TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors

Silvia Maifrede; Bac Viet Le; Margaret Nieborowska-Skorska; Konstantin Golovine; Katherine Sullivan-Reed; Wangisa M.B. Dunuwille; Joseph Nacson; Michael Hulse; Kelsey Keith; Jozef Madzo; Lisa Beatrice Caruso; Zachary Gazze; Zhaorui Lian; Antonella Padella; Kumaraswamy N. Chitrala; Boris A. Bartholdy; Ksenia Matlawska-Wasowska; Daniela Di Marcantonio; Giorgia Simonetti; Georg Greiner; Stephen M. Sykes; Peter Valent; Elisabeth M. Paietta; Martin S. Tallman; Hugo F. Fernandez; Mark R. Litzow; Mark D. Minden; Jian Huang; Giovanni Martinelli; George S. Vassiliou; Italo Tempera; Katarzyna Piwocka; Neil Johnson; Grant A. Challen; Tomasz Skorski

doi:10.1158/0008-5472.CAN-20-3761

TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors

Silvia Maifrede, Bac Viet Le, Margaret Nieborowska-Skorska, Konstantin Golovine, Katherine Sullivan-Reed, Wangisa M.B. Dunuwille, Joseph Nacson, Michael Hulse, Kelsey Keith, Jozef Madzo, Lisa Beatrice Caruso, Zachary Gazze, Zhaorui Lian, Antonella Padella, Kumaraswamy N. Chitrala, Boris A. Bartholdy, Ksenia Matlawska-Wasowska, Daniela Di Marcantonio, Giorgia Simonetti, Georg GreinerStephen M. Sykes, Peter Valent, Elisabeth M. Paietta, Martin S. Tallman, Hugo F. Fernandez, Mark R. Litzow, Mark D. Minden, Jian Huang, Giovanni Martinelli, George S. Vassiliou, Italo Tempera, Katarzyna Piwocka, Neil Johnson, Grant A. Challen, Tomasz Skorski

Hematology

Research output: Contribution to journal › Article › peer-review

Abstract

Somatic variants in TET2 and DNMT3A are founding mutations in hematological malignancies that affect the epigenetic regulation of DNA methylation. Mutations in both genes often co-occur with activating mutations in genes encoding oncogenic tyrosine kinases such as FLT3^ITD, BCR-ABL1, JAK2^V617F, and MPL^W515L, or with mutations affecting related signaling pathways such as NRAS^G12D and CALR^del52. Here, we show that TET2 and DNMT3A mutations exert divergent roles in regulating DNA repair activities in leukemia cells expressing these oncogenes. Malignant TET2-deficient cells displayed downregulation of BRCA1 and LIG4, resulting in reduced activity of BRCA1/2-mediated homologous recombination (HR) and DNA-PK–mediated non-homologous end-joining (D-NHEJ), respectively. TET2-deficient cells relied on PARP1-mediated alternative NHEJ (Alt-NHEJ) for protection from the toxic effects of spontaneous and drug-induced DNA double-strand breaks. Conversely, DNMT3A-deficient cells favored HR/D-NHEJ owing to downregulation of PARP1 and reduction of Alt-NHEJ. Consequently, malignant TET2-deficient cells were sensitive to PARP inhibitor (PARPi) treatment in vitro and in vivo, whereas DNMT3Adeficient cells were resistant. Disruption of TET2 dioxygenase activity or TET2—Wilms’ tumor 1 (WT1)–binding ability was responsible for DNA repair defects and sensitivity to PARPi associated with TET2 deficiency. Moreover, mutation or deletion of WT1 mimicked the effect of TET2 mutation on DSB repair activity and sensitivity to PARPi. Collectively, these findings reveal that TET2 and WT1 mutations may serve as biomarkers of synthetic lethality triggered by PARPi, which should be explored therapeutically.

Original language	English (US)
Pages (from-to)	5089-5101
Number of pages	13
Journal	Cancer research
Volume	81
Issue number	19
DOIs	https://doi.org/10.1158/0008-5472.CAN-20-3761
State	Published - Oct 1 2021

ASJC Scopus subject areas

Oncology
Cancer Research

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10.1158/0008-5472.CAN-20-3761

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Maifrede, S., Le, B. V., Nieborowska-Skorska, M., Golovine, K., Sullivan-Reed, K., Dunuwille, W. M. B., Nacson, J., Hulse, M., Keith, K., Madzo, J., Caruso, L. B., Gazze, Z., Lian, Z., Padella, A., Chitrala, K. N., Bartholdy, B. A., Matlawska-Wasowska, K., Marcantonio, D. D., Simonetti, G., ... Skorski, T. (2021). TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors. Cancer research, 81(19), 5089-5101. https://doi.org/10.1158/0008-5472.CAN-20-3761

Maifrede, S, Le, BV, Nieborowska-Skorska, M, Golovine, K, Sullivan-Reed, K, Dunuwille, WMB, Nacson, J, Hulse, M, Keith, K, Madzo, J, Caruso, LB, Gazze, Z, Lian, Z, Padella, A, Chitrala, KN, Bartholdy, BA, Matlawska-Wasowska, K, Marcantonio, DD, Simonetti, G, Greiner, G, Sykes, SM, Valent, P, Paietta, EM, Tallman, MS, Fernandez, HF, Litzow, MR, Minden, MD, Huang, J, Martinelli, G, Vassiliou, GS, Tempera, I, Piwocka, K, Johnson, N, Challen, GA & Skorski, T 2021, 'TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors', Cancer research, vol. 81, no. 19, pp. 5089-5101. https://doi.org/10.1158/0008-5472.CAN-20-3761

@article{c384792ec5d7441d99704be9d7d97ef1,

title = "TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors",

abstract = "Somatic variants in TET2 and DNMT3A are founding mutations in hematological malignancies that affect the epigenetic regulation of DNA methylation. Mutations in both genes often co-occur with activating mutations in genes encoding oncogenic tyrosine kinases such as FLT3ITD, BCR-ABL1, JAK2V617F, and MPLW515L, or with mutations affecting related signaling pathways such as NRASG12D and CALRdel52. Here, we show that TET2 and DNMT3A mutations exert divergent roles in regulating DNA repair activities in leukemia cells expressing these oncogenes. Malignant TET2-deficient cells displayed downregulation of BRCA1 and LIG4, resulting in reduced activity of BRCA1/2-mediated homologous recombination (HR) and DNA-PK–mediated non-homologous end-joining (D-NHEJ), respectively. TET2-deficient cells relied on PARP1-mediated alternative NHEJ (Alt-NHEJ) for protection from the toxic effects of spontaneous and drug-induced DNA double-strand breaks. Conversely, DNMT3A-deficient cells favored HR/D-NHEJ owing to downregulation of PARP1 and reduction of Alt-NHEJ. Consequently, malignant TET2-deficient cells were sensitive to PARP inhibitor (PARPi) treatment in vitro and in vivo, whereas DNMT3Adeficient cells were resistant. Disruption of TET2 dioxygenase activity or TET2—Wilms{\textquoteright} tumor 1 (WT1)–binding ability was responsible for DNA repair defects and sensitivity to PARPi associated with TET2 deficiency. Moreover, mutation or deletion of WT1 mimicked the effect of TET2 mutation on DSB repair activity and sensitivity to PARPi. Collectively, these findings reveal that TET2 and WT1 mutations may serve as biomarkers of synthetic lethality triggered by PARPi, which should be explored therapeutically.",

author = "Silvia Maifrede and Le, {Bac Viet} and Margaret Nieborowska-Skorska and Konstantin Golovine and Katherine Sullivan-Reed and Dunuwille, {Wangisa M.B.} and Joseph Nacson and Michael Hulse and Kelsey Keith and Jozef Madzo and Caruso, {Lisa Beatrice} and Zachary Gazze and Zhaorui Lian and Antonella Padella and Chitrala, {Kumaraswamy N.} and Bartholdy, {Boris A.} and Ksenia Matlawska-Wasowska and Marcantonio, {Daniela Di} and Giorgia Simonetti and Georg Greiner and Sykes, {Stephen M.} and Peter Valent and Paietta, {Elisabeth M.} and Tallman, {Martin S.} and Fernandez, {Hugo F.} and Litzow, {Mark R.} and Minden, {Mark D.} and Jian Huang and Giovanni Martinelli and Vassiliou, {George S.} and Italo Tempera and Katarzyna Piwocka and Neil Johnson and Challen, {Grant A.} and Tomasz Skorski",

note = "Funding Information: P. Valent reports personal fees from Celgene-BMS, Novartis, Blueprint, and Thermofisher, as well as grants and personal fees from Pfizer, and personal fees from AOP Orphan Pharmaceuticals outside the submitted work. M.S. Tallman reports grants from AbbVie, Orsenix, Biosight, Glycomimetics, Rafael Pharmaceuticals, Amgen, and other support from AbbVie, Daiichi-Sankyo, Orsenix, Rigel, Delta Fly Pharma, Tetraphase, Onzolyze, Jazz Pharmaceuticals, Roche, Biosight, Novartis, Innate Pharma, Kura, Syros Pharmaceuticals, and UpToDate; personal fees and nonfinancial support from EHA Congress Medscape Live Symposium and ASH CRTI Workshop, non-financial support from Hammeresmith Hospital, Britanico Hospital, and personal fees from PIME Oncology; personal fees and non-financial support from Penn State University, non-financial support from Mumbai Hematology Group, German AML Cooperative Group, and Emirates Hematology Society; personal fees and non-financial support from INDY Hematology Review-St. Vincent{\textquoteright}s Hospital, personal fees from Targeted Oncology, personal fees and non-financial support from Vanderbilt University, ASCO Direct Highlights, New Orleans Summer Cancer Meeting, Mayo Clinic, UC Davis; personal fees from FDNY, NCCN, MCI Summit of the Americas, non-financial support from Rambam Medical Center Israel, and Miami Leukemia Symposium University of Miami outside the submitted work. H.F. Fernandez reports personal fees from Incyte and Jazz Pharmaceuticals outside the submitted work. G.S. Vassiliou reports personal fees from AstraZeneca and STRM.BIO outside the submitted work. G.A. Challen reports grants from NIH and grants from LLS during the conduct of the study, and personal fees for consulting for Incyte, but not relevant to the work presented in this study. No disclosures were reported by the other authors. Funding Information: This work was funded by the NIH/NCI 1R01CA244044, 1R01CA247707, 2R01CA186238, 1R01CA237286, the Leukemia and Lymphoma Society Translational Research Program award 6565–19, the grant from When Everyone Survives Foundation (to T. Skorski) and by NIH/NIDDK 1R01DK102428 and R01HL147978 (to G.A. Challen). N. Johnson was supported by R01CA214799 and I. Tempera was supported by R01GM124449. This study was conducted in part by the ECOG-ACRIN Cancer Research Group supported by the NCI/NIH U10CA180820, UG1CA189859, UG1CA233290, and UG1CA232760. P. Valent was supported by the Austrian Science Fund (FWF), grants F4701-B20 and F4704-B20. B.V. Le has been supported by the European Union{\textquoteright}s Horizon 2020 Research and Innovation Program under the Marie Sklodowska-Curie grant agreement no 665735 and by the funding from Polish Ministry of Science and Higher Education funds for the implementation of international projects, 2016–2020 (to K. Piwocka). K. Sullivan-Reed was supported by T32CA009009035–43 from NIH. G.A. Challen is a scholar of the Leukemia and Lymphoma Society. The authors thank Dr. Scott Kauffman (Mayo Clinic, Rochester, MN) for providing AML primary cells, Dr. Ross Levine (Memorial Sloan Kettering Cancer Center, New York, NY) for providing Flt3m/m; Wt1+/−and Flt3m/m;Wt1+/+bone marrow cells and Dr. Jaroslav Jelinek for assistance in bioinformatics analyses. Funding Information: This work was funded by the NIH/NCI 1R01CA244044, 1R01CA247707, 2R01CA186238, 1R01CA237286, the Leukemia and Lymphoma Society Translational Research Program award 6565?19, the grant from When Everyone Survives Foundation (to T. Skorski) and by NIH/NIDDK 1R01DK102428 and R01HL147978 (to G.A. Challen). N. Johnson was supported by R01CA214799 and I. Tempera was supported by R01GM124449. This study was conducted in part by the ECOG-ACRIN Cancer Research Group supported by the NCI/NIH U10CA180820, UG1CA189859, UG1CA233290, and UG1CA232760. P. Valent was supported by the Austrian Science Fund (FWF), grants F4701-B20 and F4704-B20. B.V. Le has been supported by the European Union?s Horizon 2020 Research and Innovation Program under the Marie Sklodowska-Curie grant agreement no 665735 and by the funding from Polish Ministry of Science and Higher Education funds for the implementation of international projects, 2016?2020 (to K. Piwocka). K. Sullivan-Reed was supported by T32CA009009035?43 from NIH. G.A. Challen is a scholar of the Leukemia and Lymphoma Society. The authors thank Dr. Scott Kauffman (Mayo Clinic, Rochester, MN) for providing AML primary cells, Dr. Ross Levine (Memorial Sloan Kettering Cancer Center, New York, NY) for providing Flt3m/m; Wt1+/- and Flt3m/m;Wt1+/+ bone marrow cells and Dr. Jaroslav Jelinek for assistance in bioinformatics analyses. Publisher Copyright: {\textcopyright} 2021 American Association for Cancer Research",

year = "2021",

month = oct,

day = "1",

doi = "10.1158/0008-5472.CAN-20-3761",

language = "English (US)",

volume = "81",

pages = "5089--5101",

journal = "Cancer Research",

issn = "0008-5472",

number = "19",

}

TY - JOUR

T1 - TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors

AU - Maifrede, Silvia

AU - Le, Bac Viet

AU - Nieborowska-Skorska, Margaret

AU - Golovine, Konstantin

AU - Sullivan-Reed, Katherine

AU - Dunuwille, Wangisa M.B.

AU - Nacson, Joseph

AU - Hulse, Michael

AU - Keith, Kelsey

AU - Madzo, Jozef

AU - Caruso, Lisa Beatrice

AU - Gazze, Zachary

AU - Lian, Zhaorui

AU - Padella, Antonella

AU - Chitrala, Kumaraswamy N.

AU - Bartholdy, Boris A.

AU - Matlawska-Wasowska, Ksenia

AU - Marcantonio, Daniela Di

AU - Simonetti, Giorgia

AU - Greiner, Georg

AU - Sykes, Stephen M.

AU - Valent, Peter

AU - Paietta, Elisabeth M.

AU - Tallman, Martin S.

AU - Fernandez, Hugo F.

AU - Litzow, Mark R.

AU - Minden, Mark D.

AU - Huang, Jian

AU - Martinelli, Giovanni

AU - Vassiliou, George S.

AU - Tempera, Italo

AU - Piwocka, Katarzyna

AU - Johnson, Neil

AU - Challen, Grant A.

AU - Skorski, Tomasz

N1 - Funding Information: P. Valent reports personal fees from Celgene-BMS, Novartis, Blueprint, and Thermofisher, as well as grants and personal fees from Pfizer, and personal fees from AOP Orphan Pharmaceuticals outside the submitted work. M.S. Tallman reports grants from AbbVie, Orsenix, Biosight, Glycomimetics, Rafael Pharmaceuticals, Amgen, and other support from AbbVie, Daiichi-Sankyo, Orsenix, Rigel, Delta Fly Pharma, Tetraphase, Onzolyze, Jazz Pharmaceuticals, Roche, Biosight, Novartis, Innate Pharma, Kura, Syros Pharmaceuticals, and UpToDate; personal fees and nonfinancial support from EHA Congress Medscape Live Symposium and ASH CRTI Workshop, non-financial support from Hammeresmith Hospital, Britanico Hospital, and personal fees from PIME Oncology; personal fees and non-financial support from Penn State University, non-financial support from Mumbai Hematology Group, German AML Cooperative Group, and Emirates Hematology Society; personal fees and non-financial support from INDY Hematology Review-St. Vincent’s Hospital, personal fees from Targeted Oncology, personal fees and non-financial support from Vanderbilt University, ASCO Direct Highlights, New Orleans Summer Cancer Meeting, Mayo Clinic, UC Davis; personal fees from FDNY, NCCN, MCI Summit of the Americas, non-financial support from Rambam Medical Center Israel, and Miami Leukemia Symposium University of Miami outside the submitted work. H.F. Fernandez reports personal fees from Incyte and Jazz Pharmaceuticals outside the submitted work. G.S. Vassiliou reports personal fees from AstraZeneca and STRM.BIO outside the submitted work. G.A. Challen reports grants from NIH and grants from LLS during the conduct of the study, and personal fees for consulting for Incyte, but not relevant to the work presented in this study. No disclosures were reported by the other authors. Funding Information: This work was funded by the NIH/NCI 1R01CA244044, 1R01CA247707, 2R01CA186238, 1R01CA237286, the Leukemia and Lymphoma Society Translational Research Program award 6565–19, the grant from When Everyone Survives Foundation (to T. Skorski) and by NIH/NIDDK 1R01DK102428 and R01HL147978 (to G.A. Challen). N. Johnson was supported by R01CA214799 and I. Tempera was supported by R01GM124449. This study was conducted in part by the ECOG-ACRIN Cancer Research Group supported by the NCI/NIH U10CA180820, UG1CA189859, UG1CA233290, and UG1CA232760. P. Valent was supported by the Austrian Science Fund (FWF), grants F4701-B20 and F4704-B20. B.V. Le has been supported by the European Union’s Horizon 2020 Research and Innovation Program under the Marie Sklodowska-Curie grant agreement no 665735 and by the funding from Polish Ministry of Science and Higher Education funds for the implementation of international projects, 2016–2020 (to K. Piwocka). K. Sullivan-Reed was supported by T32CA009009035–43 from NIH. G.A. Challen is a scholar of the Leukemia and Lymphoma Society. The authors thank Dr. Scott Kauffman (Mayo Clinic, Rochester, MN) for providing AML primary cells, Dr. Ross Levine (Memorial Sloan Kettering Cancer Center, New York, NY) for providing Flt3m/m; Wt1+/−and Flt3m/m;Wt1+/+bone marrow cells and Dr. Jaroslav Jelinek for assistance in bioinformatics analyses. Funding Information: This work was funded by the NIH/NCI 1R01CA244044, 1R01CA247707, 2R01CA186238, 1R01CA237286, the Leukemia and Lymphoma Society Translational Research Program award 6565?19, the grant from When Everyone Survives Foundation (to T. Skorski) and by NIH/NIDDK 1R01DK102428 and R01HL147978 (to G.A. Challen). N. Johnson was supported by R01CA214799 and I. Tempera was supported by R01GM124449. This study was conducted in part by the ECOG-ACRIN Cancer Research Group supported by the NCI/NIH U10CA180820, UG1CA189859, UG1CA233290, and UG1CA232760. P. Valent was supported by the Austrian Science Fund (FWF), grants F4701-B20 and F4704-B20. B.V. Le has been supported by the European Union?s Horizon 2020 Research and Innovation Program under the Marie Sklodowska-Curie grant agreement no 665735 and by the funding from Polish Ministry of Science and Higher Education funds for the implementation of international projects, 2016?2020 (to K. Piwocka). K. Sullivan-Reed was supported by T32CA009009035?43 from NIH. G.A. Challen is a scholar of the Leukemia and Lymphoma Society. The authors thank Dr. Scott Kauffman (Mayo Clinic, Rochester, MN) for providing AML primary cells, Dr. Ross Levine (Memorial Sloan Kettering Cancer Center, New York, NY) for providing Flt3m/m; Wt1+/- and Flt3m/m;Wt1+/+ bone marrow cells and Dr. Jaroslav Jelinek for assistance in bioinformatics analyses. Publisher Copyright: © 2021 American Association for Cancer Research

PY - 2021/10/1

Y1 - 2021/10/1

N2 - Somatic variants in TET2 and DNMT3A are founding mutations in hematological malignancies that affect the epigenetic regulation of DNA methylation. Mutations in both genes often co-occur with activating mutations in genes encoding oncogenic tyrosine kinases such as FLT3ITD, BCR-ABL1, JAK2V617F, and MPLW515L, or with mutations affecting related signaling pathways such as NRASG12D and CALRdel52. Here, we show that TET2 and DNMT3A mutations exert divergent roles in regulating DNA repair activities in leukemia cells expressing these oncogenes. Malignant TET2-deficient cells displayed downregulation of BRCA1 and LIG4, resulting in reduced activity of BRCA1/2-mediated homologous recombination (HR) and DNA-PK–mediated non-homologous end-joining (D-NHEJ), respectively. TET2-deficient cells relied on PARP1-mediated alternative NHEJ (Alt-NHEJ) for protection from the toxic effects of spontaneous and drug-induced DNA double-strand breaks. Conversely, DNMT3A-deficient cells favored HR/D-NHEJ owing to downregulation of PARP1 and reduction of Alt-NHEJ. Consequently, malignant TET2-deficient cells were sensitive to PARP inhibitor (PARPi) treatment in vitro and in vivo, whereas DNMT3Adeficient cells were resistant. Disruption of TET2 dioxygenase activity or TET2—Wilms’ tumor 1 (WT1)–binding ability was responsible for DNA repair defects and sensitivity to PARPi associated with TET2 deficiency. Moreover, mutation or deletion of WT1 mimicked the effect of TET2 mutation on DSB repair activity and sensitivity to PARPi. Collectively, these findings reveal that TET2 and WT1 mutations may serve as biomarkers of synthetic lethality triggered by PARPi, which should be explored therapeutically.

AB - Somatic variants in TET2 and DNMT3A are founding mutations in hematological malignancies that affect the epigenetic regulation of DNA methylation. Mutations in both genes often co-occur with activating mutations in genes encoding oncogenic tyrosine kinases such as FLT3ITD, BCR-ABL1, JAK2V617F, and MPLW515L, or with mutations affecting related signaling pathways such as NRASG12D and CALRdel52. Here, we show that TET2 and DNMT3A mutations exert divergent roles in regulating DNA repair activities in leukemia cells expressing these oncogenes. Malignant TET2-deficient cells displayed downregulation of BRCA1 and LIG4, resulting in reduced activity of BRCA1/2-mediated homologous recombination (HR) and DNA-PK–mediated non-homologous end-joining (D-NHEJ), respectively. TET2-deficient cells relied on PARP1-mediated alternative NHEJ (Alt-NHEJ) for protection from the toxic effects of spontaneous and drug-induced DNA double-strand breaks. Conversely, DNMT3A-deficient cells favored HR/D-NHEJ owing to downregulation of PARP1 and reduction of Alt-NHEJ. Consequently, malignant TET2-deficient cells were sensitive to PARP inhibitor (PARPi) treatment in vitro and in vivo, whereas DNMT3Adeficient cells were resistant. Disruption of TET2 dioxygenase activity or TET2—Wilms’ tumor 1 (WT1)–binding ability was responsible for DNA repair defects and sensitivity to PARPi associated with TET2 deficiency. Moreover, mutation or deletion of WT1 mimicked the effect of TET2 mutation on DSB repair activity and sensitivity to PARPi. Collectively, these findings reveal that TET2 and WT1 mutations may serve as biomarkers of synthetic lethality triggered by PARPi, which should be explored therapeutically.

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UR - http://www.scopus.com/inward/citedby.url?scp=85116975591&partnerID=8YFLogxK

U2 - 10.1158/0008-5472.CAN-20-3761

DO - 10.1158/0008-5472.CAN-20-3761

M3 - Article

C2 - 34215619

AN - SCOPUS:85116975591

SN - 0008-5472

VL - 81

SP - 5089

EP - 5101

JO - Cancer Research

JF - Cancer Research

IS - 19

ER -

TET2 and DNMT3A mutations exert divergent effects on DNA repair and sensitivity of leukemia cells to PARP inhibitors

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