TP53 mutation status divides myelodysplastic syndromes with complex karyotypes into distinct prognostic subgroups

for the International Working Group for MDS Molecular Prognostic Committee

doi:10.1038/s41375-018-0351-2

TP53 mutation status divides myelodysplastic syndromes with complex karyotypes into distinct prognostic subgroups

for the International Working Group for MDS Molecular Prognostic Committee

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106 Scopus citations

Abstract

Risk stratification is critical in the care of patients with myelodysplastic syndromes (MDS). Approximately 10% have a complex karyotype (CK), defined as more than two cytogenetic abnormalities, which is a highly adverse prognostic marker. However, CK-MDS can carry a wide range of chromosomal abnormalities and somatic mutations. To refine risk stratification of CK-MDS patients, we examined data from 359 CK-MDS patients shared by the International Working Group for MDS. Mutations were underrepresented with the exception of TP53 mutations, identified in 55% of patients. TP53 mutated patients had even fewer co-mutated genes but were enriched for the del(5q) chromosomal abnormality (p < 0.005), monosomal karyotype (p < 0.001), and high complexity, defined as more than 4 cytogenetic abnormalities (p < 0.001). Monosomal karyotype, high complexity, and TP53 mutation were individually associated with shorter overall survival, but monosomal status was not significant in a multivariable model. Multivariable survival modeling identified severe anemia (hemoglobin < 8.0 g/dL), NRAS mutation, SF3B1 mutation, TP53 mutation, elevated blast percentage (>10%), abnormal 3q, abnormal 9, and monosomy 7 as having the greatest survival risk. The poor risk associated with CK-MDS is driven by its association with prognostically adverse TP53 mutations and can be refined by considering clinical and karyotype features.

Original language	English
Pages (from-to)	1747-1758
Number of pages	12
Journal	Leukemia
Volume	33
Issue number	7
DOIs	https://doi.org/10.1038/s41375-018-0351-2
State	Published - Jul 1 2019

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@article{db419dc66bf846f6aa74f327de37cc27,

title = " TP53 mutation status divides myelodysplastic syndromes with complex karyotypes into distinct prognostic subgroups",

abstract = "Risk stratification is critical in the care of patients with myelodysplastic syndromes (MDS). Approximately 10% have a complex karyotype (CK), defined as more than two cytogenetic abnormalities, which is a highly adverse prognostic marker. However, CK-MDS can carry a wide range of chromosomal abnormalities and somatic mutations. To refine risk stratification of CK-MDS patients, we examined data from 359 CK-MDS patients shared by the International Working Group for MDS. Mutations were underrepresented with the exception of TP53 mutations, identified in 55% of patients. TP53 mutated patients had even fewer co-mutated genes but were enriched for the del(5q) chromosomal abnormality (p < 0.005), monosomal karyotype (p < 0.001), and high complexity, defined as more than 4 cytogenetic abnormalities (p < 0.001). Monosomal karyotype, high complexity, and TP53 mutation were individually associated with shorter overall survival, but monosomal status was not significant in a multivariable model. Multivariable survival modeling identified severe anemia (hemoglobin < 8.0 g/dL), NRAS mutation, SF3B1 mutation, TP53 mutation, elevated blast percentage (>10%), abnormal 3q, abnormal 9, and monosomy 7 as having the greatest survival risk. The poor risk associated with CK-MDS is driven by its association with prognostically adverse TP53 mutations and can be refined by considering clinical and karyotype features.",

author = "{for the International Working Group for MDS Molecular Prognostic Committee} and Detlef Haase and Stevenson, {Kristen E.} and Donna Neuberg and Maciejewski, {Jaroslaw P.} and Aziz Nazha and Sekeres, {Mikkael A.} and Ebert, {Benjamin L.} and Guillermo Garcia-Manero and Claudia Haferlach and Torsten Haferlach and Wolfgang Kern and Seishi Ogawa and Yasunobu Nagata and Kenichi Yoshida and Graubert, {Timothy A.} and Walter, {Matthew J.} and List, {Alan F.} and Komrokji, {Rami S.} and Eric Padron and David Sallman and Elli Papaemmanuil and Campbell, {Peter J.} and Savona, {Michael R.} and Adam Seegmiller and Lionel Ad{\`e}s and Pierre Fenaux and Shih, {Lee Yung} and David Bowen and Groves, {Michael J.} and Sudhir Tauro and Michaela Fontenay and Olivier Kosmider and Michal Bar-Natan and David Steensma and Richard Stone and Michael Heuser and Felicitas Thol and Mario Cazzola and Luca Malcovati and Aly Karsan and Christina Ganster and Eva Hellstr{\"o}m-Lindberg and Jacqueline Boultwood and Andrea Pellagatti and Valeria Santini and Lynn Quek and Paresh Vyas and Heinz T{\"u}chler and Greenberg, {Peter L.} and Rafael Bejar",

note = "Funding Information: Conflict of interest RB has served as a consultant for Genoptix and Celgene and served on advisory boards for Otsuka/Astex, AbbVie/ Genetech, and Celgene and has received research funding from Cel-gene and Takeda. DH has served as consultant and advisory board member for Celgene and Novartis from both of which he has received research funding. PV receives research funding from Celgene and has been on advisory boards for Celgene, Pfizer, Novartis, Jazz, Daiichi Sanko. LQ receives research funding from Celgene. MAS has served on an advisory board for Celgene. MRE reports consultancy and research funding from Astex, Incyte, Karyopharm, Sunesis, Takeda, and TG Therapeutics; equity in Karyopharm; and DSMB membership for Celgene and Gilead. TH, CH, and WK report partial ownership of MLL–Munich Leukemia Laboratory. All other authors declare that they have no conflict of interest. Funding Information: Acknowledgements We would like to thank the MDS Foundation for their support of the International Working Group for MDS and Celgene for funding the efforts of the IWG-prognosis molecular subcommittee and this study. RB was additionally supported by K08 DK091360. PV acknowledges funding from the MRC Disease Team Awards (G1000729/94931 and MR/L008963/1) MRC Molecular Haematology Unit and the Oxford Partnership Comprehensive Biomedical Research Centre (NIHR BRC Funding scheme. oxfbrc-2012–1). LQ is funded by an MRC Clinician Scientist Fellowship. JB and AP acknowledge funding from Bloodwise (UK). LM acknowledges funding from Associazione Italiana per la Ricerca sul Cancro (AIRC, Individual Grant 20125). MH acknowledges funding from DFG grant HE 5240/6–1. In addition, we would like to thank the following for their help with this study: Jin Shao from Washington University in St. Louis, USA; Professor Mathilde Hunault-Berger from CHU Angers, France; Professor Norbert Vey from Institut Paoli Calmettes, Marseille, France; Michael Byrne, P Brent Ferrell, David R Head, Ridas Juskevicius, Carrie Kitko, Emily F Mason, Sanjay R Mohan, Claudio A Mosse, Tamara K Moyo, Aaron C Shaver, Andrew L Sochacki, and Stephen A Strickland from Vanderbilt University. Publisher Copyright: {\textcopyright} 2019, The Author(s).",

year = "2019",

month = jul,

day = "1",

doi = "10.1038/s41375-018-0351-2",

language = "English",

volume = "33",

pages = "1747--1758",

journal = "Leukemia",

issn = "0887-6924",

number = "7",

}

TY - JOUR

T1 - TP53 mutation status divides myelodysplastic syndromes with complex karyotypes into distinct prognostic subgroups

AU - for the International Working Group for MDS Molecular Prognostic Committee

AU - Haase, Detlef

AU - Stevenson, Kristen E.

AU - Neuberg, Donna

AU - Maciejewski, Jaroslaw P.

AU - Nazha, Aziz

AU - Sekeres, Mikkael A.

AU - Ebert, Benjamin L.

AU - Garcia-Manero, Guillermo

AU - Haferlach, Claudia

AU - Haferlach, Torsten

AU - Kern, Wolfgang

AU - Ogawa, Seishi

AU - Nagata, Yasunobu

AU - Yoshida, Kenichi

AU - Graubert, Timothy A.

AU - Walter, Matthew J.

AU - List, Alan F.

AU - Komrokji, Rami S.

AU - Padron, Eric

AU - Sallman, David

AU - Papaemmanuil, Elli

AU - Campbell, Peter J.

AU - Savona, Michael R.

AU - Seegmiller, Adam

AU - Adès, Lionel

AU - Fenaux, Pierre

AU - Shih, Lee Yung

AU - Bowen, David

AU - Groves, Michael J.

AU - Tauro, Sudhir

AU - Fontenay, Michaela

AU - Kosmider, Olivier

AU - Bar-Natan, Michal

AU - Steensma, David

AU - Stone, Richard

AU - Heuser, Michael

AU - Thol, Felicitas

AU - Cazzola, Mario

AU - Malcovati, Luca

AU - Karsan, Aly

AU - Ganster, Christina

AU - Hellström-Lindberg, Eva

AU - Boultwood, Jacqueline

AU - Pellagatti, Andrea

AU - Santini, Valeria

AU - Quek, Lynn

AU - Vyas, Paresh

AU - Tüchler, Heinz

AU - Greenberg, Peter L.

AU - Bejar, Rafael

N1 - Funding Information: Conflict of interest RB has served as a consultant for Genoptix and Celgene and served on advisory boards for Otsuka/Astex, AbbVie/ Genetech, and Celgene and has received research funding from Cel-gene and Takeda. DH has served as consultant and advisory board member for Celgene and Novartis from both of which he has received research funding. PV receives research funding from Celgene and has been on advisory boards for Celgene, Pfizer, Novartis, Jazz, Daiichi Sanko. LQ receives research funding from Celgene. MAS has served on an advisory board for Celgene. MRE reports consultancy and research funding from Astex, Incyte, Karyopharm, Sunesis, Takeda, and TG Therapeutics; equity in Karyopharm; and DSMB membership for Celgene and Gilead. TH, CH, and WK report partial ownership of MLL–Munich Leukemia Laboratory. All other authors declare that they have no conflict of interest. Funding Information: Acknowledgements We would like to thank the MDS Foundation for their support of the International Working Group for MDS and Celgene for funding the efforts of the IWG-prognosis molecular subcommittee and this study. RB was additionally supported by K08 DK091360. PV acknowledges funding from the MRC Disease Team Awards (G1000729/94931 and MR/L008963/1) MRC Molecular Haematology Unit and the Oxford Partnership Comprehensive Biomedical Research Centre (NIHR BRC Funding scheme. oxfbrc-2012–1). LQ is funded by an MRC Clinician Scientist Fellowship. JB and AP acknowledge funding from Bloodwise (UK). LM acknowledges funding from Associazione Italiana per la Ricerca sul Cancro (AIRC, Individual Grant 20125). MH acknowledges funding from DFG grant HE 5240/6–1. In addition, we would like to thank the following for their help with this study: Jin Shao from Washington University in St. Louis, USA; Professor Mathilde Hunault-Berger from CHU Angers, France; Professor Norbert Vey from Institut Paoli Calmettes, Marseille, France; Michael Byrne, P Brent Ferrell, David R Head, Ridas Juskevicius, Carrie Kitko, Emily F Mason, Sanjay R Mohan, Claudio A Mosse, Tamara K Moyo, Aaron C Shaver, Andrew L Sochacki, and Stephen A Strickland from Vanderbilt University. Publisher Copyright: © 2019, The Author(s).

PY - 2019/7/1

Y1 - 2019/7/1

N2 - Risk stratification is critical in the care of patients with myelodysplastic syndromes (MDS). Approximately 10% have a complex karyotype (CK), defined as more than two cytogenetic abnormalities, which is a highly adverse prognostic marker. However, CK-MDS can carry a wide range of chromosomal abnormalities and somatic mutations. To refine risk stratification of CK-MDS patients, we examined data from 359 CK-MDS patients shared by the International Working Group for MDS. Mutations were underrepresented with the exception of TP53 mutations, identified in 55% of patients. TP53 mutated patients had even fewer co-mutated genes but were enriched for the del(5q) chromosomal abnormality (p < 0.005), monosomal karyotype (p < 0.001), and high complexity, defined as more than 4 cytogenetic abnormalities (p < 0.001). Monosomal karyotype, high complexity, and TP53 mutation were individually associated with shorter overall survival, but monosomal status was not significant in a multivariable model. Multivariable survival modeling identified severe anemia (hemoglobin < 8.0 g/dL), NRAS mutation, SF3B1 mutation, TP53 mutation, elevated blast percentage (>10%), abnormal 3q, abnormal 9, and monosomy 7 as having the greatest survival risk. The poor risk associated with CK-MDS is driven by its association with prognostically adverse TP53 mutations and can be refined by considering clinical and karyotype features.

AB - Risk stratification is critical in the care of patients with myelodysplastic syndromes (MDS). Approximately 10% have a complex karyotype (CK), defined as more than two cytogenetic abnormalities, which is a highly adverse prognostic marker. However, CK-MDS can carry a wide range of chromosomal abnormalities and somatic mutations. To refine risk stratification of CK-MDS patients, we examined data from 359 CK-MDS patients shared by the International Working Group for MDS. Mutations were underrepresented with the exception of TP53 mutations, identified in 55% of patients. TP53 mutated patients had even fewer co-mutated genes but were enriched for the del(5q) chromosomal abnormality (p < 0.005), monosomal karyotype (p < 0.001), and high complexity, defined as more than 4 cytogenetic abnormalities (p < 0.001). Monosomal karyotype, high complexity, and TP53 mutation were individually associated with shorter overall survival, but monosomal status was not significant in a multivariable model. Multivariable survival modeling identified severe anemia (hemoglobin < 8.0 g/dL), NRAS mutation, SF3B1 mutation, TP53 mutation, elevated blast percentage (>10%), abnormal 3q, abnormal 9, and monosomy 7 as having the greatest survival risk. The poor risk associated with CK-MDS is driven by its association with prognostically adverse TP53 mutations and can be refined by considering clinical and karyotype features.

UR - http://www.scopus.com/inward/record.url?scp=85059915986&partnerID=8YFLogxK

U2 - 10.1038/s41375-018-0351-2

DO - 10.1038/s41375-018-0351-2

M3 - Article

C2 - 30635634

AN - SCOPUS:85059915986

SN - 0887-6924

VL - 33

SP - 1747

EP - 1758

JO - Leukemia

JF - Leukemia

IS - 7

ER -

TP53 mutation status divides myelodysplastic syndromes with complex karyotypes into distinct prognostic subgroups

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