Abstract
Sézary syndrome (SS) is an aggressive leukaemia of mature T cells with poor prognosis and limited options for targeted therapies. The comprehensive genetic alterations underlying the pathogenesis of SS are unknown. Here we integrate whole-genome sequencing (n=6), whole-exome sequencing (n=66) and array comparative genomic hybridization-based copy-number analysis (n=80) of primary SS samples. We identify previously unknown recurrent loss-of-function aberrations targeting members of the chromatin remodelling/histone modification and trithorax families, including ARID1A in which functional loss from nonsense and frameshift mutations and/or targeted deletions is observed in 40.3% of SS genomes. We also identify recurrent gain-of-function mutations targeting PLCG1 (9%) and JAK1, JAK3, STAT3 and STAT5B (JAK/STAT total ∼11%). Functional studies reveal sensitivity of JAK1-mutated primary SS cells to JAK inhibitor treatment. These results highlight the complex genomic landscape of SS and a role for inhibition of JAK/STAT pathways for the treatment of SS.
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Introduction
Sézary syndrome (SS) is an aggressive mature T-cell leukaemia with a median 5-year survival rate of <20% (refs 1, 2). The skin is almost always affected, whereas in advanced forms of SS lymph nodes and other visceral organs can be involved3. Therapy often involves extracorporeal ultraviolet phototherapy and single-agent cytotoxic chemotherapeutic agents such as methotrexate4. However, despite aggressive therapies, initial response rates are poor and disease recurrence is common5.
To date, efforts to identify genes recurrently targeted by mutation in SS genomes have been largely targeted6,7,8, or otherwise limited to a few index samples9,10. The comprehensive genomic landscape of SS has not been explored and opportunities for targeted therapies based on specific genetic mutations have not been fully exploited. To gain insights into the genetic alterations underlying the pathogenesis of SS, we integrated whole-genome sequencing (WGS) and whole-exome sequencing (WES) in combination with high-resolution copy-number variant (CNV) analysis on a large cohort of well-characterized cases of SS. Our studies reveal recurrent mutations targeting epigenetic modifiers and JAK–STAT pathway in SS.
Results
WGS reveals genomic complexity of SS
To obtain a genome-wide view of the molecular genetic alterations underlying SS at a nucleotide resolution level, we performed WGS of highly enriched (>90%) pure tumour cells from six cases that fulfilled established diagnostic criteria including characteristic cytologic, immunophenotypic and karyotypic features3. The data highlight the structural genomic complexity of SS (Fig. 1; comprehensive structural alteration data from WGS can be found in Supplementary Data 1). This analysis revealed a total of 1,010 inter- or intrachromosomal translocations in the six SS genomes (average 168±43 translocations per genome). No recurrent translocations or gene fusions were identified in these six SS cases. However, among 42 potential fusion genes (Supplementary Data 2), several noteworthy candidates were identified that may contribute to SS disease pathogenesis in selected cases.
Novel translocations identified in SS included juxtaposition of the N terminal of receptor tyrosine kinase TPR and the C terminal of hepatocyte growth factor receptor MET previously identified to be oncogenic in gastric cancers11; the N terminus of v-myb avian myeloblastosis viral oncogene homologue-like 1 MYBL1 fused with the C terminal of thymocyte high-mobility group box protein of TOX previously implicated in the pathogenesis of mycosis fungoides/SS12; and the N terminus of the Hsp40 homologue DNAJC15 and the C terminus of zinc-finger protein ZMYM2 involved in the translocation t(8;13)(p11;q12), which fuses FGFR1 with ZMYM2 associated with 8p11 myeloproliferative disorders13. Other noteworthy translocations separately targeted the MEIS1 homeobox gene previously implicated in leukemogenesis14,15, the transcription factor IKZF2, and the serine–threonine kinase VRK2 (Supplementary Data 2). WGS also revealed a novel reciprocal translocation event involving chromosomes 3 and 10 leading to interruption of coding elements of CBLB between exons 13 and 14 by insertion of the coding elements of ZEB1 beginning at exon 2. This translocation is predicted to result in a fusion gene composed of the N-terminal portion of CBLB (residues 1–653 including CBL-PTB, UBA, RING EF-hand and SH2 domains) with the entire protein structure (including all seven zinc-fingers and DNA-binding domains) of ZEB1, a zinc-finger negative transcriptional regulator of interleukin-2-stimulated cytokine signalling in T cells16. Also of note, a translocation event involving elements of the histone-lysine N-methyltransferase EZH2 on chromosome 7 juxtaposed to elements upstream of the forkhead box protein FOXP1 on chromosome 3 was observed in one SS genome. In addition to the large structural variations, WGS analyses revealed recurrent aneuploidies in SS genomes including trisomy 8 (1/6 cases) and monosomy 10 (2/6); and loss of 17p and/or isochromosome 17 (5/6). Interestingly, losses of chromosome 1p, reported to be recurrently deleted in several aCGH studies17,18,19,20,21,22, were identified in 4/6 genomes with a narrowly restricted region spanning 1p36.21-1p35.3. To date, no candidate gene within this region has been identified and implicated in SS pathogenesis.
CNV and WES analyses reveal recurrent loss-of-function loci
To identify regions of recurrent gain or loss at high resolution and thereby define genes targeted by numerical aberrations, we performed high-resolution aCGH on a total of 80 SS samples (Supplementary Fig. 1). This analysis revealed a number of recurrent gains (Supplementary Fig. 2) and losses (Supplementary Fig. 3) of chromosomal material (comprehensive CNV data is presented in Supplementary Data 3). These disruptions included previously reported alterations such as recurrent gains of chromosome 8 (∼25%) and loss of the short arm of chromosome 17 (∼40%), which frequently also involved simultaneous gains of the long arm of chromosome 17 (∼25%) of SS cases (Supplementary Fig. 4). A high-frequency of deletions of the short arm of chromosome 19 was observed. The data also defined specific regions of recurrent aneuploidy at chromosome 1p36.11, 3p21.31, 9p21.3, 10p11.22 and 13q14.2 (Supplementary Fig. 3, arrowheads). To precisely identify single-gene candidates within these chromosomal loci that may contribute to SS pathogenesis through gene mutation, we performed WES on 60 additional SS genomes (comprehensive mutational data presented in Supplementary Data 4).
Our WES data demonstrated that genes within regions of recurrent deletions previously demonstrated to be important in SS pathogenesis (TP53 on chromosome 17, CDKN2A on chromosome 9 and PTEN on chromosome 10) also were affected by deleterious mutations. Specifically, WES identified loss-of-function mutations in CDKN2A (p.W15X nonsense mutation), a frameshift mutation in PTEN in the C2 functional domain and numerous nonsense, frameshift and splice junction mutations in TP53 (Supplementary Fig. 5). To efficiently identify novel genes contributing to the pathogenesis of SS, we selected those genes which showed both a high rate of deletion (>10% of 80 SS genomes) as well as genes with at least one known deleterious mutation (either frameshift, nonsense and/or splice donor or acceptor mutation among the 66 SS genomes sequenced). This approach revealed several candidate genes involved in the pathogenesis of SS.
Loss of function of ARID and SMARC family proteins
Examination of the most frequently restricted region of recurrent deletion, the 1p36.11 locus, revealed 18 genes with at least one deleterious mutation (Supplementary Data 5). Of these, ARID1A exhibited the highest frequency of disruption and/or mutation with 27/80 genomes involved by deletions and 7/66 showing novel mutations including a frameshift mutation at residue 1449 within the GR-binding domain where the mutations seemed to co-localize; Figs 2a and 3; Supplementary Fig. 6). Disruption of ARID1A by either deletional events or mutation or both were seen in 25/62 (40.3%) SS genomes on which both WES and aCGH analyses were performed. Loss-of-function mutations in ARID1A have been implicated in the pathogenesis of other hematopoietic and non-haematopoietic malignancies23, but not in SS.
Another member of the ARID family of chromatin remodelling genes, ARID5B, was also implicated as a candidate because deletions of region 10q21.2 were observed in 23/80 genomes and point mutations in 3/66 SS genomes. The latter group included a nonsense mutation p.K239X (Fig. 3; Supplementary Fig. 7. ARID5B is recurrently mutated in endometrial malignancies24 and deleted in a fraction of paediatric B-cell acute lymphoblastic leukaemia25.
ARID family members play a critical role in the SWI/SNF complex where they exhibit helicase and ATPase activities and regulate transcription of genes by altering the surrounding chromatin structure26. SWI/SNF family members, including the SMARC group, interact with proteins encoded by the ARID family member genes27. Loss of SWI/SNF complex member SNF5 leads to T-cell lymphoma at high penetrance levels28. Interestingly, our studies revealed that SMARCC1 at 3p21.31 was recurrently targeted by deletions (<4 Mb) in 17/80 (21.3%) of SS genomes (Supplementary Fig. 3). Strikingly, deletions and/or mutations in either ARID1A, ARID5B or SMARCC1 were identified in 38/62 (61.3%) of SS genomes in which both WES and aCGH were performed. WES revealed mutations in other members of the ARID and SMARC family, namely, ARID1B, ARID4A and ARID2, which also included a case with a nonsense mutation (ARID2 p.Q1462X). Moreover, ARID3A and SMARCA4, recently found to be mutated in small cell carcinoma of the ovary, are both located on the short arm of chromosome 19, which is recurrently deleted in 29/80 and 18/80 SS genomes, respectively. Altogether, deletions and/or mutations of at least one of the 10 ARID or 13 SMARC family genes were identified in 91.9% of SS genomes (Fig. 3).
ZEB1, in addition to being implicated in a fusion event involving CBLB as described above (Fig. 1d; Table 1), was also recurrently targeted by deletions of chromosomal material (29/80 SS genomes) as well as deleterious mutations (7/66 SS genomes) including five frameshift mutations in four SS genomes (Fig. 2b). In total, 28/62 (45.2%) of SS genomes showed evidence of loss-of-function alterations of ZEB1 strongly implicating this gene as a tumour suppressor involved in the pathogenesis of SS. This concept is supported by the demonstration that TCF8/ZEB1 mutant mice frequently develop a CD4-positive T-cell lymphoma/leukaemia with a median onset of 30 weeks29,30. Further, ZEB1 has been implicated as a candidate tumour suppressor gene in adult T-cell leukaemia/lymphoma30. ZEB1 directly interacts with the trithorax group protein component SMARCA4 (also known as BRG-1) and recruits histone deacetylases HDAC1 and HDAC2 (refs 16, 31). Our results also showed that the cyclic AMP-response element-binding protein-binding protein, which is frequently mutated in acute lymphoblastic leukaemia32 and critical for trithorax group protein activity33, was recurrently altered by deletions in 19/80 and mutations in 7/66 SS genomes including a p.Q1108X nonsense mutation and several frameshift mutations (Supplementary Data 4).
MLL and SETDB and KDM6B mutations
The results also implicated members of the trithorax group histone methyltransferases, particularly MLL2, known to be frequently mutated in a variety of human malignancies34,35,36. These genes were deleted in 11 of 80 SS genomes. MLL2 was targeted in 7/66 SS genomes including one with a monoallelic nonsense mutation (p.Q4219X) and another genome with bialleleic nonsense mutations (p.S624X and p.S687X). MLL4 was mutated in 12/66 of SS genomes including one frameshift mutation (p.P622fs; Fig. 3; Table 1). In addition, MLL3 was targeted in 39/66 SS genomes, including four genomes with frameshift or nonsense mutations (Fig. 3). SETD family histone methyltransferases were involved by recurrent alterations including SETD1A deletions in 14/80 SS genomes and mutations in 4/66 genomes including one frameshift (Fig. 3; Supplementary Fig. 8); SETD1B deletions in 12/80 and mutations in 11/66 SS genomes including one frameshift and one nonsense mutation (p.E66X; Fig. 3; Supplementary Fig. 9); SETDB2 deletions in 18/80 and mutations in 2/66 SS genomes including two nonsense mutations (p.R588X) in separate genomes; and SETD6 deletions in 9/80 and mutations in 2/66 SS genomes including one frameshift mutation (Fig. 3). Altogether, deletions and/or mutations in MLL, MLL2, MLL3, MLL4, SETD1A, SETD1B, SETDB2 and SETD6 were identified in 67.7% of SS genomes. Moreover, deletions of the histone-lysine demethylase KDM6B on chromosome 17p were observed in 38/80 SS genome, whereas mutations were seen in 11/66 SS genome including one frameshift mutation p.P471fs.
In addition, we identified genetic alterations affecting other epigenetic modulators including the histone deacetylase NCOR1 on the short arm of chromosome 17 including deletions in 38/80 and mutations in 9/66 including one frameshift mutation (p.Y1997fs) and two nonsense mutations (p.Q600X and p.Q2005X; Figs 2c and 3). NCOR1 is implicated in the pathogenesis of acute lymphoid leukaemia and non-haematopoietic malignancies37,38. Six of 62 SS genomes showed simultaneous mutation and deletion events suggesting biallelic loss of function of NCOR1 (Fig. 3). These results indicate that disruption of homeostatic histone modification may contribute to the pathogenesis of SS.
Further implicating a role for deregulation of epigenetic modifiers in SS was our identification of alterations targeting multiple members of the DNA methyltransferase family, including DNMT3A, which has been implicated in the development of acute myeloid leukaemia39. DNMT3A was deleted in 14/80 and mutated in 5/66 SS genomes, including the novel nonsense mutation p.Y394X. In addition, DNMT3B was deleted in 9/80 and mutated in 5/66 SS genomes including the nonsense mutation p.R223X (Fig. 3). Additional genes involved in DNA methylation such as the demethylases, TET1 and TET2, recently implicated in the pathogenesis of myeloid malignancies40,41, also showed evidence of loss-of-function alterations. Strikingly, among the SS genomes showing deletion of any portion of chromosome 10 were eight cases with narrowly focused deletions (<0.5 Mb) involving the TET1 gene. Moreover, sequencing identified recurrent mutations affecting TET2 in 7/66 SS genomes including five nonsense mutations and a disrupted splice acceptor mutation (Fig. 2diii). Altogether, deletions and/or mutations in DNMT3A, DNMT3B, TET1 or TET2 were identified in 74.2% of SS genomes (Fig. 3). Taken together, these results support a critical role for deregulated DNA methylation in the pathogenesis of SS.
Loss-of-function alterations in cell cycle regulators
Our integrated approach highlighted involvement in SS of several novel candidate gene families involved in cell cycle regulation whose members were recurrently altered through both deletions and mutations. Loss of the well-known tumour suppressor gene CDKN1B on 12p13.1 was identified in 12/80 SS genomes, including a case showing a deletion and a single p.W76X nonsense mutation. In addition, the RB1 gene locus at 13q14.2 was deleted in 21/80 SS genomes with a number of narrowly restricted deletions (<0.7 Mb; Supplementary Fig. 5).
Gain-of-function mutations target PLCG1 and CARD11
PLCG1 is an important mediator in the T-cell receptor/CD3-NFAT signalling axis critical for T-cell activation and differentiation42.We identified recurrent gain-of-function mutations in PLCG1 including p.S345F (cases SS26 and SS31) affecting the PLCx catalytic domain and p.S520F (case SS84). In addition, we identified three additional mutations p.R1158H (case SSG01), p.R1163K (case SS9) and p.VYEEDM1161V (case SS86) tightly clustered in the C2 domain, which is a calcium-dependent membrane targeting module involved in signal transduction (Supplementary Fig. 10a).
The multidomain scaffold protein CARMA encoded by the CARD11 gene is a positive mediator for the NF-κB activation involved in antigen receptor signalling43. We identified recurrent missense mutations in CARD11 including p.M360K (case SS12), p.V266A (case SS26), p.D357A (case SS42) and p.S618F (cases SS26 and SS32; Supplementary Fig. 10b).
Overall, 6/66 (9.1%) harboured PLCG1 mutations and 4/66 (6%) harboured CARD11 mutations. These findings suggest a role for antigen receptor signalling mediators in the pathogenesis of SS.
Mutations in JAK–STAT and Ras pathways
WES revealed somatic gain-of-function mutations affecting JAK1 (2/66, 3%), JAK3 (2/66), STAT3 (2/66) and STAT5B (2/66) altogether present in 11% of cases (Fig. 3; Table 2). Importantly, recurrent mutations of JAK1, JAK3, STAT3 and STAT5B have not been previously reported in SS and were corroborated by Sanger sequencing in all cases (Fig. 4a). The mutations were clustered in the autoinhibitory pseudokinase domain and included variants detected previously in other malignancies or shown to lead to constitutive activation of JAK–STAT44 signalling including JAK1 p.Y654F45,46 and p.L710V. By comparison, the JAK3 mutations p.S989I and p.Y1023H were located in the kinase domain. This observation is intriguing given the recent observation that some mutations in the kinase domain of JAK3 confer interleukin-3 independence to Ba/F3 cells in vitro47. By WES we identified known gain-of-function mutations p.I498V48 (Table 2) and p.Y640F49 (Table 2) in STAT3, as well as p.N642H and p.Q706L (2/66, 3%) in STAT5B in SS. The JAK–STAT pathway mutations were mutually exclusive in all but one case (SS29) that harboured both STAT3 and JAK1 mutations. Matched constitutional DNA from normal tissue (for example, CD4-negative leukocytes from peripheral blood) confirmed somatic acquisition of these mutations (Fig. 4a; Table 2). Of additional interest, we identified mutations affecting the Ras homologue gene family member RhoA in 4/66 (6%) cases, namely, p.C16R (case SS8), p.N117K (cases SS33 and SS60) and p.K118T (case SS47). We also observed a known oncogenic mutation affecting NRAS (p.Q61K) in the SS-derived cell line Hut-78. Taken together, these mutations implicate a role for mutations affecting the JAK–STAT and RAS family pathways in the pathogenesis of SS.
JAK-mutated primary SS cells are sensitive to JAK inhibitors
To investigate the possible utility of targeting the JAK–STAT pathway, two primary SS samples harbouring mutations in JAK1 (SS87 p.Y654F and SS29 pL710V) were subjected to JAK inhibition. Exposure to increasing doses of JAK inhibitor I50 led to substantial reduction in cell proliferation of primary SS cells (Fig. 4b,c). Western blotting studies revealed inhibition of phosphorylation and activation of STAT1, STAT3 and STAT5 signalling in the SS cells harbouring both JAK1 mutations, whereas the mature T-cell lymphoma-derived cell line, HH, which does not carry mutations in the JAK–STAT axis, did not show any changes (Fig. 4d; Supplementary Fig. 12). Similarly, the primary SS cells harbouring the JAK1 mutations and the SS-derived cell line Hut-78 carrying the JAK1 p.Y654F and JAK3 p.A573V mutations were sensitive to the JAK1/2-selective inhibitor ruxolitinib. On the other hand, the JAK mutation-negative mycosis fungoides/SS-derived cell line HH and the JAK mutation-negative T-cell line Jurkat were both unresponsive to ruxolitinib treatment (Supplementary Fig. 11). Taken together, these data indicate that pharmacological antagonism of JAK1–STAT signalling inhibits growth of primary SS tumour cells. The effects of these mutations and of pharmacologic targeting of the JAK1–STAT pathway are diagrammed in Fig. 4.
Discussion
This study provides for the first time a comprehensive genomic landscape of SS. The integrated genomic analysis of 80 SS genomes we present reveals a complex genomic landscape with numerous structural variations including translocations, loss-of-function deletions and mutations as well as actionable gain-of-function mutations. WGS showed numerous (n=42) fusion genes including TPR-MET, MYBL1-TOX, DNAJC15-ZMYM2 and EZH2-FOXP1 which, albeit not recurrent, could contribute to the pathogenesis of SS. The WGS analyses also confirms previously observed recurrent aneuploidies, including trisomy 8, monosomy 10 and loss of 17p and/or isochromosome 17 indicating that chromosomal instability is a characteristic of this malignancy and may contribute to the poor clinical behaviour.
The data derived from this integrated genomic analyses of the SS genome show a striking profile of recurrent loss-of-function alterations in the form of deletions and inactivating mutations targeting the epigenetic modification machinery including the ARID/SMARC family chromatin remodelling complex, histone methyltransferases (MLLs and SETD1A/B) and demethylase (KDM6B), DNA methyltransferase family members and TET1/2/3 genes. These results highlight the substantial contribution of epigenetic deregulation in the pathogenesis of SS and provide targeted insights to study the mechanisms of sensitivity and resistance to inhibitors of histone deacetylases and DNA methyltransferases in SS patients. Recurrent loss-of-function alterations targeting the well-characterized tumour suppressor genes TP53, CDKN2A, PTEN as well as cell cycle regulators CDKN1B and RB1 were also common in SS.
Dysregulation of T-cell receptor signalling has been implicated in the pathogenesis of T-cell neoplasia51. Our studies reveal that mutational subversion of components of signalling pathways critical for T-cell activation and survival is common in SS. In this regard, recurrent somatic gain-of-function mutations involving PLCG1, JAK1/3 and STAT3/5B are a prominent feature of the SS mutational landscape. Inhibition of activated pathways, particularly those driven by oncogenic tyrosine kinases, has served as a molecularly tractable strategy for the targeted therapy of cancers. In this regard, we demonstrated that pharmacologic antagonism of JAK in primary SS samples harbouring JAK1 mutations led to significant inhibition of tumour cell proliferation.
In conclusion, the genomic landscape of SS reveals a heterogeneous genetic portrait with frequent disruption of epigenetic modifiers, cell cycle regulators and subversion of signalling modules involved in T-cell receptor, chemokine and cytokine signalling pathways critical for T-cell activation, survival and differentiation. Overall, these studies highlight the opportunities afforded by integrated genomic approaches in elucidating the molecular genetic alterations underlying the pathogenesis of SS. We anticipate that the findings presented here will play a role in refining disease taxonomy and offer opportunities for the definition of personalized biomarkers as well as precision therapeutics for patients with SS.
Methods
Patients and samples
Clinical samples were obtained from the archives of the Department of Pathology at The University of Texas MD Anderson Cancer Center, the University of Michigan and The University of Utah Health Sciences Center. Institutional Review Board approval for access to clinical specimens and information was obtained from the University of Michigan, the University of Texas MD Anderson Cancer Center and the University of Utah. Informed consent was obtained from the patients for use of diagnostic material. All SS cases fulfilled pathologic criteria for diagnosis of SS according to World Health Organization classification criteria. For a given patient, samples represented either formalin-fixed, paraffin-embedded tissue (FFPE), cryopreserved peripheral blood leukocytes or both. Where applicable, constitutional normal tissue represented either tumour-free FFPE tissue derived from the same patient or otherwise tumour-depleted peripheral blood leukocytes generated using EasySep column enrichment and B220- and/or Mac-1-positive cell selection (Stem Cell Technologies, Inc.). Relative tumour- depletion of resultant cell suspensions was determined by flow cytometry using an antibody directed against CD4 (BD Pharmingen). DNA was extracted from both FFPE and frozen samples using QIAGEN DNA extraction kits according to manufacturer’s instructions.
aCGH analysis
CNVs were detected using Nimblegen whole-genome arrays containing 270,000 features (Roche Applied Science) sufficient to detect CNVs of 50 kb or greater. Arrays were prepared according to manufacturer’s protocol and analysed on NimbleGen MS 200 Scanner followed by data extraction, normalization and processing for segMNT analysis using NimbleScan software according to manufacturer’s instructions. Downstream data processing and interpretation were performed using custom-designed processing algorithms solely reliant on the data comprising output segMNT data files. Circos plots were generated to display the segMNT data. The aCGH data are available at http://www.ncbi.nlm.nih.gov/bioproject/PRJNA292537 (index cases) and http://www.ncbi.nlm.nih.gov/bioproject/PRJNA292547 (discovery cases).
Sequencing
For WGS, 7–10 μg of high-molecular-weight genomic DNA was extracted from fresh frozen tumour tissue and subjected to WGS by Complete Genomics, Inc. (CGI; Mountain View, CA). CGI performs massively parallel short-read sequencing using a combinatorial probe-anchor ligation chemistry coupled with a patterned nanoarray-based platform of self-assembling DNA nanoballs. (Library generation, read-mapping to the NCBI reference genome (Build 37, RefSeq Accession nos. CM000663-CM00686). Initial read mapping and variant calling were performed using CGAtools v1.3.0 (http://cgatools.sourceforge.net/docs/1.3.0/). Additional downstream bioinformatic analyses of WGS data were performed using custom-designed processing routines. WGS yielded a mean of 351±13 Gb mapped per sample with 97.4–97.8% fully called genome fraction and 97.1–97.7% fully called exome fraction. The median genomic sequencing depth exceeded 60 × in all samples normalized across the entire genome.
For WES, genomic DNA samples were fragmented using a Covaris S2 fragmentation system to a target size of 400 bp. The samples were end-repaired, a-tailed and custom adapters were ligated using the NEBNext DNA Library Prep kit according to the manufacturers recommended protocols. The custom adapters included 6-bp barcodes and were synthesized by Integrated DNA Technologies. After ligation, the samples were size selected to 400 bp on a 2% agarose gel and 1-mm gel slices were retained. Samples were isolated from the gel using the Qiagen QIAquick gel extraction system. Seven microlitres of each ligation product was enriched using the Phusion master mix kit and custom PCR primers with a total of 14 cycles of PCR amplification (TruSeq Universal Adapter 5′-AAT-GAT-ACG-GCG-ACC-ACC-GAG-ATC-TAC-ACT-CTT-TCC-CTA-CAC-GAC-GCT-CTT-CCG-ATC-T-3′ and TruSeq Adapter, Index 1 6 5′-GAT-CGG-AAG-AGC-ACA-CGT-CTG-AAC-TCC-AGT-CAC-ATC-ACG-XXX-XXX-TAT-GCC-GTC-TTC-TGC-TTG-3′). Two PCR amplifications were performed for each sample. The PCR products were pooled and purified using AmpureXP beads.
Library QC was performed using the Agilent Tapestation and qPCR. On the basis of qPCR concentrations, 200 ng of each of five samples were pooled for a total of three pools. Each pool was captured using the Nimblegen SeqCap EZ V3 Exome Enrichment Kit according to the manufacturer’s recommended protocols. The capture pools were combined and sequenced on the Illumina HiSeq 2,000 platform across four lanes with paired-end 100-bp reads. The average depth of coverage for exome sequencing was 30.4±11.9 × with >95% of coding exons sequenced to a depth of 30 or more.
Our analysis focused on variations that were not in the Database of single-nucleotide proteins (dbSNP) and/or those that had been associated previously with cancer based on information in the Catalogue of Online Somatic Mutations in Cancer (COSMIC) database. After identifying candidate mutations of interest, 10–50 ng of genomic DNA from tumour and matched constitutional tissue or otherwise tumour-depleted, matched normal DNA was subjected to Sanger sequencing. To confirm somatic acquisition, tumour-depleted or tumour-free matched normal DNA was also subjected to WES to identify somatic alterations in SS (CD4-negative cells obtained following immunomagnetic enrichment of CD4-positive SS cells or skin uninvolved by tumour). Three parameters were combined to arrive at threshold criteria for designation of a variant as somatic in the absence of constitutional information. First, all of the variants identified in the present study were filtered to exclude variants in the dbSNP database. To develop a parameter for allele burden based on read counts obtained from next-generation sequencing, we leveraged our NGS database containing NGS data from >500 genomes and modelled the allele frequency correlation between germline variants and their corresponding read counts. Depending on the read depth, the allele frequencies of germline variants varied from 40 to 60% (variant/wild-type ratio). On the other hand, variants exhibiting ≤25 or ≥75% variant/wild-type ratios consistently and invariably represented somatic alterations. Thus, we employed these thresholds as cutoffs for designation of somatic variants. In addition, Sanger sequencing was performed to validate findings observed for 75 variants and qualitatively and quantitatively corroborated the results of NGS. Accordingly, in scenarios where constitutional DNA was not available, we assessed the allele burdens using read counts and those with mutant-to-wild-type ratios <25 or >75% were subjected to Sanger sequencing to corroborate the ratio from peak heights and scored as mutant when these ratios were maintained. Finally, when all parameters (that is, allele burden by NGS confirmed by Sanger and excluded by dbSNP) were fulfilled, the variants were presumed to be somatic. For all sequencing reactions, PCR amplification was performed using Phusion DNA polymerase (New England Biolabs) followed by conventional Sanger sequencing technology using BigDye version 3.1 chemistry run on an Applied Biosystems 3730 × l DNA Sequencer at the University of Michigan DNA sequencing Core. All sequencing reactions were performed using nested sequencing primers. Sequencing trace analysis was performed using Mutation Surveyor software. All primers were designed using a custom-developed program and purchased from Integrated DNA Technologies lyophilized in 96-well plates.
WES FASTQ sequencing data files were aligned to human NCBI Build 36 reference sequence using BWA 0.6.2 available at http://bio-bwa.sourceforge.net/. Merging and deduplication were performed using Picard 1.79 available at http://broadinstitute.github.io/picard/. The DepthOfCoverage, CountReads, RealignerTargetCreator, IndelRealigner, BaseRecalibrator, PrintReads and UnifiedGenotyper functions within GenomeAnalysisTK-1.6-9 (available at https://www.broadinstitute.org/gatk/) were used to ascertain coverage and for variant calling. Resultant VCF files were annotated using snpEff v3.1 available at http://snpeff.sourceforge.net/. Variants previously identified as somatic in malignancy were highlighted if present in the COSMIC database (http://cancer.sanger.ac.uk/cosmic). Additional custom in-house bioinformatics pipelines were designed to interpret, collate, organize and display the integrated results obtained from next-generation sequencing and aCGH data open source software tools described above will be published in a subsequent manuscript and are as yet not publically available. Custom-designed data processing algorithms used to process aCGH data for display and interpretation and for automated primer design will likely not be published and will not be made publically available as numerous open source and commercially available tools exist for these analyses. The sequencing data are available at http://www.ncbi.nlm.nih.gov/bioproject/PRJNA292537 (index cases) and http://www.ncbi.nlm.nih.gov/bioproject/PRJNA292547 (discovery cases).
Cell lines
Jurkat, HH and Hut-78 cell lines were obtained from the American Type Culture Collection. Mac-1 was kindly provided by Dr Marshall E. Kardin (Boston University School of Medicine, Massachusetts). All cell lines were grown in RPMI-1644 media supplemented with 10% fetal bovine serum (FBS) except Hut-78, which was grown in IMDM media supplemented with 10% FBS. No mycoplasma contamination was detected at the time of experiments.
Primary cell culture and JAK inhibitor treatment
Primary tumour cells were isolated from peripheral blood of SS patients for routine diagnosis and excess aliquots viably cryopreserved in FBS/dimethylsulphoxide at −140 °C. All samples were obtained with IRB approval from the University of Michigan and consents were obtained. Primary SS cells harbouring JAK1 gain-of-function mutation were thawed and grown overnight in RPMI cell culture medium followed by treatment with JAK inhibitor I (EMD Millipore), a pan inhibitor of JAK kinase activation, at different concentrations as indicated. A measure of 3 μM of JAK inhibitor I was used for time kinetics of cell growth assay on primary SS cells as indicated. Cell growth was determinate at 48 and 72 h in triplicate by WST-1 (Roche Diagnostics) according to the manufacturer’s instructions. Each assay was performed in triplicate.
Immunofluorescence
For immunofluorescence studies, cells were plated in chamber slides. Cells were fixed in 4% formaldehyde, permeabilized with 0.5% Triton X-100 for 5 min and coimmunostained with anti-ARID1A (clone 3H14, MP Biomedicals, 1/1,000) followed by staining with Alexa Fluor 594-conjugated secondary antibodies (Molecular Probes, Eugene, OR). The slides were mounted with Vectashield mounting medium containing 4′,6-diamidino-2-phenylindole (Vector Laboratories, Burlingame, CA). After staining, cells were photographed (× 40) using a Nikon Eclipse 80i confocal microscope.
Western blot
For western blot analysis, cells were treated for 4 h with JAK inhibitor I at 3 μM and protein lysates were subjected to western blot analysis. The following primary antibodies were obtained from Cell Signaling Technology: STAT1 (clone 9H2, 1/1,000), p-STAT1 (clone 58D6, 1/1,000), STAT3 (clone 79D7, 1/1,000), p-STAT3 (clone M9C6, 1/1,000), STAT5 (polyclonal, 1/1,000) and p-STAT5 (clone D47E7, 1/1,000). The loading quality was assessed using antibody against β-actin (clone AC-74, 1/10,000) from Sigma-Aldrich.
Additional information
How to cite this article: Kiel, M. J. et al. Genomic analyses reveal recurrent mutations in epigenetic modifiers and the JAK–STAT pathway in Sézary syndrome. Nat. Commun. 6:8470 doi: 10.1038/ncomms9470 (2015).
References
Agar, N. S. et al. Survival outcomes and prognostic factors in mycosis fungoides/Sezary syndrome: validation of the revised International Society for Cutaneous Lymphomas/European Organisation for Research and Treatment of Cancer staging proposal. J. Clin. Oncol. 28, 4730–4739 (2010).
Willemze, R. et al. WHO-EORTC classification for cutaneous lymphomas. Blood 105, 3768–3785 (2005).
Ralfkiaer, E., Willemze, R. & Whittaker, S. J. in WHO Classification of Tumours of Haematopoietic and Lymphoid Tissues eds Swerdlow S. H., Campo E., Harris N. L.et al. 299Lyon (2008).
Wong, H. K., Mishra, A., Hake, T. & Porcu, P. Evolving insights in the pathogenesis and therapy of cutaneous T-cell lymphoma (mycosis fungoides and Sezary syndrome). Br. J. Haematol. 155, 150–166 (2011).
Hughes, C. F. et al. Lack of durable disease control with chemotherapy for mycosis fungoides and Sezary syndrome: a comparative study of systemic therapy. Blood 125, 71–81 (2015).
Cristofoletti, C. et al. Comprehensive analysis of PTEN status in Sezary syndrome. Blood 122, 3511–3520 (2013).
Kiessling, M. K. et al. High-throughput mutation profiling of CTCL samples reveals KRAS and NRAS mutations sensitizing tumors toward inhibition of the RAS/RAF/MEK signaling cascade. Blood 117, 2433–2440 (2011).
Steininger, A. et al. Genomic loss of the putative tumor suppressor gene E2A in human lymphoma. J. Exp. Med. 208, 1585–1593 (2011).
Andersson, E. et al. Novel TBL1XR1, EPHA7 and SLFN12 mutations in a Sezary syndrome patient discovered by whole exome sequencing. Exp. Dermatol. 23, 366–368 (2014).
Vaque, J. P. et al. PLCG1 mutations in cutaneous T-cell lymphomas. Blood 123, 2034–2043 (2014).
Soman, N. R., Correa, P., Ruiz, B. A. & Wogan, G. N. The TPR-MET oncogenic rearrangement is present and expressed in human gastric carcinoma and precursor lesions. Proc. Natl Acad. Sci. USA 88, 4892–4896 (1991).
Huang, Y., Su, M. W., Jiang, X. & Zhou, Y. Evidence of an oncogenic role of aberrant TOX activation in cutaneous T-cell lymphoma. Blood 125, 1435–1443 (2015).
Xiao, S. et al. FGFR1 is fused with a novel zinc-finger gene, ZNF198, in the t(8;13) leukaemia/lymphoma syndrome. Nat. Genet. 18, 84–87 (1998).
Collins, C. et al. C/EBPalpha is an essential collaborator in Hoxa9/Meis1-mediated leukemogenesis. Proc. Natl Acad. Sci. USA 111, 9899–9904 (2014).
Kroon, E. et al. Hoxa9 transforms primary bone marrow cells through specific collaboration with Meis1a but not Pbx1b. EMBO J. 17, 3714–3725 (1998).
Wang, J. et al. The transcription repressor, ZEB1, cooperates with CtBP2 and HDAC1 to suppress IL-2 gene activation in T cells. Int. Immunol. 21, 227–235 (2009).
Caprini, E. et al. Identification of key regions and genes important in the pathogenesis of sezary syndrome by combining genomic and expression microarrays. Cancer Res. 69, 8438–8446 (2009).
Izykowska, K. & Przybylski, G. K. Genetic alterations in Sezary syndrome. Leuk. Lymphoma 52, 745–753 (2011).
Lin, W. M. et al. Characterization of the DNA copy-number genome in the blood of cutaneous T-cell lymphoma patients. J. Invest. Dermatol. 132, 188–197 (2012).
Mao, X. et al. Molecular cytogenetic characterization of Sezary syndrome. Genes Chromosomes Cancer 36, 250–260 (2003).
Mao, X. & McElwaine, S. Functional copy number changes in Sezary syndrome: toward an integrated molecular cytogenetic map III. Cancer Genet. Cytogenet. 185, 86–94 (2008).
Scarisbrick, J. J., Woolford, A. J., Russell-Jones, R. & Whittaker, S. J. Allelotyping in mycosis fungoides and Sezary syndrome: common regions of allelic loss identified on 9p, 10q, and 17p. J. Invest. Dermatol. 117, 663–670 (2001).
Wu, R. C., Wang, T. L. & Shih, Ie, M. The emerging roles of ARID1A in tumor suppression. Cancer Biol. Ther. 15, 655–664 (2014).
Cancer Genome Atlas Research, N.. et al. Integrated genomic characterization of endometrial carcinoma. Nature 497, 67–73 (2013).
Paulsson, K. et al. Genetic landscape of high hyperdiploid childhood acute lymphoblastic leukemia. Proc. Natl Acad. Sci. USA 107, 21719–21724 (2010).
Wilson, B. G. & Roberts, C. W. SWI/SNF nucleosome remodellers and cancer. Nat. Rev. Cancer 11, 481–492 (2011).
Wang, X. et al. Two related ARID family proteins are alternative subunits of human SWI/SNF complexes. Biochem. J. 383, 319–325 (2004).
Roberts, C. W., Leroux, M. M., Fleming, M. D. & Orkin, S. H. Highly penetrant, rapid tumorigenesis through conditional inversion of the tumor suppressor gene Snf5. Cancer Cell 2, 415–425 (2002).
Hidaka, T. et al. Down-regulation of TCF8 is involved in the leukemogenesis of adult T-cell leukemia/lymphoma. Blood 112, 383–393 (2008).
Nakahata, S., Yamazaki, S., Nakauchi, H. & Morishita, K. Downregulation of ZEB1 and overexpression of Smad7 contribute to resistance to TGF-beta1-mediated growth suppression in adult T-cell leukemia/lymphoma. Oncogene 29, 4157–4169 (2010).
Aghdassi, A. et al. Recruitment of histone deacetylases HDAC1 and HDAC2 by the transcriptional repressor ZEB1 downregulates E-cadherin expression in pancreatic cancer. Gut 61, 439–448 (2012).
Mullighan, C. G. et al. CREBBP mutations in relapsed acute lymphoblastic leukaemia. Nature 471, 235–239 (2011).
Steffen, P. A. & Ringrose, L. What are memories made of? How Polycomb and Trithorax proteins mediate epigenetic memory. Nat. Rev. Mol. Cell Biol. 15, 340–356 (2014).
Huether, R. et al. The landscape of somatic mutations in epigenetic regulators across 1,000 paediatric cancer genomes. Nat. Commun. 5, 3630 (2014).
Okosun, J. et al. Integrated genomic analysis identifies recurrent mutations and evolution patterns driving the initiation and progression of follicular lymphoma. Nat. Genet. 46, 176–181 (2014).
Song, Y. et al. Identification of genomic alterations in oesophageal squamous cell cancer. Nature 509, 91–95 (2014).
Gui, Y. et al. Frequent mutations of chromatin remodeling genes in transitional cell carcinoma of the bladder. Nat. Genet. 43, 875–878 (2011).
Stephens, P. J. et al. The landscape of cancer genes and mutational processes in breast cancer. Nature 486, 400–404 (2012).
Ley, T. J. et al. DNMT3A mutations in acute myeloid leukemia. N. Engl. J. Med. 363, 2424–2433 (2010).
Abdel-Wahab, O. et al. Genetic characterization of TET1, TET2, and TET3 alterations in myeloid malignancies. Blood 114, 144–147 (2009).
Delhommeau, F. et al. Mutation in TET2 in myeloid cancers. N. Engl. J. Med. 360, 2289–2301 (2009).
Huang, W. & August, A. The signaling symphony: T cell receptor tunes cytokine-mediated T cell differentiation. J. Leukoc. Biol. 97, 477–485 (2015).
Rawlings, D. J., Sommer, K. & Moreno-Garcia, M. E. The CARMA1 signalosome links the signalling machinery of adaptive and innate immunity in lymphocytes. Nat. Rev. Immunol. 6, 799–812 (2006).
Chen, E., Staudt, L. M. & Green, A. R. Janus kinase deregulation in leukemia and lymphoma. Immunity 36, 529–541 (2012).
Jeong, E. G. et al. Somatic mutations of JAK1 and JAK3 in acute leukemias and solid cancers. Clin. Cancer Res. 14, 3716–3721 (2008).
Zhang, J. et al. Key pathways are frequently mutated in high-risk childhood acute lymphoblastic leukemia: a report from the Children's Oncology Group. Blood 118, 3080–3087 (2011).
Degryse, S. et al. JAK3 mutants transform hematopoietic cells through JAK1 activation, causing T-cell acute lymphoblastic leukemia in a mouse model. Blood 124, 3092–3100 (2014).
Bashashati, A. et al. Distinct evolutionary trajectories of primary high-grade serous ovarian cancers revealed through spatial mutational profiling. J. Pathol. 231, 21–34 (2013).
Pilati, C. et al. Somatic mutations activating STAT3 in human inflammatory hepatocellular adenomas. J. Exp. Med. 208, 1359–1366 (2011).
Sanda, T. et al. TYK2-STAT1-BCL2 pathway dependence in T-cell acute lymphoblastic leukemia. Cancer Discov. 3, 564–577 (2013).
Serwold, T. et al. T-cell receptor-driven lymphomagenesis in mice derived from a reprogrammed T cell. Proc. Natl Acad. Sci. USA 107, 18939–18943 (2010).
Acknowledgements
We thank Farah Keyoumarsi for histology and specimen acquisition; Sountharia Rajendran, Nazeena Alvi, Martin Arlt and Thomas Glover for assistance with aCGH analysis; Bo Li, Ayse Ozel, Jun Z. Li, Ashwini Bhasi and James D. Cavalcoli for assistance with bioinformatics analysis of exome-sequencing data; and Constance Eaves, Brendan Tarrier and Robert Lyons for WGS and Sanger sequencing core services. K.E.J was partly supported by R01 CA136905. M.S.L. was partly supported by CA14806. This work was supported in part by the Department of Pathology at the University of Michigan.
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M.J.K., A.A.S., D.C.M.R., T.V., D.W.B., M.S.L. and K.S.J.E.-J. designed the study; M.S.L. and K.S.J.E.-J. supervised and oversaw the project and contributed to manuscript writing; P.P., J.C.B, L.J.M. and S.L.K. contributed to writing of manuscript.; M.J.K. performed WGS and WES bioinformatics analysis with assistance from B.L.B.; M.J.K. and T.V. prepared all samples for Sanger resequencing, WES and aCGH, and performed and analysed Sanger resequencing data and aCGH experiments with assistance from A.A.S.; D.C.M.R. performed primary cell culture experiments; F.C. performed fluorescence microscopy; L.J.M., R.N.M., D.B. and N.G.B. provided clinical samples.
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Supplementary information
Supplementary Information
Supplementary Figures 1-12 (PDF 1577 kb)
Supplementary Data 1
Comprehensive list of structural alterations in 6 index SS cases. Listed are the structural alterations for each of 6 index Sezary Syndrome genomes with the partner genomic regions identified by chromosome, position and strandedness. Left partner is arbitrarily-defined as the first of the two junctional positions within the genome. The distance, strand consistency and whether the alteration is strand consistent are listed as are the number of discordant reads supporting each alteration. If alteration affects one or more genes, the gene symbols and transcripts are listed as is the final assembled junctional sequence. (XLSX 216 kb)
Supplementary Data 2
List of potential fusion genes in 6 index SS genomes The subset of structural alterations listed in Supplementary Data 1 for which a viable fusion-gene might result based on alteration strandedness and gene strandedness are detailed. (XLSX 20 kb)
Supplementary Data 3
Comprehensive list of copy number variations in SS cases. The copy number alterations identified by array-CGH assays are detailed with red representing gain of chromosomal material and blue representing loss. The darker colors represent greater gains (more than 1.5x gains) or losses (less than 0.5x losses) at each of the specified loci for each of the 80 genomes for which there was sufficient DNA to perform aCGH. Shown at the far right are the genes (based on earliest chromosomal position) contained within each locus. (XLSX 10027 kb)
Supplementary Data 4
Comprehensive list of novel gene mutations identified in SS cases. Detailed information of all novel (defined as not being present in dbSNP) mutations identified in each of 66 Sezary Syndrome genomes itemized according to individual genes. Multiple mutations for a given gene in a single patient are separated by the "|" symbol. Frameshift mutations are highlighted in purple, non-sense mutations in red and mutations previously described in the COSMIC database (see Methods) in blue. Missense mutations are displayed in green. Other details for each include the protein coding consequence of the change as well as the chromosome, position and reference and alternate alleles for each mutation. (XLSX 6757 kb)
Supplementary Data 5
Truncated list of genes showing more than 10% of SS genomes with deletions and at least one deletorious mutation. This table combines the data contained within Supplementary Data 3 and 4 for those genes with at least 10% of Sezary Syndrome genomes showing deletions by aCGH and at least one deleterious mutation (defined as frameshift or nonsense mutations). (XLSX 492 kb)
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Kiel, M., Sahasrabuddhe, A., Rolland, D. et al. Genomic analyses reveal recurrent mutations in epigenetic modifiers and the JAK–STAT pathway in Sézary syndrome. Nat Commun 6, 8470 (2015). https://doi.org/10.1038/ncomms9470
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DOI: https://doi.org/10.1038/ncomms9470
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