TY - JOUR
T1 - Genomic complexity and dynamics of clonal evolution in childhood acute myeloid leukemia studied with whole-exome sequencing
AU - Masetti, Riccardo
AU - Castelli, Ilaria
AU - Astolfi, Annalisa
AU - Bertuccio, Salvatore Nicola
AU - Indio, Valentina
AU - Togni, Marco
AU - Belotti, Tamara
AU - Serravalle, Salvatore
AU - Tarantino, Giuseppe
AU - Zecca, Marco
AU - Pigazzi, Martina
AU - Basso, Giuseppe
AU - Pession, Andrea
AU - Locatelli, Franco
PY - 2016
Y1 - 2016
N2 - Despite significant improvement in treatment of childhood acute myeloid leukemia (AML), 30% of patients experience disease recurrence, which is still the major cause of treatment failure and death in these patients. To investigate molecular mechanisms underlying relapse, we performed whole-exome sequencing of diagnosis-relapse pairs and matched remission samples from 4 pediatric AML patients without recurrent cytogenetic alterations. Candidate driver mutations were selected for targeted deep sequencing at high coverage, suitable to detect small subclones (0.12%). BiCEBPa mutation was found to be stable and highly penetrant, representing a separate biological and clinical entity, unlike WT1 mutations, which were extremely unstable. Among the mutational patterns underlying relapse, we detected the acquisition of proliferative advantage by signaling activation (PTPN11 and FLT3-TKD mutations) and the increased resistance to apoptosis (hyperactivation of TYK2). We also found a previously undescribed feature of AML, consisting of a hypermutator phenotype caused by SETD2 inactivation. The consequent accumulation of new mutations promotes the adaptability of the leukemia, contributing to clonal selection. We report a novel ASXL3 mutation characterizing a very small subclone (<1%) present at diagnosis and undergoing expansion (60%) at relapse. Taken together, these findings provide molecular clues for designing optimal therapeutic strategies, in terms of target selection, adequate schedule design and reliable response-monitoring techniques.
AB - Despite significant improvement in treatment of childhood acute myeloid leukemia (AML), 30% of patients experience disease recurrence, which is still the major cause of treatment failure and death in these patients. To investigate molecular mechanisms underlying relapse, we performed whole-exome sequencing of diagnosis-relapse pairs and matched remission samples from 4 pediatric AML patients without recurrent cytogenetic alterations. Candidate driver mutations were selected for targeted deep sequencing at high coverage, suitable to detect small subclones (0.12%). BiCEBPa mutation was found to be stable and highly penetrant, representing a separate biological and clinical entity, unlike WT1 mutations, which were extremely unstable. Among the mutational patterns underlying relapse, we detected the acquisition of proliferative advantage by signaling activation (PTPN11 and FLT3-TKD mutations) and the increased resistance to apoptosis (hyperactivation of TYK2). We also found a previously undescribed feature of AML, consisting of a hypermutator phenotype caused by SETD2 inactivation. The consequent accumulation of new mutations promotes the adaptability of the leukemia, contributing to clonal selection. We report a novel ASXL3 mutation characterizing a very small subclone (<1%) present at diagnosis and undergoing expansion (60%) at relapse. Taken together, these findings provide molecular clues for designing optimal therapeutic strategies, in terms of target selection, adequate schedule design and reliable response-monitoring techniques.
KW - Acute myeloid leukemia relapse
KW - FLT3-TKD mutation
KW - Whole-exome massively parallel sequencing
KW - SETD2 mutation
KW - Pediatric acute myeloid leukemia
KW - Acute myeloid leukemia relapse
KW - FLT3-TKD mutation
KW - Whole-exome massively parallel sequencing
KW - SETD2 mutation
KW - Pediatric acute myeloid leukemia
UR - http://hdl.handle.net/10807/229622
U2 - 10.18632/oncotarget.10778
DO - 10.18632/oncotarget.10778
M3 - Article
SN - 1949-2553
VL - 7
SP - 56746
EP - 56757
JO - Oncotarget
JF - Oncotarget
ER -