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Receptor tyrosine kinase c-Kit signalling in hematopoietic progenitor cellsEdling, Charlotte January 2006 (has links)
The receptor tyrosine kinase (RTK) c-Kit is expressed in hematopoietic stem and progenitor cells, mast cells and in several non-hematopoietic tissues. In the hematopoietic system c-Kit and its ligand Steel Factor (SF, aka Stem Cell Factor) are critical for proliferation, survival and differentiation. Mutations in either receptor or ligand lead to lethal anaemia, hematopoietic stem cell defects, mast cell deficiency and a series of non-hematological defects. The aims of the studies included in this thesis are to describe the signalling pathways downstream c-Kit in hematopoietic stem/progenitor cells and to further analyse the role of c-Kit signalling in fundamental biological functions. To study c-Kit signalling in the hematopoietic system we have employed hematopoietic stem cell-like cell lines which share many properties with primary hematopoietic stem cells in vitro and in vivo, including surface markers, multipotentiality, capacity for self-renewal and long term repopulation. In paper I we demonstrate that upon SF activation the RTK c-Kit is autophosphorylated and downstream signalling mediators are transiently activated. Surprisingly we find that the c-Kit mediated activation of the MAPK pathway is dependent on the activation of phosphoinositide 3-kinase (PI3K) in hematopoietic progenitor cells and that differentiation of these progenitors to mast cells results in a signalling switch where Raf activation changes from PI3K dependent to PI3K independent. We here establish that PI3K activity is required for viability and proliferation of hematopoietic progenitor cells. In paper II we studied the conventional protein kinase C (cPKC) involvement in c-Kit signalling. We observe that the cPKCs can phosphorylate c-Kit on serine 746 and that this phosphorylation negatively regulates the activation of the receptor. We demonstrate that inhibition of this negative phosphorylation results in dramatically increased protein kinase B (PKB) activation and as a consequence inhibition of cPKCs rescues cells from starvation induced apoptosis. Moreover we exhibit that the cPKCs are necessary for full activation of extracellular signal-regulated kinase (Erk) and that impaired PKC activity leads to hampered proliferation. In paper III we demonstrate that in addition to the cPKCs also the novel PKC is required for Erk activation and proliferation. Furthermore we present results indicating that PKC negatively regulates differentiation of bone marrow. In conclusion, with the studies in this thesis we display details in the signalling pathways induced upon RTK c-Kit activation and we demonstrate that c-Kit has significant effects on hematopoietic cell-physiology.
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Teratogenicity Involved in Experimental Diabetic PregnancyGäreskog, Mattias January 2006 (has links)
Maternal diabetes is associated with increased risk of growth disturbances and congenital malformations. The malformations rate in the offspring of diabetic mothers is 2-3 fold higher compared to infants of nondiabetic mothers. In this thesis we have investigated the role of the protein kinase C (PKC) pathway and the apoptotic machinery in embryopathy. We investigated the involvement of PKC isoforms in the embryopathy of diabetic rat pregnancy. Embryos of diabetic rats showed altered activity and protein distribution of several PKC isoforms compared with embryos of normal rats. Using whole embryo culture we found increased activity of PKC-delta and PKC-zeta after 24h of culture and increased rate of malformations and growth retardation in embryos cultured in high glucose concentration compared to embryos cultured in low glucose concentration. Addition of α-cyano-4-cinnamic acid and N-acetylcysteine to the culture medium normalized malformations and growth retardations whereas specific PKC-inhibitors abolished malformations and partly restored the growth retardations. All treatment normalized glucose-induced increase of PKC activity. Estimated occurrence of apoptosis in embryos of diabetic rats and in embryonic cells exposed to high glucose concentration showed increased rate of pro-apoptotic markers. The increased apoptosis in the high glucose exposed embryonic cells was normalized by supplementation of N-acetylcysteine or apoptosis inhibitor. Treatment with vitamin E and folic acid to diabetic pregnant rats decreased diabetes-induced malformations and resorptions, concomitant with normalization of apoptotic protein levels. These results suggest that oxidative stress is augmented in embryos of diabetic rats and that it also plays a role in the activation of PKC and apoptosis. We used antioxidative treatment with beneficial effect although we could not completely abolish the embryonic demise; this may indicate that other mechanisms are involved in diabetic embryopathy. Further studies are needed to develop multi-nutrient dietary supplement to eliminate embryonic abnormalities induced by maternal diabetes.
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The Mechanisms Underlying Free Fatty Acid-induced Hepatic Insulin ResistancePark, Kyu Yol Edward 01 August 2008 (has links)
Elevated circulating free fatty acids (FFA) cause hepatic insulin resistance; however, the mechanisms for this process are incompletely understood. The objective of the studies in the thesis was to examine whether protein kinase C (PKC)-delta (d), oxidative stress, and the serine kinase IkBa kinase (IKK) B are causally involved in FFA-induced hepatic insulin resistance. To test this, we infused rats with lipid with or without inhibitors of the aforementioned factors for 7h, during the last 2h of which a hyperinsulinemic-euglycemic clamp was performed. In Study 1, inhibition of hepatic PKC-d using antisense oligonucleotide prevented FFA-induced membrane translocation of PKC-d, which is a marker of its activation, in parallel with prevention of lipid-induced hepatic insulin resistance, without affecting lipid-induced peripheral insulin resistance. These results implicate PKC-d as a causal mediator of FFA-induced hepatic insulin resistance. In Study 2, the antioxidant N-acetyl-L-cysteine (NAC) prevented lipid-induced hepatic insulin resistance in conjunction with reversal of lipid-induced increase in markers of IKKB and c-Jun NH2-terminal kinase 1 (JNK1) activation, and of impairment of insulin signaling, without affecting PKC-d membrane translocation and increase in phosphorylated p38 mitogen-activated protein kinase (MAPK) induced by lipid infusion. These findings suggested that oxidative stress is a causal mediator of lipid-induced hepatic insulin resistance upstream of IKKB and JNK1, and potentially downstream of PKC-d and p38 MAPK. In Study 3, sodium salicylate, an IKKB inhibitor, prevented FFA-induced hepatic insulin resistance via restoration of hepatic insulin signaling, thus implicating IKKB as a causal factor in the process. Together, the results from these studies demonstrate that PKC-d, oxidative stress, and IKKB are causally involved in FFA-induced hepatic insulin resistance and suggest that the sequence for the process is: FFA -> PKC-d -> oxidative stress -> IKKB -> impaired hepatic insulin signaling.
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The Mechanisms Underlying Free Fatty Acid-induced Hepatic Insulin ResistancePark, Kyu Yol Edward 01 August 2008 (has links)
Elevated circulating free fatty acids (FFA) cause hepatic insulin resistance; however, the mechanisms for this process are incompletely understood. The objective of the studies in the thesis was to examine whether protein kinase C (PKC)-delta (d), oxidative stress, and the serine kinase IkBa kinase (IKK) B are causally involved in FFA-induced hepatic insulin resistance. To test this, we infused rats with lipid with or without inhibitors of the aforementioned factors for 7h, during the last 2h of which a hyperinsulinemic-euglycemic clamp was performed. In Study 1, inhibition of hepatic PKC-d using antisense oligonucleotide prevented FFA-induced membrane translocation of PKC-d, which is a marker of its activation, in parallel with prevention of lipid-induced hepatic insulin resistance, without affecting lipid-induced peripheral insulin resistance. These results implicate PKC-d as a causal mediator of FFA-induced hepatic insulin resistance. In Study 2, the antioxidant N-acetyl-L-cysteine (NAC) prevented lipid-induced hepatic insulin resistance in conjunction with reversal of lipid-induced increase in markers of IKKB and c-Jun NH2-terminal kinase 1 (JNK1) activation, and of impairment of insulin signaling, without affecting PKC-d membrane translocation and increase in phosphorylated p38 mitogen-activated protein kinase (MAPK) induced by lipid infusion. These findings suggested that oxidative stress is a causal mediator of lipid-induced hepatic insulin resistance upstream of IKKB and JNK1, and potentially downstream of PKC-d and p38 MAPK. In Study 3, sodium salicylate, an IKKB inhibitor, prevented FFA-induced hepatic insulin resistance via restoration of hepatic insulin signaling, thus implicating IKKB as a causal factor in the process. Together, the results from these studies demonstrate that PKC-d, oxidative stress, and IKKB are causally involved in FFA-induced hepatic insulin resistance and suggest that the sequence for the process is: FFA -> PKC-d -> oxidative stress -> IKKB -> impaired hepatic insulin signaling.
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The regulation of cellular trafficking of the human lysophosphatidic acid receptor 1: identification of the molecular determinants required for receptor traffickingUrs, Nikhil Mahabir 16 May 2007 (has links)
The following thesis research was undertaken to gain a better understanding of the mechanisms that regulate the cellular trafficking and signaling of the endothelial differentiation gene (EDG) family of G-protein coupled receptors, LPA1, LPA2, and LPA3. This thesis will specifically focus on the regulation of the trafficking of the LPA1 Lysophosphatidic acid receptor, which is the most widely expressed and has been shown to be a major regulator of migration of cells expressing it.
The initial studies undertaken in this project were aimed at understanding the endocytic pathway followed by the LPA1 receptor. Lysophosphatidic acid (LPA), an abundant serum phospholipid, stimulates heterotrimeric G protein signaling by activating three closely related receptors, termed LPA1, LPA2 and LPA3. In the first part of the project we show that in addition to promoting LPA1 signaling, membrane cholesterol is essential for the association of LPA1 with β-arrestin, which leads to signal attenuation and clathrin dependent endocytosis of LPA1.
The second phase of the project was aimed at elucidating the different structural motifs required for the trafficking and signaling of the LPA1 receptor and helping us gain a more mechanistic view of the processes involved in its regulation. In the second part of the project we show that agonist-independent internalization of the LPA1 receptor is clathrin adaptor, AP-2 dependent and PKC-dependent and that it requires a distal dileucine motif, whereas agonist-dependent internalization of the LPA1 receptor is β-arrestin and clathrin-dependent and requires a cluster of serine residues in the tail region, which is upstream of the dileucine motif.
These studies collectively vastly enhance our understanding of mechanisms that regulate LPA1 trafficking and signaling. These studies can also be applied to other G-protein coupled receptors making the task easier for other scientists to understand this vast family of receptors.
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Investigation of 1alpha,25-dihydroxy vitamin D3 membrane receptor ERp60 in adipocytes from male and female lean and obese miceMcLane, Jesica Mata 19 October 2009 (has links)
The purpose of this study is to determine whether or not adipocytes harvested directly from fat pads or induced from bone marrow in lean and obese mice exhibit a sex-dependent rapid response to vitamin D metabolite 1á,25(OH)2D3 and if so to elucidate if it is via an ERp60 receptor mediated signaling pathway. The role of 1á,25(OH)2D3 and specifically the membrane effect will be examined in two genetically distinct mice to see if their cells have a differing sensitivity. The results indicate that there are differing responses in adipocytes that are induced from bone marrow versus differentiated fat pad adipocytes, and the function of 1á,25(OH)2D3 is sex-specific in some cases. Additionally, all the adipocytes tested demonstrated a rapid response to 1á,25(OH)2D3; mRNA for nVDR and ERp60 were found in all cells however the only functional protein found in the plasma membrane was ERp60 indicating that it may be necessary for the rapid response whereas nVDR is not required.
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Implication des disintégrines dans le clivage physiologique de la protéine prion : régulation par les récepteurs muscariniques et les protéines kinasesAlfa Cisse, Moustapha 21 March 2007 (has links) (PDF)
Les encéphalopathies spongiformes transmissibles (EST) constituent de graves maladies neurodégéneratives atypiques, affectant aussi bien l'homme que l'animal. Ces maladies ont une origine infectieuse, génétique ou sporadique. On distingue chez l'homme la maladie de Creutzfeldt-Jakob, le syndrome de Gerstmann-Sträussler-Sheinker, le nouveau variant de la maladie de Creutzfeldt-Jakob dû à l'ingestion d'aliments contaminés, et les formes iatrogènes, qui surviennent le plus souvent à la suite d'une contamination contractée lors d'interventions chirurgicales. Les maladies à prions animales les plus courantes sont l'encéphalopathie spongiforme bovine et la tremblante du mouton. Le facteur commun à toutes ces maladies est la protéine prion ou PrP, présente de façon ubiquitaire dans l'organisme et de manière prépondérante dans le cerveau. La PrP existe sous deux états conformationnels qui ont la même séquence en acides aminés, mais qui possèdent des propriétés physicochimiques différentes. La forme anormale du prion appelée "scrapie" ou "PrPsc " est partiellement résistante aux protéases et plus riche en feuillets b que la PrPc, ce qui lui confère une susceptibilité exacerbée à l'agrégation. L'hypothèse de "la protéine seule" proposée par Prusiner prédit que le titre infectieux serait composé uniquement de la PrPsc, capable de se répliquer de manière autocatalytique en se servant de la PrPc endogène comme matrice de conversion. Les mécanismes moléculaires régissant ce processus sont encore mal connus. Cependant ce phénomène de conversion apparaît comme l'évènement central contrôlant l'infection et sa propagation vers le système nerveux central. Ces processus nécessitent la présence de la PrPc endogène, puisqu'il a été montré que des souris invalidées pour la protéine prion résistent à l'infection et sont viables. Ces observations ouvrent de nouvelles perspectives en terme d'approches thérapeutiques théoriquement envisageables dans le domaine des EST. La PrPc, après une étape de maturation, subit un clivage physiologique à la membrane plasmique en position 111/112 qui conduit à la formation d'un fragment sécrété appelé N1. Des travaux effectués dans notre laboratoire ont montré que ce clivage est constitutif et régulé par la PKC et nécessite l'activité des disintégrines ADAM10 et ADAM17, respectivement. Mon travail de thèse à consisté à étudier ce clivage en identifiant les isoformes de la PKC impliquées, et à démontrer sa régulation par les récepteurs muscariniques.
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Quantitative Proteinexpressionsanalysen in den klinisch-pathologischen Subtypen Gastrointestinaler Stromatumoren (GIST) / The analysis of the quantitative protein expression in the clinical-pathological subtypes of Gastrointestinal stromal tumors (GIST)Helfrich, Joel 02 March 2011 (has links)
No description available.
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Multiple Cell Signaling Pathways Modulate the Cocaine-Induced Increase in Mu Opioid Receptor Protein Expression in PC12 CellsSoftah, Abrar 27 May 2013 (has links)
Cocaine is interrelated with the opioid system on many levels, especially via the mu opioid receptor (MOR). Also, cocaine has been involved in modulating nitric oxide (NO) actions within the cell. The effect of cocaine was first assessed on the MOR, and then on transcription by the use of 1 µg/ mL actinomycin D inhibitor. Several signaling pathways that cocaine may exert its action in modulating the MOR up-regulation in protein expression were also explored. Two dosage regimens were used in cocaine treatment, single continuous treatment (SCT), and repeated intermittent treatment (RIT). Different pathway inhibitors were used on PC12 cells, as follows: the PLC-PKC inhibitors 5 µM U-73122 and 10 µM BIS-1 used to investigate the involvement of the PKC signaling pathways in MOR expression levels, the evaluation of MAPK pathway by the use of 50 µM U0126 inhibitor, and the 10 µM LY94002 inhibitor was used to investigate the PI3K/Akt pathway. Moreover, the effect of NO on these signaling pathways was investigated by the use of 20 mM nonselective L-NAME inhibitor and qualitatively by DAF-2 florescence. Western blot analysis indicated that cocaine up-regulated MOR protein expression. Also, RIT cocaine treatment increased MOR protein levels via transcription. All three signaling pathways, MAPK, Akt and PKC modulated cocaine-induced increase of MOR following SCT cocaine treatment (post-transcriptional). Both MAPK and Akt have been found to modulate the cocaine-induced transcription of MOR via the two dosage regimens of cocaine, SCT and RIT. Also, inhibition of both PLC and PKC did not prevent cocaine-induced increase in MOR transcription, according to RIT of cocaine.
Furthermore, Akt and PKC appeared to modulate cocaine-induced NO production while MAPK did not. NO seemed to be involved with the PKC and Akt pathways in up-regulating MOR in RIT of cocaine directly by the Akt pathway, and indirectly by the PKC pathway. On the other hand, NO and MAPK modulated the MOR up-regulation expression simultaneously, but in an individual/parallel manner. Furthermore, signaling pathway activation levels were tested using L-NAME which concluded that NO modulated cocaine-induced increase in total Akt protein levels, but did not appear to have an effect on phosphorylated MAPK activation levels. In conclusion, different treatment regimens of cocaine activate different pathways; SCT of cocaine activated all three signaling pathways, however, RIT of cocaine activated only the MAPK and Akt pathways. / Saudi Bureau in Canada
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Protein kinase involvement in wild-type and mutant calcium-sensing receptor signallingBin Khayat, Mohd Ezuan January 2016 (has links)
The calcium-sensing receptor (CaR) is a G-protein coupled receptor that controls mammalian extracellular calcium (Ca2+o) homeostasis. CaR downstream signalling involves intracellular calcium (Ca2+i) mobilisation which can be negatively modulated by protein kinase C (PKC)-mediated phosphorylation of CaR residue Thr-888 (CaRT888). The nature of this regulation was investigated here using siRNA-based knockdown of individual PKC isotypes. Knocking down PKCα expression increased CaR-induced Ca2+i mobilisation in CaR-HEK cells, significantly lowering the EC50 for Ca2+o relative to control siRNA-transfected cells. In accordance, PKCα knockdown also decreased CaRT888 phosphorylation which also permitted the triggering of Ca2+i mobilisation in CaR-HEK cells at sub-threshold Ca2+o concentrations. Interestingly, PKCε knockdown attenuated CaR-induced Ca2+i mobilisation in CaR-HEK cells, significantly increasing the EC50 for Ca2+o. However, this knockdown was also also found to inhibit CaRT888 phosphorylation and this is the first time that CaRT888 phosphorylation has been shown to be dissociate from Ca2+i mobilisation. The results show the complexity of the interactions that potentially underlie the CaR’s pleiotropic signalling and provides novel targets for examining signal bias. Classically an increase in cAMP is known to trigger PTH seceretion. The observation in this study shows that raising intracellular cAMP levels with forskolin also decreased CaRT888 phosphorylation permitting increased Ca2+i mobilisation. This suggests that cAMP may stimulate the phosphatase (most likely protein phosphatase 2A (PP2A)). Nevertheless, knocking down Gα12, which has been shown to activate PP2A, resulted in increased CaRT888 phosphorylation and lower Ca2+i mobilisation (increased EC50 for Ca2+o). This suggests the possibility of CaR as a cAMP sensor that can detect an increase in intracellular cAMP in order to stop PTH serection. Three novel CaR effectors, P70 ribosamal protein S6 kinase, insulin-like growth factor receptor-1 and nuclear factor of kappa light polypeptide gene enhancer in B-cells inhibitor, were identified in CaR-HEK cells. It was shown that a) high Ca2+o stimulated the activation of these effectors and b) each effector was inhibited by knockdown of PKCα and Gα12, which further confirmed the association of these signals with CaR. These data show that CaR also plays an important role outside Ca2+o homeostasis, such as growth and inflammation. Finally, five CaR mutations associated with autosomal dominant hypocalcaemia (ADH) were found to increase Ca2+o-induced Ca2+i mobilisation, as well as ERK and p38MAPK activation, when transfected stably in HEK-293 cells. Cotreatment with the calcilytic NPSP795 inhibited ERK and p38MAPK phosphorylation in all 5 gain-of-function mutants and in the wild type CaR cells, with IC50s for the compound in the nanomolar range. These data highlight the potential utility of CaR negative allosteric modulators in the treatment of gain-of-function CaR mutations. Together these data enhance our understanding of CaRT888 phosphorylation and CaR signalling.
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