Global ETD Search

1	Role of fibroblast growth factor signalling on the regulation of embryonic stem cells Freile Vinuela, Paz January 2008 (has links) Fibroblast growth factor (FGF) signalling plays many fundamentally important roles during the development of the mammalian embryo. However, its effects on pluripotent stem cells derived from mouse and human embryos appear to be markedly different. FGF2 is routinely added to culture medium for propagating undifferentiated human (hES) cells, whereas in mouse (mES) cell cultures FGFs have been described as regulators of their differentiated progeny. To assess the effect of FGF signalling on undifferentiated mES cells, the effects of FGF2 and 4 were analysed in the presence of saturating and sub-saturating levels of the inhibitor of differentiation, leukaemia inhibitory factor (LIF). Mouse ES cell self-renewal was quantified by measuring the expression of the stem cell specific reporter Oct4-LacZ in biochemical and fluorometric assays. Treatment with FGF reduced the expression of the OCT4-LacZ reporter, even under saturating concentrations of LIF and this was mirrored by decreased levels of OCT4 protein. Furthermore, treatment with FGF leads to upregulation of the ectodermal differentiation marker Pax6. These results suggest that FGF signalling has a direct impact on undifferentiated mES cells, and actively promotes their differentiation. To asses the effect of FGF signalling on hES cells without the influence of undefined factors, a feeder and serum free system was developed. Cells growing in this conditions for >20 passages maintained expression of surface (SSEA3 and TRA1-60 and 81) and internal (OCT4) markers specific for undifferentiated hES cells. Expression of these markers was dependant on the continuous presence of FGF2. Indeed, withdrawal of FGF2 resulted in a rapid decrease of in hES cell growth and of the emergence of cell flattened morphology and of the surface marker SSEA1, changes typically associated with differentiation. Two important signals activated by FGF in hES cells are the ERK/MAPK and PI3K pathways. To assess their functional relevance, hES cell cultures were treated with the drugs UO126 and LY294002, inhibitors of the MAPK and PI3K pathways respectively. Drug mediated suppression of the phosphorylation of these pathways, correlated with a reduction in cell growth, flattening of the colonies and reduction in SSEA4 expression. Use of SB431542, specific inhibitor of TGFβ/activin type I receptor kinase (Alk5) also resulted in the flattening of the colonies and the appearance of dispersed cells. Therefore, inhibition of MAPK and PI3K appears to impair growth and self-renewal in hES cells and this may be happening in conjunction with TGFβ/Activin pathway. Taken together, these results suggest that FGF signalling has opposite effects in mouse and human ES cells: inducing differentiation in mES and sustaining self-renewal in hES. 571.6
2	Involvement of the matrix proteins SPARC and osteopontin in the dynamic interaction between tumour and host cells Jassim, Amir January 2016 (has links) Osteoblasts are highly active cells that are responsible for secreting bone forming components such as collagen type I and matricellular proteins that mediate collagen deposition and mineralisation. SPARC and osteopontin are matricellular proteins that are involved in bone regulation and cell-matrix interactions and are also upregulated in metastatic disease. Secretion of these proteins results in changes to the stromal environment that includes cell migration, angiogenesis, matrix degradation, matrix deposition, bone mineralisation and bone resorption. Signalling pathways not only lead to the expression of target proteins, but also have immediate early effects, for example, on cell adhesion. We asked if the ERK 1 and 2 module of the MAPK pathway was involved in the intracellular trafficking of SPARC and Osteopontin. Membrane trafficking is an essential process that ensures newly synthesised proteins pass from their site of synthesis to the extracellular environment. Using an inhibitor of ERK 1 and 2 activation (U0126), as well as siRNA directed against ERK 1 or 2 individually, a change in intracellular localisation of SPARC and osteopontin was observed in cells treated with U0126 and siRNA against ERK 2 alone, likely in or around the Golgi apparatus. Consistent with the observation above, analysis of protein secretion showed that there was a reduction of total protein secreted (30% reduction) when ERK 1 and 2 activation was prevented together or knock down of ERK 2 alone. A mechanism is proposed where ERK 2 is likely activating a substrate that is allowing SPARC and osteopontin to continue along the secretory pathway. This directly implicates ERK 2 as an important regulator of matricellular protein secretion in osteoblasts. In cancer, Ras mutations can lead to permanent activation of the MAPK pathway leading to cancer cell proliferation and survival, however, we propose another mechanism important in metastasis whereby ERK 2 activation is manipulated to facilitate secretion of matricellular proteins which can then mediate changes to the stromal environment that allow the tumour to metastasise successfully. 616.99
3	MK2 and ETV1 Are Prognostic Factors in Esophageal Adenocarcinomas Jomrich, Gerd, Maroske, Florian, Stieger, Jasmin, Preusser, Matthias, Ilhan-Mutlu, Aysegül, Winkler, Daniel, Kristo, Ivan, Paireder, Matthias, Schoppmann, Sebastian Friedrich January 2018 (has links) (PDF) Background. Esophageal cancer is ranked in the top ten of diagnosed tumors worldwide. Even though improvements in survival could be noticed over the last years, prognosis remains poor. ETS translocation variant 1 (ETV1) is a member of a family of transcription factors and is phosphorylated by mitogen-activated protein kinase (MAPK)-activated protein kinase 2 (MK2). Aim of this study was to evaluate the prognostic role of MK2 and ETV1 in esophageal cancer. Methods. Consecutive patients that underwent surgical resection at the department of surgery at the Medical University of Vienna between 1991 and 2012 were included into this study. After microscopic analysis, tissue micro arrays (TMAs) were created and immunohistochemistry was performed with antibodies against MK2 and ETV1. Results. 323 patients were included in this study. Clinical data was achieved from a prospective patient data base. Nuclear overexpression of MK2 was observed in 143 (44.3%) cases for nuclear staining and in 142 (44.0%) cases a cytoplasmic overexpression of MK2 was observed. Nuclear and cytoplasmic ETV1 overexpression was detected in 20 cases (6.2%) and 30 cases (9.3%), respectively. In univariate survival analysis, cMK2 and nETV1 were found to be significantly associated with patients' overall survival. Whereas overexpression of cMK2 was associated with shorter, nETV1 was associated with longer overall survival. In multivariate survival analysis, both cMK2 and nETV1 were found to be independent prognostic factors for the subgroup of EAC as well. Discussion. Expression of MK2 and ETV1 are prognostic factors in patients, with esophageal adenocarcinoma.
4	The molecular associations in clathrin-coated pit regulate β-arrestin-mediated MAPK signaling downstream of μ-opioid receptor / クラスリン被覆小孔の構成分子との会合がμオピオイド受容体下流のβアレスチンを介したMAPK経路のシグナル伝達を制御する Sato, Atsuko 23 March 2023 (has links) 京都大学 / 新制・課程博士 / 博士(医学) / 甲第24525号 / 医博第4967号 / 新制\|\|医\|\|1065(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授渡邊直樹, 教授中川一路, 教授秋山芳展 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM β-arrestin mitogen-activated protein kinase (MAPK) G protein-coupled receptor (GPCR) G protein clathrin-coated pit 490
5	Computational Studies Of Uncertainty In Intra-Cellular Biochemical Reaction Systems Dana, Saswati 12 1900 (has links) (PDF) With an increased popularity for systems-based approaches in biology, a wide spectrum of techniques has been applied to the simulation and analysis of biochemical systems which involves uncertainty and stochasticity. It is particularly concerned with modelling and analysis of metabolic pathways, regulatory and signal transduction networks for understanding intra-cellular pathway behaviour. Typically, parameter estimation in ordinary differential equations(ODEs) models is used for this purpose when there is large number of molecules involved in the reaction system. However this approach is correct when the system is large enough to be deterministic in nature. But there are uncertainty involved in the system and the processes are stochastic in nature due to smaller population molecules participating in the pathway reactions. In this thesis the common theme is the study of uncertainties in the chemical kinetics of biochemical reaction systems associated with various intra-cellular pathways and channels. The study is at the mesoscale of the system, i.e., we study systems that do not have too few molecules disallowing any higher scale system level approximation nor too many where a non-stochastic (mesoscale) system approximation will be valid. In our first study we estimate the parameters in the mitogen activated protein kinase (MAPK) signal transduction pathway involved in the departure from the normal Epithelial Growth Factor(EGF) dose-dependency in prostate cancer cells. A model-based pathway analysis is performed. The pathway is mathematically modelled with 28 rate equations yielding those many ordinary differential equations(ODE) with kinetic rate constants that have been reported to take random values in the existing literature. This has led to us treating the ODE model of the pathways kinetics as a random differential equations(RDE) system in which the parameters are random variables. The most likely set of values of the kinetic rate constants obtained from fitting the RDE model into the experimental data is then used in a direct transcription based dynamic optimization method for computing the changes needed in these kinetic rate constant values for the restoration of the normal EGF dose response. It identifies the parameters, i.e., the kinetic rate constants in the RDE model, that are the most sensitive to the change in the EGF dose response behaviour in the PC3 prostate cancer cells. Biochemical pathways involving chemical kinetics equations in terms of low concen-trations of the model variables can be represented as chemical Langevin equations(CLE) as there is stochasticity involved in the processes. Most CLE systems come with the implicit constraint that the concentration state cannot be negative at any time over the sample path. Due to the inherent stiffness(especially in diffusion coefficient) of the CLE system, it has been difficult for numerical schemes to meet this positivity constraint during numerical simulations. Most available methods resort to heuristics by dropping selective noise terms from the original CLE inconsistent with the mesoscale physics involved in forming the CLE. Other methods take very small time steps thus making the simulation inefficient. In our second study we preserve positivity by using a physically consistent numerical scheme which is a modified form of fully stochastic α method for stiff stochastic differential equation. Ion channels are fundamental molecules in the nervous system that catalyse the flux of ions across the cell membrane. Single ion channel flux activity is comparable to the catalytic activity of single enzyme molecules. Saturating concentrations of substrate induce dynamic disorder in the kinetic rate processes of single enzyme molecules and consequently, develop correlative memory of the previous history of activities. Conversely, binding of substrate ion is known to alter the catalytic turnover of single ion channels. Here, we investigated the possible existence of dynamic disorder and molecular memory in single human TREK1 channel due to binding of substrate/agonist using the excised inside-out patch-clamp technique. Our results suggest that single hTREK1 channel behaves as a typical Michaelis-Menten enzyme molecule with a single high-affinity binding site for substrate K+ ion but with uncertainty in reaction rates. Biochemistry - Data Analysis Biochemical Reaction Biochemistry - Numerical Analysis Ion Channels Biochemical Kinetics - Simulation Mesoscale Biochemical Kinetics Mitogen Activated Protein Kinase (MAPK) Biochemical Pathway Chemical Langevin Equations (CLE) Biochemistry
6	Analyse comparée des récepteurs D1 de la dopamine chez les vertébrés : Définition des caractères fonctionnels spécifiques de chacun des sous-types du récepteur D1 LE CROM, Stéphane 20 September 2000 (has links) (PDF) L'action de la dopamine dans les cellules est transmise par sa fixation sur des récepteurs qui appartiennent à deux classes, D1 et D2. Quatre sous-types du récepteur D1 (D1A, D1B/D5, D1C et D1D) ont été clonés jusqu'à présent chez les vertébrés. L'analyse évolutive montre que les sous-types D1A et D1B sont les plus conservés alors que les sous-types D1C et D1D sont absents chez les mammifères. Malgré cette diversité, les fonctions de la dopamine dans l'organisme ne peuvent pas être rapportées à l'action d'un sous-type précis. C'est pourquoi au cours de ce travail nous avons identifié des caractères fonctionnels capables de distinguer chacun des sous-types et de comprendre pour quelle raison ils ont été conservés chez les vertébrés. La désensibilisation est un des paramètres fonctionnels les plus important. Le récepteur D1A se caractérise par une baisse d'activité forte et biphasique, le récepteur D1B par un profil proche avec une amplitude plus faible conséquence de son activité constitutive. Enfin, le récepteur D1C ne semble pas être capable de se désensibiliser. La construction de chimères entre chacun des sous-types du récepteur D1 et la protéine GFP ont permis la visualisation des récepteurs au cours de la désensibilisation. Elles montrent que l'internalisation ne semble pas, pour les récepteurs D1 de la dopamine, intervenir dans le processus de désensibilisation fonctionnelle. L'activation simultanée des récepteurs A1 de l'adénosine bloque l'activité des récepteurs D1. L'analyse des voies de signalisation MAPK a montré que l'activation de la voie ERK était rapide et forte, et différente selon les sous-types. La voie p38 n'est que faiblement activée et la voie JNK semble ne pas l'être du tout. Il semble donc que les mécanismes d'activation et de régulation des voies de signalisation différencient les sous-types du récepteur D1 chez les vertébrés. Ces paramètres participent de façon majeure à la transmission régulée des fonctions de la dopamine dans l'organisme. [SDV:BC] Life Sciences/Cellular Biology Récepteurs de la Dopamine D1 Vertébrés Désensibilisation Green Fluorescent Protein (GFP) Evolution Internalisation
7	Role MAPK v regulaci cytoplazmatické polyadenylace během meiotického zrání savčích oocytů / Role of MAPK in regulation of cytoplasmic polyadenylation during meiotic maturation of mammalian oocytes Kráčmarová, Jana January 2017 (has links) Mammalian oocytes undergoing meiotic maturation are transcriptionally silent and gene expression is therefore regulated at the level of translation. One of the well established mechanisms employed in translational regulation of maternal mRNAs in oocytes is cytoplasmic polyadenylation. This process is generally controlled by phosphorylation and activation of cytoplasmic polyadenylation element binding protein (CPEB). The aim of this thesis is to determine the role of mitogen-activated protein kinase (MAPK) in regulation of CPEB-mediated cytoplasmic polyadenylation in maturing mouse and porcine oocytes. For this purpose, MAPK activity was inhibited using its specific inhibitor, GDC-0994 and the effect of MAPK inhibition on cyclin B1 mRNA polyadenylation was monitored. In mouse oocytes, MAPK inhibition impaired neither cyclin B1 mRNA polyadenylation nor its translation and MAPK is thus unlikely to be involved in regulation of cytoplasmic polyadenylation in this species. Based on the results of experiments performed using porcine oocytes, the possible role of MAPK in CPEB-mediated cytoplasmic polyadenylation can neither be confirmed nor ruled out. Keywords: cytoplasmic polyadenylation, mouse oocyte, porcine oocyte, mitogen-activated protein kinase (MAPK), cyclin B1, GDC-0994 inhibitor
8	Regulation and Characterization of Transcription Factor Activator Protein-2 Alpha (AP-2α) Nama, Srikanth January 2009 (has links) (PDF) Introduction AP2α is a 52 kDa retinoic acid inducible and developmentally regulated activator of transcription, which binds to the DNA in a sequence-specific manner. Transcription factor AP-2α was isolated from HeLa cells by affinity chromatography using specific binding sites with in SV40 and human metallothionein promoters. Further screening of HeLa cDNA library with oligonucleotide probes predicted partial peptide sequence which led to the isolation of AP-2α cDNA and subsequently it was mapped to chromosome 6 near HLA locus. A differentially spliced version of AP-2α, which lacks most of the C-terminus, encodes a dominant negative protein (AP-2B). Subsequent studies led to the identification of four more isoforms: AP-2β, AP-2γ, AP-2δ and AP-2ε. AP-2 family members can form homo or hetero dimers among themselves through the unique C-terminal helix span helix motif and bind DNA through basic domain lies N-terminus of DNA binding domain. Several evidences suggest that AP-2α can act as a tumor suppressor gene. It has been shown that AP-2α can activate growth suppressor genes like p21WAF1/CIP1. Transforming viral oncogenes like adenovirus E1A and SV40 large T antigen have been shown to alter AP-2α function. In addition, reduced expression of AP-2α has been reported in human breast, ovary, colon, skin, brain and prostate cancers. Further, supporting evidences suggest that more invasiveness and tumorogenicity was observed when dominant negative mutant of AP-2α was expressed in melanoma cells. In this work, we have carried out a systematic study to find the various signal transduction pathways which regulate AP-2 activity as well as we attempted to demonstrate the importance of DNA binding domain in the growth inhibitory functions of AP-2α. HDAC inhibitors (HDIs) activate AP-2 activity through spleen tyrosine kinase (Syk) In the literature, ample evidences are available that genotoxic drugs such as adriamycin, induce tumor suppressors like p53 and p73. In this study, we have screened pharmacological drugs which damage DNA and specific inhibitors of various signal transduction pathways for their ability to activate AP-2 activity. AP-2 specific reporter, 3Χ-AP2-CAT was used in this study to measure the AP-2 activity. Of all the compounds studied, we found that Histone Deacetylase Inhibitors (HDIs) efficiently activated AP-2 activity and was found to be specific as they failed to activate 3X-AP2 mut CAT, which contains mutated AP-2 binding sites as well as pGL tk Luc, which contains thymidine kinase minimal promoter and no AP-2 binding sites. To understand the mechanism of HDI-mediated of AP-2 activation, AP-2 isoforms and its coactivators transcript and protein levels were analyzed. We found significant change in transcript levels of the some of the molecules tested. While the endogenous protein levels of various AP-2 isoforms were undetectable, we found stabilization of AP-2α protein expressed from exogenous source in cells treated with HDIs. HDI stabilized AP-2α was found to be functionally active as it showed increased sequence-specific DNA-binding as well as increased apoptosis. While HDIs known for their ability to modulate the gene activities by chromatin remodeling, it is also known that they alter various signal transduction pathways. In an effort to find pathway(s) by which HDIs activate AP-2 activity, we found that HDIs failed to activate AP-2 reporter in the presence of staurosporine suggesting the involvement a staurosporine sensitive pathway(s) in this process. Stauosporine is a non-specific kinase inhibitor of different signaling pathways. Further studies using different pathway specific inhibitors identified that spleen tyrosine kinase (Syk) is essential for HDIs mediated activation of AP-2 activity. Syk is a non receptor tyrosine kinase which is known to be activated in stress conditions. Syk is considered to be a tumor suppressor since Syk over expression leads to growth suppression of breast cancer cells and is also inactivated in a subset of breast cancers. These results suggest that HDI mediated activation of AP-2 involves AP-2α stabilization through Syk pathway. Regulation of AP-2 by MAP kinase pathway Cell growth, differentiation, and apoptosis are mediated by the activation of mitogenactivated protein kinase (MAPK) pathways. These kinases constitute MAP kinase cascades mainly regulated through phosphorylation status. In mammalian cells, at least four MAPKs, namely, extracellular signal-regulated kinases (ERKs), c-Jun N-terminal kinase/stress-activated protein kinases (JNK/SAPKs), p38 and ERK5/big MAP kinase have been identified. The ERKs are usually activated by mitogenic stimuli which in turn increase the proliferation and survival. Over expression of any activator of this signaling cascade lead to the unregulated proliferation of cells. In many cancers, ERK pathways are known to be up regulated. In this study, we found that MEK (MEK is the immediate upstream regulator of ERK) inhibitors - PD98059 and U0126 activate 3X-AP2-CAT suggesting that AP-2 activity is repressed by activated MAP kinase pathway. MEK inhibitor mediated activation was found to be specific because they failed to activate transcription from pGL tk Luc which contains thymidine kinase minimal promoter and no AP-2 binding sites. To understand the mechanism of MEK inhibitor-mediated of AP-2 activation, AP-2 isoforms and its coactivators transcript and protein levels were analyzed. We found significant change in transcript levels of the some of the molecules tested. The endogenous protein levels of various AP-2 isoforms were undetectable. When AP-2α was exogenously expressed, while no change in protein levels and DNA-binding ability was seen, we found evidence for appearance of post-ranslationally modified AP-2α protein in U0126 treated cells. We also found CITED2 (CBP/p300-interacting transactivator 2, co-activator of AP-2α) transcript levels were up regulated in UO126 treated cells. Post translational modifications of AP-2α and increased and increased CITED2 levels may be responsible for MEK inhibitor mediated AP-2 activation. Thus we conclude that ERK pathway, which is an oncogenic MAP kinase pathway, inhibits AP-2 activity thereby suggesting the importance of down regulation of AP-2 activity during transformation. Essential role of DNA-binding domain of AP-2α for its growth inhibitory functions Transcription factor AP-2α has three distinct domains, N-terminal transactivation domain (52-108 aa), C-terminal DNA binding domain (204-408 aa) and dimerization domain (277-395 aa) which lies within the DNA binding domain. AP-2α exerts its effects through binding to specific DNA sequence in the promoter of its target genes leading to either repression or activation. Recent evidences suggest that AP-2α represses many genes through its competitive binding to overlapping AP-2 and other transcription factor binding sites. This suggests an important role exclusively for the DNA binding domain in AP-2α mediated functions. To address the importance of DNA binding domain for AP-2α mediated apoptosis, we have tested the ability different deletion/point mutants of AP-2α with varying DNA binding and transactivation capability to perform growth suppressor function and ability to induce apoptosis. Replication-deficient recombinant adenoviruses expressing different mutants were used in this study. We found that an intact DNA-binding domain alone even in the absence of activation domain is sufficient for AP-2α to inhibit colony formation and to induce significant levels of apoptosis. These results suggest an important role for DNA binding domain growth inhibitory functions of AP-2α and thereby implying the importance of transcriptional repression in AP-2α functions. Protein Transcription Activator Protein-2 alpha (AP-2α) Protein Binding Histone Deacetylase Inhibitors (HDIs) Mitogen Activated Protein Kinase (MAPK) AP-2 alpha AP-2 Transcription MAP Kinase Pathway AP-2 - Growth Inhibition AP2α HDAC Inhibitors Biochemistry
9	The role of the JNK/AP-1 pathway in the induction of iNOS and CATs in vascular cells Zamani, Marzieh January 2013 (has links) Nitric oxide (NO) is an important biological molecule within the body, which over production of this molecule in response to different stimulations can cause various inflammatory diseases. Over production of this molecule is caused by the induction of the inducible nitric oxide synthase (iNOS) enzyme. This enzyme uses L-arginine as a substrate and therefore the presence and transport of this amino acid into the cells can be a key factor in regulating NO over production. Different signalling mechanisms have been implicated in the regulation of this pathway and one of which involves the Mitogen Activated Protein Kinases (MAPK). This family of proteins respond to inflammatory conditions and may mediate effects induced by inflammatory mediators. Of the MAPKs, the role of the c-Jun-N-terminal kinase (JNK) pathway in the induction of iNOS is still controversial. JNK and its downstream target, the transcription factor Activator Protein-1 (AP-1), have shown contradictory effects on iNOS induction leading to controversies over their role in regulating iNOS expression in different cell systems or with various stimuli. The studies described in this thesis have determined the role of JNK/AP-1 on iNOS expression, NO production, L-arginine uptake and also on the transporters responsible for L-arginine transport into the cells. The studies were carried out in two different cell types: rat aortic smooth muscle cells (RASMCs) and J774 macrophages which are both critically associated with the over production of NO in vascular inflammatory disease states. The first approach was to block the expression of the inducible L-arginine-NO pathway using SP600125 and JNK Inhibitor VIII which are both pharmacological inhibitors of JNK. The results from these studies showed that the pharmacological intervention was without effect in RASMCs, but inhibited iNOS, NO and L-arginine transport in J774 macrophages. In contrast, the molecular approach employed using two dominant negative constructs of AP-1 (TAM-67 and a-Fos) revealed a different profile of effects in RASMCs, where a-Fos caused an induction in iNOS and NO while TAM-67 had an inhibitory effect on iNOS, NO, L-arginine transport and CAT-2B mRNA expression. The latter was unaffected in RASMCs but suppressed in J774 macrophages by SP600125. Examination of JNK isoforms expression showed the presence of JNK1 and 2 in both cell systems. Moreover, stimulation with LPS/IFN- or LPS alone resulted in JNK phosphorylation which did not reveal any difference between smooth muscle cells and macrophages. In contrast, expression and activation of AP-1 subunits revealed differences between the two cell systems. Activation of cells with LPS and IFN- (RASMCs) or LPS alone (J774 macrophages) resulted in changes in the activated status of the different AP-1 subunit which was different for the two cell systems. In both cell types c-Jun, JunD and Fra-1 were increased and in macrophages, FosB activity was also enhanced. Inhibition of JNK with SP600125 caused down-regulation in c-Jun in both cell types. Interestingly this down-regulation was in parallel with increases in the subunits JunB, JunD, c-Fos and Fra-1 in RASMCs or JunB and Fra-1 in J774 macrophages. Since, SP600125 was able to exert inhibitory effects in the latter cell type but not in RASMCs, it is possible that the compensatory up-regulation of certain AP-1 subunits in the smooth muscle cells may compensate for c-Jun inhibition thereby preventing suppression of iNOS expression. This notion clearly needs to be confirmed but it is potentially likely that hetero-dimers formed between JunB, JunD, c-Fos and Fra-1 could sustain gene transcription in the absence of c-Jun. The precise dimer required has not been addressed but unlikely to exclusively involve JunB and Fra-1 as these are up-regulated in macrophages but did not sustain iNOS, NO or induced L-arginine transport in the presence of SP600125. To further support the argument above, the dominant negatives caused varied effects on the activation of the different subunits. a-Fos down-regulated c-Jun, c-Fos, FosB, Fra-1 whereas TAM-67 reduced c-Jun and c-Fos but marginally induced Fra-1 activity. Associated with these changes was an up-regulation of iNOS-NO by a-Fos and inhibition by TAM-67. Taken together, the data proposes a complex mechanism(s) that regulate the expression of the inducible L-arginine-NO pathway in different cell systems and the complexity may reflect diverse intracellular changes that may be different in each cell type and not always be apparent using one experimental approach especially where this is pharmacological. Moreover, these findings strongly suggest exercising caution when interpreting pure pharmacological findings in cell-based systems particularly where these are inconsistent or contradictory. 616.0473
10	Étude du rôle de la tyrosine kinase Src dans la régulation de la signalisation des récepteurs opioïdes delta (∆OR) Gobeil, Mélanie P. 07 1900 (has links) Les opioïdes sont les analgésiques les plus efficaces mais leur utilisation est limitée par la tolérance, un processus lié en partie à la désensibilisation des récepteurs. Le rôle de la présente étude était de mieux caractériser le processus de désensibilisation des récepteurs et plus particulièrement, d’étudier le rôle de la tyrosine kinase Src sur la régulation de la signalisation des récepteurs delta opioïdes. Nos résultats démontrent que l’inhibition pharmacologique avec PP2 (à faible concentration : 20- 40µM) ou encore l’inhibition moléculaire de la kinase avec de faibles concentrations d’ADN d’un mutant dominant inactif de Src (0,2µg/ml) potentialise l’amplitude et la durée de l’activation de la cascade ERK lorsqu’un agoniste, DPDPE (1µM; 5 min), se lie aux récepteurs. Nous avons également démontré que de fortes concentrations d’inhibiteurs de Src (80 et 100µM de PP2 ou 1µg/ml d’ADN du mutant dominant négatif) bloquent la cascade des MAPK suivant la stimulation de DOR par l’agoniste DPDPE. Ces observations indiquent que Src a un effet biphasique sur l’activité de ERK : l’inhibition complète de Src inhibe l’activité de la cascade MAPK alors qu’une inhibition modérée potentialise cette même cascade. Nous pensons aussi que de fortes concentrations des bloqueurs de Src interfèrent avec l’activation de ERK alors que de faibles concentrations interfèrent avec la désensibilisation des récepteurs. Cette possibilité a été testée à l’aide d’essais d’accumulation d’AMPc qui visaient à évaluer l’effet des bloqueurs de Src (PP2, 20 µM; 1h) sur la désensibilisation induite par un agoniste. L'activation de DOR par DPDPE inhibe la production d’AMPc, préalablement stimulée par du forskolin, de façon dose-dépendante. Le maximum d'inhibition observé est de 61%, mais lors d’un prétraitement au DPDPE (1 µM, 30 min) l’inhibition maximale est réduite à 72% de l’inhibition initiale observée. Cependant, un prétraitement des cellules au PP2 (20µM pendant 1 heure) avant d’effectuer la désensibilisation protège contre cette désensibilisation. L’effet protecteur des bloqueurs de Src n’entraîne pas de changement au niveau de l’internalisation des DOR mais l’altération de leur internalisation via un mutant tronqué du DOR ou via un milieu sucré hypertonique (0.4M de saccharose) réduit cette protection. Ces données suggèrent alors que l’internalisation optimale du récepteur est nécessaire pour que l’effet protecteur prenne place. Nous concluons donc que Src contribue à la désensibilisation de DOR après que l’internalisation du DOR soit survenue. / Opioids are the most effective analgesics available but their use is limited by tolerance. Tolerance is related, at least in part, to receptor desensitization. Hence, the role of the present study was to better characterize the desensitization process, in particular concerning the role of the tyrosine kinase Src on regulation of delta opioid receptor signalling. Our results show that pharmacological inhibition with PP2 (administered at low concentration: 20-40µM) or molecular inhibition of the kinase with low expression levels of a dominant negative mutant of Src (0,2µg of DNA) potentiate the magnitude and duration of agonist-dependent (DPDPE; 1µM; 5 min) activation of the ERK pathway. We also showed that higher concentrations of Src inhibitors (80 and 100µM of PP2 or 1µg/ml of dominant negative mutant DNA) block the MAPK cascade following DOR stimulation by DPDPE. These observations indicate that Src has a biphasic effect on ERK activity, respectively potentiating or inhibiting agonist stimulation of the MAPK cascade at low and high levels of Src inhibition. We reasoned that high levels of Src blockers were interfering with ERK activation mechanism while low levels of inhibition were interfering with receptor desensitization. This possibility was tested by using cAMP accumulation assays to evaluate the effect of Src blockers (PP2, 20 µM; 1h) on agonist-induced desensitization. DOR stimulation by DPDPE inhibited forskolin stimulated cAMP production in a dose dependent manner with a maximal reduction of 61%. This inhibitory response was reduced by 72% following pre-exposure to DPDPE (1 µM, 30 min), an effect that was blocked by pre-treating cells with PP2 (PP2, 20 µM; 1 h) before desensitization. The protective effect of Src blockers did not involve changes in DOR internalization but interfering with internalization by using an internalization-deficient DOR mutant or hypertonic medium (0.4M sucrose) reduced this protection, indicating the need for optimal internalization in order for the protective effect of Src blockers to take place. Based on the latter observation it was possible to conclude that Src contribution to DOR desensitization is post-endocytic. Désensibilisation Desensitization Src PP2 DPDPE Internalisation Internalization Tolérance Tolerance mitogen-activated protein kinase (MAPK) Adénosine monophosphate cyclique (AMPc) cyclic adenosine monophosphate (cAMP)

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