SungMyung Kang scite author profile

SungMyung Kang

3Publications

91Citation Statements Received

104Citation Statements Given

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Affiliations

Institute of Cancer Research, University of Calgary, Alberta Children's Hospital

Publications

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Genome-wide loss-of-function genetic screening identifies opioid receptor μ1 as a key regulator of L-asparaginase resistance in pediatric acute lymphoblastic leukemia

et al. 2017

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L-asparaginase is a critical chemotherapeutic agent for acute lymphoblastic leukemia (ALL). It hydrolyzes plasma asparagine into aspartate and NH3, causing asparagine deficit and inhibition of protein synthesis and eventually, leukemic cell death. However, patient relapse often occurs due to development of resistance. The molecular mechanism by which ALL cells acquire resistance to L-asparaginase is unknown. Therefore, we sought to identify genes that are involved in L-asparaginase resistance in primary leukemic cells. By unbiased genome-wide RNAi screening, we found that among 10 resistant ALL clones, six hits were for opioid receptor mu 1 (oprm1), two hits were for carbonic anhydrase 1 (ca1) and another two hits were for ubiquitin-conjugating enzyme E2C (ube2c). We also found that OPRM1 is expressed in all leukemic cells tested. Specific knockdown of OPRM1 confers L-asparaginase resistance, validating our genome-wide retroviral shRNA library screening data. Methadone, an agonist of OPRM1, enhances the sensitivity of parental leukemic cells, but not OPRM1-depleted cells, to L-asparaginase treatment, indicating that OPRM1 is required for the synergistic action of L-asparaginase and methadone, and that OPRM1 loss promotes leukemic cell survival likely through downregulation of the OPRM1-mediated apoptotic pathway. Consistent with this premise, patient leukemic cells with relatively high levels of OPRM1 are more sensitive to L-asparaginase treatment compared to OPRM1-depleted leukemic cells, further indicating that OPRM1 loss has a crucial role in L-asparaginase resistance in leukemic patients. Thus, our study demonstrates for the first time, a novel OPRM1-mediated mechanism for L-asparaginase resistance in ALL, and identifies OPRM1 as a functional biomarker for defining high-risk subpopulations and for the detection of evolving resistant clones. Oprm1 may also be utilized for effective treatment of L-asparaginase-resistant ALL.

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HAP1 loss confers l-asparaginase resistance in ALL by downregulating the calpain-1-Bid-caspase-3/12 pathway

Lee

Kang

Wang

et al. 2019

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l-Asparaginase (l-ASNase) is a strategic component of treatment protocols for acute lymphoblastic leukemia (ALL). It causes asparagine deficit, resulting in protein synthesis inhibition and subsequent leukemic cell death and ALL remission. However, patients often relapse because of the development of resistance, but the underlying mechanism of ALL cell resistance to l-asparaginase remains unknown. Through unbiased genome-wide RNA interference screening, we identified huntingtin associated protein 1 (HAP1) as an ALL biomarker for l-asparaginase resistance. Knocking down HAP1 induces l-asparaginase resistance. HAP1 interacts with huntingtin and the intracellular Ca2+ channel, inositol 1,4,5-triphosphate receptor to form a ternary complex that mediates endoplasmic reticulum (ER) Ca2+ release upon stimulation with inositol 1,4,5-triphosphate3. Loss of HAP1 prevents the formation of the ternary complex and thus l-asparaginase-mediated ER Ca2+ release. HAP1 loss also inhibits external Ca2+ entry, blocking an excessive rise in [Ca2+]i, and reduces activation of the Ca2+-dependent calpain-1, Bid, and caspase-3 and caspase-12, leading to reduced number of apoptotic cells. These findings indicate that HAP1 loss prevents l-asparaginase–induced apoptosis through downregulation of the Ca2+-mediated calpain-1-Bid-caspase-3/12 apoptotic pathway. Treatment with BAPTA-AM [1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid tetrakis(acetoxymethyl ester)] reverses the l-asparaginase apoptotic effect in control cells, supporting a link between l-asparaginase-induced [Ca2+]i increase and apoptotic cell death. Consistent with these findings, ALL patient leukemic cells with lower HAP1 levels showed resistance to l-asparaginase, indicating the clinical relevance of HAP1 loss in the development of l-asparaginase resistance, and pointing to HAP1 as a functional l-asparaginase resistance biomarker that may be used for the design of effective treatment of l-asparaginase-resistant ALL.

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Stoichiometric expression of mtHsp40 and mtHsp70 modulates mitochondrial morphology and cristae structure via Opa1_L cleavage

Lee

Ahn

Kang

et al. 2015

MBoC

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SungMyung Kang

Genome-wide loss-of-function genetic screening identifies opioid receptor μ1 as a key regulator of L-asparaginase resistance in pediatric acute lymphoblastic leukemia

HAP1 loss confers l-asparaginase resistance in ALL by downregulating the calpain-1-Bid-caspase-3/12 pathway

Stoichiometric expression of mtHsp40 and mtHsp70 modulates mitochondrial morphology and cristae structure via Opa1_L cleavage

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SungMyung Kang

Genome-wide loss-of-function genetic screening identifies opioid receptor μ1 as a key regulator of L-asparaginase resistance in pediatric acute lymphoblastic leukemia

HAP1 loss confers l-asparaginase resistance in ALL by downregulating the calpain-1-Bid-caspase-3/12 pathway

Stoichiometric expression of mtHsp40 and mtHsp70 modulates mitochondrial morphology and cristae structure via Opa1L cleavage

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Stoichiometric expression of mtHsp40 and mtHsp70 modulates mitochondrial morphology and cristae structure via Opa1_L cleavage