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Functional studies of CALR mutations associated with Myeloproliferative Neoplasms (MPNs) using patient-derived induced pluripotent stem cell (iPSC) models and CRISPR/Cas9 genome editing

Applicant Wei Wang, Ph.D.
Subject Area Hematology, Oncology
Term from 2017 to 2020
Project identifier Deutsche Forschungsgemeinschaft (DFG) - Project number 394341827
 
Final Report Year 2021

Final Report Abstract

Myeloproliferative neoplasms (MPN) are characterized by the excessive production of one or more myeloid lineages and a propensity to progress to acute leukemia. In 2013, mutations in the CALR gene, encoding calreticulin, were identified in patients with MPN, mutually exclusive to the previously identified JAK2 and MPL (TPO-R) mutations. Subsequent studies found that CALR mutations lead to activation of JAK/STAT, mediated through aberrant interactions between mutant CALR and MPL, thus presenting an excellent opportunity for targeted therapy. However, the mechanism of MPL activation remains largely unexplained with prior studies using cell lines with exogenous expression of CALR and MPL following transfection. To create a more physiological cellular model to study the effects of CALR mutations, we established multiple iPSC lines from two patients with CALR-mutant MPN. All iPSC lines were confirmed to harbour the CALR mutation found in the corresponding patient, to express mutant calreticulin, as detected by flow cytometry using an antibody which specifically recognizes the novel calreticulin C-terminus, and to be karyotypically normal. CRISPR gene editing was used to generate isogenic CALR-corrected lines from both CALR-mutant patients. Furthermore, in order to facilitate biochemical studies, we used CRISPR to introduce a V5 epitope tag in one allele of the endogenous mutant or WT CALR gene, in mutant and isogenic corrected iPSC lines, respectively. We optimized an in vitro differentiation protocol for efficient derivation of megakaryocyte (MK) progenitors from iPSCs and found disease-relevant phenotypes, mainly TPO-independent MK colony formation in semi-solid media, which is the phenotypic hallmark of ex vivo primary MPN cells. In the absence of TPO, CALR-mutant type 1-like and CALR-mutant type 2 iPSCs generated 58.7±22.2% and 59.8±3.6%, respectively, of the number of MK colonies generated in the presence of TPO, as opposed to 8.8±1.8% and 0.5±0.9%, respectively, for the matched corrected CALR-mutant type 1-like and the corrected CALR-mutant type 2 iPSCs. Isolated CALR mutant iPSC-derived CD41a+ MK progenitors had increased phosphorylation of STAT5 following cytokine starvation as compared to isogenic corrected and non-isogenic normal cells. CALR-mutant cells expressed equal transcript levels of the WT and mutant CALR alleles. However, mutant CALR protein levels were severely reduced, at levels 1~12% of those of the WT protein. This is consistent with previous studies documenting instability of mutant calreticulin. These iPSC models offer the opportunity to study the effects of CALR mutations in a cellular context with both MPL and CALR (WT or mutant) expressed from their endogenous loci. They thus provide a powerful platform to investigate the disease mechanisms underlying CALR-mutant MPNs and to perform small molecule and genetic (CRISPR) screens to identify new therapeutic targets.

 
 

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