Rôle de mutants rares de la calréticuline et du stress du réticulum endoplasmique dans la pathogenèse des néoplasmes myéloprolifératifs

Après la découverte des mutations de la calréticuline dans les néoplasmes classiques myéloproliferatifs négatifs pour le Ph1, les travaux se sont focalisés sur les deux mutations les plus fréquentes, c'est-à-dire la calréticuline del52 et l’ins5, mais il existe environ 20% de mutants rares de la calréticuline (une cinquantaine), qui ont été classés en type-1 « like » et type-2 « like », classification basée sur leur structure. Cependant il reste à déterminer si cette classification est pertinente du point de vue fonctionnel, ce qui pourrait avoir des conséquences pour la prise en charge des patients et leur traitement. Ici, nous démontrons que deux mutants rares de type-1 (del34 et del46) et un de type-2 (del19) se comportent de manière similaire aux deux mutations fondatrices de cette classification, del52 et ins5, respectivement. Ces résultats ont été validés par des expériences in vivo chez la souris. Tous les mutants de la calréticuline (del19, del34 et del46) nécessitent absolument le récepteur de la thrombopoïétine, appelé MPL, pour induire une transformation cellulaire en provoquant une activation indépendante de la thrombopoïétine de la voie MPL / JAK2-STAT, comme les mutants del52 et ins5. Dans les expériences de transplantation de moelle osseuse de souris, les mutants rares de type-1 sont associés à une progression fréquente de la maladie d’un tableau proche d’une thrombocytémie essentielle à une myélofibrose, tandis que le mutant rare de type 2 est associé à une légère thrombocytose. Du point de vue hématopoïétique, les mutants rares de type-1 provoquent une amplification au niveau des cellules souches hématopoïétiques donc à un stade précoce tandis que les mutants rares de type-2 provoquent une amplification tardive de la mégacaryopoïèse. Grâce à une modélisation protéique basée sur l'homologie des mutants de calréticuline, nous avons identifié des domaines oncogènes qui seraient potentiellement responsables de l'interaction pathologique de la calréticuline et de MPL pour conduire à une activation indépendante de la thrombopoïétine. Maintenant, ces résultats in silico doivent être absolument validés par des études structure fonction. Enfin, nous avons modélisé un nouveau mécanisme de signalisation dans la leucémie myéloïde chronique comprenant IRE-1alpha, un bras de la voie de réponse des protéines mal repliées (UPR), qui pourrait être responsable de la perte de la fonction de la p53 pendant la progression de la leucémie myéloïde chronique vers une leucémie aiguë. Un tel mécanisme pourrait être impliqué dans les autres MPN.After the discovery of calreticulin mutations in classical Ph1- Myeloproliferative Neoplasms, extensive investigation is underway on the two most frequent mutations, i.e., del52 and ins5, but it remains that the rare calreticulin mutants, which include both type-1 like and type-2 like require a similar investigation for ascertaining whether the classification of type-1 and type-2 has a functional relevance as well as for therapeutic intervention and patient management. Here we demonstrate that type-1 like (del34 and del46) and type-2 like (del19) mutants behave similarly as del52 and ins5 mutants, respectively. Moreover, we validate our findings with in vivo experiments. All the calreticulin mutants (del19, del34 and del46) absolutely require the thrombopoietin receptor, MPL, to induce cell transformation by causing ligand independent activation of the MPL/JAK2-STAT pathway. In mouse bone marrow transplantation experiments, type-1 like mutants are associated with frequent progression from an essential thrombocythemia-like phenotype to myelofibrosis whereas type-2 like mutant is associated with mild thrombocytosis. Type-1 like mutants cause clonal amplification of early hematopoetic stem cells whereas the type-2 like mutant causes late platelet amplification. Further, by homology based protein modeling of calreticulin mutants, we have identified possible oncogenic domains responsible for pathologic interaction of CALR and MPL leading to ligand independent activation of MPL. Now they must be validated by structural-functional studies Finally, we have modelled a novel signaling mechanism in chronic myeloid leukemia comprising of IRE-1alpha, an unfolded protein response (UPR) pathway arm, which may be responsible for loss of the WT p53 function during leukemic development and progression. Such a mechanism may be involved in the other MPN

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BIOLOGICAL ASPECTS OF JAK/STAT SIGNALING IN BCR-ABL-NEGATIVE MYELOPROLIFERATIVE NEOPLASMS: Myeloproliferative disorders more recently named Myeloproliferative neoplasms (MPN) display several clinical entities: chronic myeloid leukemia (CML), the classical MPN including polycythemia vera (PV), essential thrombocythemia (ET), primary myelofibrosis (PMF) and atypical and unclassifiable NMP. The term MPN is mostly used for classical BCR-ABL-negative (myeloproliferative disorder) (ET, PV, PMF). These are clonal diseases resulting from the transformation of an hematopoietic stem cell and leading to an abnormal production of myeloid cells. The genetic defects responsible for the myeloproliferative abnormalities are called « driver » mutations and all result in deregulation of the cytokine receptor / JAK2 / STAT axis. Among them, JAK2, the thrombopoietin receptor (MPL) and calreticulin (CALR) mutations are found in around 90% of the cases. These driver MPN mutations can be associated with other driver mutations also found in other hematological malignancies, especially in PMFs. These are chronic diseases with major risks being thrombosis, hemorrhage and cytopenias for PMF and the long-term progression to myelofibrosis and the transformation to leukemia. Most recent therapeutic have focused on targeting the JAK2 signaling pathway directly by inhibitors of JAK2 or indirectly. Interferon a allows in some cases hematologic and molecular remission patients

Rare type 1-like and type 2-like calreticulin mutants induce similar myeloproliferative neoplasms as prevalent type 1 and 2 mutants in mice.

Frameshift mutations in the calreticulin (CALR) gene are present in 30% of essential thrombocythemia and myelofibrosis patients. The two most frequent mutations are CALR del52 (type 1, approximately 60%) and CALR ins5 (type 2, around 30%), but many other rarer mutations exist accounting each for less than 2% of all CALR mutations. Most of them are structurally classified as type 1-like and type 2-like CALR mutations according to the absence or presence of a residual wild-type calcium-binding motif and the modification of the alpha-helix structure. Yet, several key questions remain unanswered, especially the reason of such low frequencies of these other mutations. In an attempt to investigate specific pathogenic differences between type 1-like and type 2-like CALR mutations and del52 and ins5, we modeled two type 1-like (del34 and del46) and one type 2-like (del19) mutations in cell lines and in mice. All CALR mutants constitutively activate JAK2 and STAT5/3/1 in a similar way in the presence of the thrombopoietin receptor (MPL) and induced cytokine-independent cell growth but to a lesser extent with rare mutants over time. This correlates with reduced expression levels of rare CALR mutants compared to del52 and ins5. Lethally irradiated mice that were engrafted with bone marrow transduced with the different CALR mutations developed thrombocytosis, but to a much lesser extent with ins5 and the type 2-like CALR mutation. In contrast to type 2-like mice, type 1-like mice developed marked myelofibrosis and splenomegaly 10 months after engraftment. Similar to del52, type 1-like CALR mutations induced an expansion at an early stage of hematopoiesis compared to ins5 and type 2-like mutation. Thus, type 1-like and type 2-like CALR mutants structurally and functionally resemble del52 and ins5 mutants, respectively