Repercussion of megakaryocyte-specific Gata1 Loss on megakaryopoiesis and the hematopoietic precursor compartment

During hematopoiesis, transcriptional programs are essential for the commitment and differentiation of progenitors into the different blood lineages. GATA1 is a transcription factor expressed in several hematopoietic lineages and essential for proper erythropoiesis and megakaryopoiesis. Megakaryocyte-specific genes, such as GP1BA, are known to be directly regulated by GATA1. Mutations in GATA1 can lead to dyserythropoietic anemia and pseudo gray-platelet syndrome. Selective loss of Gata1 expression in adult mice results in macrothrombocytopenia with platelet dysfunction, characterized by an excess of immature megakaryocytes. To specifically analyze the impact of Gata1 loss in mature committed megakaryocytes, we generated Gata1-Lox|Pf4-Cre mice (Gata1cKOMK). Consistent with previous findings, Gata1cKOMK mice are macrothrombocytopenic with platelet dysfunction. Supporting this notion we demonstrate that Gata1 regulates directly the transcription of Syk, a tyrosine kinase that functions downstream of Clec2 and GPVI receptors in megakaryocytes and platelets. Furthermore, we show that Gata1cKOMK mice display an additional aberrant megakaryocyte differentiation stage. Interestingly, these mice present a misbalance of the multipotent progenitor compartment and the erythroid lineage, which translates into compensatory stress erythropoiesis and splenomegaly. Despite the severe thrombocytopenia, Gata1cKOMK mice display a mild reduction of TPO plasma levels, and Gata1cK-OMK megakaryocytes show a mild increase in Pf4 mRNA levels; such a misbalance might be behind the general hematopoietic defects observed, affecting locally normal TPO and Pf4 levels at hematopoietic stem cell niches. © 2016 Meinders et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Etude des mécanismes de formation des plaquettes sanguines : rôle de l'environnement médullaire

Megakaryocytes differentiation (megakaryopoiesis) and platelet formation mechanisms are not entirely understood, but the bone marrow environment seems to be crucial in these processes. In this thesis, we show i) that integrin β3, the extracellular matrix protein receptors, are involved in megakaryopoiesis and platelet formation, ii) that recreating a 3D environment of stiffness in the range of that of bone marrow improves the maturation of in vitro differentiated megakaryocytes and iii) a new role for myosin IIA in the cytoplasmic distribution of organelles within the megakaryocyte. As a side-project, we characterized the specificity of expression of the Pf4-cre transgene to validate its use in our experimental approaches. This work enlightens new roles for myosin IIA and integrins in megakaryocytes and indicates that stiffness of the environment influences megakaryopoiesis.Les mécanismes de formation des plaquettes sanguines à partir des mégacaryocytes ne sont pas totalement compris, mais l’environnement médullaire semble y avoir une influence cruciale. Dans ce travail nous montrons que i) les intégrines β3, récepteurs de protéines de matrice extracellulaire, semblent impliquées dans la mégacaryopoïèse et la formation des plaquettes, ii) la différenciation des cellules hématopoïétiques dans un environnement 3D de rigidité comparable à la moelle osseuse améliore la maturation des mégacaryocytes différenciés in vitro et iii) la myosine IIA est impliquée dans la distribution des organelles dans les mégacaryocytes. Parallèlement, Nous avons caractérisé la spécificité d’expression du transgène Pf4-cre pour valider son utilisation dans nos approches expérimentales. Ce travail apporte un éclairage nouveau sur le rôle de la myosine IIA et des intégrines dans les mégacaryocytes et souligne l’influence de la rigidité de l’environnement dans la mégacaryopoïèse

Study of the mechanisms of platelet formation : role for the bone marrow environment

Les mécanismes de formation des plaquettes sanguines à partir des mégacaryocytes ne sont pas totalement compris, mais l’environnement médullaire semble y avoir une influence cruciale. Dans ce travail nous montrons que i) les intégrines β3, récepteurs de protéines de matrice extracellulaire, semblent impliquées dans la mégacaryopoïèse et la formation des plaquettes, ii) la différenciation des cellules hématopoïétiques dans un environnement 3D de rigidité comparable à la moelle osseuse améliore la maturation des mégacaryocytes différenciés in vitro et iii) la myosine IIA est impliquée dans la distribution des organelles dans les mégacaryocytes. Parallèlement, Nous avons caractérisé la spécificité d’expression du transgène Pf4-cre pour valider son utilisation dans nos approches expérimentales. Ce travail apporte un éclairage nouveau sur le rôle de la myosine IIA et des intégrines dans les mégacaryocytes et souligne l’influence de la rigidité de l’environnement dans la mégacaryopoïèse.Megakaryocytes differentiation (megakaryopoiesis) and platelet formation mechanisms are not entirely understood, but the bone marrow environment seems to be crucial in these processes. In this thesis, we show i) that integrin β3, the extracellular matrix protein receptors, are involved in megakaryopoiesis and platelet formation, ii) that recreating a 3D environment of stiffness in the range of that of bone marrow improves the maturation of in vitro differentiated megakaryocytes and iii) a new role for myosin IIA in the cytoplasmic distribution of organelles within the megakaryocyte. As a side-project, we characterized the specificity of expression of the Pf4-cre transgene to validate its use in our experimental approaches. This work enlightens new roles for myosin IIA and integrins in megakaryocytes and indicates that stiffness of the environment influences megakaryopoiesis

Biogenesis of the demarcation membrane system (DMS) in megakaryocytes

The demarcation membrane system (DMS) in megakaryocytes forms the plasma membrane (PM) of future platelets. Using confocal microscopy, electron tomography, and large volume focused ion beam/scanning electron microscopy (FIB/SEM), we determined the sequential steps of DMS formation. We identified a pre-DMS that initiated at the cell periphery and was precisely located between the nuclear lobes. At all developmental stages, the DMS remained continuous with the cell surface. The number of these connections correlated well with the nuclear lobulation, suggesting a relationship with cleavage furrow formation and abortive cytokinesis. On DMS expansion, Golgi complexes assembled around the pre-DMS, and fusion profiles between trans-golgi network–derived vesicles and the DMS were observed. Brefeldin-A reduced DMS expansion, indicating that the exocytic pathway is essential for DMS biogenesis. Close contacts between the endoplasmic reticulum (ER) and the DMS were detected, suggesting physical interaction between the 2 membrane systems. FIB/SEM revealed that the DMS forms an intertwined tubular membrane network resembling the platelet open canalicular system. We thus propose the following steps in DMS biogenesis: (1) focal membrane assembly at the cell periphery; (2) PM invagination and formation of a perinuclear pre-DMS; (3) expansion through membrane delivery from Golgi complexes; and (4) ER-mediated lipid transfer

Importance of environmental stiffness for megakaryocyte differentiation and proplatelet formation.

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Broader expression of the mouse platelet factor 4-cre transgene beyond the megakaryocyte lineage

Background : Transgenic mice expressing cre recombinase under the control of the platelet factor4 (Pf4) promoter, in the context of a 100-kb bacterial artificial chromosome, have become a valuable tool with which to study genetic modifications in the platelet lineage. However, the specificity of cre expression has recently been questioned, and the time of its onset during megakaryopoiesis remains unknown. Objectives/MethodsTo characterize the expression of this transgene, we used double-fluorescent cre reporter mice. ResultsIn the bone marrow, Pf4-cre-mediated recombination had occurred in all CD42-positive megakaryocytes as early as stageI of maturation, and in rare CD42-negative cells. In circulating blood, all platelets had recombined, along with only a minor fraction of CD45-positive cells. However, we found that all tissues contained recombined cells of monocyte/macrophage origin. When recombined, these cells might potentially modify the function of the tissues under particular conditions, especially inflammatory conditions, which further increase recombination in immune cells. Unexpectedly, a subset of epithelial cells from the distal colon showed signs of recombination resulting from endogenous Pf4-cre expression. This is probably the basis of the unexplained colon tumors developed by Apc(flox/flox);Pf4-cre mice, generated in a separate study on the role of Apc in platelet formation. ConclusionAltogether, our results indicate early recombination with full penetrance in megakaryopoiesis, and confirm the value of Pf4-cre mice for the genetic engineering of megakaryocytes and platelets. However, care must be taken when investigating the role of platelets in processes outside hemostasis, especially when immune cells might be involved

Effect of Promotional Initiatives on Visits to a Dedicated Website for Physical Activity and Non-Communicable Disease in Luxembourg: An Event Study

The Sport-Santé project and its website (www.sport-sante.lu) promote physical activity for individuals with non-communicable diseases (NCDs) in Luxembourg. Our purpose was to perform an event study analysis to evaluate the effects of communication and promotional initiatives on the number of visits to the Sport-Santé website. Between September 2015 and May 2016, the Sport-Santé website was promoted during different initiatives, including participation in health-related events or publication of articles in local journals. The daily number of visits to www.sport-sante.lu website (i.e., our outcome) was recorded using Google Analytics and compared to a counterfactual collected with its benchmarking tool. The counterfactual was defined as the daily number of visits to websites in the same field. A model was created to evaluate the relationship between the number of visits to www.sport-sante.lu website and the number of visits to similar websites during a control period with no promotional initiatives (from July 2015 to September 2015). The effect of promotional initiatives was subsequently tested, by comparing the actual number of visits to our website (up to 2 days after each event) with the theoretical number of visits predicted by the model. Twenty-two initiatives were identified, of which 11 were participations at major health-related events and 11 publications of popular science articles. Of these 22 initiatives, the event study identified 2 popular science articles and 1 interactive workshop that significantly increased the daily number of visits to the www.sport-sante.lu website. One of the two articles was published on the day before the workshop was held, which did not allow us to distinguish its specific impact. The second article was published in the main national newspaper. This is the first time to our knowledge that an event study analysis has been used to evaluate the impact of promotional initiatives on the number of visits to a dedicated website for physical activity and NCDs. Our results indicate that some initiatives can aid in the number of visits, but in general their impact is limited. To observe an increased rate of participation in physical activity, additional promotional and evaluative strategies should be explored