Identification et caractérisation des cibles transcriptionnelles de ETV6, un facteur de transcription impliqué dans la leucémie de l’enfant

La leucémie lymphoblastique aiguë (LLA) est responsable d’environ 25% de l’ensemble des cancers pédiatriques. Chez 85% des enfants diagnostiqués, la LLA entraîne une prolifération massive et incontrôlée de lymphocytes immatures de type précurseurs B dans la moelle osseuse (LLA pré-B). Des avancées intéressantes ont été faites au cours des trente dernières années et ont mené à une augmentation de l’efficacité des traitements thérapeutiques. Plus de 80% des enfants atteints de LLA seront guéris de cette maladie. Malheureusement, ces traitements manquent de spécificité à cause du manque de connaissances sur les mécanismes moléculaires impliqués durant l’initiation et le développement de la LLA pré-B pédiatrique. En d’autres termes, nous connaissons peu de chose sur l’étiologie de cette maladie. Plus de 25% des enfants atteints de la LLA pré-B présentent la translocation chromosomique t(12;21)(p13;q22) qui implique les gènes ETV6 et AML1. Celle-ci est formée in utero et mène à l’expression de la protéine chimère transcriptionnelle ETV6-AML1, dont la présence seule ne suffit pas au développement de la LLA pré-B. Ainsi, d’autres événements génétiques sont nécessaires au développement de cette leucémie. La délétion de l’allèle résiduel de ETV6 est un événement génétique fréquemment rencontré au moment du diagnostic de la LLA pré-B t(12;21)+. Cette délétion entraîne l’inactivation complète de ETV6 dans les lymphocytes pré-B leucémiques. ETV6 est un répresseur transcriptionnel de la famille Ets. Mon hypothèse de recherche est que ETV6 agit comme gène suppresseur de tumeur dans la LLA pré-B pédiatrique. L’inactivation de ETV6 causerait une dérégulation de l’expression de ses cibles transcriptionnelles et, par le fait même, favoriserait l’initiation et le déroulement de la leucémogenèse pédiatrique. Dans le cadre de mon projet, comme peu de cibles transcriptionnelles de ETV6 sont connues, j’ai effectué des expériences d’immunoprécipitation de la chromatine et des essais luciférases qui ont permis d’identifier six nouvelles cibles transcriptionnelles: TP53 (p53 et Δ133p53), SPHK1, IL-18, PTGER4 et LUM. J’ai démontré que la régulation transcriptionnelle médiée par ETV6 requiert la présence de ses deux domaines fonctionnels: PNT (interactions protéiques) et ETS (liaison à l’ADN). Ces domaines favorisent la reconnaissance d’un site EBS consensus dans une région située près du promoteur de base. Ce mécanisme peut dépendre du promoteur régulé par ETV6, mais également du contexte cellulaire. Des études fonctionnelles réalisées sur des lymphocytes pré-B leucémiques ont permis de mesurer l’impact de la dérégulation de l’expression des cibles transcriptionnelles de ETV6 sur trois voies biologiques: la prolifération cellulaire, l’apoptose induite par un stress génotoxique et la migration cellulaire dirigée par la voie de signalisation CXCL12/CXCR4. Ceci a permis de démontrer l’implication des gènes SPHK1, IL-18 et PTGER4 durant la leucémogenèse pédiatrique. Cette étude est une des premières à suggérer le rôle de ETV6 comme gène suppresseur de tumeur dans la LLA pré-B pédiatrique. Suite à l’inactivation du répresseur transcriptionnel ETV6, l’augmentation de l’expression de ses cibles transcriptionnelles favoriserait la prolifération et la survie des lymphocytes pré-B leucémiques dans la moelle osseuse. L’identification de nouveaux gènes impliqués dans le développement de la LLA pré-B pédiatrique ouvre la porte au développement de nouveaux traitements thérapeutiques qui pourront présenter une meilleure spécificité envers l’étiologie de la maladie.Acute lymphoblastic leukemia (ALL) accounts for approximately 25% of all paediatric cancers. Approximately 85% of ALL cases happen in immature B precursors lymphocytes (pre-B ALL). Pre-B ALL is a sporadic cancer that leads to the massive proliferation of leukemia pre-B lymphocytes in the bone marrow. During the past 30 years, the scientific community has developed efficient therapeutic treatments against paediatric ALL, reaching more than 80% cure rate. However, these treatments lack specificity because of the lack of knowledge regarding the molecular mechanisms involved in the initiation and progression of paediatric pre-B ALL. In other words, we know little about the aetiology of this disease. Approximately 25% of children affected with pre-B ALL carry the chromosomal translocation t(12;21)(p13;q22) involving the ETV6 and AML1 genes. This translocation originates in utero and leads to the expression of the transcriptional chimera ETV6-AML1, which alone is insufficient to trigger the development of pre-B ALL. Therefore, other genetic events would be required to initiate paediatric leukemogenesis. The deletion of the residual allele of ETV6 is frequently observed at the diagnosis of pre-B ALL t(12;21)+. This leads to the complete inactivation of ETV6 in leukemia pre-B lymphocytes. ETV6 is a transcriptional repressor of the Ets family. My research hypothesis is that ETV6 acts as a tumour suppressor gene in paediatric pre-B ALL. The inactivation of ETV6 would lead to the deregulated expression of its transcriptional targets and, consequently, would favour the initiation and progression of paediatric leukemogenesis. Given the fact that only very few ETV6 transcriptional targets are known, I initially performed chromatin immunoprecipitation experiments and luciferase assays that enabled the identification of six novel transcriptional targets: TP53 (p53 and Δ133p53), SPHK1, IL-18, PTGER4 and LUM. The ETV6-mediated transcriptional regulation involves both functional domains: PNT (protein interactions) and ETS (DNA-binding domain). These functional domains facilitate the recognition of consensus EBS sites located in a region close to the basal promoter, a molecular mechanism used according to the target promoter and cellular context. Functional studies using leukemia pre-B lymphocytes were useful to understand the role of the ETV6 transcriptional targets during cell proliferation, induction of apoptosis and cell migration through the CXC12/CXCR4 signalling pathway. These functional studies showed the implication of SPHK1, IL-18 and PTGER4 genes during paediatric leukemogenesis. This study is one of the first to support the role of ETV6 as a tumour suppressor gene in paediatric pre-B ALL. Once ETV6 is inactivated, the increased expression of its transcriptional targets favours the proliferation and survival of leukemia pre-B lymphocytes in the bone marrow. The identification of new genes involved in the development of paediatric pre-B ALL opens new doors to the development of therapeutic treatments with a better specificity toward the aetiology of the disease

Utah State University Youth Conservatory Spring Graduation

An event for all the participants in the Utah State University Youth Conservatory to perform piano pieces that they practiced and mastered in the months prior. The Utah State University Youth Conservatory accepts youth up to age 18 and provides them private lessons to develop their piano skills.https://digitalcommons.usu.edu/music_programs/1114/thumbnail.jp

Mll-AF4 Confers Enhanced Self-Renewal and Lymphoid Potential during a Restricted Window in Development.

MLL-AF4+ infant B cell acute lymphoblastic leukemia is characterized by an early onset and dismal survival. It initiates before birth, and very little is known about the early stages of the disease's development. Using a conditional Mll-AF4-expressing mouse model in which fusion expression is targeted to the earliest definitive hematopoietic cells generated in the mouse embryo, we demonstrate that Mll-AF4 imparts enhanced B lymphoid potential and increases repopulation and self-renewal capacity during a putative pre-leukemic state. This occurs between embryonic days 12 and 14 and manifests itself most strongly in the lymphoid-primed multipotent progenitor population, thus pointing to a window of opportunity and a potential cell of origin. However, this state alone is insufficient to generate disease, with the mice succumbing to B cell lymphomas only after a long latency. Future analysis of the molecular details of this pre-leukemic state will shed light on additional events required for progression to acute leukemia.Core facilities at the Cambridge Institute for Medical Research are supported by Strategic Award WT100140 and equipment grant 093026; core facilities at the Edinburgh MRC Centre for Regenerative Medicine are supported by centre grant MR/K017047/1. This work was funded by a Bloodwise Bennett Senior Fellowship (10015 to K.O.), a Wellcome Trust Clinical PhD Studentship (097454/z/11/z to N.A.B.) the Gabrielle’s Angel Foundation for Cancer Research (to K.O.), and the Kay Kendall Leukaemia Fund (to K.O.).This is the final version of the article. It first appeared from Cell Press/Elsevier at http://dx.doi.org/10.1016/j.celrep.2016.06.046

DNA damage signalling from the placenta to foetal blood as a potential mechanism for childhood leukaemia initiation

Abstract For many diseases with a foetal origin, the cause for the disease initiation remains unknown. Common childhood acute leukaemia is thought to be caused by two hits, the first in utero and the second in childhood in response to infection. The mechanism for the initial DNA damaging event are unknown. Here we have used in vitro, ex vivo and in vivo models to show that a placental barrier will respond to agents that are suspected of initiating childhood leukaemia by releasing factors that cause DNA damage in cord blood and bone marrow cells, including stem cells. We show that DNA damage caused by in utero exposure can reappear postnatally after an immune challenge. Furthermore, both foetal and postnatal DNA damage are prevented by prenatal exposure of the placenta to a mitochondrially-targeted antioxidant. We conclude that the placenta might contribute to the first hit towards leukaemia initiation by bystander-like signalling to foetal haematopoietic cells

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