Key Points• Somatic mutations alter nuclear distribution and association of CHD2 with actively transcribed genes in CLL.• CHD2 is the most frequently mutated CLL driver in the IGHV-mutated prognostic subgroup.Great progress has recently been achieved in the understanding of the genomic alterations driving chronic lymphocytic leukemia (CLL). Nevertheless, the specific molecular mechanisms governing chromatin remodeling in CLL are unknown. Here we report the genetic and functional characterization of somatic mutations affecting the chromatin remodeler CHD2, one of the most frequently mutated genes in CLL (5.3%) and in monoclonal B lymphocytosis (MBL, 7%), a B-cell expansion that can evolve to CLL. Most of the mutations affecting CHD2, identified by whole-exome sequencing of 456 CLL and 43 MBL patients, are either truncating or affect conserved residues in functional domains, thus supporting a putative role for CHD2 as a tumor suppressor gene. CHD2 mutants show altered nuclear distribution, and a chromodomain helicase DNA binding protein 2 (CHD2) mutant affected in its DNA-binding domain exhibits defective association with active chromatin. Clinicobiological analyses show that most CLL patients carrying CHD2 mutations also present mutated immunoglobulin heavy chain variable region genes (IGHVs), being the most frequently mutated gene in this prognostic subgroup. This is the first study providing functional evidence supporting CHD2 as a cancer driver and opens the way to further studies of the role of this chromatin remodeler in CLL. (Blood. 2015;126(2):195-202)
IntroductionChronic lymphocytic leukemia (CLL) is the most prevalent B-cell neoplasm in Western adults. CLL shows a remarkably heterogeneous course, with some patients presenting an indolent disease and normal life span, whereas others suffer from a dismal prognosis. [1][2][3] In general, disease outcome correlates with the immunoglobulin heavy chain variable region genes (IGHV) mutational status of tumor lymphocytes, 4,5 but also with other biological features including chromosomal aberrations and the expression of CLL-specific biomarkers. [5][6][7][8] Recently, whole-genome sequencing-based reports have uncovered NOTCH1, MYD88, and XPO1 as recurrently mutated CLL drivers.9 Additionally, whole-exome sequencing approaches have identified the splicing factor SF3B1 10-13 and the shelterin complex member POT1 14 as CLL drivers associated with unfavorable prognosis. Also, mutations in sucrose isomaltase have been proposed to play a role in the CLL leukemogenic metabolic switch. 15 Moreover, clonal evolution events in CLL have been delineated, pointing to the presence of subclonal driver mutations as a relevant prognostic factor in this disease.16 Notably, mutations in many of the previously described driver genes, as well as in BRAF, EGR2, and NFKBIE, can be detected in pluripotent hematopoietic progenitor cells, indicating that founding CLL mutations appear as very early evolutionary events.17 These genomic studies have been extended by comprehensive transc...
