Role of gas molecules in the mitochondrial transport of erythroid-specific 5-aminolevulinate synthase (ALAS2) /

Al-Ansari, Ahmed M. H.,

January 1900

Thesis (M.Sc.) - Carleton University, 2007. / Includes bibliographical references (p. 84-89). Also available in electronic format on the Internet.

Eritropoietina e dexametasona em Danio rerio durante aerocistite induzida por Aeromonas hydrophila / Eritropoetine and dexamethasone in Danio rerio during aerocistities induced by Aeromonas hydrophila

Gagliardi, Patrícia Canossa [UNESP]

28 April 2017

Submitted by PATRÍCIA CANOSSA GAGLIARDI null (p.canossa@hotmail.com) on 2017-06-08T17:20:30Z No. of bitstreams: 1 Diss_Mest_PCG.pdf: 2551839 bytes, checksum: ae03233945fd3b7993bb5baed2aac057 (MD5) / Approved for entry into archive by Luiz Galeffi (luizgaleffi@gmail.com) on 2017-06-13T13:35:52Z (GMT) No. of bitstreams: 1 gagliardi_pc_me_jabo.pdf: 2551839 bytes, checksum: ae03233945fd3b7993bb5baed2aac057 (MD5) / Made available in DSpace on 2017-06-13T13:35:52Z (GMT). No. of bitstreams: 1 gagliardi_pc_me_jabo.pdf: 2551839 bytes, checksum: ae03233945fd3b7993bb5baed2aac057 (MD5) Previous issue date: 2017-04-28 / O zebrafish representa um importante candidato, apresentando alta homologia genética com seres humanos e respostas, porém, são poucas as informações sobre seus mecanismos eritropoiéticos frente ao e leucopoiéticos. Assim o presente estudo buscou investigar o efeito da administração exógena de eritropoietina e da dexametasona sobre a resposta hematopoiética e leucocitária durante estímulo inflamatório através da indução de aerocistite infecciosa. Para isto, realizou-se indução de aerosciste através de inóculo de A. hydrophila, seguida da aplicação por via subcutânea de dexametasona (DEX) na dose de 25µg por unidade animal e 2UI de eritropoietina recombinante humana (EPO), constituindo os seguintes tratamentos: CC+ = não tratada com EPO e não tratado com DEX (n=10); DEX+= não tratada com EPO e tratada com DEX (n=10); EPO+ = tratada com EPO e não tratada com DEX (n=10); EPO/DEX+= tratada com EPO e tratada com DEX (n=10) e PF= (padrão fisiológico) onde os animais não receberam nenhuma medicação e não foi induzido a aeroscistite (n=10). para posterior coleta sanguínea e do exsudato inflamatório da bexiga natatória no período de 2 e 4 dias após inoculação (2DPI e 4DPI) e contagem eritrocitária total, contagem de reticulócitos, leucocitária total, diferencial leucocitário e contagem total e diferencial celular do exsudato da bexiga natatória. Na análise dos dados obtidos, observou-se um aumento geral dos parâmetros eritrocitários e de reticulócitos nos grupos EPO+ e DEX+, bem como leucocitários no grupo EPO+, o que indica possível resposta eritropoiética e leucopoiética positiva proveniente do uso da EPO. Na análise leucocitária foi possível observar também significante redução de valor total, granulócitos, monócitos e linfócitos nos grupos de tratamento com uso de DEX, indicando um presente efeito imunossupressor derivado do uso do glicocorticoide na espécie, demonstrando efeitos similares à mamíferos da EPO e da DEX. / Zebrafish represents an important candidate, presenting high genetic homology with humans and answers, however, there is little information about its erythropoietic mechanisms against leukopoietic. Thus the present study sought to investigate the effect of exogenous administration of erythropoietin and dexamethasone on the hematopoietic and leukocyte response during inflammatory stimulation through the induction of infectious aerocystitis. For this, an aerosol induction was performed through A. hydrophila inoculum, followed by subcutaneous application of dexamethasone (DEX) at the dose of 25 μg per animal and 2UI of recombinant human erythropoietin (EPO), constituting the following treatments: CC + = untreated with EPO and not treated with DEX (n = 10); DEX + = untreated with EPO and treated with DEX (n = 10); EPO + = treated with EPO and not treated with DEX (n = 10); EPO / DEX + treated with EPO and treated with DEX (n = 10) E And PF = (physiological standard) where the animals received no medication and were not induced to aerosctitis (n = 10), for subsequent blood collection and inflammatory exudate of the swimming bladder at 2 and 4 days after inoculation (2DPI and 4DPI) and total erythrocyte count, reticulocyte count , Total leukocytes, differential leukocytes, and total and differential cell count of the swim bladder exudate. In the analysis of the obtained data, a general increase of erythrocyte and reticulocyte parameters in the EPO + and DEX + groups was observed, as well as leukocytes in the EPO + group, indicating a positive erythropoietic and leukopoietic response from EPO use. In the leukocyte analysis, it was also possible to observe a significant reduction of total value, granulocytes, monocytes and lymphocytes in the treatment groups with DEX, indicating a present immunosuppressive effect derived from glucocorticoid use in the species, demonstrating similar effects to the EPO and DEX mammals.

Leucopoiese

Danio rerio

Inflamação

Dexametasona

Stress

Erythropoiesis

Inflammation

Dexamethasone

Proteomic Characterization of Hemogen in Erythropoiesis

Somasundaram, Brinda

January 2012

Hemogen (Hemgn) is reported as a tissue specific transcriptional regulator in testis as well as hematopoietic tissues. It is known that Hemgn positively regulates erythroid differentiation; however,the underlying molecular mechanism is not well understood. In the current study, using proteomic approach in combination with other molecular biology tools,we have attempted to decipher the role of Hemgn in differentiating Murine erythroblast leukemia (MEL) cells as a model system. Our study reveals that Hemgn predominantly interacts with transcriptional regulators, chromatin modifiers and histones. Furthermore, using Chromatin Immunoprecipitation and knockdown approach, we have demonstrated that Hemgn is recruited to the b-globin locus, which is known to be activated during erythroid differentiation. Based on the results,we speculate that Hemgn acts as a tissue specific histone chaperone that regulates transcription during erythroid differentiation.

Hemgn

Proteomic Characterization

erythropoiesis

transcription regulation

b-globin

Erythropoietin treatment in anaemic patients at the Nephrology Unit of the Steve Biko Academic Hospital - a retrospective, cross-sectional study

Kok, Elandre

January 2020

Anaemia in chronic kidney disease (CKD) mostly results from a decrease in the production of erythropoietin (EPO) by the failing kidney. CKD progression requires treatment with erythropoiesis-stimulating agents and iron supplementation to ensure sufficient erythrocyte production. Best clinical practice guidelines should be adhered to in managing CKD to reduce morbidity and mortality related to anaemia associated cardiovascular disease. Likewise, guideline deviations create an increased strain on the resources of the treatment facility. It is uncertain to which extent these guidelines are followed by Nephrology Units in the public healthcare sector, or whether the documented international trends are prevalent locally due to the paucity of local data, and therefore further investigation is warranted. This study aimed to assess treatment trends in managing anaemia in CKD patients at the Steve Biko Academic Hospital (SBAH). Files of patients receiving treatment at the SBAH Nephrology Unit between 2 January 2018 - 31 August 2018 were reviewed. Only individuals with stage 5 CKD receiving either haemodialysis, or peritoneal dialysis were included, while those with less than three months’ treatment were excluded. Measured variables included demographical information, current EPO treatment and/or iron supplementation regimens versus serum haemoglobin/iron levels and quantity of administered blood products. Ninety-seven patients met the inclusion criteria. Haemodialysis accounted for 43% (n = 42), and peritoneal dialysis 57% (n = 55). Intergroup comparison between the number of results where both haemoglobin and iron were within the target range versus the number of results where both parameters fell outside the target range yielded a significant difference (p = 0.0031). Patients receiving peritoneal dialysis reached serum haemoglobin and iron levels closer to normal target values compared to those receiving haemodialysis. Managing anaemia in CKD is a complex process. More stringent iron control, especially for patients receiving haemodialysis, including the administration of long-acting EPO preparations once a month, is proposed. The latter will contribute to the improvement of clinical outcomes of patients with CKD. Keywords: Chronic kidney disease, anaemia, erythropoiesis stimulating agent, haemoglobin, iron / Dissertation (MSc (Pharmacology))--University of Pretoria, 2020. / Pharmacology / MSc (Pharmacology) / Unrestricted

Anaemia

Chronic kidney disease

Erythropoiesis stimulating agent

Haemoglobin

Iron

UCTD

Erythropoietin, erythropoiesis, and malarial anemia : the mechanisms and implications of insufficient erythropoiesis during murine blood-stage malaria

Chang, Kai-Hsin, 1974-

January 2003

No description available.

Erythropoietin.

Plasmodium chabaudi

Erythropoiesis.

Anemia -- Pathogenesis.

The non-apoptotic role of caspase-3 activation and its modulation in erythroid differentiation of TF-1 cells. / CUHK electronic theses & dissertations collection

January 2006

Apart from CAD, the transient liberation of AIF during day 6 of TF-1 differentiation could pose another threat to the genomic DNA in cells. We have demonstrated the absence of AIF in the nucleus of TF-1 cells despite its release from the mitochondria by using confocal studies. Moreover, the expression of heat shock protein 70 kDa (Hsp70), a well-known antagonist of AIF, was found to be temporarily increased at day 6. Taken together, our results implied a plausible retention of AIF in the cytoplasm by Hsp70. Although Hsp70 is commonly utilized by many cancer cells to counteract AIF and avoid DNA fragmentation, we are the first to demonstrate its role in suppressing AIF during normal erythroid maturation. / As a whole, we have illustrated that the activated caspase-3, mediated most likely by the mitochondrial pathway, is an essential component in the differentiation of TF-1 cells. Its activation was nevertheless not coupled with DNA fragmentation due to some protective mechanisms such as CAD downregulation, Hsp70 upregulation and overexpression of Bcl-XL. Our study therefore provides some insights in the understanding of the relationship between human erythropoiesis and apoptosis and a better understanding in this regard will undoubtedly facilitate the development of new drugs in the treatment of different hematopoietic diseases. / Caspases play a central role in apoptosis. Their activations during the process are accounted for different biochemical and morphological changes in apoptotic cells. Yet in recent years, increasing studies had shown that caspases were also involved in some non-apoptotic cellular events, including T and B-lymphocytes activation, as well as the terminal differentiation of lens cells, megakaryocytes and erythrocytes. / In order to find out other unknown cellular mechanisms in erythropoiesis, mRNA differential display was employed to compare the gene expression pattern of TF-1 cells at different stages of differentiation. Several differentially expressed genes were identified and subsequently confirmed by RT PCR. These genes include formin binding protein 3, destrin and T-complex protein-1 (TCP-1). Their involvement in erythroid differentiation was still not clear at the moment but would be investigated in the near future. Furthermore, aiming at identifying the interacting proteins or inhibitors of caspase-3 in the system, a pull down assay was developed by means of the bacterial expression of a recombinant human caspase-3 mutant protein. With the mutation in the active site, the binding of our recombinant caspase-3 mutant with two known partners ICAD and BIRII (Baculovirus Inhibitor of apoptosis protein Repeat II) domain has been demonstrated. We hope in the near future that it can be employed to fish out some novel caspase-3 substrates from the differentiating TF-1 cell lysate. / In the present study, the participation of caspase in in vitro erythropoiesis was investigated using a human erythroleukemia cell line TF-1. Erythropoietin (EPO) induced erythroid maturation of TF-1 as indicated by the expression of erythroid-lineage markers like glycophorin A (GPA), transferrin receptors (CD71) and synthesis of hemoglobin (Hb). Activation of caspase-3 was observed from day 6 to day 12 during TF-1 differentiation after EPO treatment. With the administration of caspase-3 specific inhibitor, expressions of GPA and CD71 were partially blocked, suggesting that caspase-3 activation is essential in erythropoiesis in our TF-1 model. / Possible involvement of the intrinsic and extrinsic apoptotic pathways was studied by investigating respectively the activation of pro-caspase-9 and -8. It was found that caspase-9, but not -8, was activated at the corresponding time point when caspase-3 was activated. Besides, a transient mitochondrial depolarization coupled with the release of cytochrome c and apoptosis inducing factor (AIF) were detected on day 6, strongly implying a role of mitochondria in triggering the activation of executioner caspase-3. On the other hand, GPA and CD71 expressions were blocked by the application of mitochondrial depolarization inhibitor cyclosporin A (CyA). Also, the recovery of mitochondrial membrane potential was found to be correlated with an overexpression of Bcl-XL at a late stage of TF-1 differentiation, and the role of Bcl-XL was subsequently manifested further by a significant retardation of erythroid differentiation in the siRNA Bcl-XL knocked down TF-1 cells. / The exact role of caspase-3 in erythroid differentiation is far from clear at this moment. Yet, its regulation in the process is equally intriguing. On the course of TF-1 maturation, activated caspase-3 was able to cleave and de-localize the Inhibitor of Caspase-activated DNase (ICAD) from the nucleus, but at the same time DNA fragmentation was not detected by TUNEL assay nor agarose electrophoresis. Furthermore, protection against DNA fragmentation was observed in the EPO-treated TF-1 cells when challenged with a potent apoptotic inducer staurosporine (STS). These observations are in contrast to our understanding that DNA is fragmented by CAD (Caspase-activated DNase) when ICAD in the ICAD-CAD complex is cleaved by caspase-3. For these apparently contradictory observations, we demonstrated that downregulation of CAD occurred at the mRNA and protein levels during the erythroid differentiation in TF-1. This provides a cell rescuing mechanism in non-apoptotic cells with activated caspases. / Lui Chun Kin Julian. / "September 2006." / Adviser: Siu Kai Kong. / Source: Dissertation Abstracts International, Volume: 68-03, Section: B, page: 1620. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2006. / Includes bibliographical references (p. 239-253). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese. / School code: 1307.

Apoptosis--Physiology

Cysteine proteinases

Erythropoiesis

Erythropoietin--Physiological effect

Leukemia

Apoptosis--physiology

Caspase 3--physiology

Erythropoiesis

Erythropoietin--physiology

The Roles of Krüppel-like Transcription Factors KLF1 and KLF2 in Mouse Embryonic and Human Fetal Erythropoiesis

Vinjamur, Divya

28 April 2014

Hemoglobinopathies are some of the most common monogenic disorders in the world, affecting millions of people and representing a growing burden on health systems worldwide. Although the pathophysiology of sickle cell anemia and beta-thalassemia, two of the most common hemoglobinopathies, have been the focus of much research over the last century, patients affected by these diseases still lack a widely applicable and easily available cure. Sickle cell anemia and beta-thalassemia are caused by defects in the structure and production of the beta-globin chains that, along with the alpha-globin chains make up the heterotetrameric hemoglobin molecule. Studies geared towards re-expression of the silenced fetal gamma-globin gene in adult erythroid cells as a therapeutic strategy to alleviate the symptoms of beta-globin deficiencies have met with some success for the treatment of sickle cell anemia but not for beta-thalassemia. A better understanding of normal gamma-globin gene regulation will undoubtedly advance the development of more effective therapeutic strategies. Because many of the potential targets that may be modulated to achieve gamma-globin re-expression also have functions in erythroid cells other than regulating the gamma-globin gene, it is imperative to understand their role in all aspects of erythropoiesis before they are used for therapy. The current study focuses on the role of two Krüppel-like transcription factors, KLF1 and KLF2, which have known roles in the processes of primitive and definitive erythropoiesis as well as globin gene regulation. The regulation of primitive erythropoiesis by KLF1 and KLF2 is studied using the mouse as a model system because it is not possible to study primitive erythropoiesis in humans. Previous studies have shown that KLF1 and KLF2 are essential for and have overlapping roles in primitive erythropoiesis. Simultaneous ablation of KLF1 and KLF2 results in a severely anemic embryonic phenotype that is not evident in KLF1 or KLF2 single knockout embryos. In this study, we show that this anemia is caused by a paucity of blood cells, and exacerbated by diminished beta-like globin gene expression. The anemia phenotype is dose-dependent, and interestingly, can be ameliorated by a single copy of the KLF2, but not the KLF1 gene. The roles of KLF1 and KLF2 in maintaining both normal peripheral blood cell numbers and globin mRNA amounts are erythroid cell-specific. It was discovered that KLF2 has an essential function in erythroid precursor maintenance. KLF1 can partially compensate for KLF2 in this role, but is uniquely crucial for erythroid precursor proliferation, through its regulation of G1- to S-phase cell cycle transition. A more drastic impairment of primitive erythroid colony formation from embryonic progenitor cells occurs with simultaneous deficiency of KLF1 and KLF2, than with loss of a single factor. The regulation of human beta-like globin gene expression is studied using a recently developed in vitro system for the production of erythroid cells from umbilical cord blood hematopoietic precursor cells, representing a more “fetal” model of globin gene expression. Previous studies have shown that KLF1 binds to the promoters of the gamma- and beta-globin genes, while KLF2 binds to the promoter of the gamma-globin gene in cord blood-derived erythroid cells. Studies using transgenic mice carrying the entire human beta-globin locus had indicated that KLF1 and KLF2 positively regulate gamma-globin expression in mouse embryonic erythroid cells. We demonstrate in this study that KLF1 appears to have dual roles in the regulation of gamma-globin expression in human cord blood-derived definitive erythroid cells. Partial depletion of KLF1 causes elevated gamma-globin expression, while nearly complete depletion of KLF1 results in a down-regulation of gamma-globin expression. Of particular interest was the observation that KLF2 positively regulates gamma-globin expression in cord blood-derived erythroid cells. Surprisingly, KLF2 also positively regulates beta-globin expression in these cells. If regulation of gamma-globin by KLF2 proves to be a direct effect, KLF2 will join a very small group of factors known to directly activate gamma-globin expression.

KLF1

KLF2

Transcription factors

Globin gene regulation

Erythropoiesis

Medical Genetics

Medical Sciences

Medicine and Health Sciences

Étude de l’interaction Ikaros/voie de signalisation Notch au cours de l'érythropoïèse

Mavoungou, Lionel

09 1900

Tout au long de la vie d’un individu, il existe un nombre optimal de cellules à produire et de progéniteurs à conserver en réserve. On parle de maintien de l’homéostasie tissulaire. De façon générale, l’organisme a cinq possibilités pour réguler l’homéostasie : l’autorenouvellement et la quiescence, souvent utilisés pour maintenir un ‘pool’ fonctionnel de progéniteurs, la différenciation qui permet de produire des cellules effectrices, l’apoptose et la sénescence, qui permettent de limiter la production de cellules ou encore d’en faire diminuer le nombre quand elles sont en excès. La régulation de ces quatre mécanismes peut se faire de façon extrinsèque en passant par différentes voies de signalisation combinées à l’action intrinsèque de facteurs de transcription comme Ikaros et GATA1. Le facteur de transcription Ikaros joue un rôle critique dans le devenir des cellules progénitrices et la différenciation des lignages hématopoïétiques. Cependant, il demeure surtout connu pour son influence sur la voie Notch dans les cellules lymphoïdes, notamment les lymphocytes T. Les cellules érythroïdes sont hautement sensibles à l’environnement et donc, particulièrement adaptées à l’étude des régulations de l’homéostasie. Les résultats de différentes études ont permis de démontrer qu’Ikaros et la voie Notch influencent l’érythropoïèse. Cependant le détail de leurs actions demeure en grande partie inconnu à ce jour. Au cours de notre étude nous avons voulu déterminer l’action d’Ikaros dans le maintien de l’homéostasie des cellules érythroïdes et si son rôle passe par un dialogue avec la voie Notch. Nous avons voulu décrypter les mécanismes de régulation transcriptionnelle utilisés par Ikaros et par Notch au cours de l’érythropoïèse et leurs effets. Notre étude montre qu’Ikaros réprime à l’aide de GATA1 le gène Hes1, une cible importante de la voie Notch, en recrutant un complexe de la famille Polycomb, le PRC2 ii (Polycomb Repressive Complex 2). Cette répression permet la promotion de la différenciation des cellules érythroïdes. Au niveau du maintien de l’homéostasie par régulation de l’apoptose, Ikaros est connu pour cibler l’anti-apoptotique Bcl2l1 dans les lymphocytes. Puisque Gata-1, partenaire préférentiel d’Ikaros cible Bcl2l1 dans les cellules érythroïdes, nous avons caractérisé leur effet sur l’expression de Bcl2l1. Nous avons découvert qu’Ikaros active de façon directe Bcl2l1 et qu’il recrute sur le gène deux complexes partenaires d’élongation : un de la famille SET1/MLL, et le complexe P-TEFb-NuRD. En l’absence d’Ikaros, le fragment intracellulaire de Notch (NICD) et son cofacteur RBP-J remplacent Ikaros et favorisent l’hyper-activation de l’expression de Bcl2l1. Ceci est associé à la modification du complexe d’élongation recruté, ainsi qu’à la mise en place de modifications épigénétiques distinctes de celles observées avec Ikaros ce qui modifie l’élongation transcriptionnelle du gène. Ikaros et Notch sont fréquemment mutés ou présentent des fonctions altérées dans les leucémies. Notre étude montre un dialogue Ikaros/Notch influençant aussi bien la différenciation que l’apoptose et met en évidence l’existence d’un circuit génétique dont le dérèglement pourrait favoriser l’apparition d’une hématopoïèse maligne. / Throughout the life of an individual, there is an optimal count of cells to produce and progenitors to conserve in stock. This is the tissue homeostasis maintenance. In a general fashion the organism has five means to regulate the homeostasis. Self-renewal and quiescence, often used in order to maintain a functional progenitors pool. Differentiation enhances effector cells production. Apoptosis and senescence can limit cell production and reduce cell number in case of excess. These regulation mechanisms can be performed in an extrinsic fashion using different signaling pathways combined with the action of transcription factors like Ikaros and GATA1. The transcription factor Ikaros is critical for progenitor cells fate and hematopoietic lineages differentiation. However, Ikaros is mostly known for its influence on Notch signaling in lymphoid cells, notably T lymphocytes. Erythroid cells are highly sensitive to the environment thus, particularly adapted to study homeostasis maintenance regulation. Results obtained in different studies showed Ikaros and Notch signaling influencing erythropoiesis. However, the detail of their effect remains mainly unknown to day. Our aim was to determine Ikaros effect on erythroid cells homeostasis maintenance and if its role involved a cross-talk with Notch signaling. We will decipher transcription regulation mechanisms used by Ikaros and Notch during erythropoiesis and their effects. We show Ikaros uses GATA1 to repress Hes1, a major Notch target by recruiting a Polycomb family complex, the PRC2 (Polycomb Repressive Complex 2). This repression promotes erythroid cells differentiation. At the apoptosis mediated control of homeostasis level, Ikaros is known to target Bcl2l1 in lymphocytes. As GATA1, Ikaros preferential partner, targets Bcl2l1 in erythroid cells, we assessed their effect on Bcl2l1 expression. We discovered Ikaros directly activates Bcl2l1 iv and recruits two elongation associated complexes: one from SET1/MLL complex family, and the P-TEFb-NuRD complex. In the absence of Ikaros, the intracellular fragment of Notch (NICD) and its cofactor RBP-J replace Ikaros and favors Bcl2l1 overactivation. This is associated with a switch of recruited elongation associated complex and the establishment of distinct epigenetic modifications from those observed with Ikaros, which modifies the gene transcriptional elongation. Ikaros and Notch are frequently mutated or present altered functions in leukemia. Our works present an Ikaros/Notch cross-talk influencing as well differentiation as apoptosis and reveal the existence of a genetic circuit for which a malfunction could favor hematologic disorders. Keywords : transcription, homeostasis, erythropoiesis

transcription

homéostasie

érythropoïèse

Ikaros

Notch

épigénétique

homeostasis

erythropoiesis

epigenetics

Caractérisation fonctionnelle du facteur nucléaire RINF au cours de l’hématopoïèse normale et pathologique. / Functional Characterization of the Nuclear Factor RINF During Normal and Tumoral Hematopoiesis

Astori, Audrey

12 December 2014

L’hématopoïèse regroupe l'ensemble des mécanismes qui assurent le renouvellement continu et régulé des cellules sanguines, à partir des cellules souches hématopoïétiques. La différenciation des cellules souches en cellules matures est un phénomène finement orchestré par divers signaux (facteurs de croissance, hormones, cytokines et microenvironnement médullaire) capables de stimuler la prolifération de cellules quiescentes ainsi que leur engagement dans diverses voies de la maturation hématopoïétique. Ces processus sont généralement régulés via l’activation de facteurs de transcription, mais également par des mécanismes épigénétiques. Le gène RINF/CXXC5 a initialement été décrit comme essentiel pour les processus de différenciation granulocytaire normale. Toutefois, son implication dans d’autres voies de l’hématopoïèse n’avait pas été étudiée. Afin de définir son rôle dans la différenciation et l’engagement vers des lignages hématopoïétiques autres que la voie granulocytaire, notamment érythroïde et monocytaire, sa contribution fonctionnelle dans des lignées hématopoïétiques et dans des cellules primaires CD34+ de moelle osseuse (donneurs sains) a été étudiée par une approche de perte ou gain de fonction. Ces expériences, dans des modèles de la voie granulocytaire (lignée NB4 et HL60 traitées par les rétinoïdes) et de la voie érythroïde (lignées K562 et UT7/GM traitées par l’hémine ou l’EPO) démontrent l’implication de RINF dans la maturation terminale de ces deux lignages. Ces données ont ensuite été validées dans des progéniteurs hématopoïétiques (tests clonogéniques) où l’expression de RINF favorise la différenciation granuleuse et interfère négativement avec la différenciation érythroïde, sans impacter la voie monocytaire. En effet, l’extinction de son expression diminue le nombre des colonies granuleuses et augmente le nombre de colonies érythroïdes. Des dérégulations au niveau de l’expression des facteurs ou co-facteurs de trancription qui régulent l’hématopoïèse peuvent aboutir à des hémopathies, telles que les Leucémies Aiguës Myéloïdes. Ces pathologies sont la résultante de l’association d’une augmentation de la prolifération cellulaire et d’un blocage des processus de différenciation. Au vu de son rôle important au cours de la granulopoïèse et de l’érythropoïèse, l’hypothèse que des dérégulations de RINF pourraient intervenir dans les processus de leucémogenèse a été testée par l’étude de son niveau d’expression dans les différentes Leucémies Aiguës Myéloïdes. Ainsi, il a été démontré que parmi les patients dont le niveau d’expression de RINF est le plus élevé, le pronostic vital est mauvais, associé à une résistance aux traitements chimiothérapeutiques. L’ensemble de ces données a permis d’aboutir à la conclusion que des dérégulations de l’expression de RINF pourraient contribuer au processus de leucémogenèse, et qu’ainsi RINF pourrait être une potentielle cible thérapeutique dans le cadre des LAM. D’un point de vue moléculaire, le mode d’action de la protéine RINF reste à ce jour du domaine de l’hypothèse, mais la présence d’un doigt de zinc de type CXXC lui permettrait d’intervenir dans des mécanismes des régulations épigénétiques, tels que la méthylation de l’ADN. Une meilleure compréhension des mécanismes régulés par la protéine pourrait permettre à terme une meilleure compréhension des régulations de l’hématopoïèse, voire des processus de leucémogenèse. / During hematopoiesis, hematopoietic stem cells (HSC) differentiation is orchestred by different signals, able to stimulate cell proliferation of quiescent cells, and their commitment in the different hematopoietic lineages. These process are regulated by transcription factors activation, as well by epigenetic mecanisms. By a microarray approach, we have identified a novel retinoid-responsive gene (CXXC5) encoding a Retinoid-Inducible Nuclear Factor (RINF) that plays an essential role during in vitro human hematopoiesis. Indeed, expression studies and gene silencing experiments both demonstrate RINF requirement during in vitro terminal differentiation of myeloid leukemia cells (NB4, HL60), but also during normal myelopoiesis of bone marrow progenitors (CD34+ HSPC cells in presence of cytokines). In the present study, we demonstrate that in cell lines, RINF overexpression provokes an earlier myeloid differentiation under retinoids treatement and slow-downs erythroid maturation induced by hemin whereas its down-regulation accelerates erythroid terminal differentiation. In normal CD34+ HSCP, we demonstrated that RINF down regulation (1) promotes differentiation in erythroid lineage at the expense of granulocyte lineage, and (2) accelerates terminal erythroid differentiation. Overexpression, contribute to promote myeloid pathway even though cells are in erythroid conditions. Because of its role during hematopoiesis regulation and its gene localization in 5q31.2, we investigated CXXC5/RINF expression in primary human acute myeloid leukemia (AML) cells derived from 594 patients. A wide variation in CXXC5/RINF mRNA levels was observed in the immature leukemic myeloblasts. Furthermore, patients with low-risk cytogenetic abnormalities showed significantly lower levels compared to patients with high-risk abnormalities, and high RINF/CXXC5/ mRNA levels were associated with decreased overall survival for patients receiving intensive chemotherapy for newly diagnosed AML. CXXC5/RINF knockdown in AML cell lines caused increased susceptibility to chemotherapy-induced apoptosis, and regulation of apoptosis also seemed to differ between primary human AML cells with high and low RINF expression. The association with adverse prognosis together with the antiapoptotic effect of CXXC5/RINF suggests that targeting of CXXC5/RINF should be considered as a possible therapeutic strategy, especially in high-risk patients who show increased expression in AML cells compared with normal hematopoietic cells.

Granulopoïèse

RINF/CXXC5

Érythropoïèse

Leucémies Aiguës Myéloïdes

Granulopoiesis

RINF/CXXC5

Erythropoiesis

Acute Myeloid Leukemia

Molecular Basis of Erythroid Cell Proliferation and Differentiation / Les bases moléculaires de la prolifération et de la différentiation érythroide

Penglong, Tipparat

20 April 2015

Pour assurer la production de milliards de globules rouges, l’érythropoièse doit parfaitement contrôler les processus de prolifération et de différenciation. Ces deux processus sont régulés par l’expression de gènes spécifiques dépendant d’une coordination entre l’activité des facteurs de transcription (FT) et les fonctions épigénétiques portées par exemple par les protéines à bromodomaine. Cette étude se concentre sur les conséquences de l’association ou la dissociation du FT clef de l’érythropoièse GATA-1 avec les FT déterminant pour le cycle cellulaire, pRb et E2F. Dans la première partie de ma thèse, j’ai participé à l’étude du rôle de l’association/dissociation de GATA-1 et FOG-2 avec pRb/E2F dans le contrôle la balance prolifération/différenciation cellulaire. Nos résultats montrent que les souris exprimant une mutation de GATA-1 sur la sérine 310 (GATA-1S310A), qui a la capacité accrue à séquestrer E2F-2, présentent une anémie létale lorsqu’un mécanisme de compensation de production de E2F-2 induit par l’IGF-1 est inhibé. Puis, nous avons trouvé que les propriétés décrites pour GATA-1 sont partagées par le FT FOG-2 et montré que l’abrogation de sa fixation avec pRb induit une perturbation de l’adiposité dans des souris FOG-2pRb-. Dans la deuxième partie, l’expression de c-Myc étant régulé différentiellement par GATA-1 et E2F, j’ai testé si la drogue « JQ1 », premier inhibiteur épigenétique chimique de l’expression de c-Myc, pouvait contrôler l’érythropoièse. Pour cela, j’ai utilisé la ligné érythroleucémique UT7 qui prolifère sans se différencier en présence d’érythropoiétine (stade proérythroblaste). Les résultats montrent que le traitement par JQ1 bloque la prolifération des cellules UT7 et permet de réinitier le programme de différentiation érythroide terminale. J’ai alors recherché les mécanismes moléculaires impliqués dans cette régulation et trouvé que l’inhibition transcriptionnelle de c-Myc par JQ1 est associée à l’inhibition de l’activité transcriptionnelle de STAT5 sans modification de son état de phosphorylation. Enfin, j’ai montré que JQ1 pouvait avoir une activité comparable à celle du TGF-b mais sans implication les voies Smad. Des études in vivo montre que JQ1 augmente la viabilité cellulaire et accélère la maturation des cellules érythroides à la fois chez les souris sauvages et thalassémiques. Cette différence d’action de JQ1 sur l’érythropoièse normale et pathologique implique des modifications épigénétiques différentielles entre ces deux types cellulaires et sont à la base de nouvelles stratégies du traitement du cancer. Le rôle clef de la régulation de l’association/dissociation de GATA-1 ou FOG-2 avec pRb/E2F dans l’érythropoièse et l’adipogénèse, nous a conduit, dans une troisième partie, à déterminer in vivo, les conséquences physiologiques de la séquestration de E2F par pRb. Pour cela nous avons crée une souris transgénique exprimant de façon conditionnelle un peptide contenant la partie N terminale de GATA-1 qui se fixe à pRb (GATA-1Nter). In vitro, ce peptide séquestre E2F dans le complexe GATA-1Nter/pRb et inhibe la prolifération cellulaire de façon irréversible. In vivo, aucune souris transgéniques exprimant le peptide GATA-1Nter n’a pu être sélectionnée et une mortalité au stade embryonnaire est observée. Une expression induite de ce peptide au stade adulte ne produit que des souris chimériques avec une fréquence de recombinaison du transgène GATA-1Nter importante. L’établissement de lignées stables de souris exprimant le peptide GATA-1Nter permettra de déterminer les conséquences physiologiques de la séquestration de E2F dans le complexe GATA-1Nter/pRb. / To ensure the generation of billions of erythrocytes daily, erythropoiesis must be well controlled by proliferation and differentiation processes. These two processes are regulated by expressions of specific genes, coordinated by transcription factors (TFs) and epigenetic factors, such as bromodomain proteins. This study focused on the effects of the binding and dissociation of a key erythroid TF, GATA-1, to the crucial cell cycle TFs, pRb and E2F. In the first part of this thesis, the role of GATA-1 and FOG-2 binding to pRb/E2F in a control balances between cell proliferation and differentiation was studied. Mice bearing a GATA-1 mutation (GATA-1S310A) displayed higher levels of E2F2 sequestration and suffered from fatal anemia when the compensatory pathway of E2F2 production via IGF-1 signaling was also inhibited. The properties described for GATA-1 were found to be common to FOG-2, and the abolition of FOG-2 binding to pRb led to obesity resistance in FOG-2pRb- mice. In the second part of this work, as c-Myc is regulated by GATA-1 and E2F, the first chemical epigenetic inhibitor repressing c-Myc expression to be described, JQ1, was investigated to see if it could control erythropoiesis. The UT7 erythroleukemia cell line, which proliferates without differentiating was used. This cell line stops differentiation at the proerythroblast stage, in response to erythropoietin. JQ1 treatment inhibited UT7 proliferation and restored terminal erythroid differentiation. The molecular mechanism underlying this regulation by JQ1 was shown that the inhibition of c-Myc expression was associated with the inhibition of STAT5 transcription, with no change in the phosphorylation of this protein. It was found that JQ1 had a putative TGF--like activity, which did not involve the Smad pathway. It was shown in the ex vivo studies that JQ1 increased the viability of erythroid cells and accelerated the maturation of these cells in both WT and thalassemic mice. The observed differences between leukemic and normal erythropoiesis involved differential epigenetic modifications that could be at the basis of new strategies regarding cancer treatment.The key role of the association of GATA-1 or FOG-2 had with pRb/E2F, and the dissociation of these factors, in erythropoiesis and adipogenesis, respectively, led us to investigate, in vivo, the physiological consequences of E2F sequestration by pRb. As a result, transgenic mice displaying conditional expression of a peptide containing the N-terminal part of GATA-1 that binds to pRb (GATA-1Nter) were developed. In vitro, this peptide traps E2F in a GATA-1Nter/pRb complex, resulting in the irreversible inhibition of cell proliferation. The yield of transgenic mice expressing the GATA-1Nter peptide in vivo was unsuccessful, as this expression lead to lethality at the embryonic stage. Using an alternative approach, based on the inducible expression of the peptide in adults, chimeric mice with a high frequency of recombination of the GATA-1Nter transgene were obtained for this study. The establishment of a stable mouse line expressing the GATA-1Nter peptide should make it possible to determine the pathophysiological consequences of E2F sequestration in the GATA-1Nter/pRb complex.

Erythropoïèse

GATA-1

PRB

C-MYC

Bromodomaine

Erythropoiesis

GATA-1

PRB

C-MYC

Bromodomain