistar-Ratten beteiligt sind, die Wirkung eng mit der Veränderung der NO-Konzentration verbunden ist und dass diese im dorsomedialen Hypothalamus vermittelt wird. Inwieweit diese Mechanismen auch in Amygdala und Hippokampus eine Rolle spielen kann mit den vorliegenden Daten nicht abschließend beantwortet werden.
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Local Purinergic Control of Arteriolar Reactivity in Pancreatic Islets and Renal GlomeruliGao, Xiang January 2014 (has links)
Local control of regional blood flow is exerted mainly through the arterioles. An adequate minute-to-minute regulation of blood perfusion of the kidney and the pancreas is obtained by the modulation of arteriolar reactivity, which will influence the organ function. The importance of purinergic signaling in this concept has been addressed, with special emphasis on the role of the adenosine A1 receptor. The effects of adenosine on two specialized vascular beds, namely the renal glomerulus and the pancreatic islets, have been examined. Characteristic for these regional circulations is their very high basal blood flow, but with somewhat different responses to vasoconstrictor and vasodilator stimuli. By adapting a unique microperfusion technique it was possible to separately perfuse isolated single mouse arterioles with attached glomeruli or pancreatic islets ex vivo. Microvascular responses were investigated following different additions to the perfusion fluid to directly examine the degree of dilation or constriction of the arterioles. This has been performed on transgenic animals in this thesis, e.g. A1 receptor knockout mice. Also effects of P2Y receptors on islet arterioles were examined in both normoglycemic and type 2 diabetic rats. Furthermore, interference with adenosine transport in glomerular arterioles were examined.. Our studies demonstrate important, yet complex, effects of adenosine and nucleotide signaling on renal and islet microvascular function, which in turn may influence both cardiovascular and metabolic regulations. They highlight the need for further studies of other purinergic receptors in this context, studies that are at currently being investigated.
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Die Beteiligung von Purinnukleotiden an der Modulation des Angstverhaltens via Stimulation von P2Y1-Rezeptoren bei der Ratte untersucht im elevated plus-maze ModellSchultheis, Nina 28 October 2010 (has links)
Die hohe Dichte und breite Verteilung von P2Y-Rezeptoren im Hirn von Säugetieren lässt für diese Rezeptoren eine wichtige Rolle in den Prozessen des zentralen Nervensystems vermuten. Um die Beteiligung von P2Y-Rezeptoren bei der Verarbeitung von Angst zu untersuchen, wurde in dieser Arbeit das P2Y1,11,12,13 -rezeptorspezifische ADP-Analogon Adenosin-5\''-O-2-thiodiphosphat (ADPßS), der P2X1,3-Rezeptoragonist a,b-methylen-ATP (a,bmeATP), der unspezifische P2-Rezeptorantagonist Pyridoxalphosphat-6-azophenyl-2’,4’-disulfonat (PPADS) und der spezifische P2Y1-Rezeptorantagonist N6-methyl-2’-deoxyadenosin-3’:5’bisphosphat (MRS 2179) Ratten intracerebroventrikulär injiziert und die Wirkung in einem Verhaltensversuch im standardisierten Angstmodell des elevated plus-maze untersucht. Die Substanzen wurden zu 0,5 μl verabreicht. ADPßS (50 fmol und 500 fmol) zeigte dabei anxiolytische Wirkung mit vermehrten Eintritten und gesteigerter Aufenthaltszeit der Tiere auf den offenen Armen. Eine Prämedikation mit PPADS (5 pmol) oder MRS 2179 (5 pmol) konnte diesen Effekt vollständig antagonisieren. Auch eine Vorbehandlung durch den unspezifischen NO-Synthase-Inhibitor Nw-nitro-L-arginin-methyl-ester (L-NAME) konnte die ADPβS-Wirkung verhindern. Bei alleiniger Gabe zeigten diese drei Substanzen anxiogene Wirkung mit einer verminderten Aufenthaltszeit und einer geringeren Zahl von Eintritten in die offenen Armen. Der anxiogene Effekt konnte wiederum durch eine Gabe von L-Arginin (500 pmol), einem Substrat der NO-Synthase (NOS), verhindert werden, nicht aber durch das Enantiomer D-Arginin (500 pmol), das kein Substrat der NOS darstellt.
Die doppelte Immunfluoreszenz konnte die Präsenz der P2Y1-Rezeptoren an Neuronen in dorsomedialen Hypothalamus, Amygdala, Hippokampus und zentralen Höhlengrau wie auch die Kolokalisation von P2Y1-Rezeptoren und nNOS nachweisen. Die höchste Dichte an Immunoreaktivität fand sich im dorsomedialen Hypothalamus. Durch die lokale bilaterale Mikroinjektion von ADPßS und MRS 2179 konnten die in den vorausgegangen Versuchen erreichten Ergebnisse reproduziert und bestätigt werden.
Zusammenfassend lässt sich postulieren, dass P2Y1-Rezeptoren maßgeblich an der Verarbeitung von Angst bei männlichen Wistar-Ratten beteiligt sind, die Wirkung eng mit der Veränderung der NO-Konzentration verbunden ist und dass diese im dorsomedialen Hypothalamus vermittelt wird. Inwieweit diese Mechanismen auch in Amygdala und Hippokampus eine Rolle spielen kann mit den vorliegenden Daten nicht abschließend beantwortet werden.
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