Global ETD Search

71	Einfluss der Calstabin2-Mutante FKBP12.6D37S in gesunden Mauskardiomyozyten und in einem transgenen Herzinsuffizienzmodell, das die Kalzium/Calmodulin-abhängige Proteinkinase IIδc überexprimiert / Influence of the calstabin2-mutante FKBPD37S in normal mice cardiomyocytes and in a transgenic heart failure modell overexpressing the calcium/calmodulin-kinase IIδc Hellenkamp, Kristian 05 October 2011 (has links) No description available. 610 Medizin, Gesundheit Medicine 44.85 MED 411: Kardiologie
72	Relation entre CaMKII et les dynamiques calciques endothéliales : impact de l'hypertension arterielle Charbel, Chimène 04 1900 (has links) No description available. Signalisation calcique locale Pulsars calciques Projections myoendothéliales CaMKII Espèces réactives à l’oxygène Endothélium vasculaire Angiotensine II Hypertension artérielle Oxyde nitrique Local calcium signaling Calcium pulsars Myoendothelial projections CaMKII Nitric oxide Reactive oxygen species Vascular endothelium Angiotensin II Arterial hypertension
73	Endothelin-1 and H2O2-induced signaling in vascular smooth muscle cells : modulation by CaMKII and Nitric oxide Bouallegue, Ali 08 1900 (has links) L’endothéline-1 (ET-1) est un peptide vasoactif extrêmement puissant qui possède une forte activité mitogénique dans les cellules du muscle lisse vasculaire (VSMCs). Il a été démontré que l’ET-1 est impliquée dans plusieurs maladies cardio-vasculaires, comme l’athérosclérose, l'hypertension, la resténose après l'angioplastie, l’insuffisance cardiaque et l'arythmie. L’ET-1 exerce ses effets via plusieurs voies de signalisation qui incluent le Ca2+, les protéines kinases activées par les mitogènes (MAPKs) y compris les kinases régulées par les signaux extracellulaires (ERK1/2) et la voie de la phosphatidylinositol 3-kinase (PI-3K)/protein kinase B (PKB). Plusieurs études ont démontré que les dérivés réactifs de l'oxygène (ROS) peuvent jouer un rôle important dans la signalisation d’ERK1/2 et de PKB induite par plusieurs facteurs de croissance et hormones. Nous avons précédemment montré que l'ET-1 produit des ROS qui agissent comme médiateur de la signalisation cellulaire induite par l’ET-1. Le peroxyde d’hydrogène (H2O2), une molécule qui appartient à la famille des ROS, peut activer les voies de la MAPK et de la PKB dans les VSMCs. Par ailleurs, nos résultats suggèrent également que le Ca2+ et la calmoduline (CaM) sont essentiels pour la phosphorylation d’ERK1/2, de p38 et de PKB induite par le H2O2 dans les VSMCs. La Ca2+/CaM-dependent protein kinases II (CaMKII) est une sérine/thréonine protéine kinase multifonctionnelle activée par le Ca2+/CaM. Il a été montré que la CaMKII est impliquée dans les voies de signalisation induite par le H2O2 dans les cellules endothéliales. Cependant, le rôle de la CaMKII dans la phosphorylation d’ERK1/2, de PKB et de la proline-rich tyrosine kinase 2 (Pyk2) induite par l’ET-1 et le H2O2, de même que son rôle dans l’effet hypertrophique et prolifératif de l’ET-1 dans les VSMCs demeure inexploré. Le monoxyde d’azote (NO) est une molécule vasoactive impliquée dans la régulation de plusieurs réponses hormonales. Le NO peut moduler la signalisation contrôlant la croissance cellulaire induite par plusieurs agonistes d’où son rôle protecteur dans le système vasculaire. Des études ont montré que le NO peut inhiber la voie de Ras/Raf/ERK1/2 et la voie de PKB induite par le facteur de croissance endothélial (EGF) et l’angiotensine II (Ang II). Beaucoup d’autres travaux ont mis en évidence un cross-talk entre les voies de signalisation activées par l’ET-1 et le NO. La capacité du NO à inhiber la signalisation intracellulaire induite par l’ET-1 dans les VSMCs demeure inconnue. Le travail présenté dans cette thèse vise à déterminer le rôle du système Ca2+-CaM-CaMKII dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1 et le H2O2 ainsi que son rôle dans la croissance et la prolifération cellulaire induites par l’ET-1 dans les VSMCs. Nous avons également testé le rôle du NO dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 ainsi que la synthèse protéique induite par l’ET-1. Dans la première partie de notre étude, nous avons examiné le rôle de la CaMKII dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs en utilisant trois approches différentes i.e. l'usage d'inhibiteurs pharmacologiques, un peptide auto-inhibiteur de la CaMKII (CaMKII AIP) et la technique de siRNA. Nous avons démontré que la CaMKII est impliquée dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs. Des études précédentes ont montré à l’aide d’inhibiteurs pharmacologiques comme le KN-93 que l'Ang II et les agents induisant une augmentation de la concentration en Ca2+ intracellulaire comme l’ionomycine, provoquent la phosphorylation d’ERK1/2 via la CaM dans les VSMCs. Cependant, en utilisant différentes approches, nos études ont montré pour la première fois une implication de la CaMKII dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs. Nous avons également rapporté pour la première fois, un rôle crucial de la CaMKII dans la pathophysiologie vasculaire associée à l’ET-1 puisque l’activation de la CaMKII joue un rôle important dans l’hypertrophie et la croissance cellulaire. Dans la deuxième partie, à la lumière des études précédentes qui montraient que les ROS agissent comme médiateurs de la signalisation induite par l’ET-1 dans les VSMCs, nous avons examiné si la CaMKII est également impliquée dans l’activation des voies d’ERK1/2 et de PKB induite par le H2O2. En utilisant des approches pharmacologiques et moléculaires, nous avons montré, comme pour l’ET-1, que la CaMKII joue un rôle critique en amont de la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par le H2O2. Nous avons précédemment montré que la transactivation du récepteur de type I de l’insulin-like growth factor (IGF-1R) est nécessaire à l’activation de PKB induite par le H2O2. Pour cette raison, nous avons examiné l'effet de l'inhibition de la CaMKII par l’inhibiteur pharmacologique ou par le knock-down de la CaMKII sur la phosphorylation d’IGF-1R induite par le H2O2. Les résultats démontrent que la CaMKII joue un rôle critique en amont de la phosphorylation d’ERK1/2, de PKB et d’IGF-1R induite par le H2O2. Dans la troisième partie de notre étude, nous avons également examiné le mécanisme moléculaire par lequel le NO exerce ses effets anti-mitogéniques et anti-hypertrophiques dans la signalisation induite par l’ET-1. En testant l'effet de deux différents donneurs de NO (S-nitroso-N-acetylpenicillamine (SNAP), sodium nitroprusside (SNP)) et un inhibiteur de NO synthase, le N (G)-nitro-L-arginine methyl ester (L-NAME) dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1, nous avons observé que le NO a un effet inhibiteur sur la signalisation induite par l’ET-1 dans les VSMCs. Par ailleurs, le 8-Br-GMPc, un analogue du GMPc, a un effet similaire à celui des deux donneurs du NO, tandis que l’oxadiazole quinoxaline (ODQ), un inhibiteur de la guanylate cyclase soluble, inverse l'effet inhibiteur du NO. Nous concluons que le NO diminue la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1 d’une manière dépendante du GMPc. Le NO inhibe aussi les effets hypertrophiques de l’ET-1 puisque le traitement avec le SNAP diminue la synthèse des protéines induite par l’ET-1. En résumé, les études présentées dans cette thèse démontrent que l’ET-1 et le H2O2 sont des activateurs de la phosphorylation d’ERK1/2, de PKB et de Pyk2 dans les VSMCs et que la CaMKII s’avère nécessaire pour ce processus, en agissant en amont de l’activation de IGF-1R induite par le H2O2 dans les VSMCs. Elles montrent également que le NO inhibe la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1. Enfin, nos travaux suggèrent aussi que l’activation de la CaMKII stimule la synthèse des protéines et de l’ADN induites par l’ET-1 alors que le NO inhibe la synthèse des protéines induite par ET-1. Mots clés: Endothéline ; Peroxyde d'hydrogène ; CaMKII ; Monoxyde d’azote ; Système vasculaire ; PKB; ERK1/2; IGF-1R; Hypertrophie. / Endothelin-1 has emerged as an extremely potent vasoactive peptide exhibiting potent mitogenic activity in vascular smooth muscle cells (VSMCs). A critical role of ET-1 in many cardiovascular diseases, such as atherosclerosis, hypertension, restenosis after angioplasty, heart failure and arrhythmia has been suggested. ET-1 exerts its effects through multiple signaling pathways which include Ca2+, mitogen-activated protein kinases (MAPKs) including extracellular signal-regulated kinases 1/2 (ERK1/2) and phosphatidylinositol 3-kinase (PI-3K)/protein kinase B (PKB)/Akt pathways. Several studies have also demonstrated that reactive oxygen species (ROS) may play an important role in mediating the signals of several growth factors and peptides hormones linked to these pathways. We have previously reported that ET-1 generates ROS which mediates ET-1-induced signaling. H2O2, an important ROS molecule, activates both MAPKs and PKB signaling in VSMCs. In addition, we have also suggested that Ca2+ and CaM are essential to trigger H2O2-induced ERK1/2, p38 and PKB phosphorylation in A-10 VSMCs. Ca2+/calmodulin (CaM)-dependent protein kinase II (CaMKII) is a multifunctional serine/threonine protein kinase which is believed to transduce the downstream effects of Ca2+/CaM, and has been shown to be involved in H2O2-induced signaling in endothelial cells. However, a role of CaMKII in mediating ET-1 and H2O2-induced ERK1/2, PKB, Pyk2 phosphorylation, as well as its effect on hypertrophic and proliferative responses of ET-1 in VSMCs remains unexplored. Interestingly, a role of CaMKII in several cardiovascular diseases has been reported and studies showing that pharmacological inhibition of CaMKII, by using KN-93, prevent arrhythmic activity improved vascular dysfunction in diabetes or in Ang II-induced hypertension. Nitric oxide (NO) is also an important reactive species and vasoactive molecule involved in the regulation of several hormone-mediated responses. NO has been suggested to modify growth-promoting signaling events and thus may serve as a vascular protective agent. Studies have shown that NO can attenuate EGF and Ang II-induced Ras/Raf/ERK1/2 as well as increase in PKB phosphorylation signaling pathways. There is also evidence for a potential cross-talk between ET-1 and NO, however not much information on the ability of NO to modify ET-1-induced signaling in VSMCs is available. Therefore, the work presented in this thesis has investigated the role of CaMKII system in ET-1 and H2O2-induced ERK1/2, PKB and Pyk2 phosphorylation, as well as in cell growth and proliferation evoked by ET-1 in VSMCs. We also investigated the role of NO in ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation as well as protein synthesis. In the first part of our studies, by using three different approaches, i.e. use of pharmacological inhibitors, a CaMKII AIP (autoinhibitor peptide) and siRNA techniques, we have investigated the involvement of CaMKII in ET-1-induced ERK1/2 and PKB phosphorylation in A-10 VSMC. We have demonstrated that CaMKII mediates the effect of ET-1 on ERK1/2 and PKB phosphorylation in A-10 VSMC. By using pharmacological inhibitor alone such as, KN-93, earlier studies have reported that AngII and Ca2+ elevating agents, such as ionomycin, exert their effects on ERK1/2 phosphorylation via CaM-dependent pathways in VSMC. However, by using multiple approaches, our studies, have provided the first evidence to suggest an involvement of CaMKII in mediating the effect of ET-1 on ERK1/2 and PKB phosphorylation in A-10 VSMC. We have also reported for the first time, a crucial role of CaMKII in vascular pathophysiology related to ET-1 by regulating the growth and hypertrophic events by using the technique of [3H]leucine and [3H]thymidine incorporation. In the second part, in view of earlier studies showing that ROS mediates ET-1-induced signaling events in VSMC, we have also investigated if CaMKII is also implicated in H2O2-induced activation of ERK1/2 and PKB pathways. By using both pharmacological and molecular approaches, we show that similar to ET-1, CaMKII serves as a critical upstream component in triggering H2O2-induced ERK1/2, PKB and Pyk2 phosphorylation in VSMC. Furthermore, since we have previously reported that IGF-1R transactivation is needed for H2O2-induced PKB activation, we have investigated the effect of CaMKII inhibition and knocking-down on IGF-1R phosphorylation evoked by H2O2. Taken together, these results demonstrate that CaMKII plays a critical upstream role in mediating the effect of H2O2 on ERK1/2, PKB and IGF-1R phosphorylation. In the third part of our studies, we have investigated the molecular mechanism by which NO exerts its anti-mitogenic and anti-hypertrophic effect on ET-1-induced signaling. By testing the effect of two different NO donors (SNAP and SNP) and L-NAME, an inhibitor of NO synthase, in ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation, we observed that NO has an inhibitory effect in ET-1-induced signaling in VSMC. In addition, 8-Br-cGMP, an analogue of cGMP, exerted similar effect to that of NO donors whereas, oxadiazole quinoxalin (ODQ), an inhibitor of soluble guanylyl cyclase (sGC), reversed the inhibitory effect of NO. We conclude that NO, in a cGMP-dependent manner, attenuated ET-1-induced phosphorylation of ERK1/2, PKB and Pyk2 and also antagonized the hypertrophic effects of ET-1, since SNAP treatment decreased the protein synthesis induced by ET-1. In summary, the studies presented in this thesis demonstrate that both ET-1 and H2O2 induce ERK1/2, PKB and Pyk2 phosphorylation in VSMC and CaMKII activation is required for these events. We have also shown that CaMKII phosphorylation is upstream of H2O2-induced IGF-1R transactivation in VSMC. We have also provided evidence that NO attenuates ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation. Finally, we have established that CaMKII activation stimulates ET-1-evoked protein and DNA synthesis, yet NO attenuates protein synthesis induced by ET-1. Keywords : Endothelin; Hydrogen peroxide; CaMKII; Nitric oxide; Vascular; Protein Kinase B; Extracellular Signal-Regulated Kinase1/2; IGF-1R; Growth. Endothéline Peroxyde d'hydrogène CaMKII Monoxyde d’azote Système vasculaire PKB ERK1/2 IGF-1R Hypertrophie Endothelin Hydrogen peroxide Nitric oxide Vascular Protein Kinase B Growth
74	Auswirkungen des neuartigen CaMKII-Inhibitors SMP-114 auf das diastolische SR Ca2+-Leck und die elektromechanische Kopplung isolierter Herzmuskelzellen / Effects of the novel CaMKII inhibitor SMP-114 on diastolic SR Ca2+ leak and EC coupling in isolated cardiomyocites Mann, Christian 28 October 2015 (has links) No description available. 610 EC coupling CaMKII heart failure ca2+ leak SMP-114 AIP Ca2+ Sparls SCE events diastolic Ca2+ loss SR Ca2+ loss Kardiologie (PPN619875755)
75	Endothelin-1 and H2O2-induced signaling in vascular smooth muscle cells : modulation by CaMKII and Nitric oxide Bouallegue, Ali 08 1900 (has links) L’endothéline-1 (ET-1) est un peptide vasoactif extrêmement puissant qui possède une forte activité mitogénique dans les cellules du muscle lisse vasculaire (VSMCs). Il a été démontré que l’ET-1 est impliquée dans plusieurs maladies cardio-vasculaires, comme l’athérosclérose, l'hypertension, la resténose après l'angioplastie, l’insuffisance cardiaque et l'arythmie. L’ET-1 exerce ses effets via plusieurs voies de signalisation qui incluent le Ca2+, les protéines kinases activées par les mitogènes (MAPKs) y compris les kinases régulées par les signaux extracellulaires (ERK1/2) et la voie de la phosphatidylinositol 3-kinase (PI-3K)/protein kinase B (PKB). Plusieurs études ont démontré que les dérivés réactifs de l'oxygène (ROS) peuvent jouer un rôle important dans la signalisation d’ERK1/2 et de PKB induite par plusieurs facteurs de croissance et hormones. Nous avons précédemment montré que l'ET-1 produit des ROS qui agissent comme médiateur de la signalisation cellulaire induite par l’ET-1. Le peroxyde d’hydrogène (H2O2), une molécule qui appartient à la famille des ROS, peut activer les voies de la MAPK et de la PKB dans les VSMCs. Par ailleurs, nos résultats suggèrent également que le Ca2+ et la calmoduline (CaM) sont essentiels pour la phosphorylation d’ERK1/2, de p38 et de PKB induite par le H2O2 dans les VSMCs. La Ca2+/CaM-dependent protein kinases II (CaMKII) est une sérine/thréonine protéine kinase multifonctionnelle activée par le Ca2+/CaM. Il a été montré que la CaMKII est impliquée dans les voies de signalisation induite par le H2O2 dans les cellules endothéliales. Cependant, le rôle de la CaMKII dans la phosphorylation d’ERK1/2, de PKB et de la proline-rich tyrosine kinase 2 (Pyk2) induite par l’ET-1 et le H2O2, de même que son rôle dans l’effet hypertrophique et prolifératif de l’ET-1 dans les VSMCs demeure inexploré. Le monoxyde d’azote (NO) est une molécule vasoactive impliquée dans la régulation de plusieurs réponses hormonales. Le NO peut moduler la signalisation contrôlant la croissance cellulaire induite par plusieurs agonistes d’où son rôle protecteur dans le système vasculaire. Des études ont montré que le NO peut inhiber la voie de Ras/Raf/ERK1/2 et la voie de PKB induite par le facteur de croissance endothélial (EGF) et l’angiotensine II (Ang II). Beaucoup d’autres travaux ont mis en évidence un cross-talk entre les voies de signalisation activées par l’ET-1 et le NO. La capacité du NO à inhiber la signalisation intracellulaire induite par l’ET-1 dans les VSMCs demeure inconnue. Le travail présenté dans cette thèse vise à déterminer le rôle du système Ca2+-CaM-CaMKII dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1 et le H2O2 ainsi que son rôle dans la croissance et la prolifération cellulaire induites par l’ET-1 dans les VSMCs. Nous avons également testé le rôle du NO dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 ainsi que la synthèse protéique induite par l’ET-1. Dans la première partie de notre étude, nous avons examiné le rôle de la CaMKII dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs en utilisant trois approches différentes i.e. l'usage d'inhibiteurs pharmacologiques, un peptide auto-inhibiteur de la CaMKII (CaMKII AIP) et la technique de siRNA. Nous avons démontré que la CaMKII est impliquée dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs. Des études précédentes ont montré à l’aide d’inhibiteurs pharmacologiques comme le KN-93 que l'Ang II et les agents induisant une augmentation de la concentration en Ca2+ intracellulaire comme l’ionomycine, provoquent la phosphorylation d’ERK1/2 via la CaM dans les VSMCs. Cependant, en utilisant différentes approches, nos études ont montré pour la première fois une implication de la CaMKII dans la phosphorylation d’ERK1/2 et de PKB induite par l’ET-1 dans les VSMCs. Nous avons également rapporté pour la première fois, un rôle crucial de la CaMKII dans la pathophysiologie vasculaire associée à l’ET-1 puisque l’activation de la CaMKII joue un rôle important dans l’hypertrophie et la croissance cellulaire. Dans la deuxième partie, à la lumière des études précédentes qui montraient que les ROS agissent comme médiateurs de la signalisation induite par l’ET-1 dans les VSMCs, nous avons examiné si la CaMKII est également impliquée dans l’activation des voies d’ERK1/2 et de PKB induite par le H2O2. En utilisant des approches pharmacologiques et moléculaires, nous avons montré, comme pour l’ET-1, que la CaMKII joue un rôle critique en amont de la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par le H2O2. Nous avons précédemment montré que la transactivation du récepteur de type I de l’insulin-like growth factor (IGF-1R) est nécessaire à l’activation de PKB induite par le H2O2. Pour cette raison, nous avons examiné l'effet de l'inhibition de la CaMKII par l’inhibiteur pharmacologique ou par le knock-down de la CaMKII sur la phosphorylation d’IGF-1R induite par le H2O2. Les résultats démontrent que la CaMKII joue un rôle critique en amont de la phosphorylation d’ERK1/2, de PKB et d’IGF-1R induite par le H2O2. Dans la troisième partie de notre étude, nous avons également examiné le mécanisme moléculaire par lequel le NO exerce ses effets anti-mitogéniques et anti-hypertrophiques dans la signalisation induite par l’ET-1. En testant l'effet de deux différents donneurs de NO (S-nitroso-N-acetylpenicillamine (SNAP), sodium nitroprusside (SNP)) et un inhibiteur de NO synthase, le N (G)-nitro-L-arginine methyl ester (L-NAME) dans la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1, nous avons observé que le NO a un effet inhibiteur sur la signalisation induite par l’ET-1 dans les VSMCs. Par ailleurs, le 8-Br-GMPc, un analogue du GMPc, a un effet similaire à celui des deux donneurs du NO, tandis que l’oxadiazole quinoxaline (ODQ), un inhibiteur de la guanylate cyclase soluble, inverse l'effet inhibiteur du NO. Nous concluons que le NO diminue la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1 d’une manière dépendante du GMPc. Le NO inhibe aussi les effets hypertrophiques de l’ET-1 puisque le traitement avec le SNAP diminue la synthèse des protéines induite par l’ET-1. En résumé, les études présentées dans cette thèse démontrent que l’ET-1 et le H2O2 sont des activateurs de la phosphorylation d’ERK1/2, de PKB et de Pyk2 dans les VSMCs et que la CaMKII s’avère nécessaire pour ce processus, en agissant en amont de l’activation de IGF-1R induite par le H2O2 dans les VSMCs. Elles montrent également que le NO inhibe la phosphorylation d’ERK1/2, de PKB et de Pyk2 induite par l’ET-1. Enfin, nos travaux suggèrent aussi que l’activation de la CaMKII stimule la synthèse des protéines et de l’ADN induites par l’ET-1 alors que le NO inhibe la synthèse des protéines induite par ET-1. Mots clés: Endothéline ; Peroxyde d'hydrogène ; CaMKII ; Monoxyde d’azote ; Système vasculaire ; PKB; ERK1/2; IGF-1R; Hypertrophie. / Endothelin-1 has emerged as an extremely potent vasoactive peptide exhibiting potent mitogenic activity in vascular smooth muscle cells (VSMCs). A critical role of ET-1 in many cardiovascular diseases, such as atherosclerosis, hypertension, restenosis after angioplasty, heart failure and arrhythmia has been suggested. ET-1 exerts its effects through multiple signaling pathways which include Ca2+, mitogen-activated protein kinases (MAPKs) including extracellular signal-regulated kinases 1/2 (ERK1/2) and phosphatidylinositol 3-kinase (PI-3K)/protein kinase B (PKB)/Akt pathways. Several studies have also demonstrated that reactive oxygen species (ROS) may play an important role in mediating the signals of several growth factors and peptides hormones linked to these pathways. We have previously reported that ET-1 generates ROS which mediates ET-1-induced signaling. H2O2, an important ROS molecule, activates both MAPKs and PKB signaling in VSMCs. In addition, we have also suggested that Ca2+ and CaM are essential to trigger H2O2-induced ERK1/2, p38 and PKB phosphorylation in A-10 VSMCs. Ca2+/calmodulin (CaM)-dependent protein kinase II (CaMKII) is a multifunctional serine/threonine protein kinase which is believed to transduce the downstream effects of Ca2+/CaM, and has been shown to be involved in H2O2-induced signaling in endothelial cells. However, a role of CaMKII in mediating ET-1 and H2O2-induced ERK1/2, PKB, Pyk2 phosphorylation, as well as its effect on hypertrophic and proliferative responses of ET-1 in VSMCs remains unexplored. Interestingly, a role of CaMKII in several cardiovascular diseases has been reported and studies showing that pharmacological inhibition of CaMKII, by using KN-93, prevent arrhythmic activity improved vascular dysfunction in diabetes or in Ang II-induced hypertension. Nitric oxide (NO) is also an important reactive species and vasoactive molecule involved in the regulation of several hormone-mediated responses. NO has been suggested to modify growth-promoting signaling events and thus may serve as a vascular protective agent. Studies have shown that NO can attenuate EGF and Ang II-induced Ras/Raf/ERK1/2 as well as increase in PKB phosphorylation signaling pathways. There is also evidence for a potential cross-talk between ET-1 and NO, however not much information on the ability of NO to modify ET-1-induced signaling in VSMCs is available. Therefore, the work presented in this thesis has investigated the role of CaMKII system in ET-1 and H2O2-induced ERK1/2, PKB and Pyk2 phosphorylation, as well as in cell growth and proliferation evoked by ET-1 in VSMCs. We also investigated the role of NO in ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation as well as protein synthesis. In the first part of our studies, by using three different approaches, i.e. use of pharmacological inhibitors, a CaMKII AIP (autoinhibitor peptide) and siRNA techniques, we have investigated the involvement of CaMKII in ET-1-induced ERK1/2 and PKB phosphorylation in A-10 VSMC. We have demonstrated that CaMKII mediates the effect of ET-1 on ERK1/2 and PKB phosphorylation in A-10 VSMC. By using pharmacological inhibitor alone such as, KN-93, earlier studies have reported that AngII and Ca2+ elevating agents, such as ionomycin, exert their effects on ERK1/2 phosphorylation via CaM-dependent pathways in VSMC. However, by using multiple approaches, our studies, have provided the first evidence to suggest an involvement of CaMKII in mediating the effect of ET-1 on ERK1/2 and PKB phosphorylation in A-10 VSMC. We have also reported for the first time, a crucial role of CaMKII in vascular pathophysiology related to ET-1 by regulating the growth and hypertrophic events by using the technique of [3H]leucine and [3H]thymidine incorporation. In the second part, in view of earlier studies showing that ROS mediates ET-1-induced signaling events in VSMC, we have also investigated if CaMKII is also implicated in H2O2-induced activation of ERK1/2 and PKB pathways. By using both pharmacological and molecular approaches, we show that similar to ET-1, CaMKII serves as a critical upstream component in triggering H2O2-induced ERK1/2, PKB and Pyk2 phosphorylation in VSMC. Furthermore, since we have previously reported that IGF-1R transactivation is needed for H2O2-induced PKB activation, we have investigated the effect of CaMKII inhibition and knocking-down on IGF-1R phosphorylation evoked by H2O2. Taken together, these results demonstrate that CaMKII plays a critical upstream role in mediating the effect of H2O2 on ERK1/2, PKB and IGF-1R phosphorylation. In the third part of our studies, we have investigated the molecular mechanism by which NO exerts its anti-mitogenic and anti-hypertrophic effect on ET-1-induced signaling. By testing the effect of two different NO donors (SNAP and SNP) and L-NAME, an inhibitor of NO synthase, in ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation, we observed that NO has an inhibitory effect in ET-1-induced signaling in VSMC. In addition, 8-Br-cGMP, an analogue of cGMP, exerted similar effect to that of NO donors whereas, oxadiazole quinoxalin (ODQ), an inhibitor of soluble guanylyl cyclase (sGC), reversed the inhibitory effect of NO. We conclude that NO, in a cGMP-dependent manner, attenuated ET-1-induced phosphorylation of ERK1/2, PKB and Pyk2 and also antagonized the hypertrophic effects of ET-1, since SNAP treatment decreased the protein synthesis induced by ET-1. In summary, the studies presented in this thesis demonstrate that both ET-1 and H2O2 induce ERK1/2, PKB and Pyk2 phosphorylation in VSMC and CaMKII activation is required for these events. We have also shown that CaMKII phosphorylation is upstream of H2O2-induced IGF-1R transactivation in VSMC. We have also provided evidence that NO attenuates ET-1-induced ERK1/2, PKB and Pyk2 phosphorylation. Finally, we have established that CaMKII activation stimulates ET-1-evoked protein and DNA synthesis, yet NO attenuates protein synthesis induced by ET-1. Keywords : Endothelin; Hydrogen peroxide; CaMKII; Nitric oxide; Vascular; Protein Kinase B; Extracellular Signal-Regulated Kinase1/2; IGF-1R; Growth. Endothéline Peroxyde d'hydrogène CaMKII Monoxyde d’azote Système vasculaire PKB ERK1/2 IGF-1R Hypertrophie Endothelin Hydrogen peroxide Nitric oxide Vascular Protein Kinase B Growth
76	Synaptic Plasticity Induced Through CP-AMPARs is Dependent on the ERK/MAPK Signalling Cascade Asrar, Suhail 15 April 2010 (has links) Recent literature has shown that AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) receptors lacking the GluR2 subunit (thus calcium permeable) are widely expressed in the CNS, especially in interneurons and glia, where they contribute to synaptic transmission and plasticity. Studies have also indicated that calcium permeable AMPARs (CP-AMPARs) are expressed and participate in synaptic regulation in principal neurons, including hippocampal pyramidal neurons. Furthermore, CP-AMPARs and their resultant calcium influx are implicated in various pathophysiological conditions such as ischemia and seizures. However, the synaptic events activated by calcium influx through CP-AMPARs remain unknown. I took advantage of genetically altered mice without (GluR2-/-) or with reduced GluR2 (GluR2+/-), thus allowing the expression and detailed analysis of synaptic CP-AMPARs in hippocampal pyramidal neurons. Utilizing electrophysiological techniques, I demonstrated that these receptors were capable of inducing numerous forms of long-term potentiation (referred to as CP-AMPAR-dependent LTP) through a number of different induction protocols, including high-frequency stimulation (HFS) and theta-burst stimulation (TBS). This included a previously undemonstrated form of protein-synthesis dependent late-LTP (L-LTP) at CA1 synapses that is NMDA-receptor (NMDAR) independent. This form of plasticity was completely blocked by the selective CP-AMPAR inhibitor IEM-1460. Surprisingly, calcium/calmodulin-dependent kinase II (CaMKII), the key protein kinase that is indispensable for NMDAR-dependent LTP at CA1 synapses appeared to be not required for the induction of CP-AMPAR-dependent LTP due to the lack of effect of two separate pharmacological inhibitors (KN-62 and staurosporine) on this form of potentiation. Both KN-62 and staurosporine strongly inhibited NMDAR dependent LTP in control studies. In contrast, inhibitors for the extracellular signal-regulated kinase/mitogen-activated protein kinase (ERK/MAPK) cascade (PD98059 and U0126) significantly attenuated this CP-AMPAR-dependent LTP. Additional studies with knockout mice revealed that the ERK/MAPK signalling cascade is likely acting through p-21 activated kinase 1 (or PAK1, a Rho-GTPase associated kinase) dependent mechanisms. These results suggest that distinct synaptic signalling underlies GluR2-lacking CP-AMPAR-dependent LTP, and reinforces the recent notions that CP-AMPARs are important facilitators of synaptic plasticity in the brain. Synaptic plasticity AMPA receptors Calcium signalling ERK/MAPK LTP CaMKII GluR2 PI3K Ras L-LTP protein synthesis hippocampus CA1 memory ischemia addiction seizure PAK1 ROCK2 calcium pemeable AMPA receptors NMDA receptors electrophysiology knockout mice Western Blot 0317 0719 0307
77	Synaptic Plasticity Induced Through CP-AMPARs is Dependent on the ERK/MAPK Signalling Cascade Asrar, Suhail 15 April 2010 (has links) Recent literature has shown that AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) receptors lacking the GluR2 subunit (thus calcium permeable) are widely expressed in the CNS, especially in interneurons and glia, where they contribute to synaptic transmission and plasticity. Studies have also indicated that calcium permeable AMPARs (CP-AMPARs) are expressed and participate in synaptic regulation in principal neurons, including hippocampal pyramidal neurons. Furthermore, CP-AMPARs and their resultant calcium influx are implicated in various pathophysiological conditions such as ischemia and seizures. However, the synaptic events activated by calcium influx through CP-AMPARs remain unknown. I took advantage of genetically altered mice without (GluR2-/-) or with reduced GluR2 (GluR2+/-), thus allowing the expression and detailed analysis of synaptic CP-AMPARs in hippocampal pyramidal neurons. Utilizing electrophysiological techniques, I demonstrated that these receptors were capable of inducing numerous forms of long-term potentiation (referred to as CP-AMPAR-dependent LTP) through a number of different induction protocols, including high-frequency stimulation (HFS) and theta-burst stimulation (TBS). This included a previously undemonstrated form of protein-synthesis dependent late-LTP (L-LTP) at CA1 synapses that is NMDA-receptor (NMDAR) independent. This form of plasticity was completely blocked by the selective CP-AMPAR inhibitor IEM-1460. Surprisingly, calcium/calmodulin-dependent kinase II (CaMKII), the key protein kinase that is indispensable for NMDAR-dependent LTP at CA1 synapses appeared to be not required for the induction of CP-AMPAR-dependent LTP due to the lack of effect of two separate pharmacological inhibitors (KN-62 and staurosporine) on this form of potentiation. Both KN-62 and staurosporine strongly inhibited NMDAR dependent LTP in control studies. In contrast, inhibitors for the extracellular signal-regulated kinase/mitogen-activated protein kinase (ERK/MAPK) cascade (PD98059 and U0126) significantly attenuated this CP-AMPAR-dependent LTP. Additional studies with knockout mice revealed that the ERK/MAPK signalling cascade is likely acting through p-21 activated kinase 1 (or PAK1, a Rho-GTPase associated kinase) dependent mechanisms. These results suggest that distinct synaptic signalling underlies GluR2-lacking CP-AMPAR-dependent LTP, and reinforces the recent notions that CP-AMPARs are important facilitators of synaptic plasticity in the brain. Synaptic plasticity AMPA receptors Calcium signalling ERK/MAPK LTP CaMKII GluR2 PI3K Ras L-LTP protein synthesis hippocampus CA1 memory ischemia addiction seizure PAK1 ROCK2 calcium pemeable AMPA receptors NMDA receptors electrophysiology knockout mice Western Blot 0317 0719 0307
78	Elucidating the reversibility of ataxia Šuminaite, Daumante January 2017 (has links) Heterozygous and recently identified homozygous mutations in the SPTBN2 gene, encoding b-III spectrin, are implicated in spinocerebellar ataxia type 5 (SCA5) and spectrin-associated autosomal recessive cerebellar ataxia type 1 (SPARCA1), respectively. Our mouse model, lacking b-III spectrin (KO), mimics the progressive human phenotype displaying motor deficiencies as well as reduced Purkinje cell firing frequency followed by dendritic tree degeneration and cell death. The aims of this study were to evaluate progression of Purkinje cell degeneration following loss of b-III spectrin function and determine whether the reintroduction of C-terminus (C-trm) of b-III spectrin to the cerebellum is enough to halt, alleviate or reverse the disease phenotype. Additionally, this study investigated whether the abnormal electrophysiological and morphological phenotypes of Purkinje cells from KO mice are re-capitulated in a primary cerebellar culture and if so, whether they could be rescued by modulating calcium signaling. Morphological and histological analyses revealed that Purkinje cell degeneration is not uniform throughout the cerebellum of KO mice with Purkinje cells from posterior cerebellar regions possessing significantly smaller dendritic trees when compared to anterior cerebellum (p=0.0003, N=4-6, n=11-29). Similarly, significant reduction in Purkinje cell density was observed in posterior, not anterior regions of KO mice when compared to WT animals (p=0.014, N=3) and reduced tonic firing is most significant in Purkinje cells from the posterior cerebellum compared to WT mice (p=0.0328, N=3-6, n=11-29), with posterior KO PCs appearing to have elevated input resistance. Two-week expression of C-trm b-III spectrin in 3-month old KO animals significantly reduced Purkinje cell input resistance when compared to non-transduced cells (p=0.0139, N=4-5, n=15), but no effect was seen 9 months after viral injection. In contrast, a difference in cell surface area was no longer detected between WT and KO animals at 12 months of age following 9-months of viral expression. Nevertheless, using the elevated beam test motor deterioration was still observed 5 months after surgery (p=0.0023, N=4). In contrast, earlier stereotaxic injections at 6-weeks of age had a positive effect on mice motor performance with no deterioration in performance detected 5 months after the surgery. Latency to stay on the rotarod at 3 rpm was also significantly extended 6 months after stereotaxic injections at 6-weeks of age with slower motor deterioration (p=0.0348, N=6). In primary cerebellar cultures, Purkinje cells from KO animals exhibit an abnormal morphology with significantly more dendritic branches (p < 0.0001, N=4-7, n=35-69) and a larger total dendritic length (p=0.0079). Chronic application of 2 μM mibefradil, a T-type calcium channel blocker, was observed to reduce total dendritic length and branching in KO animal cultures bringing these morphological measurements closer to WT Purkinje cell levels. Finally although after 14 days in vitro 40% of Purkinje cells were found to be spontaneously firing, no significant difference in firing frequency (p=0.9434) or input resistance (p=0.8434, N=4, n=6-10) was detectable between WT and KO cultures. In summary, Purkinje cells in posterior cerebellar regions of KO mice were found to be more susceptible to dendritic degeneration and cellular death than cells in the anterior cerebellum. Expression of C-trm b-III spectrin at 3 months of age had an immediate effect on cell input resistance and a modest effect on Purkinje cell morphology but no effect on motor decline. Viral injections at 6-weeks of age, however, significantly slowed motor decline. Although an abnormal KO cell morphology could be successfully recapitulated in primary cell culture, it was not possible to discern any differences in electrophysiological properties. Nevertheless, the abnormal cell morphology was successfully modified in vitro by manipulating calcium signaling via T-type calcium channels.
79	The effects of CaMKII signaling on neuronal viability Ashpole, Nicole M. 10 December 2013 (has links) Indiana University-Purdue University Indianapolis (IUPUI). / Calcium/calmodulin-dependent protein kinase II (CaMKII) is a critical modulator of synaptic function, plasticity, and learning and memory. In neurons and astrocytes, CaMKII regulates cellular excitability, cytoskeletal structure, and cell metabolism. A rapid increase in CaMKII activity is observed within the first few minutes of ischemic stroke in vivo; this calcium-dependent process is also observed following glutamate stimulation in vitro. Activation of CaMKII during pathological conditions is immediately followed by inactivation and aggregation of the kinase. The extent of CaMKII inactivation is directly correlated with the extent of neuronal damage. The studies presented here show that these fluctuations in CaMKII activity are not correlated with neuronal death; rather, they play a causal role in neuronal death. Pharmacological inhibition of CaMKII in the time immediately surrounding glutamate insult protects cultured cortical neurons from excitotoxicity. Interestingly, pharmacological inhibition of CaMKII during excitotoxic insult also prevents the aggregation and prolonged inactivation of the kinase, suggesting that CaMKII activity during excitotoxic glutamate signaling is detrimental to neuronal viability because it leads to a prolonged loss of CaMKII activity, culminating in neuronal death. In support of this, CaMKII inhibition in the absence of excitotoxic insult induces cortical neuron apoptosis by dysregulating intracellular calcium homeostasis and increasing excitatory glutamate signaling. Blockade of the NMDA-receptors and enzymatic degradation of the extracellular glutamate signal affords neuroprotection from CaMKII inhibition-induced toxicity. Co-cultures of neurons and glutamate-buffering astrocytes also exhibit this slow-induced excitotoxicity, as CaMKII inhibitors reduce glutamate uptake within the astrocytes. CaMKII inhibition also dysregulates calcium homeostasis in astrocytes and leads to increased ATP release, which was neurotoxic when applied to naïve cortical neurons. Together, these findings indicate that during aberrant calcium signaling, the activation of CaMKII is toxic because it supports aggregation and prolonged inactivation of the kinase. Without CaMKII activity, neurons and astrocytes release stores of transmitters that further exacerbate neuronal toxicity. CaMKII Neuron Neurotransmitter Neurotoxicity Neural transmission -- Research Neurotoxicology Protein kinases Cellular signal transduction Calcium -- Physiological effect Calmodulin -- Antagonists Apoptosis
80	THE MEMBRANE BLOCK TO POLYSPERMY IN MAMMALIAN EGGS; ANALYSES OF CALCIUM SIGNALING AND ACTIN DYNAMICS DURING FERTILIZATION Nicole Leigh Branca (15353446) 27 April 2023 (has links) <p> </p> <p>When mammalian eggs are fertilized, they undergo an egg-to-embryo transition during which different egg activation events take place. Egg activation events include the establishment of blocks to polyspermy, which prevent multiple sperm from fertilizing an egg. One of these blocks to polyspermy occurs at the level of the egg plasma membrane (the membrane block to polyspermy). Previous work in our lab provides evidence that the mammalian membrane block to polyspermy is mediated by sperm-induced calcium signaling and the egg’s actomyosin cytoskeleton (McAvey et al., 2002). This thesis research builds upon this foundation, testing hypotheses about two specific effector molecules, one involved in calcium signaling and one with the actin cytoskeleton, and also developing the use of an actin probe for live-cell imaging, with the goal of imaging actin dynamics in eggs undergoing fertilization. Specifically, we examined the calcium effector molecule Ca2+/Calmodulin-dependent-protein kinase IIg (<strong>CaMKII</strong>g), based on previous studies showing that CaMKII plays a role in the membrane block (Gardner et al., 2007) and that the g isoform of CaMKII is necessary and sufficient for eggs to complete meiosis (Backs et al., 2010). We tested the hypothesis that CaMKIIg would mediate the membrane block to polyspermy but found that egg activation driven by expression of a constitutively active form of CaMKIIg was not sufficient to establish the membrane block. Our studies of the actin cytoskeleton focused on the Arp2/3 complex as a candidate. We tested the hypothesis that Arp2/3, which mediates actin filament branching, was involved in membrane block establishment, building on the finding that disruption of actin with the drug cytochalasin D impairs the membrane block (McAvey et al., 2022). These studies used the Arp2/3 inhibitor CK666, predicting that we would see increased sperm incorporation in CK666-treated eggs. However, an assay of sperm incorporation over time indicated that Arp2/3 may not play a significant role in the membrane block to polyspermy, although follow-up studies will be beneficial. Lastly, the actin probe SiR- Actin was assessed for use on oocytes undergoing live-cell imaging during meiosis I and II. Oocytes were treated with differing concentrations of SiR-Actin and live cell imaged while maturing through meiosis I or completing meiosis II. Higher doses and longer exposure to SiR- Actin caused abnormalities in oocytes during meiosis I but not in eggs completing meiosis II. Together, this work sets the stage of a range of future studies into the mammalian membrane block to polyspermy. </p> Reproduction Membrane Block to Polyspermy mammalian fertilization ARP2/3 complex CaMKII y Calcium signaling actin cytoskeletal dynamics Oocyte Meiosis SiR-Actin actin probes Live cell imaging analysis

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