The Molecular Landscape of Pediatric Acute Myeloid Leukemia Reveals Recurrent Structural Alterations and Age-specific Mutational Interactions

Overview

Journal Nat Med

Specialties General Medicine
Molecular Biology

Date 2017 Dec 12

PMID 29227476

Citations 402

Authors

Hamid Bolouri

Jason E Farrar

Timothy Triche Jr

Rhonda E Ries

Emilia L Lim

Todd A Alonzo

Yussanne Ma

Richard Moore

Andrew J Mungall

Marco A Marra

Jinghui Zhang

Xiaotu Ma

Yu Liu

Yanling Liu

Jaime M Guidry Auvil

Tanja M Davidsen

Patee Gesuwan

Leandro C Hermida

Bodour Salhia

Stephen Capone

Giridharan Ramsingh

Christian Michel Zwaan

Sanne Noort

Stephen R Piccolo

E Anders Kolb

Alan S Gamis

Malcolm A Smith

Daniela S Gerhard

Soheil Meshinchi

Affiliations

Soon will be listed here.

Abstract

We present the molecular landscape of pediatric acute myeloid leukemia (AML) and characterize nearly 1,000 participants in Children's Oncology Group (COG) AML trials. The COG-National Cancer Institute (NCI) TARGET AML initiative assessed cases by whole-genome, targeted DNA, mRNA and microRNA sequencing and CpG methylation profiling. Validated DNA variants corresponded to diverse, infrequent mutations, with fewer than 40 genes mutated in >2% of cases. In contrast, somatic structural variants, including new gene fusions and focal deletions of MBNL1, ZEB2 and ELF1, were disproportionately prevalent in young individuals as compared to adults. Conversely, mutations in DNMT3A and TP53, which were common in adults, were conspicuously absent from virtually all pediatric cases. New mutations in GATA2, FLT3 and CBL and recurrent mutations in MYC-ITD, NRAS, KRAS and WT1 were frequent in pediatric AML. Deletions, mutations and promoter DNA hypermethylation convergently impacted Wnt signaling, Polycomb repression, innate immune cell interactions and a cluster of zinc finger-encoding genes associated with KMT2A rearrangements. These results highlight the need for and facilitate the development of age-tailored targeted therapies for the treatment of pediatric AML.

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