Expression and Function of the Na ⁺-K ⁺ATPase α-Isoforms in Smooth Muscle: Evidence from Transgenic Mice

PRITCHARD, TRACY J.

08 October 2007

No description available.

transgenic mice

hypertension

vascular smooth muscle

Na+-Ca2+ exchanger

The functional study of Na+/Ca2+ exchanger in vascular smooth muscle cells

Zhao, Jun, e52677@ems.rmit.edu.au

January 2007

Na+/Ca2+ exchanger (NCX) is a membrane protein which can mediate either Ca2+ entry (reverse mode) or exit (forward mode) in cells. As one of the major Ca2+ transport systems, NCX is postulated to play a critical role in the vascular smooth muscle cell. The aims of the present study are to firstly demonstrate the functional existence of NCX in vascular smooth muscle (including aorta and arteriole); to clarify the modulation of NCX; to explore the selectivity of NCX inhibitor KB-R7943; and lastly to investigate the role of NCX in the myogenic response. KB-R7943 has been widely used as a NCX inhibitor. The study investigated its pharmacological actions in rat aorta on a variety of Ca2+ dependent systems. Rat aortic rings were used. The constriction to low extracellular [Na+] is a functional response mediated by NCX operating in reverse mode. The data demonstrate that 10 µM KB-R7943 inhibited L-type Ca2+ channel, the capacitative Ca2+ entry and  adrenergic receptor pathway. Nevertheless, KB-R7943 can be used as a selective inhibitor of NCX at the lower concentration of 1 µM in rat aortic rings. The study investigated whether the endothelium could modulate NCX in rat aortic rings. Lowering extracellular [Na+] to 1.18 mM induced constriction in endothelium denuded rat aortic rings, but only a small constriction in endothelium intact rat aortic rings. In endothelium intact rat aortic rings, the guanylate cyclise inhibitor ODQ (1 µM) and the nitric oxide synthase inhibitor L-NAME (50 µM) greatly amplified the vasoconstriction to lowering extracellular [Na+], but had no effect when the endothelium was removed. The adenylate cyclise inhibitor SQ 22536 (100 µM) and the cyclooxygenase inhibitor indomethacin (10 M) showed no significant effect on the low-Na+ induced vasoconstriction in either endothelium denuded or intact aortic rings. The results suggest that endothelium modulated the NCX operation via the nitric oxide/guanylate cyclase, not the adenylate cyclase system; further prostanoids including prostacyclin was not involved. The interaction between nitric oxide and NCX was furt her explored using the nitric oxide donor sodium nitroprusside. Endothelium denuded rat aortic rings were preconstricted to the same extent with either low Na+ (1.18 mM), or the thromboxane A2 agonist U46619 (0.1 µM) or high K+ (80 mM). The vasorelaxation of SNP (30 nM) in low Na+ constriction was significantly larger compared to other agents. This indicates that NO has a special antagonism of low Na+ constriction and a hypothesis is proposed involving Na+/K+ ATPase. The investigation of NCX is mainly conducted in large vessels; much less evidence is available for small resistance vessels. The study investigated the role of NCX on myogenic response in pressurized cremaster muscle arterioles. Reducing extracellular [Na+] resulted in graded vasoconstriction which was inhibited by NCX inhibitor SEA0400 (1 µM). Myogenic vasoconstriction and the concomitant rise in internal [Ca2+] were induced by a transmural pressure increase from 70 to 120 mmHg which was prevented by NCX inhibitor: SEA0400 (1 µM). In conclusion, the present study suggests that NCX contributes to the myogenic response in cremaster arteriole.

Na+/Ca2+ exchanger

vascular smooth muscle cell

aorta

arteriole

myogenic

KB-R7943

SEA0400

nitric oxide

endothelium.

Membrane potential and intracellular cyclic AMP as regulators of calcium homeostasis in formyl peptide-activated human neutrophils : lessons from chronic granulomatous disease

Tintinger, Gregory Ronald

04 November 2005

Neutrophils playa key role in the systemic inflammatory response which may lead to serious tissue injury and multiple organ dysfunction. In this setting, activated neutrophils, largely in response to tumour necrosis factor-alpha (TNF-α), secrete reactive oxidants, granule proteases and bioactive lipids, as well as pro-inflammatory cytokines, emphasising the importance of these cells as targets for anti-inflammatory therapies. There are, however, only a few currently available agents that directly modulate neutrophil pro-inflammatory responses in clinical practice, with corticosteroids being relatively ineffective against these cells. Although, the anti-inflammatory potential of cAMP-elevating agents has been recognised, the exact molecular/biochemical mechanisms which underlie the anti-inflammatory actions of epinephrine and related β-agonists with neutrophils, have not been established. Epinephrine treatment of neutrophils resulted in increased intracellular cAMP and dose-related inhibition of both superoxide production and elastase release, which was potentiated by the type 4 phosphodiesterase inhibitor, rolipram, further supporting a cAMP-mediated effect. Although epinephrine did not affect the release of Ca2+ from neutrophil intracellular stores, the rate of clearance of cytosolic Ca2+ was accelerated by this agent. In the setting of decreased efflux and a reduction in store-operated influx of Ca2+, these effects of epinephrine are compatible with enhancement of the cAMP-dependent Ca2+ sequestering/resequestering endo-membrane Ca2+-ATPase. Epinephrine therefore down-regulates the pro-inflammatory activation of neutrophils by cAMP-mediated enhancement of the clearance of cytosolic Ca2+. Comparison of the effects of 4 selective (fenoterol, formoterol, salbutamol and salmeterol) and 3 non-selective (epinephrine, norepinephrine and isoproterenol) β-adrenoreceptor agonists, on the pro-inflammatory activities of human neutrophils, demonstrated that the agents tested clearly differ with respect to anti-inflammatory potential. Epinephrine, isoproterenol, fenoterol and formoterol significantly increased intracellular concentrations of cAMP in neutrophils, an activity which was paralleled by inhibition of the production of reactive oxidants and release of elastase from FMLP-activated cells. Salbutamol and salmeterol on the other hand, did not cause significant suppression of the pro-inflammatory activities of these cells. The effect of norepinephrine was intermediate between these two groups. The inhibitory effects of βagonists are mediated via β2-adrenergic receptors on the neutrophil membrane. The relationship between activation of NAOPH oxidase, alterations in membrane potential and triggering of Ca2+ fluxes in human phagocytes has been investigated using neutrophils from 4 subjects with chronic granulomatous disease (CGO). Activation of CGO neutrophils was accompanied by a prolonged increase in cytosolic Ca2+, occurring in the setting of trivial membrane depolarisation and accelerated influx of Ca2+. This was associated with hyperactivity of the cells with excessive elastase release, which was attenuated by the type 4 phosphodiesterase inhibitor, rolipram. These findings support the involvement of NAOPH oxidase in regulating membrane potential and Ca2+ influx in activated neutrophils, and may explain the disordered inflammatory responses, and granuloma formation, which are characteristic of CGO. Store-operated influx of Ca2+ into activated neutrophils is stringently regulated, presumably to prevent hyperactivation of the cells. The major contributors to this physiologic, anti-inflammatory process are NAOPH oxidase which, by its membrane depolarising actions excludes extracellular Ca2+, and the plasma membrane and endomembrane Ca2+-ATPases, which mediate clearance of store-derived cation. Subsequent influx of the cation, through store-operated Ca2+ channels is controlled by the relatively slow, restraining, membrane repolarising action of the Na+/Ca2+ exchanger, enabling efficient diversion of incoming cation into stores. / Thesis (DPhil (Immunology))--University of Pretoria, 2005. / Immunology / unrestricted

Adrenaline

Elastases

Na+/ca2+ exchanger

Membrane depolarisation

Neutrophils

Chemoattractants

Calcium

Chronic granulomatous disease

UCTD

Estudos estruturais de fragmentos do trocador de Na+/Ca2+ por RMN em solução / Structural studies of fragments derived from the Na+/Ca2+ exchanger by solution NMR

Stabelini, Tatiana Comporte

08 October 2018

Proteínas de membrana estão envolvidas em processos fisiológicos essenciais como, por exemplo, a manutenção do equilíbrio iônico e sinalização intracelular. No entanto, apesar do envolvimento em inúmeros processos fisiológicos e de grande interesse farmacêutico, o estudo estrutural de proteínas de membrana ainda é um processo custoso e muito mais complexo do que o estudo estrutural de proteínas solúveis. Os trocadores de Na+/Ca2+ são proteínas de membrana que atuam na manutenção da homeostase de Ca2+ intracelular e estão envolvidos em processos patológicos como doenças cardíacas. Estes trocadores estão presentes em diversas espécies de mamíferos (NCX) e insetos, por exemplo, na mosca Drosophila melanogaster (CALX). A topologia destas proteínas é constituída de dois domínios. O domínio transmembranar, que contém dois segmentos de 5 hélices transmembranares (TMH) e é responsável por promover o transporte específico de íons Ca2+ e Na+ através da membrana, e o domínio citoplasmático, responsável por regular a atividade do trocador. O domínio citoplasmático consiste de uma alça que contém dois domínios sensores de Ca2+ intracelular (CBD1 e CBD2). Trabalhos mostraram que o trocador CALX é inibido pela ligação de Ca em CBD1, enquanto que trocadores NCX são ativados. As regiões citosólicas que conectam CBD1 e CBD2 à TMH5 e TMH6 são conservadas e ainda não foram caracterizadas estruturalmente. Adjacente à TMH5 há um segmento anfipático, denominado exchanger inhibitory peptide (XIP), que está envolvido no mecanismo de regulação do trocador. Na ausência de dados estruturais do CALX completo, o estudo de TMH5-XIP poderá aumentar a compreensão sobre a estrutura e o funcionamento do trocador. A construção TMH5-XIP foi fusionada à MBP no N-terminal e a uma sequência de 8 histidinas no C-terminal. Apesar da expressão da proteína de fusão ter sido bem sucedida, problemas de precipitação e ineficiência durante a clivagem da conexão com a MBP impediram a conclusão dos estudos estruturais. Logo, uma construção menor, contendo apenas a região equivalente ao XIP, foi estudada por espectroscopia de RMN em solução e dicroísmo circular. XIP forma uma 310-hélice a baixa temperatura, 7 oC, que se desestabiliza a maior temperatura, 27 oC. Estes dados permitem a formulação de hipóteses sobre o papel de XIP no mecanismo de regulação do domínio transmembranar de CALX. / Membrane proteins are involved in essential physiological processes such as maintenance of the ionic balance and intracellular signaling. However, despite their role in numerous physiological processes of well-recognized pharmaceutical relevance, structural studies of membrane proteins remain being more complex than structural studies of globular proteins. Na+/Ca2+ exchangers (NCX) are membrane proteins that play essential roles in the maintenance of the intracellular Ca2+ homeostasis. Not surprisingly, the NCXs are involved in pathologies such as heart diseases. These exchangers are present in several species of mammals (NCX) and insects, for example, in the fly Drosophila melanogaster (CALX). The topology of these proteins consists of a transmembrane and a hydrophilic domain. The transmembrane domain corresponds to two segments of 5 transmembrane helices (TMH) forming a 10-helix bundle that is responsible for the specific transport of Ca2+ and Na+ across the cellular membrane. The hydrophilic domain is composed of a large cytoplasmic loop, which is associated with the regulation of the ion exchange activity of the transmembrane domain. The loop contains two Ca2+-sensors domains, CBD1 and CBD2, and uncharacterized regions. Studies showed that Ca2+ binding to CBD1 inhibits the CALX, whereas it activates the NCX. The juxtamembrane cytosolic regions linking the CBD1 and CBD2 domains to the TMH5 and TMH6, respectively, are highly conserved but have not yet been structurally characterized. The segment near TMH5 is amphipathic, and it is also called exchanger inhibitory peptide (XIP). In the absence of a three-dimensional structure of the complete CALX, the study of TMH5-XIP may contribute to our understanding of the structure and operation of the exchanger. In order to study TMH5-XIP, it was fused to an MBP tag at the N-terminus, and to a sequence of 8 histidines at the C-terminus. Although the expression of the fusion protein was successful, precipitation and inefficient MBP-tag cleavage prevented the isolation of pure TMH5-XIP for structural studies. Hence, a smaller construct, containing only the region equivalent to XIP, was studied by NMR spectroscopy in solution and circular dichroism. The structure assumed by XIP in solution is temperature dependent, being intrinsically disordered at 27 C or a 310-helix at 7 C, respectively. These findings allowed us to infer how XIP could participate in the CALX regulation mechanism.

CALX

CALX

Na+/Ca2+ Exchanger

Nuclear Magnetic Resonance

Ressonância Magnética Nuclear

TMH5

TMH5

Trocador Na+/Ca2+

XIP

XIP

Estudos estruturais de fragmentos do trocador de Na+/Ca2+ por RMN em solução / Structural studies of fragments derived from the Na+/Ca2+ exchanger by solution NMR

Tatiana Comporte Stabelini

08 October 2018

Proteínas de membrana estão envolvidas em processos fisiológicos essenciais como, por exemplo, a manutenção do equilíbrio iônico e sinalização intracelular. No entanto, apesar do envolvimento em inúmeros processos fisiológicos e de grande interesse farmacêutico, o estudo estrutural de proteínas de membrana ainda é um processo custoso e muito mais complexo do que o estudo estrutural de proteínas solúveis. Os trocadores de Na+/Ca2+ são proteínas de membrana que atuam na manutenção da homeostase de Ca2+ intracelular e estão envolvidos em processos patológicos como doenças cardíacas. Estes trocadores estão presentes em diversas espécies de mamíferos (NCX) e insetos, por exemplo, na mosca Drosophila melanogaster (CALX). A topologia destas proteínas é constituída de dois domínios. O domínio transmembranar, que contém dois segmentos de 5 hélices transmembranares (TMH) e é responsável por promover o transporte específico de íons Ca2+ e Na+ através da membrana, e o domínio citoplasmático, responsável por regular a atividade do trocador. O domínio citoplasmático consiste de uma alça que contém dois domínios sensores de Ca2+ intracelular (CBD1 e CBD2). Trabalhos mostraram que o trocador CALX é inibido pela ligação de Ca em CBD1, enquanto que trocadores NCX são ativados. As regiões citosólicas que conectam CBD1 e CBD2 à TMH5 e TMH6 são conservadas e ainda não foram caracterizadas estruturalmente. Adjacente à TMH5 há um segmento anfipático, denominado exchanger inhibitory peptide (XIP), que está envolvido no mecanismo de regulação do trocador. Na ausência de dados estruturais do CALX completo, o estudo de TMH5-XIP poderá aumentar a compreensão sobre a estrutura e o funcionamento do trocador. A construção TMH5-XIP foi fusionada à MBP no N-terminal e a uma sequência de 8 histidinas no C-terminal. Apesar da expressão da proteína de fusão ter sido bem sucedida, problemas de precipitação e ineficiência durante a clivagem da conexão com a MBP impediram a conclusão dos estudos estruturais. Logo, uma construção menor, contendo apenas a região equivalente ao XIP, foi estudada por espectroscopia de RMN em solução e dicroísmo circular. XIP forma uma 310-hélice a baixa temperatura, 7 oC, que se desestabiliza a maior temperatura, 27 oC. Estes dados permitem a formulação de hipóteses sobre o papel de XIP no mecanismo de regulação do domínio transmembranar de CALX. / Membrane proteins are involved in essential physiological processes such as maintenance of the ionic balance and intracellular signaling. However, despite their role in numerous physiological processes of well-recognized pharmaceutical relevance, structural studies of membrane proteins remain being more complex than structural studies of globular proteins. Na+/Ca2+ exchangers (NCX) are membrane proteins that play essential roles in the maintenance of the intracellular Ca2+ homeostasis. Not surprisingly, the NCXs are involved in pathologies such as heart diseases. These exchangers are present in several species of mammals (NCX) and insects, for example, in the fly Drosophila melanogaster (CALX). The topology of these proteins consists of a transmembrane and a hydrophilic domain. The transmembrane domain corresponds to two segments of 5 transmembrane helices (TMH) forming a 10-helix bundle that is responsible for the specific transport of Ca2+ and Na+ across the cellular membrane. The hydrophilic domain is composed of a large cytoplasmic loop, which is associated with the regulation of the ion exchange activity of the transmembrane domain. The loop contains two Ca2+-sensors domains, CBD1 and CBD2, and uncharacterized regions. Studies showed that Ca2+ binding to CBD1 inhibits the CALX, whereas it activates the NCX. The juxtamembrane cytosolic regions linking the CBD1 and CBD2 domains to the TMH5 and TMH6, respectively, are highly conserved but have not yet been structurally characterized. The segment near TMH5 is amphipathic, and it is also called exchanger inhibitory peptide (XIP). In the absence of a three-dimensional structure of the complete CALX, the study of TMH5-XIP may contribute to our understanding of the structure and operation of the exchanger. In order to study TMH5-XIP, it was fused to an MBP tag at the N-terminus, and to a sequence of 8 histidines at the C-terminus. Although the expression of the fusion protein was successful, precipitation and inefficient MBP-tag cleavage prevented the isolation of pure TMH5-XIP for structural studies. Hence, a smaller construct, containing only the region equivalent to XIP, was studied by NMR spectroscopy in solution and circular dichroism. The structure assumed by XIP in solution is temperature dependent, being intrinsically disordered at 27 C or a 310-helix at 7 C, respectively. These findings allowed us to infer how XIP could participate in the CALX regulation mechanism.

CALX

Ressonância Magnética Nuclear

TMH5

Trocador Na+/Ca2+

XIP

CALX

Na+/Ca2+ Exchanger

Nuclear Magnetic Resonance

TMH5

XIP

Estudo da dinâmica funcional dos domínios regulatórios do trocador de Na+/Ca2+ de Drosophila melanogaster por ressonância magnética nuclear em solução / Functional dynamics of the regulatory domains from the Drosophila melanogaster\'s Na+/Ca2+ exchanger by nuclear magnetic resonance in solution.

Abiko, Layara Akemi

20 March 2015

O trocador de Na+/Ca2+ (NCX) constitui um dos principais mecanismos de extrusão de Ca2+ intracelular em células excitáveis. Foi demonstrado que alterações no funcionamento do NCX estão relacionadas a diversas situações patológicas. Por este motivo, o entendimento do mecanismo molecular da manutenção da concentração de Ca2+ intracelular via NCX é importante para a compreensão do funcionamento do trocador, bem como para o desenvolvimento de fármacos. Além de transportar Na+/Ca2+, o NCX também é regulado por esses íons. Este trocador é composto por dois domínios transmembranares, cada um deles contendo 5 α-hélices (TM), e uma grande alça intracelular que conecta as hélices TM5 e TM6. O domínio transmembranar é responsável por catalisar o transporte de Na+/Ca2+ através da bicamada lipídica, enquanto que a alça citoplasmática está envolvida com a regulação do trocador. Esta alça contém dois domínios sensores de Ca2+ adjacentes, denominados CBD1 e CBD2. Apesar da importância fisiológica do NCX, o mecanismo de regulação alostérica do trocador por Ca2+ intracelular permanece desconhecido. Neste trabalho, a espectroscopia de ressonância magnética nuclear (RMN) de alta resolução foi utilizada para investigar a conformação e a dinâmica de CBD1 e CBD2 do trocador de Na+/Ca2+ de Drosophila melanogaster (CALX), isolados ou conectados covalentemente em uma construção denominada CBD12. Um total de 98% das ressonâncias da cadeia principal de CBD1 isolado na presença de Ca2+ foi assinalado, enquanto que na ausência de Ca2+, assinalamentos para apenas uma parte da cadeia principal puderam ser obtidos. Os assinalamentos adquiridos para CBD12 foram baseados na análise de um conjunto de espectros de RMN tridimensional heteronuclear e por comparação com os espectros dos domínios isolados. Uma análise preliminar dos deslocamentos químicos e dos parâmetros de relaxação de 15N obtidos para CBD1 indicou que este domínio é flexível na ausência de Ca2+, mas torna-se rígido após a adição deste íon. As medidas das velocidades de relaxação de 15N e de acoplamentos dipolares residuais (RDCs) de 1H-15N realizadas para CBD12 nas formas apo e holo indicaram que a ligação de Ca2+ em CBD1 estabiliza uma orientação rígida entre os domínios. A análise dos RDCs de 1H-15N mostrou ainda que a orientação média entre CBD1 e CBD2 é praticamente linear na ausência de Ca2+, enquanto que um ângulo menor é assumido após a adição deste íon. Os dados descritos nesta tese suportam um modelo de regulação alostérica em que a modulação da plasticidade de CBD12 pela ligação de Ca2+ no domínio CBD1 controla a abertura e o fechamento do trocador. / The Na+/Ca2+ exchanger (NCX) is a major mechanism for the extrusion of intracellular Ca2+ in excitable cells. It was demonstrated that altered functioning of this protein is related to various pathological situations. Therefore, the understanding of the molecular mechanism for maintaining the intracellular Ca2+ concentration by means of the NCX is important to understand the functioning of the exchanger and to develop drug-based therapies. Besides transporting Na+/Ca2+, the exchanger is also regulated by these ions. The NCX is composed of two transmembrane domains, each of them containing 5 transmembrane alpha-helices (TM), and a very large cytosolic loop that connects TM5 to TM6. The transmembrane domains are responsible for catalyzing the transport of Na+ and Ca2+ ions across the lipid bilayer, while the cytosolic loop is involved in regulation of the exchanger activity. It contains two regulatory Ca2+- binding domains, called CBD1 and CBD2, that appear in tandem. Despite the physiological importance of the NCX, the mechanism of allosteric regulation of the exchanger by intracellular calcium remains unclear. In this work we used high-resolution NMR spectroscopy to study the conformation and the dynamics of the two Ca2+-binding regulatory domains of Drosophila\'s Na+/Ca2+ exchanger (CALX), CBD1 and CBD2, in isolation as well as in a covalent construct called CBD12. Complete backbone NMR resonance assignments were obtained for the isolated CBD1 domain in the Ca2+-bound state, while partial assignments were obtained for CBD1 in the free state. Partial backbone NMR resonance assignments were obtained for the CBD12 construct through the analysis of a standard set of triple resonance NMR spectra. Additional assignments were obtained by comparison with the isolated CBD1 and CBD2 domains. A preliminary analysis of NMR chemical shifts and 15N relaxation data obtained for CBD1 indicates that this domain displays considerable amount of flexibility in the free state, but becomes more rigid upon Ca2+-binding. NMR 15N relaxation rates and 1H-15N residual dipolar couplings (RDCs) obtained for the Apo and Ca2+-bound states of the CBD12 domain indicate that calcium binding stabilizes a rigid inter-domain orientation. Analysis of 1H-15N RDCs further shows that Drosophila\'s CBD12 domain assumes an almost linear inter-domain orientation in the absence of Ca2+, while a smaller inter-domain angle was found in its presence. These findings support a model in which modulation of CBD12 plasticity by the binding of Ca2+ to the CBD1 domain controls the opening and closing of the exchanger.

15N relaxation

Acoplamentos dipolares residuais

Dinâmica de proteínas

Espectroscopy nuclear magnetic resonance

Na+/Ca2+ exchanger

Protein dynamics

Relaxação de 15N

Residual dipolar couplings

RMN em solução

Solution NMR

Trocador de Na+/Ca2+

Estudo da dinâmica funcional dos domínios regulatórios do trocador de Na+/Ca2+ de Drosophila melanogaster por ressonância magnética nuclear em solução / Functional dynamics of the regulatory domains from the Drosophila melanogaster\'s Na+/Ca2+ exchanger by nuclear magnetic resonance in solution.

Layara Akemi Abiko

20 March 2015

O trocador de Na+/Ca2+ (NCX) constitui um dos principais mecanismos de extrusão de Ca2+ intracelular em células excitáveis. Foi demonstrado que alterações no funcionamento do NCX estão relacionadas a diversas situações patológicas. Por este motivo, o entendimento do mecanismo molecular da manutenção da concentração de Ca2+ intracelular via NCX é importante para a compreensão do funcionamento do trocador, bem como para o desenvolvimento de fármacos. Além de transportar Na+/Ca2+, o NCX também é regulado por esses íons. Este trocador é composto por dois domínios transmembranares, cada um deles contendo 5 α-hélices (TM), e uma grande alça intracelular que conecta as hélices TM5 e TM6. O domínio transmembranar é responsável por catalisar o transporte de Na+/Ca2+ através da bicamada lipídica, enquanto que a alça citoplasmática está envolvida com a regulação do trocador. Esta alça contém dois domínios sensores de Ca2+ adjacentes, denominados CBD1 e CBD2. Apesar da importância fisiológica do NCX, o mecanismo de regulação alostérica do trocador por Ca2+ intracelular permanece desconhecido. Neste trabalho, a espectroscopia de ressonância magnética nuclear (RMN) de alta resolução foi utilizada para investigar a conformação e a dinâmica de CBD1 e CBD2 do trocador de Na+/Ca2+ de Drosophila melanogaster (CALX), isolados ou conectados covalentemente em uma construção denominada CBD12. Um total de 98% das ressonâncias da cadeia principal de CBD1 isolado na presença de Ca2+ foi assinalado, enquanto que na ausência de Ca2+, assinalamentos para apenas uma parte da cadeia principal puderam ser obtidos. Os assinalamentos adquiridos para CBD12 foram baseados na análise de um conjunto de espectros de RMN tridimensional heteronuclear e por comparação com os espectros dos domínios isolados. Uma análise preliminar dos deslocamentos químicos e dos parâmetros de relaxação de 15N obtidos para CBD1 indicou que este domínio é flexível na ausência de Ca2+, mas torna-se rígido após a adição deste íon. As medidas das velocidades de relaxação de 15N e de acoplamentos dipolares residuais (RDCs) de 1H-15N realizadas para CBD12 nas formas apo e holo indicaram que a ligação de Ca2+ em CBD1 estabiliza uma orientação rígida entre os domínios. A análise dos RDCs de 1H-15N mostrou ainda que a orientação média entre CBD1 e CBD2 é praticamente linear na ausência de Ca2+, enquanto que um ângulo menor é assumido após a adição deste íon. Os dados descritos nesta tese suportam um modelo de regulação alostérica em que a modulação da plasticidade de CBD12 pela ligação de Ca2+ no domínio CBD1 controla a abertura e o fechamento do trocador. / The Na+/Ca2+ exchanger (NCX) is a major mechanism for the extrusion of intracellular Ca2+ in excitable cells. It was demonstrated that altered functioning of this protein is related to various pathological situations. Therefore, the understanding of the molecular mechanism for maintaining the intracellular Ca2+ concentration by means of the NCX is important to understand the functioning of the exchanger and to develop drug-based therapies. Besides transporting Na+/Ca2+, the exchanger is also regulated by these ions. The NCX is composed of two transmembrane domains, each of them containing 5 transmembrane alpha-helices (TM), and a very large cytosolic loop that connects TM5 to TM6. The transmembrane domains are responsible for catalyzing the transport of Na+ and Ca2+ ions across the lipid bilayer, while the cytosolic loop is involved in regulation of the exchanger activity. It contains two regulatory Ca2+- binding domains, called CBD1 and CBD2, that appear in tandem. Despite the physiological importance of the NCX, the mechanism of allosteric regulation of the exchanger by intracellular calcium remains unclear. In this work we used high-resolution NMR spectroscopy to study the conformation and the dynamics of the two Ca2+-binding regulatory domains of Drosophila\'s Na+/Ca2+ exchanger (CALX), CBD1 and CBD2, in isolation as well as in a covalent construct called CBD12. Complete backbone NMR resonance assignments were obtained for the isolated CBD1 domain in the Ca2+-bound state, while partial assignments were obtained for CBD1 in the free state. Partial backbone NMR resonance assignments were obtained for the CBD12 construct through the analysis of a standard set of triple resonance NMR spectra. Additional assignments were obtained by comparison with the isolated CBD1 and CBD2 domains. A preliminary analysis of NMR chemical shifts and 15N relaxation data obtained for CBD1 indicates that this domain displays considerable amount of flexibility in the free state, but becomes more rigid upon Ca2+-binding. NMR 15N relaxation rates and 1H-15N residual dipolar couplings (RDCs) obtained for the Apo and Ca2+-bound states of the CBD12 domain indicate that calcium binding stabilizes a rigid inter-domain orientation. Analysis of 1H-15N RDCs further shows that Drosophila\'s CBD12 domain assumes an almost linear inter-domain orientation in the absence of Ca2+, while a smaller inter-domain angle was found in its presence. These findings support a model in which modulation of CBD12 plasticity by the binding of Ca2+ to the CBD1 domain controls the opening and closing of the exchanger.

Acoplamentos dipolares residuais

Dinâmica de proteínas

Relaxação de 15N

RMN em solução

Trocador de Na+/Ca2+

15N relaxation

Espectroscopy nuclear magnetic resonance

Na+/Ca2+ exchanger

Protein dynamics

Residual dipolar couplings

Solution NMR

Mécanismes sous-jacents aux différences sexuelles dans la fibrillation auriculaire

Thibault, Simon

11 1900

La fibrillation auriculaire (FA) est l’arythmie cardiaque la plus fréquente et elle peut entraîner des complications médicales sévères, notamment des accidents vasculaires cérébraux. On observe des différences sexuelles importantes dans la présentation clinique de la FA. Son incidence est 1,5 à 2 fois plus élevée chez les hommes, tandis que les femmes tendent à développer de la FA plus tardivement et plus sévèrement. Malheureusement, on ignore toujours les causes de ces différences sexuelles. La FA est une pathologie multifactorielle généralement causée par un débalancement des propriétés électrophysiologiques et/ou structurelles des oreillettes favorisant l’initiation et/ou le maintien de cette arythmie. Le but de ce projet est de déterminer s’il existe des différences sexuelles parmi les mécanismes impliqués dans la pathogenèse de la FA chez la souris. Sachant que les hormones sexuelles peuvent avoir un impact considérable sur l’électrophysiologie cardiaque, un objectif complémentaire de ce projet est de déterminer la contribution des hormones sexuelles dans les différences observées. Au cours de ce projet, nous avons découvert que la prédisposition masculine à la FA est également retrouvée chez la souris mâle. Nous avons identifié des différences sexuelles dans la régulation du calcium intracellulaire favorisant l’initiation de la FA chez les mâles. Celles-ci sont reliées à une expression et une activité plus élevée de l’échangeur Na+-Ca2+ chez les mâles. Nous avons également observé que le maintien de la FA était favorisé par des oreillettes de plus grande taille et par une latéralisation plus prononcée des connexines chez les mâles. L’orchiectomie réduit la susceptibilité des mâles à la FA en diminuant la latéralisation des connexines ainsi que la taille des cardiomyocytes auriculaires, suggérant un rôle des androgènes. À terme, ce projet permettra de mieux comprendre les mécanismes impliqués dans les différences sexuelles dans la pathogenèse de la FA. Une meilleure compréhension de ces mécanismes pourrait mener à une approche thérapeutique mieux adaptée au sexe des patients, pour une meilleure prise en charge de ceux-ci. / Atrial fibrillation (AF) is the most common type of cardiac arrhythmia, and it can lead to severe medical complications, including stroke. There are significant sex differences in the clinical presentation of AF. Its incidence is 1.5- to 2-fold higher in men, whereas women tend to develop AF later and more severely. Unfortunately, the mechanisms underlying these sex differences remain unknown. AF is a multifactorial pathology generally caused by an imbalance in electrophysiological and/or structural properties of the atria that promote AF initiation and/or maintenance. The aim of this project is to determine whether there are sex differences among the mechanisms involved in the pathogenesis of AF in mice.. Knowing that sex hormones can have a considerable impact on cardiac electrophysiology, a complementary objective of this project was to explore the contribution of sex hormones in the sex differences we observed. We first discovered that the male predisposition to AF is also found in mice. We have identified major sex differences in the regulation of intracellular calcium that promote AF initiation in males. These differences are related to a higher Na+-Ca2+ exchanger expression and function in males. We have also observed that AF maintenance was favoured by larger atria and more pronounced lateralization of connexins in males. Orchiectomy reduced AF susceptibility of males by reducing connexin lateralization and the dimensions of atrial myocytes, suggesting a role for androgens. Ultimately, this project will provide a better understanding of the mechanisms underlying sex differences in the pathogenesis of AF. This information could lead to a therapeutic approach better adapted to the sex of the patients, for a better management of AF.

Fibrillation auriculaire

Arythmie cardiaque

Différences sexuelles

Hormones sexuelles

Homéostasie calcique

Échangeur Na+-Ca2+

Connexines

Souris

Atrial fibrillation

Cardiac arrhythmia

Sex differences

Sex hormones

Calcium handling

Ionic currents

Na+ -Ca2+ exchanger

Connexins

Mice