Relapsed acute lymphoblastic leukaemia (ALL) is a leading cause of death due to disease in young people, but the biologic determinants of treatment failure remain poorly understood. Recent genome-wide profiling of structural DNA alterations in ALL have identified multiple submicroscopic somatic mutations targeting key cellular pathways 1, 2, and have demonstrated substantial evolution in genetic alterations from diagnosis to relapse3. However, detailed analysis of sequence mutations in ALL has not been performed. To identify novel mutations in relapsed ALL, we resequenced 300 genes in matched diagnosis and relapse samples from 23 patients with ALL. This identified 52 somatic non-synonymous mutations in 32 genes, many of which were novel, including the transcriptional coactivators CREBBP and NCOR1, the transcription factors ERG, SPI1, TCF4 and TCF7L2, components of the Ras signalling pathway, histone genes, genes involved in histone modification (CREBBP and CTCF), and genes previously shown to be targets of recurring DNA copy number alteration in ALL. Analysis of an extended cohort of 71 diagnosisrelapse cases and 270 acute leukaemia cases that did not relapse found that 18.3% of relapse cases had sequence or deletion mutations of CREBBP, which encodes the transcriptional coactivator and histone acetyltransferase (HAT) CREB-binding protein (CBP) 4 . The mutations were either present
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Author ManuscriptNature. Author manuscript; available in PMC 2011 September 10. at diagnosis or acquired at relapse, and resulted in truncated alleles or deleterious substitutions in conserved residues of the HAT domain. Functionally, the mutations impaired histone acetylation and transcriptional regulation of CREBBP targets, including glucocorticoid responsive genes. Several mutations acquired at relapse were detected in subclones at diagnosis, suggesting that the mutations may confer resistance to therapy. These results extend the landscape of genetic alterations in leukaemia, and identify mutations targeting transcriptional and epigenetic regulation as a mechanism of resistance in ALL.Acute lymphoblastic leukaemia (ALL) is the commonest childhood malignancy 5 , and is a leading cause of cancer-related death in young people. Several structural chromosomal alterations in ALL, including rearrangement of MLL and the Philadelphia chromosome 6 are associated with a high risk of treatment failure and relapse. However, many ALL cases that fail therapy lack these alterations, and the biologic basis of treatment failure in these cases is poorly understood. Genome-wide profiling of ALL has identified multiple recurring submicroscopic genetic alterations targeting lymphoid development, cell cycle regulation, tumour suppression and apoptosis 1,2 , and has identified genetic alterations that predict a high risk of relapse, including deletion of IKZF1 (IKAROS) 7, 8. Moreover, profiling of structural DNA alterations in matched diagnosis and relapse samples has demonstrated that in the majority of cases there are substant...
