Molecular regulation and enhancement of megakaryopoiesis and thrombopoiesis by the p45 subunit of NF-E2.

Fock, Ee-Ling, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

Megakaryocytes (MKs) are a rare population of haematopoietic cells, which produce platelets. Platelet production is a complex process that is tightly regulated at the transcriptional level by lineage specific transcription factors such as p45 NF-E2. Understanding how transcriptional regulators operate is imperative to advance our knowledge of disease pathophysiology and to propose novel treatment options. Therefore, the aims of this study were to: i) study the effects of p45 NF-E2 overexpression on various stages of megakaryopoiesis; (ii) elucidate the nuclear transport mechanisms of p45 NF-E2; and iii) determine the impact of a p45 NF-E2 modification called SUMOylation on thrombopoiesis. Exogenous p45 NF-E2 was overexpressed in haematopoietic cells in culture and various aspects of megakaryopoiesis were examined. Overexpression of p45 NF-E2 enhanced multiple stages of MK differentiation such as colony forming unit (CFU)-MK formation and terminal MK maturation. Most importantly, p45 NF-E2 overexpression resulted in significant increases in proplatelet and functional platelet production in vitro. This latter result was confirmed in vivo using lethally irradiated mice transplanted with cells that overexpressed p45 NF-E2. Unexpectedly, the enhancement of MK differentiation was at the expense of myeloid development and, for the first time, identified p45 NF-E2 as a negative regulator of myeloid differentiation. Secondly, we determined the nuclear localisation signal of p45-NF-E2 and the pathway responsible for nuclear import. We also investigated the importance of p45 NF-E2 nuclear import in thrombopoiesis. Finally, we showed that p45 NF-E2 is modified mainly by SUMO-2/3 in bone marrow cells and this process is involved in the transcriptional activation of MK-specific genes and platelet release. Taken together, these results suggest that enforced expression of p45 NF-E2 selectively enhances many aspects of MK differentiation including early and terminal MK maturation, proplatelet formation and platelet release. Equally important, this thesis also indicates that white blood cell differentiation may be inhibited by p45 overexpression, while molecular processes such as the nuclear import and SUMOylation of p45 NF-E2 are vital for thrombopoiesis. These observations will facilitate subsequent studies into the feasibility of manipulating p45 NF-E2 protein levels for the treatment of conditions such as thrombocytopaenia and other platelet disorders.

Thrombopoiesis

Megakaryocytes

NF-E2

Molecular regulation and enhancement of megakaryopoiesis and thrombopoiesis by the p45 subunit of NF-E2.

Fock, Ee-Ling, Clinical School - St George Hospital, Faculty of Medicine, UNSW

January 2008

Megakaryocytes (MKs) are a rare population of haematopoietic cells, which produce platelets. Platelet production is a complex process that is tightly regulated at the transcriptional level by lineage specific transcription factors such as p45 NF-E2. Understanding how transcriptional regulators operate is imperative to advance our knowledge of disease pathophysiology and to propose novel treatment options. Therefore, the aims of this study were to: i) study the effects of p45 NF-E2 overexpression on various stages of megakaryopoiesis; (ii) elucidate the nuclear transport mechanisms of p45 NF-E2; and iii) determine the impact of a p45 NF-E2 modification called SUMOylation on thrombopoiesis. Exogenous p45 NF-E2 was overexpressed in haematopoietic cells in culture and various aspects of megakaryopoiesis were examined. Overexpression of p45 NF-E2 enhanced multiple stages of MK differentiation such as colony forming unit (CFU)-MK formation and terminal MK maturation. Most importantly, p45 NF-E2 overexpression resulted in significant increases in proplatelet and functional platelet production in vitro. This latter result was confirmed in vivo using lethally irradiated mice transplanted with cells that overexpressed p45 NF-E2. Unexpectedly, the enhancement of MK differentiation was at the expense of myeloid development and, for the first time, identified p45 NF-E2 as a negative regulator of myeloid differentiation. Secondly, we determined the nuclear localisation signal of p45-NF-E2 and the pathway responsible for nuclear import. We also investigated the importance of p45 NF-E2 nuclear import in thrombopoiesis. Finally, we showed that p45 NF-E2 is modified mainly by SUMO-2/3 in bone marrow cells and this process is involved in the transcriptional activation of MK-specific genes and platelet release. Taken together, these results suggest that enforced expression of p45 NF-E2 selectively enhances many aspects of MK differentiation including early and terminal MK maturation, proplatelet formation and platelet release. Equally important, this thesis also indicates that white blood cell differentiation may be inhibited by p45 overexpression, while molecular processes such as the nuclear import and SUMOylation of p45 NF-E2 are vital for thrombopoiesis. These observations will facilitate subsequent studies into the feasibility of manipulating p45 NF-E2 protein levels for the treatment of conditions such as thrombocytopaenia and other platelet disorders.

Thrombopoiesis

Megakaryocytes

NF-E2

Établissement d'une lignée cellulaire pro-érythroïde de souris : outil d'étude de la régulation transcriptionnelle des gènes de globine

Hajj Hassan, Houssein

January 2004

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Chromatine

Histones

Épigénétique

Immortalisation

Lignée érythroïde

Locus de la [bêta] globine

EKLF

NF-E2

GATA-1

Crystal structure of the kelch domain of human keap1

Li, Xuchu,

January 2005

Thesis (Ph. D.)--University of Missouri-Columbia, 2005. / The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Vita. Includes bibliographical references.

Participação do Nrf2 no processo de autofagia de células de brônquios humanos expostas ao material particulado de diesel / Participation of Nrf2 in the autophagy process of human bronchial cells exposed to diesel particulate matter

Frias, Daniela Perroni

10 December 2018

As partículas eliminadas na exaustão do diesel (DEP) são importantes fontes diárias de partículas inaladas, responsáveis por gerar espécies reativas de oxigênio no sistema respiratório, fazendo com que as células ativem mecanismos de defesa, como o sistema Keap1-Nrf2 e a autofagia. Para investigar o papel do Nrf2 no processo de autofagia induzida pelas DEPs, BEAS-2B foram expostas às DEP, coletadas diretamente de um motor a diesel. BEAS-2B foram tratadas com sulforafano, bafilomicina e EBSS para testar a relação entre as vias autofágica e antioxidante. A quantidade relativa de mRNA foi verificada por RT-PCR para os seguintes genes: Nrf2, NQO1, HO-1, p62, Atg5 e LCB3. A seguir, BEAS-2B foram transfectadas com RNA silenciador (siRNA) para Nrf2, expostas ou não às DEPs (10 e 50 micro g/mL por 1h e 2 h), e mRNA detectado por RT-PCR e Western blot para proteínas. Bafilomicina (inibidor de autofagia) mostrou uma diminuição significativa nos marcadores antioxidantes Nrf2 (p = 0,024), HO-1 (p = 0,002) e NQO1 (p = 0,003), enquanto sulforafano (ativador de Nrf2) aumentou os marcadores autofágicos LC3B (p = 0,004) e Atg5 (p = 0,007). BEAS-2B expostas às DEP na concentração de 50 micro g/mL por 2hs mostraram um aumento significativo nos genes autofágicos LC3B (p = 0,018) e p62 (p = 0,007) e nos genes da via antioxidante Nrf2 (p = 0,007) e NQO1 (p = 0,025). Houve uma diminuição significativa no mRNA de LC3B (p < 0,001), p62 (p = 0,001) e Atg5 (p = 0,024) nas células transfectadas com siRNA, expostas ou não à DEP. Western blotting mostrou uma redução das proteínas Nrf2, p62 e LC3II nas BEAS-2B siRNA, indicando que a exposição ao silenciamento de Nrf2 modificou a expressão de marcadores de autofagia (R < 1). Os resultados deste estudo mostram que, em células brônquicas expostas às DEP, o sistema Nrf2 e a autofagia trabalham em conjunto para tentar manter a homeostase celular / Diesel Exhaust Particles (DEPs) are main sources of daily inhaled particles, responsible for generating reactive oxygen species in the respiratory system, and causing the cells to activate defense mechanisms, such as the Keap1-Nrf2 system and autophagy. In order to investigate the role of Nrf2 in Dep-induced autophagy, BEAS-2B cells collected directly from a diesel engine were exposed to DEP and treated with sulforaphane, bafilomycin and BESS to test the relationship between autophagic and antioxidant pathways. The relative amount of mRNA was verified by RT-PCR for the following genes: Nrf2, NQO1, HO-1, p62, Atg5 and LCB3. Next, BEAS-2B cells were transfected with silencer RNA (siRNA) specific to Nrf2, exposed or not to DEPs (10 and 50 micro g/mL 1h and 2hs), and mRNA detected by RT-PCR and Western blotting for protein. Bafilomycin ( autophagy inhibitor) showed a significant decrease in the antioxidant markers Nrf2 (p=0.024), HO-1 (p = 0.002) and NQO1 (p = 0.003), whereas sulforaphane (Nrf2 activator) increased the expression levels of autophagic markers LC3B (p=0.004) and Atg5 (p=0.007). BEAS-2B exposed to DEP at a concentration of 50 micro g/mL for 2hs showed a significant increase in autophagic genes LC3B (p=0.018) and p62 (p=0.007),and in the antioxidant pathway markers Nrf2 (p=0.007) and NQO1 (p=0.025). There was a significant decrease in mRNA of the LC3B (p < 0.001), p62 (p=0.001) and Atg5 (p=0.024) in cells transfected with siRNA, exposed or not to DEP. Western blotting showed a reduction of Nrf2, p62 and LC3II proteins in BEAS-2B transfected with siRNA, indicating that Nrf2 silencedexposed to DEP modulated the expression of autophagy markers (R < 1). The results of this study show that, in bronchial cells exposed to DEP, the Nrf2 system and autophagy work together in order to try to maintain cellular homeostasis

Antioxidant response elements

Autofagia

Autophagy

Bronchi

Brônquios

Elementos de resposta antioxidante

Environmental pollution

Estresse oxidativo

Fator 2 relacionado a NF-E2

NF-E2-related factor 2

Oxidative stress

Particulado de diesel

Particulate of diesel

Poluição ambiental

Participação do Nrf2 no processo de autofagia de células de brônquios humanos expostas ao material particulado de diesel / Participation of Nrf2 in the autophagy process of human bronchial cells exposed to diesel particulate matter

Daniela Perroni Frias

10 December 2018

As partículas eliminadas na exaustão do diesel (DEP) são importantes fontes diárias de partículas inaladas, responsáveis por gerar espécies reativas de oxigênio no sistema respiratório, fazendo com que as células ativem mecanismos de defesa, como o sistema Keap1-Nrf2 e a autofagia. Para investigar o papel do Nrf2 no processo de autofagia induzida pelas DEPs, BEAS-2B foram expostas às DEP, coletadas diretamente de um motor a diesel. BEAS-2B foram tratadas com sulforafano, bafilomicina e EBSS para testar a relação entre as vias autofágica e antioxidante. A quantidade relativa de mRNA foi verificada por RT-PCR para os seguintes genes: Nrf2, NQO1, HO-1, p62, Atg5 e LCB3. A seguir, BEAS-2B foram transfectadas com RNA silenciador (siRNA) para Nrf2, expostas ou não às DEPs (10 e 50 micro g/mL por 1h e 2 h), e mRNA detectado por RT-PCR e Western blot para proteínas. Bafilomicina (inibidor de autofagia) mostrou uma diminuição significativa nos marcadores antioxidantes Nrf2 (p = 0,024), HO-1 (p = 0,002) e NQO1 (p = 0,003), enquanto sulforafano (ativador de Nrf2) aumentou os marcadores autofágicos LC3B (p = 0,004) e Atg5 (p = 0,007). BEAS-2B expostas às DEP na concentração de 50 micro g/mL por 2hs mostraram um aumento significativo nos genes autofágicos LC3B (p = 0,018) e p62 (p = 0,007) e nos genes da via antioxidante Nrf2 (p = 0,007) e NQO1 (p = 0,025). Houve uma diminuição significativa no mRNA de LC3B (p < 0,001), p62 (p = 0,001) e Atg5 (p = 0,024) nas células transfectadas com siRNA, expostas ou não à DEP. Western blotting mostrou uma redução das proteínas Nrf2, p62 e LC3II nas BEAS-2B siRNA, indicando que a exposição ao silenciamento de Nrf2 modificou a expressão de marcadores de autofagia (R < 1). Os resultados deste estudo mostram que, em células brônquicas expostas às DEP, o sistema Nrf2 e a autofagia trabalham em conjunto para tentar manter a homeostase celular / Diesel Exhaust Particles (DEPs) are main sources of daily inhaled particles, responsible for generating reactive oxygen species in the respiratory system, and causing the cells to activate defense mechanisms, such as the Keap1-Nrf2 system and autophagy. In order to investigate the role of Nrf2 in Dep-induced autophagy, BEAS-2B cells collected directly from a diesel engine were exposed to DEP and treated with sulforaphane, bafilomycin and BESS to test the relationship between autophagic and antioxidant pathways. The relative amount of mRNA was verified by RT-PCR for the following genes: Nrf2, NQO1, HO-1, p62, Atg5 and LCB3. Next, BEAS-2B cells were transfected with silencer RNA (siRNA) specific to Nrf2, exposed or not to DEPs (10 and 50 micro g/mL 1h and 2hs), and mRNA detected by RT-PCR and Western blotting for protein. Bafilomycin ( autophagy inhibitor) showed a significant decrease in the antioxidant markers Nrf2 (p=0.024), HO-1 (p = 0.002) and NQO1 (p = 0.003), whereas sulforaphane (Nrf2 activator) increased the expression levels of autophagic markers LC3B (p=0.004) and Atg5 (p=0.007). BEAS-2B exposed to DEP at a concentration of 50 micro g/mL for 2hs showed a significant increase in autophagic genes LC3B (p=0.018) and p62 (p=0.007),and in the antioxidant pathway markers Nrf2 (p=0.007) and NQO1 (p=0.025). There was a significant decrease in mRNA of the LC3B (p < 0.001), p62 (p=0.001) and Atg5 (p=0.024) in cells transfected with siRNA, exposed or not to DEP. Western blotting showed a reduction of Nrf2, p62 and LC3II proteins in BEAS-2B transfected with siRNA, indicating that Nrf2 silencedexposed to DEP modulated the expression of autophagy markers (R < 1). The results of this study show that, in bronchial cells exposed to DEP, the Nrf2 system and autophagy work together in order to try to maintain cellular homeostasis

Autofagia

Brônquios

Elementos de resposta antioxidante

Estresse oxidativo

Fator 2 relacionado a NF-E2

Particulado de diesel

Poluição ambiental

Antioxidant response elements

Autophagy

Bronchi

Environmental pollution

NF-E2-related factor 2

Oxidative stress

Particulate of diesel

Rôle de la protéine immuno-régulatrice PD-L1 sur le métabolisme des cellules tumorales / PD-L1 immunoregulatory protein impact on cancer cells metabolic reprogramming

Berthe, Julie

07 September 2018

Lorsque les cellules normales évoluent vers un état néoplasique, elles acquièrent de nombreuses caractéristiques. Par exemple, ces cellules exhibent des voies métaboliques anormales et possèdent la capacité d’échapper à la destruction par les cellules de l’immunité, notamment en exploitant des points de contrôles immunitaires ou « immune checkpoints ». La molécule PD-L1 (Programmed Death-Ligand 1) appartient à la famille de protéines immuno-régulatrices B7 et a tout d’abord été décrite comme impliquée dans l’immuno-échappement tumoral suite à son interaction avec PD-1, récepteur exprimé à la surface des lymphocytes T. Associée à un mauvais pronostic, une expression aberrante de PD-L1 est retrouvée dans les hémopathies malignes ainsi que dans de multiples tumeurs solides. De manière intéressante, il a été montré que PD-L1 possède également des fonctions pro-tumorales intrinsèques. En effet, cette protéine joue un rôle dans la prolifération des cellules cancéreuses et leur résistance aux chimiothérapies, sans interagir avec PD-1. Toutefois, les mécanismes moléculaires modulés par PD-L1 et impliqués dans ces fonctions sont encore inconnus. Des voies métaboliques anormales ont été décrites comme pouvant contribuer à la croissance tumorale et la résistance aux thérapies. Ainsi, les objectifs de ma thèse ont été d’explorer le potentiel rôle de la protéine PD-L1 dans le métabolisme des cellules tumorales. En utilisant la méthode d’édition du génome avec les Zinc Finger Nucleases, nous avons invalidé le gène CD274 codant la protéine PD-L1 dans les cellules cancéreuses de sein MDA-MB-231 et investigué les fonctions métaboliques de cette molécule après surexpression dans ces mêmes cellules. Nous avons observé que PD-L1 induit un shift de la phosphorylation oxydative vers la glycolyse, correspondant à l’effet Warburg. Afin de valider cette reprogrammation métabolique, nous avons analysé le profil métabolique de ces cellules et mis en évidence une élévation des niveaux des intermédiaires de la glycolyse tels que le F-6-P, le F-1,6-P, le GAP, le DHAP, le PEP et le pyruvate dans la lignée surexprimant PD-L1, confirmant nos précédents résultats. D’autre part, et en accord avec nos observations quant à une augmentation de la production de ROS (Reactive Oxygen Species), nos données transcriptomiques suggèrent une répression de la voie de réponse au stress oxydatif NRF2 suite à l’expression de PD-L1 et notamment de ses gènes cibles tels que NQO2, GSTM3 et ABCC2. En outre, l’analyse in silico de bases de données de cohortes de patients atteints de cancer du sein a révélé une corrélation entre l’expression du gène PD-L1/CD274 et l’expression des gènes de la voie du stress oxydant (GSTM3 ; CYBB) ou des gènes codant les transporteurs de glucose (SLC2A1/GLUT1 ; SLC2A3/GLUT3), ces données supportant nos résultats obtenus in vitro. Par ailleurs, le glucose étant principalement utilisé par les cellules cancéreuses pour favoriser la biosynthèse de diverses biomolécules nécessaires à la prolifération cellulaire, ces résultats pourraient expliquer la tumorigénicité augmentée dans la lignée surexprimant PD-L1 lors des expériences de xénogreffe de cellules de cancer du sein humain chez des souris Nude. Ainsi, les travaux présentés dans cette thèse mettent en évidence de nouvelles fonctions intrinsèques de PD-L1 promouvant le développement tumoral, suggérant l’utilisation d’agents thérapeutiques inhibant ces mécanismes seraient prometteurs pour le traitement du cancer du sein. / Evolving to a neoplastic state, normal cells acquire many characteristics; indeed, tumor cells follow abnormal metabolic pathways and exhibit the ability to avoid immune destruction, partly by exploiting immune checkpoints. Many of these are currently under clinical investigation for new cancer treatments, notably the PD-1/PD-L1 axis.Programmed Death-Ligand 1 (PD-L1) molecule belongs to the B7 immunoregulatory proteins family and was originally described as mediating tumor immuno-escape through interaction with its receptor PD-1 on T cells. Associated with poor cancer outcome, aberrant PD-L1 expression has been observed in hematologic malignancies and in multiple solid tumor types. Actually, this protein has been shown to regulate tumor cell proliferation and resistance to chemotherapy through apoptosis inhibition, without interacting with PD-1. However, cellular mechanisms modulated by PD-L1 and involved in these functions are still unclear. Abnormal metabolic pathways are known for contributing to tumor growth and therapy resistance; therefore, the objective of my PhD thesis was to investigate the impact of PD-L1 in breast cancer cell metabolic reprogramming.Using genome editing, we knocked-out the CD274 gene encoding PD-L1 in breast cancer cell line MDA-MB-231 and investigated metabolic functions after PD-L1 overexpression in the same cells. We observed that PD-L1 induces a shift from oxidative phosphorylation to glycolysis, indicating this molecule promotes the Warburg effect in these tumor cells. To validate PD-L1 metabolic reprogramming, we performed metabolomic profiling that highlighted significantly increased levels of glycolysis intermediated such as F6P, F1,6P, GAP, DHAP, PEP and pyruvate in PD-L1-expressing cells, confirming our latter results. Moreover, in agreement with an increasing mitochondrial reactive oxygen species (ROS) production, transcriptomic study suggested that PD-L1 represses NRF2-mediated oxidative stress response pathway, especially NQO2, GSTM3 and ABCC2 genes. Furthermore, in silico analysis of breast cancer patients databases highlighted a correlation between PD-L1/CD274 gene and oxidative stress gene signature (GSTM3; CYBB) or glucose transporters genes (SLC2A1; SLC2A3) expressions, supporting our results. Besides, glucose is mostly used by cancer cells to favor biosynthesis of diverse biomolecules required for cellular proliferation; the above results could explain our human breast cancer cells xenograft experiments in Nude mice demonstrating that PD-L1 increases tumoreginicity.Thus, the work presented in this thesis evidences novel PD-L1 intrinsic tumor-promoting functions, suggesting that therapeutic agents inhibiting these mechanisms would be promising for breast cancer treatment.

Antigène CD274

Métabolisme

Tumeurs

Cancer

Stress oxydatif

Facteur-2 apparenté à NF-E2

NRF2-mediated oxidative stress

Metabolism

Cancer

Oxidative stress

Nrf2/p-Fyn/ABCB1 axis accompanied by p-Fyn nuclear accumulation plays pivotal roles in vinorelbine resistance in non-small cell lung cancer / 非小細胞肺癌のビノレルビン耐性におけるNrf2/p-Fyn/ABCB1と核内p-Fynの意義

Tamari, Shigeyuki

23 March 2023

京都大学 / 新制・課程博士 / 博士(医学) / 甲第24508号 / 医博第4950号 / 新制||医||1064(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 平井 豊博, 教授 武藤 学, 教授 中島 貴子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

non-small cell lung cancer

vinorelbine resistance

phosphorylated Fyn

ABC subfamily B member 1

NF-E2-related factor 2

490

Étude de la collaboration entre les facteurs de transcription hématopoïétiques lors du développement et de la différenciation des cellules érythroïdes

Ross, Julie

11 1900

La régulation transcriptionnelle des gènes est cruciale pour permettre le bon fonctionnement des cellules. Afin que les cellules puissent accomplir leurs fonctions, les gènes doivent être exprimés adéquatement dans le bon type cellulaire et au stade de développement et de différenciation approprié. Un dérèglement dans l’expression de un ou plusieurs gènes peut entraîner de graves conséquences sur le destin de la cellule. Divers éléments en cis (ex : promoteurs et enhancers) et en trans (machinerie transcriptionnelle et facteurs de transcription) sont impliqués dans la régulation de la transcription. Les gènes du locus humain beta-globine (hub) sont exprimés dans les cellules érythroïdes et sont finenement régulés lors du développement et de la différenciation. Des mutations dans différentes régions du locus causent entre autres les beta-thalassémies. Nous avons utilisé ce modèle bien caractérisé afin d’étudier différents mécanismes de régulation favorisés par les facteurs de transcription qui sont exprimés dans les cellules érythroïdes. Nous nous sommes intéressés à l’importance de l’élément en cis HS2 du Locus control region. Cet élément possède plusieurs sites de liaison pour des facteurs de transcription impliqués dans la régulation des gènes du locus hub. Nos résultats montrent que HS2 possède un rôle dans l’organisation de la chromatine du locus qui peut être dissocié de son rôle d’enhancer. De plus, HS2 n’est pas essentiel pour l’expression à haut niveau du gène beta alors qu’il est important pour l’expression des gènes gamma. Ceci suggère que le recrutement des différents facteurs au site HS2 lors du développement influence différement les gènes du locus. Dans un deuxième temps, nous avons investigué l’importance de HS2 lors de la différenciation des cellules érythroïdes. Il avait été rapporté que l’absence de HS2 influence grandement la potentialisation de la chromatine du gène beta. La potentialisation dans les cellules progénitrices favorise l’activation transcriptionnelle du gène dans les cellules matures. Nous avons caractérisé le recrutement de différents facteurs de transcription au site HS2 et au promoteur beta dans les cellules progénitrices hématopoïétiques (CPH) ainsi que dans les cellules érythroïdes matures. Nos résultats montrent que le facteur EKLF est impliqué dans la potentialisation de la chromatine et favorise le recrutement des facteurs BRG1, p45 et CBP dans les CPH. L’expression de GATA-1 dans les cellules érythroïdes matures permet le recrutement de GATA-1 au locus hub dans ces cellules. Ces données suggèrent que la combinaison de EKLF et GATA-1 est requise pour permettre une activation maximale du gène beta dans les cellules érythroïdes matures. Un autre facteur impliqué dans la régulation du locus hub est Ikaros. Nous avons étudié son recrutement au locus hub et avons observé que Ikaros est impliqué dans la répression des gènes gamma. Nos résultats montrent aussi que GATA-1 est impliqué dans la répression de ces gènes et qu’il interagit avec Ikaros. Ensemble, Ikaros et GATA-1 favorisent la formation d’un complexe de répression aux promoteurs gamma. Cette étude nous a aussi permis d’observer que Ikaros et GATA-1 sont impliqués dans la répression du gène Gata2. De façon intéressante, nous avons caractérisé le mécanisme de répression du gène Hes1 (un gène cible de la voie Notch) lors de la différenciation érythroïde. Similairement à ce qui a été observé pour les gènes gamma, Hes1 est aussi réprimé par Ikaros et GATA-1. Ces résultats suggèrent donc que la combinaison de Ikaros et GATA-1 est associée à la répression de plusieurs de gènes dans les cellules érythroïdes. Globalement cette thèse rapporte de nouveaux mécanismes d’action de différents facteurs de transcription dans les cellules érythroïdes. Particulièrement, nos travaux ont permis de proposer un modèle pour la régulation des gènes du locus hub lors du développement et de la différenciation. De plus, nous rapportons pour la première fois l’importance de la collaboration entre les facteurs Ikaros et GATA-1 dans la régulation transcriptionnelle de gènes dans les cellules érythroïdes. Des mutations associées à certains des facteurs étudiés ont été rapportées dans des cas de beta-thalassémies ainsi que de leucémies. Nos travaux serviront donc à avoir une meilleure compréhension des mécanismes d’action de ces facteurs afin de potentiellement pouvoir les utiliser comme cibles thérapeutiques. / Gene transcriptional regulation is crucial for appropriate cell functioning. Genes must be properly expressed in the right cell type as well as at the right developmental and differenciation stage in order to allow the cells to accomplish their functions. Abnormal expression of one or many genes can dramatically influence cell fate. Diverse cis (ex : promoters and enhancers) and trans (transcriptional machinery and transcription factors) elements are involved in transcriptional regulation. Genes of the human beta-globin (hub) locus are expressed in erythroid cells and are thightly regulated during development and differentiation. Mutations in several regions of the locus are involved in beta-thalassemia. We used this well characterized model in order to study different regulation mechanisms that are mediated by transcription factors expressed in erythroid cells. We were interested in the important role of the cis element HS2 from the Locus control region. This region contains several binding sites for transcription factors that are involved in hub locus gene regulation. Our results show that HS2 has a role in chromatin organization of the locus which is distinct from its enhancer function. Moreover, HS2 is not essential for high level beta gene expression while it is important for gamma gene expression. This suggest that the influence of transcription factors recruited to HS2 varies during development. Secondly, we investigated HS2 importance during erythroid differentiation. It was reported the HS2 deletion strongly influences chromatin potentiation of beta gene. Potentiation in progenitor cells favors gene transcriptional activation in mature cells. We characterized transcription factor recruitment to HS2 and b promoter in hematopoietic progenitor cells (HPC). Our results show that EKLF is involved in chromatin potentiation and favors the recruitment of BRG1, p45 and CBP in HPC. GATA-1 expression in mature erythroid cells allows GATA-1 recruitment to hub locus in these cells. These data suggest that EKLF and GATA-1 combination is required to allow maximal beta gene activation in mature erythroid cells. Another factor involved in hub locus regulation is Ikaros. We studied its recruitment to hub locus and found that Ikaros is involved in gamma gene repression. Our data also shows that GATA-1 is involved in the repression of these genes and that it interacts with Ikaros. Together, Ikaros and GATA-1 favors the formation of a repressive complex to gamma promoters. In this study, we also observed that Ikaros and GATA-1 are involved in Gata2 gene repression. Interestingly, we have also characterized the repression mechanism of Hes1 gene (a Notch target gene) during erythroid differentiation. Similar to what is observed for gamma genes, Hes1 is also repressed by Ikaros and GATA-1. Collectivelly, our data suggest that Ikaros and GATA-1 combination is associated with the repression of several genes in erythroid cells. Globally, this thesis reports new mechanisms of action for different transcription factors in erythroid cells. Particularly, our work allows us to propose a model for hub locus gene regulation during development and differentiation. Moreover, we show for the first time that the combination of Ikaros and GATA-1 is relevant for gene regulation in erythroid cells. Several mutations in the transcription factors that we studied were associated with beta-thalassemia or leukemia. Our work will thus help to better understand mechanisms of action of these transcription factors in order to potentially use them as therapeutical targets.

Beta-globine

Facteurs de transcription

Chromatine

Cellules érythroïdes

Hes1

GATA-1

EKLF

NF-E2

Ikaros

Beta-globin

Transcription factors

Chromatin

Erythroid cells

Efeitos do sulforafano em parâmetros de estresse oxidativo em cultura de cardiomiócitos adultos

Corssac, Giana Blume

January 2017

O sulforafano (SFN) é um composto natural que possui propriedades antioxidantes, estimulando, principalmente, o sistema antioxidante endógeno celular. Este composto está associado a uma via clássica de ativação, a via do fator eritroide nuclear tipo 2 (Nrf2). Entretanto, estudos mais recentes têm demonstrado que a ação do SFN também pode se dar pela via do coativador 1-alfa do receptor ativado por proliferador do peroxissoma (PGC-1α). A diferença da via de ativação pelo SFN parece ter relação com o tempo de exposição das células a este composto. Visto que o SFN é uma importante estratégia terapêutica no combate ao estresse oxidativo, que está relacionado ao desenvolvimento de diversas doenças cardiovasculares, a investigação do seu mecanismo de ação é necessária. A análise in vitro é uma ferramenta importante para a investigação das vias e tempos de incubação envolvidos na ação antioxidante do SFN. Sendo assim, a cultura primária de cardiomiócitos de ratos adultos é um dos modelos que pode ser utilizado, sendo a sua principal vantagem, o fato da fisiologia destas células se aproximar mais das condições fisiológicas in vivo. O objetivo deste estudo, então, foi analisar a estimulação de defesas antioxidantes feita pelo SFN, através das vias do Nrf2 e do PGC-1α, em tempos diferentes, utilizando a técnica de cultura de cardiomiócitos adultos. Ratos Wistar machos foram eutanasiados, para que seus corações fossem retirados e submetidos ao processo de isolamento de células cardíacas, em aparelho de Langendorff modificado. As células foram isoladas através da perfusão do coração com solução de Krebs e colagenase tipo II, por um período de 30 minutos. Após isso, as células isoladas foram plaqueadas e mantidas em incubadora a 37°C e 5% de CO2. Foi realizado o tratamento com 5 μM de SFN e/ou 5 μM de peróxido de hidrogênio (H2O2). As células foram divididas nos seguintes grupos experimentais: Controle, SFN, H2O2 e SFN+H2O2. Os grupos foram subdivididos em dois tempos de incubação: 1 e 24 horas. Foram realizadas as análises dos níveis totais de espécies reativas de oxigênio (ROS) e de lipoperoxidação (LPO); atividade das enzimas antioxidantes superóxido dismutase (SOD), catalase (CAT) e glutationa s-transferase (GST); expressão proteica das isoformas citosólica (SOD-1) e mitocondrial (SOD-2) da SOD, e dos fatores Nrf2 e PGC-1α. Os resultados do trabalho mostram que, em relação ao tempo de 1 hora, o SFN incubado por 24 horas aumentou em 59% a atividade da SOD, 55% a expressão proteica da SOD-1, 24% a expressão proteica da SOD-2 e 69% a expressão proteica do PGC-1α. A expressão do Nrf2 foi 17% maior no tempo de 1 hora, em relação a 24 horas. Em relação à atividade da catalase e aos níveis de ROS e de LPO, houve diferença somente nos grupos incubados por 1 hora, nos quais a atividade da CAT foi menor no grupo H2O2, os níveis de ROS estavam diminuídos no grupo SFN, e os níveis de LPO estavam maiores no grupo H2O2. Não foram encontradas diferenças em relação à atividade da GST. Como conclusão, o SFN demonstrou um papel protetor nos grupos 1 hora, impedindo a geração de ROS e de dano a lipídeos, apesar de não apresentar um efeito expressivo sobre as enzimas antioxidantes. O efeito dos tempos de incubação na expressão do Nrf2 (aumentada em 1 hora) e do PGC-1α (aumentada em 24 horas) mostrou que realmente há uma relação temporal entre a sinalização destas duas vias, ativadas pelo SFN. Este resultado é instigante para que futuras análises dessa relação temporal das vias do SFN sejam realizadas. / Sulforaphane (SFN) is a natural compound that has antioxidant properties, mainly stimulating the endogenous cellular antioxidant system. This compound is associated with a classical pathway of activation, the nuclear erythroid factor 2 (Nrf2) pathway. However, more recent studies have shown that the action of SFN can also occur through the peroxisome proliferator-activated receptor coactivator 1-alpha (PGC-1α). The difference in the pathway of activation by SFN seems to be related to the time of exposure of the cells to this compound. Since SFN is an important therapeutic strategy in the fight against oxidative stress, which is related to the development of various cardiovascular diseases, the investigation of its mechanism of action is necessary. In vitro analysis is an important tool for investigating the pathways and incubation times involved in the antioxidant action of SFN. Thus, a primary culture of adult mouse cardiomyocytes is one of the models that can be used, the main advantage being that the physiology of these cells are closer to the physiological conditions in vivo. The objective of this study was to use adult cardiomyocyte culture technique to analyze the stimulation of antioxidant defenses by SFN through Nrf2 and PGC-1α pathways at different times. Male Wistar rats were euthanized, so that their hearts were removed and submitted to the process of isolation of cardiac cells, in modified Langendorff apparatus. Cells were isolated by perfusion of the heart with Krebs solution and type II collagenase for a period of 30 minutes. After that, the isolated cells were plated and incubated at 37°C and 5% CO2. Treatment was performed with 5μM SFN and/or 5μM hydrogen peroxide (H2O2). Cells were divided into the following experimental groups: Control, SFN, H2O2 and SFN+H2O2. The groups were subdivided into two incubation times: 1 and 24 hours. Analyzes of total oxygen reactive species (ROS) and lipoperoxidation (LPO) levels were performed; activity of antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and glutathione s-transferase (GST); protein expression of citosolic (SOD-1) and mitochondrial (SOD-2) isoforms of SOD, as well as Nrf2 and PGC-1α factors. The results of this work show that, compared to 1 hour time, SFN incubated for 24 hours increased SOD activity by 59%, SOD-1 protein expression by 55%, SOD-2 protein expression by 24%, and 69% PGC-1α protein expression. Expression of Nrf2 was 17% higher at 1 hour, over 24 hours of incubation. Regarding catalase activity and ROS and LPO levels, there were differences only in the groups incubated for 1 hour, in which the CAT activity was lower in H2O2 group, the ROS levels were decreased in SFN group, and levels of LPO were higher in H2O2 group. No differences were found in relation to GST activity. In summary, SFN demonstrated a protective role in 1 hour groups, preventing generation of ROS and lipid damage, although it does not present an expressive effect on the expression of antioxidant enzymes. The effect of incubation times on expression of Nrf2 (increased by 1 hour) and PGC-1α (increased by 24 hours) showed that there is actually a temporal relationship between the signaling of these two pathways, activated by SFN. This result is instigating for future analyzes of this temporal relationship of SFN pathways to be performed.

Estresse oxidativo

Miócitos cardíacos

Compostos fitoquímicos

Fator 2 relacionado a NF-E2

Sequência rica em GC

Primary culture

Oxidative stress

PGC-1α

Nrf2

Sulforaphane

Adult cardiomyocyte