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P324: PHARMACOLOGIC INHIBITION OF DYRK1A RENDERS HIGH-RISK KMT2A-R ALL SENSITIVE TO VENETOCLAX
Wertheim, G. Chukinas, J. Bhansali, R. Swaminathan, S. Crispino, J. Shi, J. Tasian, S. Carroll, M.
Wertheim, G.
Chukinas, J.
Bhansali, R.
Swaminathan, S.
Crispino, J.
Shi, J.
Tasian, S.
Carroll, M.
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Journal article
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2022-06-23
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http://dx.doi.org/10.1097/01.hs9.0000844184.61581.6e
Abstract
Background: KMT2A-rearranged (R) ALL is a high-risk disease with a frequency of 70% in infants and 10% in children and adults with ALL and is associated with chemoresistance, relapse, and poor survival. Current intensive multiagent chemotherapy regimens induce significant side effects, yet fail to cure many patients, demonstrating continued need for novel therapeutic approaches. Aims: Determine if pharmacologic DYRK1A inhibition may be a novel treatment strategy for patients with KMT2A-R ALL. Methods: To identify novel targets in KMT2A-R leukemia, we performed a domain-specific kinome-wide CRISPR screen and identified multiple kinases required for cell growth. We focused on DYRK1A as it met the following three criteria: 1) Growth inhibition upon kinase targeting was greater in KMT2A-R leukemic cells than in non-KMT2A-R cells, 2) DYRK1A was not found to be common essential gene assessed through the Cancer Dependency Map, 3) Small molecule inhibitors are available. Results: We analyzed multiple ChIP-Seq experiments and identified that KMT2A-fusions directly bind to the DYRK1A promoter. Our RT-PCR and Western blot analyses demonstrate that KMT2A-R ALL cells treated with a menin inhibitor to disrupt the transcriptional activity of the KMT2A-R complex, downregulate DYRK1A, indicating direct regulation of DYRK1A by the KMT2A-fusion. We further observed that pharmacologic inhibition of DYRK1A with EHT1610 induced leukemic cell growth inhibition in vitro and in vivo, demonstrating that DYRK1A could be a new therapeutic target in KMT2A-R ALL cells. To further elucidate the mechanism of DYRK1A function, we treated several KMT2A-R ALL cell lines in vitro with EHT1610, which surprisingly resulted in the upregulation of MYC and hyperphosphorylation of the RAS/MAPK target ERK. Given that ERK hyperactivation stops B cell proliferation during early B cell development to allow them to rearrange their B cell receptor, we hypothesized that cell cycle inhibition upon ERK hyperactivation remains as a conserved mechanism of cell cycle regulation in KMT2A-R ALL. Strikingly, combining DYRK1A inhibition with the MEK inhibitor trametinib antagonistically rescued KMT2A-R ALL cell proliferation, indicating that ERK hyperactivation is the main driver of DYRK1A inhibitor mediated cell cycle arrest. Given that DYRK1A inhibitor does not induce apoptosis and cells restart cell proliferation after EHT1610 withdrawal we concluded that a DYRK1A monotherapy may not be an ideal new treatment option. However, it has been reported that increased MYC activity induces the accumulation of BIM in Burkitt’s Lymphoma. Given the increased expression of MYC following DYRK1A inhibition we performed a new Western blot analysis and validated increased expression of BIM in our KMT2A-R ALL cell lines after EHT1610 treatment. To test if targeting the interaction of BIM with BCL2 will induce an apoptotic effect when combined with EHT1610, we treated four KMT2A-R ALL cell lines with increasing concentrations of EHT1610 and the BCL2 inhibitor venetoclax. Strikingly, the combination of DYRK1A inhibition with BCL2 inhibition synergistically killed KMT2A-R ALL cells and significantly reduced the leukemia burden in vivo.
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Hurtz, C.1,; Wertheim, G.2; Chukinas, J.3; Bhansali, R.4; Swaminathan, S.5; Crispino, J.6; Shi, J.7; Tasian, S.3; Carroll, M.8. P324: PHARMACOLOGIC INHIBITION OF DYRK1A RENDERS HIGH-RISK KMT2A-R ALL SENSITIVE TO VENETOCLAX. HemaSphere 6():p 224-225, June 2022. DOI: 10.1097/01.HS9.0000844184.61581.6e
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Wiley Open Access
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HemaSphere, Vol. 6
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