Secreted Mutant Calreticulins As Rogue Cytokines Trigger Thrombopoietin Receptor Activation Specifically in CALR Mutated Cells: Perspectives for MPN Therapy

Background Mutant calreticulins carrying the sequence translated after a +1 frameshift at the C-terminus are major drivers of myeloproliferative neoplasms (MPNs). These mutant CALRs bind and activate TpoR/MPL in cells co-expressing TpoR and mutant CALRs, resulting in persistent JAK2-STAT5 signaling. Whether mutant CALR proteins are secreted, thus acting in trans on other cells, is not known. Aims Our objectives were to: 1) assess the direct TpoR-mutant CALR interaction both when expressed in the same or in different cells; 2) determine whether mutant CALRs are secreted; and 3) determine whether mutant CALR can act as extracellular cytokines. Methods Engineered CALR and TpoR mutants were analyzed by a combination of biochemical approaches (bioluminescence resonance energy transfer, recombinant protein production), functional assays (cell growth and transcriptional assays, flow cytometry, primary megakaryocytic clonogenic assay, analysis of CALR del52 knock-in mice) and cell imaging (confocal microscopy, flow cytometry and immuno-gold electron microscopy). Secreted CALRs were determined by ELISA using mutant specific antibodies. Results 1) Two systems provided evidence that mutant CALRs and TpoR directly interact. First, using Nano-BRET in cells co-expressing N-terminally fused TpoR or EpoR with Nano-luciferase and mutant or WT CALR C-terminally tagged with HaloTag that is bound to the 618-ligand fluorophore, we show that TpoR and mutant CALRs interact in a complex whether the two proteins are within 10 nm. The interaction does not occur between TpoR and WT CALR, or between EpoR and mutant or WT CALRs. Second, expressing mutant CALR and TpoR extracellular domain in S2 Drosophila Schneider cells showed that stable complex formation requires immature high mannose structure on TpoR. Lastly, we could detect surface expression of the TpoR/CALRdel52 complex using proximity ligation assay with anti-TpoR and anti-mutant CALR antibodies in CRISPR/Cas9 engineered UT7/Tpo cells that express endogenous mutant CALR and TpoR levels. 2) We used flow cytometry, confocal immunofluorescence and immunogold electron microscopy and could show that mutant CALRs are trafficking via cis-, medial- and trans-Golgi to the cell-surface and are secreted, independently from TpoR expression. Importantly, mutant CALRs are also secreted in CALR mutated MPN patients as determined by mutant CALR-specific ELISA assay in patient plasma (mean plasma level 24.6 ng/ml, range 0-156.5 ng/ml). In the