Contributions
Abstract: S883
Type: Oral Presentation
Presentation during EHA23: On Saturday, June 16, 2018 from 16:30 - 16:45
Location: Room A8
Background
Recurrent somatic mutations in exon 9 of the calreticulin (CALR) gene are found in a majority of JAK2-unmutated myeloproliferative neoplasms (MPNs). All known mutations result in a +1-frameshift in the CALR reading frame that creates a novel C-terminal domain encoded by an alternative reading frame. We and others have previously demonstrated that mutant CALR binds to and activates the thrombopoietin receptor MPL and confers cytokine-independent growth. Moreover, we showed that these oncogenic activities of mutant CALR are dependent on a threshold of basic amino acid residues in the mutant C-terminus. However, relatively less is known regarding the role of the N-domain of mutant CALR in oncogenic transformation.
Aims
We aim to identify key features of the N-domain of mutant CALR which are required for its oncogenic activity.
Methods
Mutations in the FLAG-tagged human CALR cDNA harbouring a “type I” del52 mutation (CALRMUT) were introduced by site-directed mutagenesis. Transforming activity of CALRMUT variants was assessed based on their ability to confer cytokine-independence to Ba/F3 cell line expressing human MPL (Ba/F3-MPL). Interaction between CALRMUT variants and MPL was assessed by FLAG-pulldown experiments.
Results
We previously demonstrated that the lectin binding motif of CALRMUT was essential for oncogenic activity. The crystal structure of the CALR globular domain reveals that the carbohydrate binding pocket is proximal to a patch of histidine (His) residues which are required to coordinate Zn2+ and mediate regional domain structure of wild-type CALR. Here, we undertook a systematic mutagenesis screen to test the role of 3 His residues (His82, His128 and His153) and their effects on Zn2+ homeostasis in CALRMUT oncogenic activity. We observed that CALRMUT harbouring of any single His residue retained the ability to confer cytokine-independence, bind to MPL and activate Stat3/5. In contrast, CALRMUT harbouring loss of His82 in combination with either His128 or His153 (but not His25 which resides on the opposite face of the CALR N-domain) were compromised in their capacity to confer cytokine independence and bind MPL, suggesting that His82 needs to cooperate with other nearby Zn2+-coordinating His residues on the carbohydrate binding face of CALRMUT to facilitate oncogenic activity. The stability of all CALRMUT His variants exhibited comparable stability and folding in vitro, suggesting these changes in CALRMUT activity likely reflect a disruption of a critical domain within CALR rather than affecting protein stability. Finally, given the role of the His residues in wild-type CALR in regulating Zn2+ binding, we tested that CALRMUT activity may be affected by intracellular Zn2+ levels. We used CRISPRi to repress expression of metallothionein 1a (MT1a) which is required for Zn2+ uptake, and observed that MT1a depletion rendered CALR mutant cells more sensitive to the JAK inhibitor ruxolitinib. These data suggest that Zn2+ homeostasis is able to regulate MPN pathogenesis.
Conclusion
We show that Zn2+ binding by histidine residues are essential for CALRMUT to bind to MPL and engender transformation, and that disrupting intracellular Zn2+ levels has the potential to sensitise CALRMUT-expressing cells to existing MPN therapies such as ruxolitinib.
Session topic: 15. Myeloproliferative neoplasms – Biology & Translational Research
Keyword(s): mutation analysis, Myeloproliferative disorder, Receptor tyrosine kinase
Abstract: S883
Type: Oral Presentation
Presentation during EHA23: On Saturday, June 16, 2018 from 16:30 - 16:45
Location: Room A8
Background
Recurrent somatic mutations in exon 9 of the calreticulin (CALR) gene are found in a majority of JAK2-unmutated myeloproliferative neoplasms (MPNs). All known mutations result in a +1-frameshift in the CALR reading frame that creates a novel C-terminal domain encoded by an alternative reading frame. We and others have previously demonstrated that mutant CALR binds to and activates the thrombopoietin receptor MPL and confers cytokine-independent growth. Moreover, we showed that these oncogenic activities of mutant CALR are dependent on a threshold of basic amino acid residues in the mutant C-terminus. However, relatively less is known regarding the role of the N-domain of mutant CALR in oncogenic transformation.
Aims
We aim to identify key features of the N-domain of mutant CALR which are required for its oncogenic activity.
Methods
Mutations in the FLAG-tagged human CALR cDNA harbouring a “type I” del52 mutation (CALRMUT) were introduced by site-directed mutagenesis. Transforming activity of CALRMUT variants was assessed based on their ability to confer cytokine-independence to Ba/F3 cell line expressing human MPL (Ba/F3-MPL). Interaction between CALRMUT variants and MPL was assessed by FLAG-pulldown experiments.
Results
We previously demonstrated that the lectin binding motif of CALRMUT was essential for oncogenic activity. The crystal structure of the CALR globular domain reveals that the carbohydrate binding pocket is proximal to a patch of histidine (His) residues which are required to coordinate Zn2+ and mediate regional domain structure of wild-type CALR. Here, we undertook a systematic mutagenesis screen to test the role of 3 His residues (His82, His128 and His153) and their effects on Zn2+ homeostasis in CALRMUT oncogenic activity. We observed that CALRMUT harbouring of any single His residue retained the ability to confer cytokine-independence, bind to MPL and activate Stat3/5. In contrast, CALRMUT harbouring loss of His82 in combination with either His128 or His153 (but not His25 which resides on the opposite face of the CALR N-domain) were compromised in their capacity to confer cytokine independence and bind MPL, suggesting that His82 needs to cooperate with other nearby Zn2+-coordinating His residues on the carbohydrate binding face of CALRMUT to facilitate oncogenic activity. The stability of all CALRMUT His variants exhibited comparable stability and folding in vitro, suggesting these changes in CALRMUT activity likely reflect a disruption of a critical domain within CALR rather than affecting protein stability. Finally, given the role of the His residues in wild-type CALR in regulating Zn2+ binding, we tested that CALRMUT activity may be affected by intracellular Zn2+ levels. We used CRISPRi to repress expression of metallothionein 1a (MT1a) which is required for Zn2+ uptake, and observed that MT1a depletion rendered CALR mutant cells more sensitive to the JAK inhibitor ruxolitinib. These data suggest that Zn2+ homeostasis is able to regulate MPN pathogenesis.
Conclusion
We show that Zn2+ binding by histidine residues are essential for CALRMUT to bind to MPL and engender transformation, and that disrupting intracellular Zn2+ levels has the potential to sensitise CALRMUT-expressing cells to existing MPN therapies such as ruxolitinib.
Session topic: 15. Myeloproliferative neoplasms – Biology & Translational Research
Keyword(s): mutation analysis, Myeloproliferative disorder, Receptor tyrosine kinase