Unraveling the Connections between Calreticulin and Myeloproliferative Neoplasms via Calcium Signalling

Abstract

AbstractMutations in the form of insertions and deletions (INDEL) in the calreticulin gene lead to essential thrombocythemia which is characterized by the formation of thrombosis. However, the connection between calreticulin INDEL and essential thrombocythemia remains largely elusive. Through combined molecular dynamics simulation and in-vitro studies on the wild type and mutated isoforms of calreticulin, the mechanism underlying the calreticulin INDEL induced essential thrombocythemia was investigated at the molecular level. Our results demonstrate that mutations in exon-9 could lead to significant conformational variations of calreticulin structure and thereby reducing its interaction with calcium ions due to decreased electrostatic contributions. The consequence of mutations on calreticulin’s structural integrity was revealed by identifying the key residues and their roles in calcium binding. Furthermore, mutations implemented by CRISPR-Cas9 in exon-9 showed diminished calcium signaling in HEK-293T cells, which agree well with our in-silico findings. The current study might help in understanding of the interactions between calreticulin exon-9 INDEL and calcium ions mediated by the structural variations of calreticulin. The results provide useful information for designing novel therapeutic approaches targeting essential thrombocythemia.