Mecanismo associados à  perda da regulação da nox1 NADPH oxidase pela dissulfeto isomerase proteica em células com ativação sustentada da via ras / Mechanisms associated with loss of regulation of NADPH oxidase nox1 by protein disulfide isomerase in cells with sustained activation of the ras pathway

Tiphany Coralie de Bessa

29 March 2018

Dissulfeto isomerase proteica como a PDIA1 tem sido implicada na progressão do câncer, porém os mecanismos envolvidos ainda não foram claramente identificados. Previamente, nós demonstramos um importante efeito da PDIA1 induzindo a superexpressão da Nox1 NADPH oxidase, associada à geração de espécie reativas de oxigênio (ROS). Uma vez que a perda na regulação de ROS envolve o crescimento tumoral, nós propusemos que a PDIA1 atua como um mecanismo regulador proximal na produção de ROS em tumores. No presente estudo, nós focamos no câncer colorretal (CRC) com distintos efeitos na ativação de KRas. Resultados provenientes de bancos de dados de RNAsec e validação direta, indicam um significante aumento na expressão de PDIA1 em CRC com alta ativação constitutiva da Kras (HCT116) vs. ativação intermediária (HKE3) ou basal (Caco2). A PDIA1 sustenta a produção de superóxido dependente da Nox1 em CRC; entretanto, observamos pela primeira vez uma ação dupla da PDIA1 correlacionada ao nível de ativação da Ras: em células Caco2 e HKE3, experimentos de perda de função indicam que o PDIA1 sustenta a produção de superóxido dependente de Nox1; no entanto, em células HCT116, PDIA1 limita a produção de superóxido pela Nox1. Este comportamento da PDIA1 é associado ao aumento da expressão / atividade da Rac1. A transfecção do mutante constitutivamente ativo Rac1G12V em células HKE3 faz com que a PDIA1 se torne restritiva a produção de superóxido dependente de Nox1, paralelamente, em células HCT116 tratadas com inibidor da Rac1, PDIA1 se torna favorável à produção de superóxido. Um screening em importantes vias de sinalização celular em HKE3 mostrou que a perda de função da PDIA1 promove inativação da GSK3? em paralelo à diminuicão da ativacção de Stat3; em HCT116 em estado basal, GSK3beta é inativada enquanto Stat3 está ativa, já o silenciamento da PDIA1 não resulta em nenhum efeito adicional. As implicações funcionais do silenciamento da PDIA1 incluíram uma diminuição da proliferação e migração celular em HKE3, não detectável em HCT116. Além disso, a PDIA1 parece sustentar a transição epitélio-mesenquimal (EMT), uma vez que após o silenciamento da PDIA1, observamos um aumento da expressão da E-caderina em HKE3 e uma diminuição em HCT116. Assim, a superativação da Ras se associa a uma alteração no padrão de regulação da Nox1 pela PDIA1. A supressão do efeito regulador da PDIA1 pela Kras é provavelmente devido a uma ativação sustentada da Rac1. Portanto, PDIA1 pode exercer um papel redox-dependente adaptativo crucial relacionado à progressão tumoral / Protein disulfide isomerases such as PDIA1 have been implicated in cancer progression, but the underlying mechanisms are unclear. We showed previously important PDIA1 effects enabling vascular Nox1 NADPH oxidase expression and associated generation of reactive oxygen species (ROS). Since deregulated ROS production underlies tumor growth, we proposed that PDIA1 acts as an upstream regulatory mechanism of tumor-associated ROS production. We focused on colorectal cancer (CRC) with distinct levels of KRas activation. Our results from RNAseq databanks and direct validation indicate significant increase in PDIA1 expression in CRC with constitutive high (HCT116) vs. moderate (HKE3) or basal (e.g. Caco2) Ras activity. PDIA1 supported Nox1-dependent superoxide production in CRC; however, we observed for the first time a dual effect correlated with Ras level activity: in Caco2 and HKE3 cells, loss-of-function experiments indicate that PDIA1 sustains Nox1-dependent superoxide production; however, in HCT116 cells, PDIA1 restricted Nox1-dependent superoxide production. This PDIA1 behavior in HCT116 is associated with increased Rac1 expression/activity. Transfection of Rac1G12V active mutant into HKE3 cells induced PDIA1 to become restrictive of Nox1-dependent superoxide; accordingly, in HCT116 cells treated with Rac1 inhibitor, PDIA1 became supportive of superoxide production. Screening of cell signaling routes affected by PDIA1 silencing showed induced GSK3beta inactivation and parallel decrease of active Stat3 in HKE3 cells; in baseline HCT116 cells, GSK3beta was inactivated and Stat3 active, whereas PDIA1 silencing had no further effect. Functional implications of PDIA1 silencing included a decrease of cell proliferation and migration in HKE3, not detectable in HCT116 cells. Also, PDIA1 may support epithelial-mesenchymal transition (EMT), since after PDIA1 silencing, E-cadherin expression increased in HKE3 and decreased in HCT116. Thus, Ras overaction associates with a switched in PDIA1 pattern regulation of Nox1. Ras-induced PDIA1 bypass may involve direct Rac1 activation. Therefore, PDIA1 may be a crucial regulator of redox-dependent adaptive processes related to cancer progression

Espécies de oxigênio reativas

Estresse oxidativo

Isomerase de dissulfetos de proteínas

NADPH oxidase

Neoplasias

Proteínas ras

Proto-oncogenes

Superóxidos

NADPH oxidase

Neoplasms

Oxidative stress

Protein disulfide-isomerases

Proto-oncogenes

Ras proteins

Reactive oxygen species

Superoxides

Papel da dissulfeto isomerase proteica (PDI) na migração de células musculares lisas vasculares: possível envolvimento de Nox1 NADPH oxidase e RhoGTPases / The role of protein disulfide isomerase (PDI) in vascular smooth muscle cell migration: possible interaction with Nox1 NADPH oxidase and RhoGTPases

Luciana Pescatore-Alves

03 February 2012

A migração de células musculares lisas (VSMC) da camada média do vaso para a íntima é essencial para vasculogênese e contribui para o processo de aterosclerose e estenose após lesão por cateter-balão, caracterizando-se como um importante alvo terapêutico. Diversos trabalhos já demonstraram que fatores de crescimento (como PDGF e FGF) estimulam a migração de VSMC, inclusive, muitos desses fatores de crescimento induzem sinalização redox associadas à geração de espécies reativas de oxigênio (ROS) (ex. Nox1 NADPH oxidase). Nosso grupo já descreveu interações físicas e regulação funcional da NADPH oxidase por uma chaperona redox do retículo endoplasmático, a Dissulfeto Isomerase Protéica (PDI). Contudo, tanto a relevância fisiológica como os mecanismos desta interação ainda não estão claros. O objetivo geral do presente trabalho é investigar por meio de experimentos de perda e ganho de função da PDI, a importância da PDI na migração celular associada à ativação do complexo NADPH oxidase, bem como possíveis mecanismos envolvidos na interação entre a PDI e esse complexo enzimático durante a migração celular. Os objetivos específicos são: i) avaliar o efeito do silenciamento da PDI, bem como da expressão forçada de PDI wild type na migração de VSMC in vitro; ii) analisar o efeito da transfecção de siRNA da PDI atividade e expressão de distintas isoformas da NADPH oxidase vascular e produção de ROS induzida por PDGF; iii) investigar o envolvimento de RhoGTPases na regulação do complexo NADPH oxidase pela PDI. No presente trabalho, mostramos que o PDGF induz redistribuição da PDI e aumento da produção de ROS. O silenciamento da PDI inibe a produção de ROS e a expressão do mRNA da Nox1, sem alterar a expressão do mRNA da Nox4. Mais ainda, o silenciamento da PDI reduz a migração celular induzida por PDGF, em diferentes modelos de migração, enquanto a super-expressão da PDI induz aumento espontâneo da migração na condição basal. Análise utilizando métodos de Biologia de Sistemas de redes de interação física proteína-proteína em bancos de dados e técnicas de análise de centralidade, topologia e ontologia gênica indicou forte convergência entre PDI e proteínas da família das pequenas RhoGTPases e seus reguladores. Em VSMC com silenciamento da PDI, a presença do PDGF induziu uma redução na atividade de Rac1 e RhoA, sem alterar a expressão total destas proteínas. Estudos mostraram que a PDI colocaliza com Rac1 na região perinuclear e co-imunoprecipita com Rac1 e RhoA, tanto na presença como na ausência de PDGF. Além disso, ocorreu a interação entre PDI e o regulador de GTPases RhoGDI (inibidor da dissociação da guanina) na condição basal (por microscopia confocal e co-imunoprecipitação), diminuída após estimulo com PDGF. O silenciamento da PDI induziu ainda alterações em estrutura de citoesqueleto: desorganização das fibras de estresse, e redução no número e tamanho de adesões focais e vesículas de adesão marcadas por RhoGDI e Rac1. Assim, os dados apresentados no presente trabalho sugerem que a PDI sustenta a migração de VSMC dependente de sinalização redox e RhoGTPases. Além disso, RhoGTPases podem ser um alvo proximal importante mediando a convergência entre PDI e o complexo NADPH oxidase / Vascular Smooth Muscle Cell (VSMC) migration into vessel neointima is a therapeutic target for atherosclerosis and post-injury restenosis. NADPH oxidase-derived oxidants synergize with growth factors to support VSMC migration. We described interaction between NADPH oxidases and the endoplasmic reticulum redox chaperone Protein Disulfide Isomerase (PDI) in many cell types. However, physiological implications as well as mechanisms of such association are yet unclear. The aim of the present work was to investigate, througth experiments of gain or loss of PDI function, the importance of PDI in VSMC migration associated to NADPH oxidase. The specific aims were: i) to evaluate effects of PDI silencing or PDI overexpression in VSMC migration in vitro; ii) to evaluate effects of PDI silencing on PDGF-induced NADPH oxidase isoform expression and ROS production; iii) to evaluate the involvement of RhoGTPases on NADPH oxidase regulation by PDI. We show here that PDGF promoted subcellular redistribution of PDI concomitant to ROS production and that siRNA-mediated PDI silencing inhibited such ROS production, while near-totally suppressing the increase in Nox1 expression, with no change in Nox4. Furthermore, PDI silencing inhibited PDGF-induced VSMC migration assessed by distinct methods, while PDI overexpression increased spontaneous basal VSMC migration. To address possible mechanisms of PDI effects, we searched for PDI interactome by PPPI networks, which indicated convergence with small GTPases and their regulator RhoGDI. PDI silencing decreased PDGF-induced Rac1 and RhoA activities, without change in their expression. PDI displayed small detectable points of perinuclear co-localization with Rac1 and co-immunoprecipitated with Rac1 and RhoA in a PDGF-independent way. Moreover, there was PDI association with RhoGDI at baseline (confocal and co-immunoprecipitation), decreased after PDGF. Of note, PDI silencing promoted strong cytoskeletal changes: branched stress fiber disorganization, markedly decreased number of focal adhesions and reduced number of RhoGDI-containing vesicular recycling adhesion structures. Overall, these data suggest that PDI is required to support redox and GTPase-dependent VSMC migration. Moreover, RhoGTPases are a potential upstream target mediating the convergence between PDI and NADPH oxidase

Espécies de oxigênio reativas

Isomerase de dissulfetos de proteínas

Movimento celular

NADPH oxidase

Peróxido de hidrogênio

Proteínas rho de ligação ao GTP

Retículo endoplasmático

Superóxidos

Cell moviment

Endoplasmic reticulum

Hydrogen peroxide

NADPH oxidase

Platelet-derived growth factos

Protein dissulfide isomerase

Reactive oxygen species

Rho GTP-binding proteins

Superoxides

Rôle du système rénine-angiotensine intrarénal dans l’hypertension et les dommages rénaux chez les souris transgéniques diabétiques

Liu, Fang

09 1900

Plusieurs expériences et études cliniques ont démontré que l’activation du système rénine-angiotensine (RAS) peut induire l’hypertension, un facteur de risque majeur pour les maladies cardiovasculaires et rénales. L’angiotensinogène (Agt) est l’unique substrat du RAS. Cependant, il n’a pas encore été démontré si l’activation du RAS intrarénal peut à elle seule induire des dommages rénaux, indépendamment de l’hypertension systémique, et ainsi jouer un rôle prépondérant dans la progression de la néphropathie diabétique. Afin d’explorer le rôle du RAS intrarénal dans les dommages rénaux, un diabète a été induit par l’injection de streptozotocin chez des souris transgéniques (Tg) surexprimant l’Agt de rat dans les cellules des tubules proximaux du rein (RPTC). Les souris Tg diabétiques ont été traitées soit avec des inhibiteurs du RAS (perindopril et losartan), de l’insuline ou une combinaison des deux pour 4 semaines avant d’être euthanasiées. Pour une autre étude, des souris Tg non-diabétiques ont été traitées soit avec des inhibiteurs du RAS, l’hydralazine (vasodilatateur) ou l’apocynine (inhibiteur de la NADPH oxydase) pour une période de 8 semaines avant l’euthanasie. Des souris non-Tg ont été utilisées comme contrôles. Des cellules immortalisées de tubule proximal de rat (IRPTC) transfectées de manière stable avec un plasmide contenant l’Agt ou un plasmide contrôle ont été employées comme modèle in vitro. Nos résultats ont démontré que les souris Tg présentaient une augmentation significative de la pression systolique, l’albuminurie, l’apoptose des RPTC et l’expression de gènes pro-apoptotiques par rapport aux souris non-Tg. Les mêmes changements ont été observés chez les souris Tg diabétiques par rapport aux souris non-Tg diabétiques. L’insuline et/ou les inhibiteurs du RAS ont permis d’atténuer ces changements, sauf l’hypertension qui n’était réduite que par les inhibiteurs du RAS. Chez les IRPTC transfectées avec l’Agt in vitro, les hautes concentrations de glucose augmentent l’apoptose et l’activité de la caspase-3 par rapport aux cellules contrôles et l’insuline et/ou les inhibiteurs du RAS empêchent ces augmentations. En plus des changements physiologiques, les RPTC des souris Tg présentent aussi une augmentation significative de la production des espèces réactive de l’oxygène (ROS) et de l’activité de la NADPH oxydase, ainsi qu’une augmentation de l’expression du facteur de croissance transformant-beta 1 (TGF-β1), de l’inhibiteur activateur du plasminogène de type 1 (PAI-1), des protéines de la matrice extracellulaire, du collagène de type IV et de la sousunité p47 de la NADPH oxydase. Le traitement des souris Tg avec l’apocynine et le perindopril a permis d’améliorer tous ces changements, sauf l’hypertension qui n’était pas corrigée par l’apocynine. D’autre part, l’hydralazine a prévenu l’hypertension, sans modifier l’albuminurie, l’apoptose des RPTC ou l’expression des gènes pro-apoptotiques. Ces résultats montrent bien que l’activation du RAS intrarénal et l’hyperglycémie agissent de concert pour induire l’albuminurie et l’apoptose des RPTC, indépendamment de l’hypertension systémique. La génération des ROS via l’activation de la NADPH oxydase induit en partie l’action du RAS intrarénal sur l’apoptose des RPTC, la fibrose tubulo-interstitielle et l’albuminurie chez les souris Tg. D’autre part, une expérience en cours a tenté d’encore mieux délimiter les effets de l’activation du RAS intrarénal, tout en éliminant la néphrotoxicité du STZ. Pour cette étude, les souris Tg surexprimant l’Agt de rat dans leurs RPTC ont été croisées aux souris Ins2Akita, un modèle spontané de diabète de type I, afin de générer des souris Akita-rAgt-Tg. Les résultats préliminaires indiquent que le RAS intrarénal est activé dans les souris Akita et que la combinaison avec l’hyperglycémie induit du stress du réticulum endoplasmique (ER) dans les RPTC in vivo. Le stress du ER contribue à l’apoptose des RPTC observée dans le diabète, à tout le moins dans le modèle Akita. Le traitement avec des inhibiteurs du RAS permet d’atténuer certains des dommanges rénaux observés dans les souris Akita-rAgt-Tg. / Experimental and clinical studies have shown that renin-angiotensin system (RAS)activation may lead to hypertension, a major cardiovascular and renal risk factor. Angiotensinogen (Agt) is the sole substrate of the RAS. However, it is unclear whether intrarenal RAS activation alone could induce kidney injury independently of systemic hypertension and play an important role in the progression of diabetic nephropathy (DN). To explore the role of intrarenal RAS in kidney injury, transgenic (Tg) mice overexpressing rat Agt in their renal proximal tubular cells (RPTCs) were rendered diabetic by streptozotocin (STZ). Diabetic Tg mice were treated with RAS blockers (perindopril and losartan), insulin or a combination of both and then euthanized after 4 weeks of treatment. In a separate study, non-diabetic Tg mice were treated with RAS blockers or hydralazine (a vasodilator) or apocynin (an NADPH oxidase inhibitor) and then euthanized after 8 weeks of treatment. Non-Tg littermates served as controls in both studies. Immortalized rat proximal tubule cells (IRPTCs) stably transfected with Agt cDNA or control plasmid were used in the experiments as an in vitro model. Our results showed that non-diabetic Tg mice displayed a significant increase in systolic blood pressure (SBP), albuminuria, RPTC apoptosis, and proapoptotic gene expression. Diabetic Tg mice had a further increase of albuminuria, RPTC apoptosis, and proapoptotic gene expression, though the SBP of the diabetic Tg mice was similar to that of non-diabetic Tg mice. RAS blockers and/or insulin treatments markedly attenuated these changes, except that insulin had no impact on hypertension. In vitro, high-glucose melieu significantly increased apoptosis and caspase-3 activity in Agt stable transfectants compared to control cells, and these changes were attenuated by insulin and/or RAS blockers. Furthermore, non-diabetic Tg mice showed significantly elevated reactive oxygen species (ROS) production and NADPH oxidase activity, as well as enhanced expression of transforming growth factor-beta 1 (TGF-β1), plasminogen activator inhibitor-1 (PAI-1), extracellular matrix proteins, collagen type IV, and NADPH oxidase subunit p47 in their RPTC. Treatment with apocynin and perindopril ameliorated these changes, but apocynin had no effect on SBP. In contrast, hydralazine prevented hypertension but not albuminuria, RPTC apoptosis, or proapoptotic gene expression. These data indicate that intrarenal RAS activation and hyperglycemia act in concert to induce albuminuria and RPTC apoptosis independent of systemic hypertension. ROS generation via NADPH oxidase activation mediates, at least in part, intrarenal RAS action on RPTC apoptosis, tubulointerstitial fibrosis and albuminuria in Tg mice. On the other hand, in an on-going experiment, to avoid the nephro-toxic effects of STZ and further delineate the effects of intrarenal RAS activation, Tg mice overexpressing rat Agt in their RPTCs were crossbred with Ins2Akita mice, a spontaneous type I diabetes model, to generate Akita-rAgt-Tg mice. Preliminary data indicated that hyperglycaemia and intrarenal RAS activation induced endoplasmic reticulum (ER) stress in RPTC in vivo, and the ER stress pathway contributed to RPTC apoptosis in diabetes, at least in the Akita model. RAS blockade was effective in attenuating some parameters of renal injury in AkitarAgt-Tg mice.

Rein

néphropathie diabétique

hypertension

apoptose

fibrose tubulo-interstitielle

ROS

NADPH oxidase

stress du ER

modèle de souris Ins2Akita

kidney

diabetic nephropathy

apoptosis

tubulo-interstitial fibrosis

ER stress

Ins2Akita mouse model

La glycine décarboxylase désensibilise les cellules initiatrices de tumeur à la metformine

Moineau-Vallée, Karine

07 1900

Le cancer du pancréas est l’un des plus chimiorésistants, avec un taux de survie sur 5 ans inférieur à 5%. La chimiorésistance pourrait être due à la présence de cellules initiatrices de tumeur (TICs), une petite sous-population des cellules tumorales possédant la capacité de régénérer une nouvelle tumeur. Il a été démontré que la metformine cible les TICs par un mécanisme non élucidé. Il est connu que la metformine affecte le métabolisme du carbone. Il a également été démontré que le métabolisme du carbone, plus précisément la glycine décarboxylase (GLDC), est à la fois nécessaire et suffisant à l’acquisition de propriétés d’initiation tumorale. Nous proposons que la metformine cible les cellules initiatrices de tumeur en affectant le métabolisme du carbone. Nous avons utilisé des lignées cellulaires dérivées d’un modèle murin de cancer du pancréas pour comparer l’expression génique de lésions bénignes versus malignes. Les cellules malignes surexpriment Gldc. La metformine diminue l’expression de Gldc, et la surexpression de Gldc diminue la sensibilité à la metformine dans un essai de sphères tumorales. La metformine induit une augmentation du ratio NADP+/NADPH, et la surexpression de Gldc empêche cette augmentation. Nous proposons que la metformine diminue l’expression de Gldc, ce qui cause une diminution du flux du métabolisme du carbone, et donc une diminution de la production de NADPH par ce dernier. L’augmentation du ratio NADP+/NADPH inhibe la synthèse des acides gras et la régénération de la glutathione, ce qui pourrait expliquer la diminution de la formation de sphères tumorales sous traitement metformine. / Pancreatic cancer is one of the most chemoresistant cancers, with a 5-year survival rate lesser than 5%. Chemoresistance might be due to the presence of tumor-initiating cells (TICs), a small subpopulation of tumor cells with stem-like characteristics which possess the unique ability to self-renew and to generate a new tumor. Metformin has been shown to affect TICs in various cancer types, but the mechanism through which it does so is unclear. It is known that metformin affects one-carbon metabolism. It has also been shown that one-carbon metabolism, more precisely the glycine decarboxylase (GLDC) enzyme, is both necessary and sufficient to the acquisition of tumor-initiating properties. Considering this, we propose that metformin affects TICs by targeting one-carbon metabolism. Using cell lines derived from a genetically engineered mouse model of pancreatic cancer, we compared gene expression data from cells derived from benign pancreatic neoplasia with cells derived from pancreatic ductal adenocarcinoma (PDAC), and found that PDAC cells exhibited a dramatic increase in Gldc expression. Metformin treatment decreases Gldc expression in PDAC cell lines, and Gldc overexpression greatly decreases metformin sensitivity in a tumor sphere assay. Metformin induces an increase in NADP+/NADPH ratio, which is rescued by Gldc overexpression. We propose a model in which metformin decreases Gldc expression, which causes reduced flux through mitochondrial one-carbon metabolism. This results in decreased NADPH production by this pathway. This increase in NADP+/NADPH ratio impairs fatty acid biosynthesis and glutathione regeneration. Together these effects might explain the decrease of tumor sphere formation under metformin treatment.

cancer du pancréas

cellules initiatrices de tumeur

glycine décarboxylase

métabolisme du cancer

métabolisme du carbone

metformine

NADPH

cancer metabolism

glycine decarboxylase

metformin

one-carbon metabolism

pancreatic cancer

tumor-initiating cells

The role and regulatory mechanisms of nox1 in vascular systems

Yin, Weiwei

28 June 2012

As an important endogenous source of reactive oxygen species (ROS), NADPH oxidase 1 (Nox1) has received tremendous attention in the past few decades. It has been identified to play a key role as the initial "kindle," whose activation is crucial for amplifying ROS production through several propagation mechanisms in the vascular system. As a consequence, Nox1 has been implicated in the initiation and genesis of many cardiovascular diseases and has therefore been the subject of detailed investigations. The literature on experimental studies of the Nox1 system is extensive. Numerous investigations have identified essential features of the Nox1 system in vasculature and characterized key components, possible regulatory signals and/or signaling pathways, potential activation mechanisms, a variety of Nox1 stimuli, and its potential physiological and pathophysiological functions. While these experimental studies have greatly enhanced our understanding of the Nox1 system, many open questions remain regarding the overall functionality and dynamic behavior of Nox1 in response to specific stimuli. Such questions include the following. What are the main regulatory and/or activation mechanisms of Nox1 systems in different types of vascular cells? Once Nox1 is activated, how does the system return to its original, unstimulated state, and how will its subunits be recycled? What are the potential disassembly pathways of Nox1? Are these pathways equally important for effectively reutilizing Nox1 subunits? How does Nox1 activity change in response to dynamic signals? Are there generic features or principles within the Nox1 system that permit optimal performance? These types of questions have not been answered by experiments, and they are indeed quite difficult to address with experiments. I demonstrate in this dissertation that one can pose such questions and at least partially answer them with mathematical and computational methods. Two specific cell types, namely endothelial cells (ECs) and vascular smooth muscle cells (VSMCs), are used as "templates" to investigate distinct modes of regulation of Nox1 in different vascular cells. By using a diverse array of modeling methods and computer simulations, this research identifies different types of regulation and their distinct roles in the activation process of Nox1. In the first study, I analyze ECs stimulated by mechanical stimuli, namely shear stresses of different types. The second study uses different analytical and simulation methods to reveal generic features of alternative disassembly mechanisms of Nox1 in VSMCs. This study leads to predictions of the overall dynamic behavior of the Nox1 system in VSMCs as it responds to extracellular stimuli, such as the hormone angiotensin II. The studies and investigations presented here improve our current understanding of the Nox1 system in the vascular system and might help us to develop potential strategies for manipulation and controlling Nox1 activity, which in turn will benefit future experimental and clinical studies.

Atherosclerosis

Mechanotransduction

NADPH oxidase 1

Computational model

Biochemical systems theory

System biology

Cardiovascular system

Design princple

Reactive oxygen species

Pathway analysis

Multi-scale system modeling

Signaling pathway modeling

Monte Carlo method

Dynamic simulation

Endothelium

Nitric oxide

Active oxygen

Rôle du système rénine-angiotensine intrarénal dans l’hypertension et les dommages rénaux chez les souris transgéniques diabétiques

Liu, Fang

09 1900

Plusieurs expériences et études cliniques ont démontré que l’activation du système rénine-angiotensine (RAS) peut induire l’hypertension, un facteur de risque majeur pour les maladies cardiovasculaires et rénales. L’angiotensinogène (Agt) est l’unique substrat du RAS. Cependant, il n’a pas encore été démontré si l’activation du RAS intrarénal peut à elle seule induire des dommages rénaux, indépendamment de l’hypertension systémique, et ainsi jouer un rôle prépondérant dans la progression de la néphropathie diabétique. Afin d’explorer le rôle du RAS intrarénal dans les dommages rénaux, un diabète a été induit par l’injection de streptozotocin chez des souris transgéniques (Tg) surexprimant l’Agt de rat dans les cellules des tubules proximaux du rein (RPTC). Les souris Tg diabétiques ont été traitées soit avec des inhibiteurs du RAS (perindopril et losartan), de l’insuline ou une combinaison des deux pour 4 semaines avant d’être euthanasiées. Pour une autre étude, des souris Tg non-diabétiques ont été traitées soit avec des inhibiteurs du RAS, l’hydralazine (vasodilatateur) ou l’apocynine (inhibiteur de la NADPH oxydase) pour une période de 8 semaines avant l’euthanasie. Des souris non-Tg ont été utilisées comme contrôles. Des cellules immortalisées de tubule proximal de rat (IRPTC) transfectées de manière stable avec un plasmide contenant l’Agt ou un plasmide contrôle ont été employées comme modèle in vitro. Nos résultats ont démontré que les souris Tg présentaient une augmentation significative de la pression systolique, l’albuminurie, l’apoptose des RPTC et l’expression de gènes pro-apoptotiques par rapport aux souris non-Tg. Les mêmes changements ont été observés chez les souris Tg diabétiques par rapport aux souris non-Tg diabétiques. L’insuline et/ou les inhibiteurs du RAS ont permis d’atténuer ces changements, sauf l’hypertension qui n’était réduite que par les inhibiteurs du RAS. Chez les IRPTC transfectées avec l’Agt in vitro, les hautes concentrations de glucose augmentent l’apoptose et l’activité de la caspase-3 par rapport aux cellules contrôles et l’insuline et/ou les inhibiteurs du RAS empêchent ces augmentations. En plus des changements physiologiques, les RPTC des souris Tg présentent aussi une augmentation significative de la production des espèces réactive de l’oxygène (ROS) et de l’activité de la NADPH oxydase, ainsi qu’une augmentation de l’expression du facteur de croissance transformant-beta 1 (TGF-β1), de l’inhibiteur activateur du plasminogène de type 1 (PAI-1), des protéines de la matrice extracellulaire, du collagène de type IV et de la sousunité p47 de la NADPH oxydase. Le traitement des souris Tg avec l’apocynine et le perindopril a permis d’améliorer tous ces changements, sauf l’hypertension qui n’était pas corrigée par l’apocynine. D’autre part, l’hydralazine a prévenu l’hypertension, sans modifier l’albuminurie, l’apoptose des RPTC ou l’expression des gènes pro-apoptotiques. Ces résultats montrent bien que l’activation du RAS intrarénal et l’hyperglycémie agissent de concert pour induire l’albuminurie et l’apoptose des RPTC, indépendamment de l’hypertension systémique. La génération des ROS via l’activation de la NADPH oxydase induit en partie l’action du RAS intrarénal sur l’apoptose des RPTC, la fibrose tubulo-interstitielle et l’albuminurie chez les souris Tg. D’autre part, une expérience en cours a tenté d’encore mieux délimiter les effets de l’activation du RAS intrarénal, tout en éliminant la néphrotoxicité du STZ. Pour cette étude, les souris Tg surexprimant l’Agt de rat dans leurs RPTC ont été croisées aux souris Ins2Akita, un modèle spontané de diabète de type I, afin de générer des souris Akita-rAgt-Tg. Les résultats préliminaires indiquent que le RAS intrarénal est activé dans les souris Akita et que la combinaison avec l’hyperglycémie induit du stress du réticulum endoplasmique (ER) dans les RPTC in vivo. Le stress du ER contribue à l’apoptose des RPTC observée dans le diabète, à tout le moins dans le modèle Akita. Le traitement avec des inhibiteurs du RAS permet d’atténuer certains des dommanges rénaux observés dans les souris Akita-rAgt-Tg. / Experimental and clinical studies have shown that renin-angiotensin system (RAS)activation may lead to hypertension, a major cardiovascular and renal risk factor. Angiotensinogen (Agt) is the sole substrate of the RAS. However, it is unclear whether intrarenal RAS activation alone could induce kidney injury independently of systemic hypertension and play an important role in the progression of diabetic nephropathy (DN). To explore the role of intrarenal RAS in kidney injury, transgenic (Tg) mice overexpressing rat Agt in their renal proximal tubular cells (RPTCs) were rendered diabetic by streptozotocin (STZ). Diabetic Tg mice were treated with RAS blockers (perindopril and losartan), insulin or a combination of both and then euthanized after 4 weeks of treatment. In a separate study, non-diabetic Tg mice were treated with RAS blockers or hydralazine (a vasodilator) or apocynin (an NADPH oxidase inhibitor) and then euthanized after 8 weeks of treatment. Non-Tg littermates served as controls in both studies. Immortalized rat proximal tubule cells (IRPTCs) stably transfected with Agt cDNA or control plasmid were used in the experiments as an in vitro model. Our results showed that non-diabetic Tg mice displayed a significant increase in systolic blood pressure (SBP), albuminuria, RPTC apoptosis, and proapoptotic gene expression. Diabetic Tg mice had a further increase of albuminuria, RPTC apoptosis, and proapoptotic gene expression, though the SBP of the diabetic Tg mice was similar to that of non-diabetic Tg mice. RAS blockers and/or insulin treatments markedly attenuated these changes, except that insulin had no impact on hypertension. In vitro, high-glucose melieu significantly increased apoptosis and caspase-3 activity in Agt stable transfectants compared to control cells, and these changes were attenuated by insulin and/or RAS blockers. Furthermore, non-diabetic Tg mice showed significantly elevated reactive oxygen species (ROS) production and NADPH oxidase activity, as well as enhanced expression of transforming growth factor-beta 1 (TGF-β1), plasminogen activator inhibitor-1 (PAI-1), extracellular matrix proteins, collagen type IV, and NADPH oxidase subunit p47 in their RPTC. Treatment with apocynin and perindopril ameliorated these changes, but apocynin had no effect on SBP. In contrast, hydralazine prevented hypertension but not albuminuria, RPTC apoptosis, or proapoptotic gene expression. These data indicate that intrarenal RAS activation and hyperglycemia act in concert to induce albuminuria and RPTC apoptosis independent of systemic hypertension. ROS generation via NADPH oxidase activation mediates, at least in part, intrarenal RAS action on RPTC apoptosis, tubulointerstitial fibrosis and albuminuria in Tg mice. On the other hand, in an on-going experiment, to avoid the nephro-toxic effects of STZ and further delineate the effects of intrarenal RAS activation, Tg mice overexpressing rat Agt in their RPTCs were crossbred with Ins2Akita mice, a spontaneous type I diabetes model, to generate Akita-rAgt-Tg mice. Preliminary data indicated that hyperglycaemia and intrarenal RAS activation induced endoplasmic reticulum (ER) stress in RPTC in vivo, and the ER stress pathway contributed to RPTC apoptosis in diabetes, at least in the Akita model. RAS blockade was effective in attenuating some parameters of renal injury in AkitarAgt-Tg mice.

Rein

néphropathie diabétique

hypertension

apoptose

fibrose tubulo-interstitielle

ROS

NADPH oxidase

stress du ER

modèle de souris Ins2Akita

kidney

diabetic nephropathy

apoptosis

tubulo-interstitial fibrosis

ER stress

Ins2Akita mouse model

Insights into the Host Cell Entry of Ehrlichia chaffeensis: Roles of the Bacterial Outer Membrane Protein EtpE

Mohan Kumar, Dipu

15 September 2014

No description available.

Immunology

Microbiology

Medicine

Ehrlichia chaffeensis

Human monocytic ehrlichiosis

EtpE

DNase X

GPI-1anchored protein

receptor, ligand

invasin

receptor-mediated endocytosis

CD147

hnRNP-K

actin

cytoskeletal mobilization

vaccine

N-WASP

ROS

NADPH Oxidase

lysosomes

vaccine

Caractérisation du gène de l'enzyme de conversion de l'angiotensine-2 dans le rein diabétique et implication dans le développement de la néphropathie diabétique et de l'hypertension

Shi, Yixuan

07 1900

De nombreuses études ont bien démontré que l’activation du système rénine-angiotensine (RAS) joue un rôle important dans le développement de l’hypertension et de la néphropathie diabétique (DN). La découverte de l’enzyme de conversion de l’angiotensine-2 (ACE2) et l’identification du récepteur MAS, spécifique pour l’angiotensine 1-7 (Ang 1-7), ont permis d’identifier deux nouveaux membres du RAS. L’axe ACE2/Ang 1-7/MAS contrebalance les effets de l’axe ACE/Ang II/AT1. Plusieurs évidences impliquent la contribution du RAS intrarénal dans la DN. Des études réalisées dans notre laboratoire avec des souris transgéniques surexprimant l’angiotensinogène de rat dans les cellules de leurs tubules proximaux rénaux (RPTCs) ont permis de démontrer l’importance du RAS intrarénal dans l’induction de l’hypertension et les dommages rénaux. Nous avons également observé que l’expression rénale de l’ACE2 et les niveaux urinaires d’ANG 1-7 sont plus faibles chez les souris Akita (diabète de type 1) et qu’un traitement avec des bloqueurs du RAS permet de normaliser l’expression de l’ACE2 et de prévenir le développement de l’hypertension dans le modèle des souris Akita. Dans un milieu diabétique, à la fois la glycémie et l’angiotensine II (Ang II) peuvent induire la génération des espèces réactives de l’oxygène (ROS), contribuant ainsi aux dommages rénaux. Afin d’explorer la relation entre les ROS, ACE2 et la DN, nous avons créé des souris Akita transgéniques surexprimant la catalase (Cat) dans les RPTCs, en croisant des souris Akita diabétique de type 1 à notre modèle de souris transgéniques surexprimant la Cat de rat dans les RPTCs. Dans une seconde étude, des souris Akita ont été traitées avec l’Ang 1-7 ou une combinaison d’Ang 1-7 et de son antagoniste, A779, afin d’étudier la relation entre l’action de l’Ang 1-7, l’hypertension systolique (sHTN), le stress oxydatif, les dommages rénaux, ACE2 et l’expression du récepteur Mas. Nos résultats ont montré que la surexpression de Cat atténue le stress oxydatif rénal; prévient l’hypertension, améliore le taux de filtration glomérulaire, l’albuminurie, l’hypertrophie rénale, la fibrose tubulo-interstitielle et l’apoptose tubulaire; et supprime l’expression des gènes profibrotiques et proapoptotiques dans les RPTCs des souris Akita Cat-Tg lorsque comparées aux souris Akita. De plus, la surexpression de Cat dans les RPTC des souris Akita normalise l’expression rénale de l’ACE2 et les niveaux urinaires d’Ang 1-7. D’autre part, l’administration d’Ang 1-7 prévient l’hypertension systémique, normalise le ratio albumine/créatinine urinaire et atténue l’hyperfiltration glomérulaire des souris Akita, sans affecter la glycémie sanguine. De plus, le traitement avec l’Ang 1-7 atténue aussi le stress oxydatif et l’expression de la NADPH oxydase, Agt, ACE, TGF-β1 (transforming growth factor-β1) et collagène IV, tout en augmentant l’expression de l’ACE2 et du récepteur Mas dans les reins des souris Akita. Ces effets sont renversés par la co-admininstration d’A779. Ces résultats démontrent que la surexpression de Cat prévient l’hypertension et la progression de la néphropathie, en plus de mettre en lumière l’importance du stress oxydatif intrarénal et l’expression de l’ACE2 comme facteurs contribuant à l’hypertension et les dommages rénaux observés dans le diabète. En outre, nos données suggèrent que l’Ang 1-7 joue un rôle protecteur dans l’hypertension et les dommages aux RPTC dans le diabète, principalement en réduisant les voies de signalisations du stress oxydatif dans les reins et en normalisant l’expression de l’ACE2 et du récepteur Mas. Nos résultats indiquent aussi que l’Ang 1-7 pourrait agir comme un agent thérapeutique potentiel dans le traitement de l’hypertension systémique et les dommages rénaux observés dans le diabète. En conséquence, l’Ang 1-7 est responsable du rôle protecteur de l’ACE2 dans l’hypertension et la DN. / It is well accepted that renin-angiotensin system (RAS) activation plays an important role in the development of hypertension and diabetic nephropathy (DN). With the discovery of angiotensin-converting enzyme-2 (ACE2) and recognition of MAS as the receptor of Angiotensin 1-7 (Ang 1-7), new players in RAS, ACE2/Ang 1-7/MAS axis, have been identified to counteract the effect of ACE/Ang II/ AT1 axis. Evidence implicates the intrarenal RAS’s contribution to DN. Previous studies from our laboratory using transgenic mice overexpressing rat Angiotensinogen (Agt) in their renal proximal tubular cells (RPTCs) have demonstrated the importance of the intrarenal RAS in renal damage and the induction of hypertension. We also recently observed that renal ACE2 expression and urinary Ang 1–7 were lower in type 1 diabetic Akita mice and that treatment with RAS blockers normalized ACE2 expression and prevented hypertension development in these Akita mice. In the diabetic milieu, both glycemia and angiotensin II (Ang II) can induce reactive oxygen species (ROS) generation, which contributes to kidney injury. To explore the relationship among ROS, ACE2 and DN, we created Akita transgenic mice overexpressing catalase (Cat) in RPTCs by crossbreeding type I diabetic Akita mice with our established transgenic mice overexpressing rat Cat in RPTCs. In another study, Akita mice were treated with Ang 1-7 or combination of Ang 1-7 and its antagonist, A779, to investigate the relations between Ang 1-7 action, systolic hypertension (sHTN), oxidative stress, kidney injury, ACE2 and Mas receptor expression. Our results showed that overexpression of Cat attenuated renal oxidative stress; prevented hypertension; ameliorated glomerular filtration rate, albuminuria, kidney hypertrophy, tubulointerstitial fibrosis, and tubular apoptosis; and suppressed profibrotic and proapoptotic gene expression in RPTCs of Akita Cat-Tg mice compared with Akita mice. Furthermore, overexpression of Cat in RPTCs of Akita mice normalized renal ACE2 expression and urinary Ang 1–7 levels. On the other hand, Ang 1-7 administration prevented systemic hypertension, normalized urinary albumin/creatinine ratio and attenuated glomerular hyperfiltration without affecting blood glucose levels in Akita mice. Furthermore, Ang 1-7 treatment also attenuated oxidative stress and the expression of NADPH oxidase 4, Agt, ACE, transforming growth factor-β1 (TGF-β1) and collagen IV, and increased the expression of ACE2 and Mas receptor in Akita mouse kidneys. These effects were reversed by co-administration of A779. These data demonstrated that Cat overexpression prevents hypertension and progression of nephropathy and highlight the importance of intrarenal oxidative stress and ACE2 expression contributing to hypertension and renal injury in diabetes. Furthermore, our data suggest that Ang 1-7 plays a protective role in hypertension and RPTC injury in diabetes, predominantly through decreasing renal oxidative stress-mediated signaling and normalizing ACE2 and Mas receptor expression. Our results also indicate Ang 1-7 as a potential therapeutic agent for treatment of systemic hypertension and kidney injury in diabetes. Therefore, Ang 1-7 mediates the major protective role of ACE2 in the hypertension and DN.

système rénine-angiotensine

catalase

hypertension

angiotensine 1-7

récepteur Mas

néphropathie diabétique

apoptose

fibrose tubulo-interstitielle

espèces réactives de l’oxygène

renin-angiotensin system

angiotensin-converting enzyme 2

Mas receptor

diabetic nephropathy

apoptosis

tubulointerstitial fibrosis

reactive oxygen species

NADPH oxidase

Regulation von oxidativem Stress durch biomechanische Kräfte und fettreiche Ernährung im Herz-Kreislaufsystem

Göttsch, Claudia

09 March 2007

Erkrankungen des Herz-Kreislaufsystems sind trotz erheblicher Fortschritte in Diagnostik und Therapie noch immer die häufigste Todesursache in Deutschland. Neben bekannte Risikofaktoren wie Hypercholesterinämie, Hyperlipoproteinämie, Diabetes mellitus, Adipositas, Bewegungsmangel, Stress und hohem Alter wird eine pathophysiologisch erhöhte Bildung reaktiver Sauerstoffspezies (ROS) als Ursache für deren Entstehung diskutiert. NAD(P)H-Oxidasen, von denen 7 Isoformen der katalytischen Nox-Untereinheiten bekannt sind, stellen dabei die Hauptquelle für vaskuläre Superoxidanionen und oxidativen Stress dar. In dieser Arbeit konnte die vorrangige Bedeutung eines intrazellulär lokalisierten Nox4-haltigen NAD(P)H-Oxidase-Komplexes für die konstitutive Radikalbildung in primären humanen Endothelzellen nachgewiesen werden. Weiterhin konnte gezeigt werden, dass durch chronische Applikation der biomechanischen Kräfte Schubspannung und Dehnung oxidativer Stress in humanen Endothelzellen in vitro vermindert werden kann. Die Herabregulation der Superoxidanionen-Bildung sowie die vermehrte Freisetzung von NO durch chronische Applikation biomechanischer Kräfte trägt zur positiven Balance von NO/Superoxidanionen und zum vasoprotektiven Potential physiologischer Schubspannung bzw. Dehnung bei. Durch Nox4-Promotordeletionsanalysen und Mutationsstudien konnte der Transkriptionsfaktor AP-1 als entscheidend für die schubspannungsabhängige Herabregulation von Nox4 identifiziert werden. Durch Stimulation von Endothelzellen bzw. murinen Gefäßringen mit oxidiertem LDL konnte dagegen die vaskuläre ROS-Bildung in vitro und ex vivo induziert werden. Zur weiteren Aufklärung des Mechanismus der LDL-induzierten ROS-Bildung in vivo und des Einflusses von NAD(P)H-Oxidasen wurden C57BL/6 (Wildtyp)- und Nox2-/--Mäuse 10 Wochen lang mit einer fettreichen Diät (Western diet) gefüttert und anschließend der Einfluss dieser Fütterung auf die NAD(P)H-Oxidase-Expression und ROS-Bildung analysiert. In der Aorta thoracalis beider Mausstämme zeigte sich durch das fettreiche Futter ein signifikanter Anstieg der NAD(P)H-Oxidase-Aktivität im Vergleich zum Standardfutter. Durch Western diet-Fütterung wurde die Nox4-mRNA-Expression in der A. thoracalis von Nox2-/--Mäuse und die p22phox-mRNA-Expression in beiden Mausstämmen induziert. Die Analyse weiterer Organe (Herz, Niere) zeigte keine Induktion von NAD(P)H-Oxidase-Untereinheiten durch Western diet-Fütterung. Zusammenfassend sprechen die Ergebnisse der vorliegenden Arbeit für eine entscheidende Rolle der Nox4-haltigen NAD(P)H-Oxidase bei der vaskulären Radikalbildung in vitro und in vivo. / Cardiovascular diseases are the most common causes of death in Germany. Beside the known risk factors hypercholesteremia, hyperlipoproteinemia, diabetes mellitus, obesity, sedentary lifestyle, stress and high age, a pathophysiologically increased formation of reactive oxygen species (ROS) are discussed as cause of development of cardiovascular diseases. Nicotine adenine dinucleotide phosphate (NADPH) oxidase complexes have been identified as main source of oxidative stress and vascular superoxide anions. There are 7 known isoforms of the catalytic Nox subunit of the NADPH oxidase. In this dissertation it was shown that NADPH oxidase subunit Nox4 is the major Nox isoform in human endothelial cells. Nox4 could be localized in the perinuclear space. Overexpression of Nox4 enhanced endothelial superoxide anion formation. Furthermore, a reduction of oxidative stress could be demonstrated by chronic application of the biomechanical forces laminar shear stress and cyclic strain in endothelial cells in vitro. The observed downregulation of superoxide anion formation and upregulation of NO formation by application of biomechanical forces contribute to the positive balance between NO and superoxide anion and the vasoprotective potential of physiological shear stress and cyclic strain. Molecular cloning and functional analysis of the human Nox4 promoter revealed that an AP-1 binding site is essential for downregulation of Nox4 by laminar shear stress. On the other hand stimulation of endothelial cells and murine vessels with oxidized lipids caused an upregulation of vascular ROS production in vitro and ex vivo. In order to examine the mechanism of LDL induced ROS formation and the influence of NADPH oxidase, C57BL/6 (wild-type) and Nox2-/- mice were feed with a diet high in fat and sugar (Western-type diet) for 10 weeks. After feeding, the influence of diet on the expression of NADPH oxidase and ROS production was analyzed in the A. thoracalis. Both mice strains showed a significant upregulation of aortic ROS production in comparison to normal chow. The mRNA expression of aortic Nox4 was induced in Nox2-/- mice. Furthermore, the aortic p22phox mRNA expression was upregulated in both mice strains. The analysis of other organs (heart, kidney) showed no influence of the Western-type diet. In conclusion, the results demonstrate a major role of a Nox4 containing NADPH oxidase in the vascular radical formation in vitro and in vivo.

oxidativer Stress

Endothel

NAD(P)H-Oxidase

reaktive Sauerstoffspezies (ROS)

Schubspannung

Dehnung

oxidierte Lipide

oxidative stress

endothelium

NADPH oxidase

reactive oxygen species

laminar shear stress

cyclic strain

oxidized lipids

ddc:540

rvk:WW 7700

Oxidativer Stress

Endothel

NADH-Oxidase

Reaktive Sauerstoffspezies

Schubspannung

Dehnung

Lipide

Etude structurale de biomarqueurs de neuropathologies : Cas particulier de la protéine CRYM, une Cytosolic-3,3',5-triiodo-L-thyronine(T3)-Binding Protein

Hachi, Isma

29 September 2010

Mon projet de thèse s'inscrit dans un vaste projet de caractérisation de protéines nouvellement identifiées dont l'expression est sélective à certaines régions du cerveau. Cette expression sélective pouvant être liée aux phénomènes de dégénérescence neuronale qui caractérisent les maladies neurodégénératives, ces protéines constituent donc des biomarqueurs potentiels. Une étude structurale et physico-chimique a été effectuée sur une dizaine de protéines, dont la protéine CRYM murine (mCRYM) qui fait parti de la famille des Cytosolic- 3,3',5-triiodo-L-thyronine(T3)-Binding Protein car elle régule la concentration en hormone thyroïdienne T3 libre dans la cellule. mCRYM appartient également à la famille des µ-crystallines et à la superfamille des µ-crystallines/Ornithines Cyclodésaminases. Les protéines présentant des homologies pour ces trois familles sont la plupart différentes par leur fonction (enzymatique ou structurale), leur localisation tissulaire et leurs caractéristiques physico-chimiques. Cette diversité est due au recrutement de gènes de la superfamille des crystallines pour diverses fonctions métaboliques tout en conservant le taxon spécifique des crystallines. Je suis parvenue à résoudre sa structure cristallographique complexée au NADP(H) et à l'hormone thyroïdienne T3 à une résolution de 1,75 Å. La protéine mCRYM est un exemple intéressant d'évolution par son appartenance à différentes familles de protéines et, à ce jour, aucune activité enzymatique n'a été identifiée. Sa caractérisation structurale et thermodynamique a donc permis de mettre en évidence les différences et les similitudes avec ses homologues enzymatiques et d'émettre des hypothèses quant à son évolution moléculaire. Ces résultats soulèvent de nouvelles questions concernant son rôle physiologique : mCRYM est-elle une enzyme ou une protéine structurale ? Comment intervient le couple redox NADPH/NADP+ pour réguler l'action génomique et/ou non génomique de l'hormone T3 ? L'hormone T3 est-il le seul ligand physiologique de CRYM dans le cerveau ?

CRYM

3

3'

5-triiodo-L-thyronine(T3)

NADPH/ NADP+

superfamille µ-crystallines/OCDs

Cytosolic-3