Global ETD Search

41	Activation de la voie NF-kB par les protéines Tax des HTLV : Rôles des modifications post-traductionnelles et de la localisation de Tax / Activation of the N F-kB pathway by the Tax proteins of the HTLV viruses : Roles of Tax post-translational modifications and localization Bonnet, Amandine 15 November 2012 (has links) Le virus T lymphotrope humain de type 1 (HTLV-1, Human T cell Leukemia Virus type 1) est l'agent responsable de la leucémie à cellules T de l'adulte, une prolifération maligne de lymphocytes T CD4+. L'activation constitutive de la voie NF-kB dans les lymphocytes T exprimant la protéine virale Tax s'est révélée primordiale pour la prolifération et la transformation induites par HTLV-1. Selon le modèle classique, Tax agit à deux niveaux de la voie NF-kB. Dans le cytoplasme, Tax active constitutivement le complexe IKK (IKB Kinase) en se liant à sa sous-unité régulatrice NEMO/IKKy. Dans le noyau, Tax interagit directement avec les dimères NF-kB dans des corps nucléaires Tax. L'ubiquitinylation et la SUMOylation de Tax ont été initialement décrites comme nécessaires pour l'activation de la phase cytoplasmique et de la phase nucléaire respectivement. Cependant, les mécanismes régulateurs des modifications post-traductionnelles de Tax restent difficiles à identifier car il n'a pas été possible d'étudier séparément l'ubiquitinylation et la SUMOylation de Tax.Au laboratoire, nous avons généré et caractérisé fonctionnellement un nouveau mutant de Tax qui nous a permis de découpler les rôles de l'ubiquitinylation et de la SUMOylation de Tax. Tax- P79AQ81A est ubiquitinylé de façon quantitativement similaire à Tax mais présente une forte réduction (80%) de SUMOylation. De plus, Tax-P79AQ81A ne forme pas de corps nucléaires. Néanmoins, ces deux défauts ne semblent pas préjudiciables pour la capacité du mutant à activer la voie NF-KB non seulement dans des lignées cellulaires mais également dans des lymphocytes T CD4+ primaires. En parallèle, nous avons montré que les corps nucléaires Tax sont rarement présents dans des lymphocytes T chroniquement infectés par HTLV-1, renforçant l'idée que ces structures ne sont pas requises pour l'activation de la voie NF-KB et probablement pas pour les autres fonctions de Tax. Enfin, nous avons démontré que les capacités d'activation de la voie NF-KB de différents mutants de Tax sont fortement corrélées à leur niveau d'ubiquitinylation mais pas de SUMOylation, confirmant que l'ubiquitinylation de Tax est la modification essentielle pour l'activation de la voie NF-KB.Le virus HTLV-2 ne possède pas les propriétés transformantes du virus HTLV-1 et les propriétés de la protéine Tax2 comparées à celles de Tax1 pourraient être à l'origine des différences de pathogénicité entre les deux virus. Notre étude a révélé que, de façon surprenante, l'activation de la voie NF-KB par la protéine Tax2 est non seulement indépendante de la SUMOylation et de la formation des corps nucléaires comme pour Tax1, mais également indépendante d'une quelconque ubiquitinylation, suggérant des mécanismes différents d'activation du complexe IKK parTax1 et Tax2.Nos études, aussi bien de la protéine Tax1 que de la protéine Tax2, nous ont donc permis de revisiter le modèle actuel d'activation de la voie NF-kB en démontrant l'impact mineur de la SUMOylation et en révélant une différence majeure en ce qui concerne le rôle de l'ubiquitinylation, distinguant les virus HTLV-1 et HTLV-2 / Human T cell Leukemia Virus type 1 (HTLV-1) is the etiological agent of adult T-cell leukemia (ATL), a CD4+ T-cell malignancy, Constitutive activation of the NF-KB pathway plays a crucial role in cell proliferation and transformation induced by HTLV-1, According to the classical model, Tax acts at two levels on the NF-KB pathway, In the cytoplasm, Tax activates the IKB kinase (IKK) complex by directly interacting with the regulatory subunit NEMO/IKKy, In the nucleus, Tax directly interacts with the NF-KB dimers in particular structures named Tax nuclear bodies, Both ubiquitinylation and SUMOylation were initially considered as critical for activation of the cytoplasmic or nuclear phase, respectively, However, the individual role of each modification was difficult to assess because of the lack of molecular tools allowing to study Tax ubiquitination and SUMOylation separately,In the laboratory, we functionally characterized a new Tax mutant, Tax-P 7 9AQ81A, which gave us the opportunity to uncouple Tax ubiquitination and SUMOylation, Indeed, Tax-P79AQ81A is ubiquitinated similarly to wild-type Tax but is severely reduced in SUMOylation, In addition, Tax- P 7 9AQ81A does not form nuclear bodies, However, despite these two severe defects, we found that the mutant is fully able to activate the NF-KB pathway not only in cells lines but also in CD4+ primary T cells, Moreover we showed that Tax nuclear bodies are hardly present in HTLV-1 chronically infected T cell lines, confirming the idea that these structures are not required for Tax-induced NF-KB activation and probably for other Tax functions, Finally, we demonstrated that ability of different Tax mutant to activate the NF-KB pathway is strongly correlated with their ubiquitination but not SUMOylation level, confirming that ubiquitination is the key Tax modification required for activation of the NF-KB pathway,In contrast to HTLV-1, the related HTLV-2 virus is not a transforming virus and therefore, the properties of the Tax2 protein compared to that of Tax1 could be responsible for the different pathogenicity of HTLV-2 and HTLV-1, We studied the post-translational modifications of Tax2 and surprisingly, found that Tax2-induced NF-KB activation is not only independent of SUMOylation and nuclear body formation but also of ubiquitination, suggesting different mechanisms of activation of the IKK complex by Tax1 and Tax2,In conclusion, our results led us to propose a new model for both Tax1- and Tax2-induced NF- KB activation in which SUMOylation has a minor role and in which the requirement of Tax ubiquitination distinguishes between HTLV-1 and HTLV-2 Tax HTLV-1 HTLV-2 Ubiquitinylation SUMOylation Corps nucléaire NF-KB Tax HTLV-1 HTLV-2 Ubiquitinilation SUMOylation Nuclear bodies NF-KB
42	Etude des modifications post-traductionnelles de la protéine ATF7 / Study of the protein ATF7 post-translational modifications Schaeffer, Étienne 24 June 2014 (has links) L’objectif de ces travaux de thèse est l’étude des modifications post-traductionnelles de la protéine ATF7. Cette protéine est phosphorylée sur les résidus thréonine (T) 51, T53 et T112 lorsque les cellules subissent un stress (UVs, choc osmotique). Cela permet à la protéine d’être active transcriptionnellement. En absence de stress une fraction de la protéine ATF7 est sumoylée et cela induit une inhibition de son activité transcriptionnelle. Le premier projet consiste à développer des outils qui permettent l’étude de la forme sumoylée de la protéine ATF7. Ces travaux ont permis l’élaboration de scFv-bispécifiques tétramériques qui permettent la reconnaissance simultanée de la protéine ATF7 et de la protéine SUMO1. L’autre projet principal était l’étude du rôle de la phosphorylation de la T112 en absence de stress. Les travaux menés au laboratoire ont permis de montrer que cette thréonine est phosphorylée pendant la phase M du cycle cellulaire et que cet événement est conduit par une autre voie de phosphorylation que la voie du stress et met en jeu la CDK1. / The objective of this thesis work was is the study of post-translationnal modifications (PTM) of the protein ATF7. This protein is phosphorylated on several threonine (T) residues upon stress (UVs, osmotic chock). This allows the protein to be transcriptionally active. In the absence of stress, a fraction of the protein is sumoylated resulting in an inhibition of its transcriptional activity. The first project raise to the development of tools that will enable the study of the sumoylated form of ATF7 protein. This work raise to the development of tetrameric bispecific scFv possessing a simultaneously recognizing ability of the proteins ATF7 and SUMO1. The other main project was the study of ATF7 T112 phosphorylation in the absence of stress. The experiments drove in the lab have shown that thus threonine is phosphorylated during mitosis by a specific pathway, which includes the CDK1. Cycle cellulaire Phosphorylation Sumoylation CDK ScFv Anticorps bispécifiques ATF7 Anticorps recombinants Post-translationnal modification Protein ATF7 Mitosis Sumoylation CDK ScFv Inhibition 571.8 572.8
43	TIF1gamma, nouveau régulateur négatif de la voie de signalisation du TGFbeta / TIF1gamma, a new negative regulator of TGFbeta signaling Fattet, Laurent 28 March 2013 (has links) Le TGFbeta intervient dans la régulation de nombreux processus cellulaires comme la prolifération, la différenciation, la migration, l'apoptose, du développement embryonnaire jusqu'à la vie adulte. Le TGFbeta est aujourd'hui bien décrit pour son rôle de suppresseur de tumeur de par ses activités anti-prolifératives et pro-apoptotiques, en particulier sur les cellules épithéliales. Cependant, au cours de la progression tumorale, le TGFbeta devient un promoteur de tumeur en favorisant l'angiogenèse, l'échappement de la tumeur vis-à-vis du système immunitaire et en induisant la transition épithélio-mésenchymateuse. Après fixation du ligand TGFbeta , le complexe de récepteurs active les protéines cytoplasmiques Smad2 et Smad3 qui s'associent à Smad4 pour former le complexe transcriptionnel qui se transloque alors dans le noyau pour réguler la transcription de nombreux gènes cibles. Récemment, la protéine TIF1gamma a été décrite pour intervenir dans la régulation négative de la voie du TGFbeta , en monoubiquitinant Smad4 ou en interagissant avec Smad2/3 en compétition avec Smad4. Cette voie de signalisation devant être finement contrôlée pour cibler son action en fonction du contexte cellulaire, nous analysons ici la régulation des interactions fonctionnelles entre la voie canonique du TGFbeta et la protéine TIF1gamma. Dans cette étude, nous montrons que TIF1gamma agit comme un régulateur négatif des fonctions de Smad4 dans la voie de signalisation du TGFbeta au cours du processus de transition épithélio-mésenchymateuse et au cours de la différenciation terminale des cellules épithéliales mammaires et de la lactation. Nous étudions également la SUMOylation de TIF1gamma comme nouveau niveau de régulation de la réponse cellulaire au TGFbeta . Nous avons ainsi caractérisé les sites fonctionnels de SUMOylation de TIF1gamma et montré que cette modification post-traductionnelle inhibe la formation du complexe transcriptionnel Smad et est nécessaire pour réguler temporellement la résidence de Smad4 au niveau du promoteur de gènes cibles du TGFbeta . Nos résultats montrent le rôle important de la SUMOylation de TIF1gamma dans la régulation de la transition épithélio-mésenchymateuse induite par le TGFbeta . En conclusion, notre travail met en avant le rôle majeur de TIF1gamma dans la régulation de la réponse transcriptionnelle au TGFbeta . De plus, nous montrons que la SUMOylation de TIF1gamma est nécessaire à son activité répressive sur Smad4 / The cytokine TGFbeta regulates several cellular processes such as proliferation, differentiation, migration and apoptosis, from embryonic development to adulthood. TGFbeta is well described for its tumor suppressor role through antiproliferative and proapoptotic activities, in particular in epithelial cells. During tumor progression however, TGFbeta becomes a tumor promotor, favoring angiogenesis, immune suppression and inducing the epitheliomesenchymal transition. Binding of TGFbeta ligand to its receptors activate cytoplasmic messenger Smad2 and Smad3 to complex with Smad4 and shuttle into the nucleus to regulate TGFbetatarget genes expression. Recently, TIF1gamma has been described as a new negative regulator of TGFbeta signaling, through monoubiquitination of Smad4 or direct competition with Smad4 to bind activated Smad2/3. This signaling pathway has to be finely tuned to target an action dependent on a cellular context, which is why we analyze here the regulation of functional interactions between the TGFbeta canonical signaling and TIF1gamma. In this study, we show that TIF1gamma acts as a negative regulator of Smad4 functions in TGFbetasignaling during the epithelio-mesenchymal transition and during terminal differentiation of mammary epithelial cells and lactation. We are also interested in studying TIF1gamma SUMOylation as additional level of regulation of cell response to TGFbeta. Thus we characterized four functional SUMOylation sites in TIF1gamma and we found that this post-translational modification inhibits the formation of Smads transcriptional complex and is needed to temporally restrict Smad4 residence on the promoter of TGFbetatarget genes. Our results show the critical role of TIF1gamma SUMOylation in the regulation of TGFbeta- induced epithelio-mesenchymal transition. As a conclusion, our study unveils the major role of TIF1gamma in the regulation of TGFbeta transcriptional responses. Moreover, we show that TIF1gamma requires SUMOylation to exert its repressive activity on TGFbetasignaling TGFβ TIF1γ Smad4 SUMOylation Signalisation Transition épithélio-mésenchymateuse Progression tumorale Lactation TGFβ TIF1γ Smad4 SUMOylation Signaling Epithelio-mesenchymal transition Tumor progression Lactation 571.6
44	Etude du rôle de la sumoylation dans le métabolisme des ribonucléoparticules d'ARN messagers (mRNPs) / The role of sumoylation in messenger ribonucleoproteins (mRNPs) metabolism Rouvière, Jérôme 24 March 2016 (has links) Au sein des cellules, les ARNms sont liés par de nombreuses protéines, générant ainsi des particules appelées mRNPs (Ribonucléoparticules de messagers). Leur formation est cotranscriptionnelle, et leur composition va réguler l’ensemble des étapes du métabolisme des ARNms : stabilité, maturation, export, localisation et traduction. Au vu de l’importance de ces mécanismes dans la physiologie cellulaire, le contenu protéique des mRNPs est finement régulé dans le temps et l’espace et fait l’objet de nombreux remodelages. Ces changements de composition dépendent notamment des hélicases, ainsi que des modifications post-traductionnelles ; cependant, ces mécanismes demeurent à caractériser de façon plus approfondie. Une modification post-traductionnelle susceptible de moduler ces remaniements depuis la levure S. cerevisiae jusqu’aux métazoaires est la sumoylation. En effet, la SUMO-protéase Ulp1/SENP2, une enzyme clé de la machinerie de sumoylation, est localisée au panier des pores nucléaires, à proximité d’une plateforme d’ancrage des mRNPs destinées à l’export. Par ailleurs, il a été rapporté chez la levure que des mutants affectant la localisation et la stabilité d’Ulp1 présentent des défauts d’export et de localisation des mRNPs. Au vu de ces données, le laboratoire s’est intéressé aux rôles potentiels de la sumoylation dans le métabolisme de ces particules d’ARNm. Dans ce but, un crible protéomique a été réalisé chez la levure S. cerevisiae afin de comparer la composition des mRNPs entre des cellules sauvages ou mutantes pour Ulp1. Ce crible a mis en évidence un rôle d’Ulp1 dans le recrutement de deux composants des mRNPs, le complexe THO et l’hnRNP Hek2. Le complexe THO est un facteur multiprotéique qui participe à la prévention de l’instabilité génique et contribue à la transcription des ARNms, à l’assemblage des mRNPs et à leur export. L’hnRNP Hek2 est une protéine aux rôles multiples, dont l’association à un ARNm est susceptible de moduler sa stabilité, sa traduction et/ou sa localisation. Des analyses biochimiques nous ont permis de mettre en évidence l’existence de formes sumoylées de la sous-unité Hpr1 du complexe THO ainsi que de l’hnRNP Hek2. Toutes deux sont Ulp1-dépendantes, et interviennent sur la partie C-terminale de ces protéines. Nous avons également mis en évidence que chacune de ces sumoylations contrôle le recrutement de son substrat au sein des mRNPs. L’analyse fonctionnelle d’un mutant affectant la sumoylation d’Hpr1 a identifié cette modification comme nécessaire au recrutement du complexe THO sur une population d’ARNms impliqués dans la résistance au stress acide, autrement dégradés par l’exosome. Ainsi, l’absence de sumoylation d’Hpr1 diminue fortement la viabilité cellulaire en conditions de stress, un phénotype supprimé par l’inactivation de l’exosome. L’étude des effets de la sumoylation d’Hek2 suggère une modulation par SUMO de certaines de ses fonctions, notamment dans la localisation cellulaire des ARNms. L’ensemble de ces données fournit donc les deux premiers exemples de régulation du métabolisme des mRNPs par des événements de sumoylation intervenant au niveau du pore nucléaire. / Within the cells, mRNAs are associated to proteins, thereby generating particles called mRNPs (messenger ribonucleoproteins). mRNPs form in a cotranscriptional manner and their composition defines the fate of mRNAs by modulating the different steps of their metabolism, including their stability, their processing, their export, their localisation and their translation. In view of the importance of such mechanisms for cell physiology, several mechanisms ensure a tight spatio-temporal control of mRNPs composition through multiple mRNP remodelling events. These changes in the protein content of mRNPs depend on helicases and post-translational modifications, but remain to be further investigated. Sumoylation is one of the modifications that could contribute to mRNPs remodelling from yeast (S. cerevisiae) to metazoans. Indeed, it has been reported that the SUMO-protease Ulp1/SENP2, a key enzyme of the sumoylation machinery, is localized at the basket of nuclear pore complexes, in close vicinity with mRNPs committed for export. This particular localization, together with the reported defects in mRNPs export and localisation of yeast mutants affecting Ulp1, prompted the lab to ask whether sumoylation could contribute to mRNP biogenesis. In order to investigate this hypothesis, our lab compared mRNPs composition between wild-type and ulp1 mutant S. cerevisiae yeast strains using a proteomic approach. This screen identified two mRNP components that depend on Ulp1 for their recruitment onto these particles: the THO complex and the hnRNP Hek2. The THO complex is a multi-subunit factor that prevents genome instability and contributes to transcription, mRNP assembly and export. Hek2 has multiple functions in mRNA stability, translation and/or localization. Using biochemical approaches, we have been able to visualize sumoylated versions of the Hpr1 subunit of the THO complex and of the hnRNP Hek2. In both cases, this modification depends on Ulp1 activity and occurs on the C-terminal part of the protein. We further showed that these sumoylation events control THO and Hek2 recruitment onto mRNPs. Functional analysis of a mutant impairing Hpr1 sumoylation revealed that this modification is required for proper recruitment of the THO complex onto a subset of mRNAs involved in acidic stress resistance, which are otherwise degraded by the exosome. Decreased Hpr1 sumoylation results in a strong reduction of viability in acid stress conditions, a phenotype that is rescued by inactivation of the exosome. The investigation of the role of Hek2 sumoylation in mRNPs metabolism suggests that this modification regulates some of Hek2 functions, especially in mRNA localisation. All together, these results provide the two first examples of mRNPs components whose functions are regulated by sumoylation events occurring at the level of nuclear pores. Ribonucléoparticules d'ARN messagers Sumoylation Pore nucléaire Localisation des ARNs Stabilité des ARNs SUMO-Protéase Ulp1 Messenger ribonucleoproteins Sumoylation Nuclear pore RNA localization RNA stability Ulp1 SUMO-Protease
45	INDUCTION OF THE HEAT SHOCK RESPONSE TO PROTECT AGAINST POLYGLUTAMINE DISEASES AND THE ROLE OF PROTEIN SUMOYLATION IN LAMINOPATHIES AND ALZHEIMER'S DISEASE Zhang, Yu-Qian 01 January 2008 (has links) Heat shock proteins function as molecular chaperones which help protein folding and prevent protein aggregation. My study shows that celastrol, a pharmacological compound capable of up-regulating the levels of heat shock proteins, inhibits cell death and protein aggregation caused by expanded polyglutamine containing protein, and the protective effects of celastrol are dependent on heat shock factor 1. These results suggest the potential of celastrol as a therapeutic agent in the treatment of polyglutamine diseases. Sumoylation is a protein modification which plays diverse roles in regulating the target proteins. My study shows that lamin A is a target of protein sumoylation, and two lamin A mutants associated with familial dilated cardiomyopathy, E203G and E203K, exhibit decreased sumoylation. My results also indicate that sumoylation is important for the normal localization of lamin A, and support a role for altered sumoylation in the underlying molecular mechanism of cardiomyopathies associated with the E203G/E203K lamin A mutations. In the third project, my results show that amyloid precursor protein is another target of SUMO modification, and sumoylation of amyloid precursor protein reduces the levels of amyloid β aggregates, which are the primary causative factor for Alzheimer’s disease. My results provide a new mechanism for the generation of amyloid β, and indicate the potential of up-regulating activity of the cellular sumoylation machinery as an approach against Alzheimer’s disease. My results also provide the first demonstration that SUMO E2 enzyme exists in the lumen of the endoplasmic reticulum, extending the sub-cellular reach of sumoylation to include the regulation of proteins in secretory pathways. Celastrol Polyglutamine Diseases Protein Sumoylation Lamin A Amyloid Precursor Protein Medical Biochemistry
46	IDENTIFICATION OF SUMOYLATED PROTEINS AND INVESTIGATION OF PROTEIN UBIQUITINATION IN THE NF-κB PATHWAY Liu, Xiaoyan 01 January 2012 (has links) SUMOylation and ubiquitination are important post-translational modifications. While ubiquitination is well known for targeting proteins for degradation, SUMOylation often regulates the intracellular localization of substrates. In the first project of this dissertation, we developed proteomic strategies to identify novel SUMOylated proteins in mammalian cells. In the second project, we investigated the regulation of protein ubiquitination in the NF-κB signaling pathway in the context of Paget’s disease of bone (PDB). Identification of SUMOylated proteins has been a challenge because of low abundance of SUMOylation substrates. Here, we utilized a mass spectrometry (MS)-based proteomic approach to identify novel SUMOylated proteins in mammalian cells. Seventy-four unique proteins were commonly identified in the collection of four SUMO-1 plasmids, thus considered candidate SUMOylated proteins. Many of these proteins are associated with the nucleus. The results were validated by confirming SUMOylation of a novel substrate Drebrin and a well known substrate Ran-GAP1. Furthermore, the potential SUMOylation sites in Drebrin have been identified and confirmed using site-directed mutagenesis. PDB is a disorder characterized by increased bone turnover containing hyperactive osteoclasts. Mutations in Sequestosome 1 (p62) are associated with 40% of familial PDB. P62 is a scaffold protein and plays a critical role in regulating ubiquitination of TRAF family signaling molecules and mediating the activation of NF-κB by RANK and TNFα ligands. P62 also plays a critical role in shuttling substrates for autophagic degradation. The objective of this project is to determine the effects of PDB-associated p62 mutants on NF-κB signaling and autophagy. We compared the effect of wild-type (WT) p62 and PDB mutations (A381V, M404V and P392L) on the TNFα-induced NF-κB signaling using an NF-κB luciferase assay. Our results show that these p62 mutations increased the NF-κB signaling. In addition, we found that the PDB mutations did not change the interaction between p62 and the autophagy marker protein LC3. In summary, the PDB mutations in p62 are likely gain-of-function mutations that can increase NF-κB signaling and potentially contribute to disease progression. Based on the results, we proposed a model to speculate the synergetic role of p62 PDB mutant on NF-κB signaling and autophagy. SUMOylation ubiquitination Paget’s disease of bone (PDB) p62 NF-κB signaling Medical Biochemistry
47	Analysis of protein SUMOylation and its role in Alzheimer's disease using mouse models Stankova, Trayana 02 February 2017 (has links) No description available. 570 Posttranslational modifications SUMOylation Alzheimer´s disease Mouse model 5xFAD SUMO1 SUMO3 Neurodegeneration Biologie (PPN619462639)
48	Identification de la sumoylation de ZNF74 et de l'interaction de cette protéine à multidoigt de zinc avec UBC9 et PIAS1 Abenhaim, Samantha January 2004 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Syndrome de DiGeorge ZNF74 Multidoigt de zinc Motif KRAB Sumoylation UBC9 PIAS Répression transcriptionnelle Double hybride
49	Neuroprotective therapies centred on post-translational modifications by sumoylation Bernstock, Joshua January 2018 (has links) No description available.
50	Molecular insights into the biological role / mechanisms of GATA-4 and FOG-2 in normal cardiac function and in cardiac hypertrophy. Philips, Alana Sara, Clinical School - St George Hospital, Faculty of Medicine, UNSW January 2007 (has links) The regulation of cardiac-specific genes such as GATA-4 and its co-factor FOG-2 is paramount for normal heart development and function. Indeed, those mechanisms that regulate GATA-4 and FOG-2 function, such as nuclear transport and the post-translational modification of SUMOylation, are of critical importance for cardiogenesis. Therefore the aims of this study were to: i) elucidate the nuclear transport mechanisms of GATA-4; ii) determine the function of SUMOylation on the biological activity of both GATA-4 and FOG-2; and iii) examine how these mechanisms impact on the role of GATA-4 and FOG-2 in cardiac hypertrophy. Firstly, we characterised a non-classical nuclear localisation signal that mediates active import of GATA-4 in both HeLa cells and cardiac myocytes. Fine mapping studies revealed four crucial residues within this region that interacted with importin ?? to mediate GATA-4 import via the non-classical import pathway. In addition, a cardiac myocyte-specific CRM1-dependent nuclear export signal, which consists of three essential leucine residues, was identified. We also investigated the residues of GATA-4 that are responsible for its DNAbinding activity and therefore transcriptional control of cardiac-specific genes. Secondly, we demonstrated that SUMOylation of both GATA-4 and FOG-2 is exclusively carried out by SUMO-2/3. Moreover, SUMOylation is involved in the nuclear localisation of both GATA-4 and FOG-2 in cardiac myocytes as well as the transcriptional regulation of cardiac-specific genes, such as cardiac troponin I. Finally, and perhaps most biologically significant, we showed that nuclear transport as well as SUMOylation of GATA-4 is imperative for the ability of GATA-4 to induce cardiac hypertrophy. Moreover, it was determined that FOG-2 SUMOylation is involved in the ability of FOG-2 to protect against cardiac hypertrophy. In conclusion, the current study provides detailed information on the nuclear transport pathways of GATA-4 as well as the SUMOylation of both GATA-4 and FOG-2 and the role these two mechanisms play in gene transcription and cardiac hypertrophy. Cardiac hypertrophy. GATA-4. Nuclear transport. SUMOylation. FOG-2. Genes. Heart -- Hypertrophy.

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