GADD34 : Lien moléculaire entre la détection des pathogènes et les voies intégrées de réponses au stress / GADD34 : Linking pathogen detection with the integrated stress response pathways

Ladeira costa claudio, Nuno filipe

05 June 2012

Les cellules dendritiques (DCs) sont les plus efficaces cellules présentatrices d'antigène. La détection de motifs pathogènes, tel que lipopolysaccharides bactériens et ARNs double-brins (ARNdb) viraux, par les DCs provoque leur maturation et induit de nombreux changements morphologiques et biochimiques permettant aux DCs d'acquérir leurs puissants fonctions activatrices des cellules T. Dans ce travail, les réponses des DCs à l'ARNdb ont été analysées. Nous avons montré que, en réponse à au poly I:C, un analogue synthétique des ARNdb, les DCs montent une réponse de stress intégré spécifique au cours de laquelle le facteur de transcription ATF4 et le cofacteur de la phosphatase 1, GADD34, sont exprimés. Les DCs activées par le poly I:C présentent un profil de transcrits similaire à ce qui est produit au cours d'une ‘unfolded protein response'. GADD34 est important pour contrebalancer la phosphorylation du facteur d'initiation de la synthèse protéique eIF2α par la kinase PKR au cours de l'activation des DCs. Contrairement aux fibroblastes embryonnaires murins, les DCs résistent à l'inhibition de la synthèse des protéines induite en réponse à la stimulation avec poly I:C. Néanmoins, l'expression de GADD34 n'a pas un impact majeur sur la synthèse protéique globale. Par contre, GADD34 a été démontré être absolument nécessaire à la production d'interféron du type I et d'IL-6 par les fibroblastes et les DCs en réponse à l'ARNdb. Cette observation a des implications importantes en liant la détection des pathogènes avec les voies intégrés de réponse au stress. / Dendritic cells (DCs) are the most important antigen presenting cells. In response to inflammatory stimulation, DCs display a distinct pattern of differentiation that exhibits specific mechanisms to control the immune response. In this work the responses to dsRNA were analyzed. We have shown that in response to a mimic of dsRNA, polyriboinosinic:polyribocytidylic acid (poly I:C), DCs mount a specific integrated stress response during which the transcription factor ATF4 and the growth arrest and DNA damage-inducible protein 34 (GADD34), a phosphatase 1 (PP1) cofactor, are expressed. GADD34 is important to counteract phosphorylation of eIF2α by PKR. In contrast to murine embryonic fibroblasts (MEFs), DCs resist to protein synthesis inhibition induced in response to cytosolic dsRNA. Nevertheless, GADD34 expression does not have a major impact on global protein synthesis. Importantly, GADD34 was shown to be absolutely required for type I-IFN and IL-6 production by MEFs and DCs in response to dsRNA. This observation has important implications in linking pathogen detection with the integrated stress response pathways. The importance of this link is further underlined by the extreme susceptibility of GADD34-deficient fibroblasts and neonate mice to Chikungunya virus infection.

Cellules dendritiques

Gadd34

Poly I :C

EIF2&#945

Traduction

Dendritic cells

Gadd34

Poly I:C

EIF2&#945

Translation

Fatores de Plasmodium falciparum envolvidos na fosforilação de eIF2α em resposta a melatonina. / Plasmodium falciparum factors involved in eIF2α phosphorylation in response to melatonin.

Almeida, Fahyme Costa da Silva

17 February 2016

A malária é causada por parasitas Plasmodium falciparum, e embora vários aspectos ainda sejam desconhecidos, é sabido que a regulação do ciclo intraeritrocítico é crítica para a compreensão do ciclo celular e patogênese. A melatonina modula o ciclo de P. falciparum promovendo a sincronização, mas, o mecanismo de transdução de sinal é parcialmente caracterizado, envolvendo variações citosólicas de cálcio, AMPc e ativação da PKA. Modificações pós-traducionais participam na via de sinalização, e diversas proteínas quinase podem estar envolvidas na sinalização por melatonina. eIF2α fosforilado é capaz de ativar a tradução de mRNAs em resposta a situações desfavoráveis. O genoma de P. falciparum codifica três quinases cujo substrato é eIF2α: PfeIK1, PfeIK2 e PfPK4. Investigamos o papel da PfeIK1 na via de transdução de sinal de melatonina usando cepas nocaute para PfeIK1. Além disso, os efeitos de metabólitos da degradação do heme sobre a fosforilação de eIF2α. Sugerimos que o mecanismo de fosforilação e defosforilação de eIF2α possam ser relevantes para a resposta do parasita a hemina ou biliverdina. Nossos dados indicam a PfeIK1, juntamente com a PfK7 e PKA, como quinases-chaves no controle do desenvolvimento durante o ciclo intraeritrocítico. / Malaria is caused by Plasmodium falciparum parasites, and although some aspects are still unknown, its established that the intraerythrocytic cycle regulation is critic for understanding the cell cycle and pathogenesis of the parasite. Melatonin modulates the cycle of P. falciparum promoting synchronization; however, the signal transduction mechanism is partially characterized, and it contains cytosolic variations of calcium, AMPc and PKA activation. Post-translational modifications participate in this signal pathway, and several kinase proteins may be involved in melatonin signaling pathway. Phosphorylated eIF2α is able to activate mRNAs translation in stress conditions. The genome of P. falciparum encodes three kinases whose substrate is eIF2α: PfeIK1, PfeIK2 e PfPK4. We investigate the role of PfeIK1 in melatonin signaling pathway by using knockout strains for PfeIK1. Furthermore, we investigate the effects of heme degradation metabolities in eIF2α phosphorylation. We suggest that the phosphorylation and dephosphorylation mechanisms of eIF2α may be relevant for parasite response to heme and billiverdin. Our data indicates PfeIK1, PfK7 and PKA as key kinases for the development control during intraerythrocytic cycle.

Plasmodium falciparum

Plasmodium falciparum

Biliverdin

Biliverdina

eIF2α

eIF2α

Kinase

Melatonin

Melatonina

PfeIK1

PfeIK1

Quinase

Fatores de Plasmodium falciparum envolvidos na fosforilação de eIF2α em resposta a melatonina. / Plasmodium falciparum factors involved in eIF2α phosphorylation in response to melatonin.

Fahyme Costa da Silva Almeida

17 February 2016

A malária é causada por parasitas Plasmodium falciparum, e embora vários aspectos ainda sejam desconhecidos, é sabido que a regulação do ciclo intraeritrocítico é crítica para a compreensão do ciclo celular e patogênese. A melatonina modula o ciclo de P. falciparum promovendo a sincronização, mas, o mecanismo de transdução de sinal é parcialmente caracterizado, envolvendo variações citosólicas de cálcio, AMPc e ativação da PKA. Modificações pós-traducionais participam na via de sinalização, e diversas proteínas quinase podem estar envolvidas na sinalização por melatonina. eIF2α fosforilado é capaz de ativar a tradução de mRNAs em resposta a situações desfavoráveis. O genoma de P. falciparum codifica três quinases cujo substrato é eIF2α: PfeIK1, PfeIK2 e PfPK4. Investigamos o papel da PfeIK1 na via de transdução de sinal de melatonina usando cepas nocaute para PfeIK1. Além disso, os efeitos de metabólitos da degradação do heme sobre a fosforilação de eIF2α. Sugerimos que o mecanismo de fosforilação e defosforilação de eIF2α possam ser relevantes para a resposta do parasita a hemina ou biliverdina. Nossos dados indicam a PfeIK1, juntamente com a PfK7 e PKA, como quinases-chaves no controle do desenvolvimento durante o ciclo intraeritrocítico. / Malaria is caused by Plasmodium falciparum parasites, and although some aspects are still unknown, its established that the intraerythrocytic cycle regulation is critic for understanding the cell cycle and pathogenesis of the parasite. Melatonin modulates the cycle of P. falciparum promoting synchronization; however, the signal transduction mechanism is partially characterized, and it contains cytosolic variations of calcium, AMPc and PKA activation. Post-translational modifications participate in this signal pathway, and several kinase proteins may be involved in melatonin signaling pathway. Phosphorylated eIF2α is able to activate mRNAs translation in stress conditions. The genome of P. falciparum encodes three kinases whose substrate is eIF2α: PfeIK1, PfeIK2 e PfPK4. We investigate the role of PfeIK1 in melatonin signaling pathway by using knockout strains for PfeIK1. Furthermore, we investigate the effects of heme degradation metabolities in eIF2α phosphorylation. We suggest that the phosphorylation and dephosphorylation mechanisms of eIF2α may be relevant for parasite response to heme and billiverdin. Our data indicates PfeIK1, PfK7 and PKA as key kinases for the development control during intraerythrocytic cycle.

Plasmodium falciparum

Biliverdina

eIF2α

Melatonina

PfeIK1

Quinase

Plasmodium falciparum

Biliverdin

eIF2α

Kinase

Melatonin

PfeIK1

Translation Regulation of UV-induced Transcription Factor NF-κB and Oncogene COX-2

László, Csaba F.

24 April 2009

No description available.

Molecular Biology

NF-kappa-B

eIF2&945

UV

COX-2

translation regulation

Signalling of ciclyn o complexes through EIF2alpha phosphorylation

Ortet Cortada, Laura

04 June 2010

We have identified a novel Cyclin, called Cyclin O, which is able to bind and activate Cdk2 in response to intrinsic apoptotic stimuli. We have focused on the study of Cyclin Oα and Cyclin Oβ, alternatively spliced products of the gene. Upon treatment with different stress stimuli, transfected Cyclin Oα accumulates in dense aggregations in the cytoplasm compatible with being Stress Granules (SGs). Furthermore, we have seen that Cyclin Oβ and a point mutant of the N-terminal part of the protein constitutively localize to the SGs. Although both alpha and beta isoforms are proapoptotic, only Cyclin Oα can bind and activate Cdk2. On the other hand, we have demonstrated that Cyclin O is upregulated by Endoplasmic Reticulum (ER) stress and is necessary for ER stress-induced apoptosis. Cyclin O activates specifically the PERK pathway and interacts with the PERK inhibitor protein p58IPK. Moreover, Cyclin O participates in the activation of other eIF2α kinases. We have also observed that a pool of Cyclin O is located in active mitochondria, suggesting a function of the protein linked to oxidative metabolism.Hemos identificado una nueva Ciclina, llamada Ciclina O, que es capaz de unirse y activar Cdk2 en respuesta a estímulos apoptóticos intrínsecos. Nos hemos centrado en el estudio de la Ciclina Oα y la Ciclina Oβ, productos de splicing alternativo del gen. En respuesta a diferentes tipos de estrés, la Ciclina Oα se acumula en agregaciones citoplásmicas densas que podrían corresponder a Gránulos de Estrés (SGs). Además, hemos visto que la Ciclina Oβ y un mutante puntual de la parte N-terminal de la proteína se localizan constitutivamente en los SGs. Aunque las dos isoformas alfa y beta son proapoptóticas, solo la Ciclina Oα es capaz de unirse y activar Cdk2. Por otro lado, hemos demostrado que los niveles de Ciclina O se incrementan en respuesta al estrés de Retículo Endoplásmico (RE) y que esta proteína es necesaria para la inducción de apoptosis dependiente de estrés de RE. La Ciclina O activa específicamente la vía de PERK e interacciona con la proteína inhibidora de PERK p58IPK. Además, la Ciclina O participa en la activación de otras quinasas de eIF2α. La Ciclina O se localiza en mitocondrias activas, lo que sugiere una función de la proteína ligada al metabolismo oxidativo.

retículo endoplásmico

gránulos de estrés

respuesta a proteinas mal plegadas

apoptosis

p58IPK

Mitochondria

Endoplasmic Reticulum

IRE1

ATF6

Unfolded Protein Response

PKR

GCN2

HRI

PERK

CHOP

TIA-1

stress granules

eIF2α

shRNA

Cdk2

cyclin O

apoptosis

mitocondria

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