Global ETD Search

1	Étude de la régulation des canaux potassiques ROMK1 par un antidiabétique, la rosiglitazone implication des PPARgamma Ait Benichou, Siham January 2011 (has links) Les thiazolidinediones (TZDs) sont des médicaments antidiabétiques (agonistes des récepteurs nucléaires de type PPAR[gamma]) utilisés au cours des dix dernières années pour le traitement du diabète de type II. Malheureusement leur utilisation peut provoquer, chez certains patients, une rétention accrue de fluides et une formation d?oedèmes rénaux. Des études récentes suggèrent l'implication d'un canal sodique épithélial (ENaC), exprimé au niveau du tubule collecteur rénal, dans ces effets secondaires. En effet, la stimulation des PPAR[gamma] par les TZDs activent les canaux sodiques épithéliaux probablement via l'expression et l'activation de SGK1 (Serum and Glucocorticoid-regulated Kinase 1). Sachant que les transports des ions sodiques et potassiques sont étroitement liés au niveau rénal, notre objectif est de déterminer si les TZDs seraient impliqués dans la régulation des canaux potassiques (ROMK1). Nous montrons qu'en traitant les ovocytes de xénopes exprimant ROMK et PPAR[gamma], avec un TZDs comme la rosiglitazone (RGZ), le courant potassique mesuré par voltage-clamp (TEVC) est augmenté de deux fois. Cette augmentation est bloquée par l'utilisation d'un antagoniste de PPAR[gamma], le GW9662. Nous démontrons aussi l'implication de SGK1 dans la régulation de l'activité des canaux ROMK1 d'une part en mutant son site de phosphorylation sur ROMK1 (sérine 44) et d'autre part en utilisant son inhibiteur, GSK. Finalement les expériences d'immunofluorescences ont montré un recrutement de ROMK1 à la membrane des ovocytes traités à la RGZ. L'ensemble des données présentées dans ce travail suggère que la RGZ augmente le courant potassique en augmentant l'expression de SGK1. Xenopus laevis Oocyte Rosiglitazone SGK1 PPAR[gamma] ROMK1
2	The signalling pathways allowing hormonal regulation of Na+ transport in murine collecting duct cells Mansley, Morag K. January 2010 (has links) The collecting duct of the distal nephron marks the final location where adjustments to Na+ excretion can be made, therefore determining the final concentration of Na+ conserved in the extracellular fluid which plays a role in governing overall blood volume and pressure. This transport of Na+ is subject to hormonal regulation but the signalling pathways underpinning this regulation however, are not fully understood. In this thesis the signalling pathways allowing both basal and insulin-stimulated Na+ absorption were explored in the murine collecting duct cell line, mpkCCDcl4. The effects of two insulin-sensitizing drugs, TZDs, on ENaC-mediated Na+ transport were investigated and the signalling pathways underlying two other hormonal regulators of ENaC, dexamethasone and vasopressin, were also examined. Unstimulated monolayers of mpkCCDcl4 cells generated spontaneous Na+ absorption which was quantified by measuring equivalent short circuit current (Ieq). Selective inhibition of PI3-kinase, mTORC2 and SGK1 left ~80 % of the current intact, indicating these signalling molecules are not required for basal Na+ transport. Acute addition of insulin stimulated Ieq and this occurred with a concomitant increase in mTORC2, SGK1 and Akt activity. Inhibition of PI3-kinase abolished the insulin-stimulated response as well as phosphorylation of downstream substrates, indicating a crucial role of PI3-kinase. Inhibition of mTORC1 with rapamycin did not alter basal or insulin-stimulated Na+ transport. The mTOR inhibitors TORIN1 and PP242 could therefore be used to evaluate the role of mTORC2. These inhibitors greatly reduced insulin-stimulated ENaC-mediated Na+ transport and also abolished SGK1 and mTORC2 activity, indicating a novel role of mTORC2. An inhibitor of SGK1, GSK650394A abolished insulin-stimulated Na+ transport and specifically inhibited SGK1 acitivty demonstrating the importance of SGK1 in insulin signalling. The inhibitor Akti-1/2 also abolished insulin-mediated Na+ transport but this compound inhibited both Akt and SGK1 activity. The TZDs pioglitazone and rosiglitazone did not alter basal or insulin-stimulated Na+ transport and had no effect on SGK1 activity indicating these drugs do not alter Na+ absorption in this cell line. Dexamethasone stimulated ENaC-mediated Na+ transport in a similar manner to insulin and this could be blocked with rapamycin. This drug did not alter phosphorylation of NDRG1 indicating that dexamethasone stimulates Na+ transport in an mTORC1-dependent manner but without altering SGK1 activity. Arginine vasopressin also stimulated Ieq but did so by reducing Rt with an associated depolarisation of Vt. Ieq could be blocked with amiloride and vasopressin-stimulated Ieq was insensitive to TORIN1 and PP242. Vasopressin suppressed SGK1 phosphorylation of NDRG1 but did stimulate protein kinase A (PKA) activity. Therefore vasopressin stimulates Ieq via a PKA-dependent but mTOR- and SGK1-independent pathway. 573.4
3	Epithelial Sodium Channels in the Brain: Effect of High Salt Diet on Their Expression Amin, Md. Shahrier 28 June 2011 (has links) Statement of the problem: The epithelial sodium channels (ENaC) play an important role in regulation of blood pressure (BP). Although the genes are identical in Dahl salt sensitive (S) and Dahl salt resistant (R) rats, expression of ENaC subunits is increased in kidneys of S rats on high salt diet. Intracerebroventricular (icv) infusion of ENaC blocker benzamil prevents Na+ induced hypertension. It was not known whether ENaC subunits are expressed in the brain and whether or not brain ENaC plays a role in regulation of [Na+] in CNS. Hypothesis: 1. Epithelial sodium channels are expressed in the brain. 2. Expression of ENaC is increased in the kidneys and brain of Dahl S rats on high salt diet. 3. ENaC in the brain contributes to regulation of [Na+] in the CSF and brain interstitium. Methods of investigation: We studied expression and distribution of the ENaC subunits and assessed the effects of icv infusion of Na+-rich aCSF in Wistar rats or high salt diet in Dahl S rats in different areas of the brain. Function of ENaC in the choroid plexus was evaluated by studying the effects of benzamil and ouabain on Na+ transport. Major findings: In Wistar rats, both mRNA and protein of all three ENaC subunits are expressed in brain epithelia and magnocellular neurons in the supraoptic (SON) and paraventricular (PVN) nucleus. ENaC abundance is higher on the apical versus basolateral membrane of choroid cells. Benzamil decreases Na+ influx into choroid cells by 20-30% and increases CSF [Na+] by ~8 mmol/L. Na+ rich aCSF increases apical membrane expression of βENaC in the choroid cells and of α and βENaC in basolateral membrane of ependymal cells, but has no effect on neuronal ENaC. Expression of ENaC is higher in choroid cells and SON of Dahl S versus R rats and the higher expression persists on a high salt diet. High salt attenuates the ouabain blockable efflux of Na+ from choroid cells and has no effect on CSF [Na+] in Dahl R rats. In contrast, high salt does not attenuate ouabain blockable efflux of 22Na+ and CSF [Na+] increases in Dahl S. Main Conclusion: ENaC in the brain contributes to Na+ transport into the choroid cells and appear to be involved in reabsorption of Na+ from the CSF. Aberrant regulation of Na+ transport and of Na+K+ATPase activity, might contribute to increases in CSF [Na+] in Dahl S rats on high-salt diet. ENaC in magnocellular neurons may contribute to enhanced secretion of mediators such as ‘ouabain’ leading to sympathetic hyperactivity in Dahl S rats. Epithelial sodium channel Brain Kidney Salt sensitive hypertension Mineralocorticoid receptor SGK1
4	Epithelial Sodium Channels in the Brain: Effect of High Salt Diet on Their Expression Amin, Md. Shahrier 28 June 2011 (has links) Statement of the problem: The epithelial sodium channels (ENaC) play an important role in regulation of blood pressure (BP). Although the genes are identical in Dahl salt sensitive (S) and Dahl salt resistant (R) rats, expression of ENaC subunits is increased in kidneys of S rats on high salt diet. Intracerebroventricular (icv) infusion of ENaC blocker benzamil prevents Na+ induced hypertension. It was not known whether ENaC subunits are expressed in the brain and whether or not brain ENaC plays a role in regulation of [Na+] in CNS. Hypothesis: 1. Epithelial sodium channels are expressed in the brain. 2. Expression of ENaC is increased in the kidneys and brain of Dahl S rats on high salt diet. 3. ENaC in the brain contributes to regulation of [Na+] in the CSF and brain interstitium. Methods of investigation: We studied expression and distribution of the ENaC subunits and assessed the effects of icv infusion of Na+-rich aCSF in Wistar rats or high salt diet in Dahl S rats in different areas of the brain. Function of ENaC in the choroid plexus was evaluated by studying the effects of benzamil and ouabain on Na+ transport. Major findings: In Wistar rats, both mRNA and protein of all three ENaC subunits are expressed in brain epithelia and magnocellular neurons in the supraoptic (SON) and paraventricular (PVN) nucleus. ENaC abundance is higher on the apical versus basolateral membrane of choroid cells. Benzamil decreases Na+ influx into choroid cells by 20-30% and increases CSF [Na+] by ~8 mmol/L. Na+ rich aCSF increases apical membrane expression of βENaC in the choroid cells and of α and βENaC in basolateral membrane of ependymal cells, but has no effect on neuronal ENaC. Expression of ENaC is higher in choroid cells and SON of Dahl S versus R rats and the higher expression persists on a high salt diet. High salt attenuates the ouabain blockable efflux of Na+ from choroid cells and has no effect on CSF [Na+] in Dahl R rats. In contrast, high salt does not attenuate ouabain blockable efflux of 22Na+ and CSF [Na+] increases in Dahl S. Main Conclusion: ENaC in the brain contributes to Na+ transport into the choroid cells and appear to be involved in reabsorption of Na+ from the CSF. Aberrant regulation of Na+ transport and of Na+K+ATPase activity, might contribute to increases in CSF [Na+] in Dahl S rats on high-salt diet. ENaC in magnocellular neurons may contribute to enhanced secretion of mediators such as ‘ouabain’ leading to sympathetic hyperactivity in Dahl S rats. Epithelial sodium channel Brain Kidney Salt sensitive hypertension Mineralocorticoid receptor SGK1
5	Mechanisms of Methylglyoxal-elicited Leukocyte Recruitment 2014 June 1900 (has links) Methylglyoxal (MG) is a reactive dicarbonyl metabolite formed during glucose, protein and fatty acid metabolism. In hyperglycemic conditions, an increased MG level has been linked to the development of diabetes and the accompanying vascular inflammation encountered at both macro- and microvascular levels. The present study explores the mechanisms of MG-induced leukocyte recruitment in mouse cremasteric microvasculature. Biochemical and intravital microscopy studies performed suggest that administration of MG (25 and 50 mg/kg) to mouse cremaster muscle tissue induces dose-dependent leukocyte recruitment in cremasteric vasculature with 84-92% recruited cells being neutrophils. MG treatment up-regulated the expression of endothelial cell (EC) adhesion molecules P-selectin, E-selectin and intercellular adhesion molecule-1 (ICAM-1) via the activation of nuclear factor-κB (NF-κB) signalling pathway and contributed to the increased leukocyte rolling flux, reduced leukocyte rolling velocity, and increased leukocyte adhesion, respectively. The inhibition of NF-κB blunted MG-induced endothelial adhesion molecule expression and thus attenuated leukocyte recruitment. Further study of signalling pathways revealed that MG induced Akt-regulated transient glycogen synthase kinase 3 (GSK3) activation in ECs, which was responsible for NF-κB activation at early time-points (< 1 h). After MG activation for 1 h, the endothelial GSK3 activity was decreased due to the up-regulation of serum- and glucocorticoid-regulated kinase 1 (SGK1), which was responsible for maintaining NF-κB activity at later time-points. Silencing GSK3 or SGK1 attenuated P-selectin, E-selectin and ICAM-1 expression in ECs, and abated MG-induced leukocyte recruitment. SGK1 also promoted cyclic adenosine monophosphate (cAMP) response element-binding protein (CREB) activity which was partially involved in ICAM-1 expression. Silencing CREB blunted ICAM-1 expression while P-selectin and E-selectin levels remained unaffected. MG also induced GSK3 activation in isolated neutrophils after 30 min treatment, an effect that was not responsible for MG-elicited Mac-1 expression. These data suggest the sequential activation of GSK3 and SGK1 in ECs as the pivotal signalling mechanism in MG-elicited leukocyte recruitment. Additionally, MG-treatment led to uncoupling of endothelial nitric oxide synthase (eNOS) following MG-induced superoxide generation in ECs. MG triggered eNOS uncoupling and hypophosphorylation associated with superoxide generation and biopterin depletion in EA.hy926 ECs. In cremaster muscle, as well as in cultured murine and human primary ECs, MG increased eNOS monomerization and decreased 5,6,7,8-tetrahydroboipterin (BH4)/total biopterin ratio, effects that were significantly mitigated by supplementation of BH4 or its precursor sepiapterin but not by NG-nitro-L-arginine methyl ester (L-NAME) or 5,6,7,8-tetrahydroneopterin (NH4). These observations confirm that MG administration triggers eNOS uncoupling. In murine cremaster muscle, MG triggered the reduction of leukocyte rolling velocity and the increases in rolling flux, adhesion, emigration and microvascular permeability. MG-induced leukocyte recruitment was significantly attenuated by supplementation of BH4 or sepiapterin or suppression of superoxide by L-NAME confirming the role of eNOS uncoupling in MG-elicited leukocyte recruitment. MG treatment further decreased the expression of guanosine triphosphate cyclohydrolase I in murine primary ECs, suggesting the impaired BH4 biosynthesis caused by MG. Taken together, these data suggest that vascular inflammation and endothelial dysfunction occurring in diabetes may be linked to GSK3/SGK1 regulated adhesion molecule expression, as well as the uncoupling of eNOS evoked by elevated levels of MG. These findings not only provide a better understanding of the role of MG in the development of diabetic vascular inflammation, but also suggest the potential therapeutic targets for MG-sensitive endothelial dysfunction in diabetes. Methylglyoxal Leukocyte recruitment Endothelial cell GSK3 SGK1 eNOS uncoupling NF-kB
6	Epithelial Sodium Channels in the Brain: Effect of High Salt Diet on Their Expression Amin, Md. Shahrier 28 June 2011 (has links) Statement of the problem: The epithelial sodium channels (ENaC) play an important role in regulation of blood pressure (BP). Although the genes are identical in Dahl salt sensitive (S) and Dahl salt resistant (R) rats, expression of ENaC subunits is increased in kidneys of S rats on high salt diet. Intracerebroventricular (icv) infusion of ENaC blocker benzamil prevents Na+ induced hypertension. It was not known whether ENaC subunits are expressed in the brain and whether or not brain ENaC plays a role in regulation of [Na+] in CNS. Hypothesis: 1. Epithelial sodium channels are expressed in the brain. 2. Expression of ENaC is increased in the kidneys and brain of Dahl S rats on high salt diet. 3. ENaC in the brain contributes to regulation of [Na+] in the CSF and brain interstitium. Methods of investigation: We studied expression and distribution of the ENaC subunits and assessed the effects of icv infusion of Na+-rich aCSF in Wistar rats or high salt diet in Dahl S rats in different areas of the brain. Function of ENaC in the choroid plexus was evaluated by studying the effects of benzamil and ouabain on Na+ transport. Major findings: In Wistar rats, both mRNA and protein of all three ENaC subunits are expressed in brain epithelia and magnocellular neurons in the supraoptic (SON) and paraventricular (PVN) nucleus. ENaC abundance is higher on the apical versus basolateral membrane of choroid cells. Benzamil decreases Na+ influx into choroid cells by 20-30% and increases CSF [Na+] by ~8 mmol/L. Na+ rich aCSF increases apical membrane expression of βENaC in the choroid cells and of α and βENaC in basolateral membrane of ependymal cells, but has no effect on neuronal ENaC. Expression of ENaC is higher in choroid cells and SON of Dahl S versus R rats and the higher expression persists on a high salt diet. High salt attenuates the ouabain blockable efflux of Na+ from choroid cells and has no effect on CSF [Na+] in Dahl R rats. In contrast, high salt does not attenuate ouabain blockable efflux of 22Na+ and CSF [Na+] increases in Dahl S. Main Conclusion: ENaC in the brain contributes to Na+ transport into the choroid cells and appear to be involved in reabsorption of Na+ from the CSF. Aberrant regulation of Na+ transport and of Na+K+ATPase activity, might contribute to increases in CSF [Na+] in Dahl S rats on high-salt diet. ENaC in magnocellular neurons may contribute to enhanced secretion of mediators such as ‘ouabain’ leading to sympathetic hyperactivity in Dahl S rats. Epithelial sodium channel Brain Kidney Salt sensitive hypertension Mineralocorticoid receptor SGK1
7	Epithelial Sodium Channels in the Brain: Effect of High Salt Diet on Their Expression Amin, Md. Shahrier January 2011 (has links) Statement of the problem: The epithelial sodium channels (ENaC) play an important role in regulation of blood pressure (BP). Although the genes are identical in Dahl salt sensitive (S) and Dahl salt resistant (R) rats, expression of ENaC subunits is increased in kidneys of S rats on high salt diet. Intracerebroventricular (icv) infusion of ENaC blocker benzamil prevents Na+ induced hypertension. It was not known whether ENaC subunits are expressed in the brain and whether or not brain ENaC plays a role in regulation of [Na+] in CNS. Hypothesis: 1. Epithelial sodium channels are expressed in the brain. 2. Expression of ENaC is increased in the kidneys and brain of Dahl S rats on high salt diet. 3. ENaC in the brain contributes to regulation of [Na+] in the CSF and brain interstitium. Methods of investigation: We studied expression and distribution of the ENaC subunits and assessed the effects of icv infusion of Na+-rich aCSF in Wistar rats or high salt diet in Dahl S rats in different areas of the brain. Function of ENaC in the choroid plexus was evaluated by studying the effects of benzamil and ouabain on Na+ transport. Major findings: In Wistar rats, both mRNA and protein of all three ENaC subunits are expressed in brain epithelia and magnocellular neurons in the supraoptic (SON) and paraventricular (PVN) nucleus. ENaC abundance is higher on the apical versus basolateral membrane of choroid cells. Benzamil decreases Na+ influx into choroid cells by 20-30% and increases CSF [Na+] by ~8 mmol/L. Na+ rich aCSF increases apical membrane expression of βENaC in the choroid cells and of α and βENaC in basolateral membrane of ependymal cells, but has no effect on neuronal ENaC. Expression of ENaC is higher in choroid cells and SON of Dahl S versus R rats and the higher expression persists on a high salt diet. High salt attenuates the ouabain blockable efflux of Na+ from choroid cells and has no effect on CSF [Na+] in Dahl R rats. In contrast, high salt does not attenuate ouabain blockable efflux of 22Na+ and CSF [Na+] increases in Dahl S. Main Conclusion: ENaC in the brain contributes to Na+ transport into the choroid cells and appear to be involved in reabsorption of Na+ from the CSF. Aberrant regulation of Na+ transport and of Na+K+ATPase activity, might contribute to increases in CSF [Na+] in Dahl S rats on high-salt diet. ENaC in magnocellular neurons may contribute to enhanced secretion of mediators such as ‘ouabain’ leading to sympathetic hyperactivity in Dahl S rats. Epithelial sodium channel Brain Kidney Salt sensitive hypertension Mineralocorticoid receptor SGK1
8	Reprolifilage d'une petite molécule chimique à activité thérapeutique et cellules souches cancéreuses : étude et compréhension du mécanisme d'action du bisacodyl sur les cellules souches cancéreuses isolées de glioblastome / Study of the mechanism of action of bisacodyl in cancer stem-like cells isolated from glioblatoma Chen, Wanyin 24 May 2017 (has links) Les glioblastomes (GBM) sont les formes les plus agressives de tumeurs gliales avec une survie médiane des patients traités n’excédant pas 2 ans. Ce mauvais pronostic est dû, entre autres, à l’hétérogénéité de ces tumeurs avec la présence de cellules souches cancéreuses (CSCs) en prolifération ou quiescentes, particulièrement résistantes aux traitements conventionnels. Cibler ces cellules au sein du microenvironment tumoral hypoxique et acides fait donc partie des thérapies d’avenir des GBMs. Le laxatif bisacodyl a été identifié par criblage de la chimiothèque Prestwick comme un composé induisant la mort par nécrose des CSCs de glioblastome (GSCs en prolifération et en quiescence), uniquement dans des conditions de faible acidité retrouvées également au sein des tumeurs. Une activité antitumorale in vivo a également été démontrée pour ce composé. Cette thèse présente l’identification du mode d’action du bisacodyl dans les GSCs. Celui-ci implique la serine/thréonine kinase WNK1 et ses partenaires, les kinases Akt et SGK1 et des co-transporteurs Na+/HCO3- NBC. Nos résultats ont également révélé un rôle de WNK1 dans la physiopathologie des GSCs. / Glioblastoma (GBM), the most aggressive glial tumor, is currently incurable with a very short-term patient survival (< 2 years). The heterogeneity of GBM and the presence of highly resistant proliferating and quiescent cancer stem-like cells (CSCs), is largely responsible for poor prognosis in this disease. Thus, new approaches targeting glioblastoma CSCs (GSCs), within the acidic/hypoxic tumor microenvironment, are promising strategies for treating GBM. The laxative bisacodyl was identified in a high throughput screening of the Prestwick chemical library as a compound inducing necrotic cell death in proliferating and quiescent GSCs only in acidic microenvironments similar to those found in tumors. Bisacodyl was further shown to induce tumor shrinking and to increase survival in in vivo GBM models. In this thesis work, we identify bisacodyl’s mechanism of action in GSCs. This mechanism involves the serine/threonine kinase WNK1 and its signaling partners including protein kinases Akt and SGK1 and NBC Na+/HCO3- cotransporters. Our data also highlight a previously unknown role of WNK1 in GSC physiopathology. Glioblastome Cellules souches cancéreuses Tumorosphères Acidité tumorale Quiescence Bisacodyl WNK1 Akt SGK1 Co-transporteurs Na+/HCO3-NBC Glioblastoma Cancer stem-like cells Tumorospheres Intratumoral acidity Quiescence Bisacodyl WNK1 Akt SGK1 NBC Na+/HCO3- cotransporters 571.6 615.7 616.99
9	Hormone-induced expression of the epithelial sodium channel in human airway cells Ismail, Noor January 2013 (has links) Respiratory distress syndrome and pulmonary oedema often result in poor health and in the worst case scenario, death. Several studies have proposed that the eventual resolution of these dangerous conditions is due to active sodium reabsorption through the epithelial sodium channel (ENaC), which is crucial for lung fluid clearance. Although clinical prognosis can be improved by using glucocorticoid hormones to augment the ENaC-dependent removal of liquid from the lungs, we still require a better understanding of the underlying mechanism in order to improve treatments in the future. This thesis, therefore explores the role of serum / glucocorticoid-inducible protein kinase 1 (SGK1) and protein kinase A (PKA) in the responses of hormone-stimulated H441 human airway cells. Dexamethasone, a synthetic glucocorticoid hormone, is thought to evoke expression of the gene encoding SGK1 and, to become catalytically active, this gene product must then be phosphorylated via TORC2 and PDK1, protein kinases activated via the P13-kinase pathway. Once activated, SGK1 appears to exert control over the surface abundance of ENaC subunits by phosphorylation, and thus inactivating, a ubiquitin ligase (Nedd4-2), that normally mediate the withdrawal of ENaC subunits from the plasma membrane. Protein kinase A (PKA) may contribute to this control mechanism by also phosphorylating Nedd4-2. In order to clarify the way in which these pathways contribute to glucocorticoid-induced lung liquid clearance, the present thesis has explored the effects of dexamethasone and / or PKA activation upon the overall / surface expression of ENaC subunits, the activities of SGK1 and PKA and the phosphorylation status of physiologically-important residues within Nedd4-2 itself. 616.2
10	NOVEL THYROID HORMONE TARGET GENES IN THE LIVER, AND THEIR ROLES IN THYROID HORMONE SIGNALING AND PHYSIOLOGY TALASILA, PHANI KUMAR 26 September 2012 (has links) No description available. Biomedical Research "Thyroid hormone T3 liver energy metabolism lipid metabolism SGK1 ANGPTL4 PI3 kinase GSK650394 transcription angiopoietins oligomerization cleavage LPL LDL VLDL HDL serum triglycerides PGC1a co-activators LPL assay DGGR"

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