Literature DB >> 34661159

Hyperthermia Selectively Destabilizes Oncogenic Fusion Proteins.

Yasen Maimaitiyiming1,2,3, Qian Qian Wang1,3, Chang Yang1,3, Yasumitsu Ogra4, Yinjun Lou5, Clayton A Smith6, Liaqat Hussain1, Yi Ming Shao7, Jiebo Lin2, Jinfeng Liu2, Lingfang Wang2, Yong Zhu8, Haiyan Lou5, Yuan Huang9, Xiaoxia Li10, Kao-Jung Chang11, Hao Chen12, Hongyan Li13, Ying Huang14, Eric Tse15, Jie Sun5, Na Bu16, Shih-Hwa Chiou17, Yan Fang Zhang5, Hao Ying Hua18, Li Ya Ma5, Ping Huang19, Ming Hua Ge19, Feng-Lin Cao10, Xiaodong Cheng16, Hongzhe Sun13, Jin Zhou10, Vasilis Vasliou8, Pengfei Xu14, Jie Jin5, Mikael Bjorklund20, Hong-Hu Zhu3,5, Chih-Hung Hsu2, Hua Naranmandura1,3.   

Abstract

The PML/RARα fusion protein is the oncogenic driver in acute promyelocytic leukemia (APL). Although most APL cases are cured by PML/RARα-targeting therapy, relapse and resistance can occur due to drug-resistant mutations. Here we report that thermal stress destabilizes the PML/RARα protein, including clinically identified drug-resistant mutants. AML1/ETO and TEL/AML1 oncofusions show similar heat shock susceptibility. Mechanistically, mild hyperthermia stimulates aggregation of PML/RARα in complex with nuclear receptor corepressors leading to ubiquitin-mediated degradation via the SIAH2 E3 ligase. Hyperthermia and arsenic therapy destabilize PML/RARα via distinct mechanisms and are synergistic in primary patient samples and in vivo, including three refractory APL cases. Collectively, our results suggest that by taking advantage of a biophysical vulnerability of PML/RARα, thermal therapy may improve prognosis in drug-resistant or otherwise refractory APL. These findings serve as a paradigm for therapeutic targeting of fusion oncoprotein-associated cancers by hyperthermia. SIGNIFICANCE: Hyperthermia destabilizes oncofusion proteins including PML/RARα and acts synergistically with standard arsenic therapy in relapsed and refractory APL. The results open up the possibility that heat shock sensitivity may be an easily targetable vulnerability of oncofusion-driven cancers.See related commentary by Wu et al., p. 300. ©2021 American Association for Cancer Research.

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Year:  2021        PMID: 34661159      PMCID: PMC8513904          DOI: 10.1158/2643-3230.BCD-20-0188

Source DB:  PubMed          Journal:  Blood Cancer Discov        ISSN: 2643-3230


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Journal:  Blood Cancer Discov       Date:  2021-03
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