Histone methyltransferases (HMTs) are important epigenetic regulators of gene transcription and have been found disrupted at the genomic level in a spectrum of human tumors including hematological malignancies. In CLL, recurring genomic lesions targeting chromatin modifiers are emerging in the literature (Puente 2015, Nature) but their biological and clinical significance remain uncertain. We studied 802 CLL patients, divided into a discovery [n=261, sampled pre-treatment] and two validation cohorts [n=541, 431 pre-treatment and 110 ultra-high risk], using high-resolution SNP-arrays [n=572, Affymetrix SNP6.0 and HumanOmniS-8] and high-throughput re-sequencing [n=320, Haloplex and TruSeq] to identify genomic lesions targeting HMT genes. In our discovery cohort, we identified nine novel regions of copy-number changes; the prime finding was a recurrent deletion of chromosome 3p in 4% of patients between genomic positions 47.12-47.36Mb. This region included SETD2, KIF9 and KLHL18 (Fig 1A), with SETD2 being the most significantly under-expressed gene (p=0.001) in 3p-deleted [n=6] versus non-deleted cases [n=8]. Further validation in two independent cohorts showed that SETD2 deletions were enriched in ultra high-risk CLL and associated with loss of TP53 (p=0.003), genomic complexity (in TP53 wild-type cases, p=0.01) and chromothripsis.

Next, we screened for somatic mutations in SETD2 using targeted re-sequencing and identified non-synonymous mutations in four (4.5%) discovery cases (p.D99G, p.W1306X, p.Q1545K, p.E1955Q), and 7/231 (3%) in the pre-treatment validation cases (p.A50T, p.P167L, p.E670K, p.M1742L, p.M1889T (x2), p.I2295M) (Fig 1B). Mutations were somatic in all samples tested [n=5]. To study the clonal nature of the SETD2 deletions, we assigned each genomic CNA with a relative copy-number by normalizing CNA intensity values from array features, and could infer that the 3p deletion was in the dominant clonal population in 14/21 cases with data available for analysis. Employing either the ABSOLUTE algorithm for our discovery cohort or manually correcting for tumor sample purity and local copy-number changes in our validation cohort, we observed that 10/11 SETD2 mutations exhibited a clonal cell fraction. These data strongly imply that SETD2 aberrations represent early clonal events in the pathobiology of CLL. Next, we extended our gene expression analysis to include additional wild-type, deleted, and mutated patients, showing reduced expression both in deleted and mutant cases (p=0.035), thus confirming haplo-insufficiency also for the SETD2-mutant cases. W e reviewed the DNA methylation status of the SETD2 gene body and promoter regions (15 & 9 CpG probes, respectively) from published data, and found no correlation between SETD2 methylation and RNA expression, suggesting that DNA methylation does not play a substantial role in regulating SETD2 expression in CLL.

Finally, we analyzed the impact of SETD2 lesions on treatment-free survival (TFS) and overall survival (OS). For TFS and OS, we observed a significantly worse outcome (TFS: 44 vs. 105 months; p=0.004, OS: 85 vs. 199 months; p=0.002) in SETD2 deleted cases that were wild-type for TP53/ATM, compared to cases wild type for TP53/ATM/SETD2 (Fig 1D). Mutant SETD2 cases (wild-type for TP53/ATM) and those wild-type for TP53/ATM/SETD2 exhibited median TFS of 74 and 106 months respectively, differences that did not reach significance (p=0.1). Whilst these data suggest that SETD2 lesions may be clinically relevant, further investigations in larger materials are warranted to understand their full impact on survival.

In conclusion, we report for the first time somatic deletions and mutations in SETD2, a gene found disrupted invarious human solid and hematological tumors, in ~7% of CLL patients requiring treatment. These are likely to be early clonal events and associate with TP53 dysfunction, genomic complexity and chromothripsis, with deletions enriched in ultra high-risk CLL.

Figure 1.

SETD2 lesions. A. SNP6.0 data for the del(3p) cases. B. Schematic diagram highlighting the prevalence and positioning of SETD2 mutations. C. Clonal cell fraction data for SETD2 and other gene mutations. D. Treatment-free survival (TFS).

Figure 1.

SETD2 lesions. A. SNP6.0 data for the del(3p) cases. B. Schematic diagram highlighting the prevalence and positioning of SETD2 mutations. C. Clonal cell fraction data for SETD2 and other gene mutations. D. Treatment-free survival (TFS).

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Disclosures

Tausch:Gilead: Other: Travel support. Steele:Portola Pharmaceuticals: Other: Travel bursary to ASH 2015; Janssen: Other: Travel bursary to EHA 2015. Hillmen:Janssen: Consultancy, Honoraria, Research Funding; GSK: Consultancy, Honoraria, Research Funding; Novartis: Honoraria, Research Funding; Roche: Consultancy, Honoraria, Research Funding; Celgene: Research Funding; Gilead: Consultancy, Honoraria, Research Funding; AbbVie: Consultancy, Honoraria, Research Funding. Dyer:Gilead: Research Funding; Roche Pharmaceuticals: Speakers Bureau; ONO Pharmaceuticals: Research Funding. Stilgenbauer:AbbVie, Amgen, Boehringer-Ingelheim, Celgene, Genentech, Genzyme, Gilead, GSK, Janssen, Mundipharma, Novartis, Pharmacyclics, Roche: Consultancy, Honoraria, Research Funding. Schuh:Acerta Pharma BV: Research Funding. Strefford:Roche: Research Funding.

Author notes

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Asterisk with author names denotes non-ASH members.

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