Genomic analysis of 220 CTCLs identifies a novel recurrent gain-of-function alteration in RLTPR (p.Q575E).

Cutaneous T-cell lymphoma (CTCL) is an incurable non-Hodgkin lymphoma of the skin-homing T cell. In early-stage disease, lesions are limited to the skin, but in later-stage disease, the tumor cells can escape into the blood, the lymph nodes, and at times the visceral organs. To clarify the genomic basis of CTCL, we performed genomic analysis of 220 CTCLs. Our analyses identify 55 putative driver genes, including 17 genes not previously implicated in CTCL. These novel mutations are predicted to affect chromatin (BCOR, KDM6A, SMARCB1, TRRAP), immune surveillance (CD58, RFXAP), MAPK signaling (MAP2K1, NF1), NF-κB signaling (PRKCB, CSNK1A1), PI-3-kinase signaling (PIK3R1, VAV1), RHOA/cytoskeleton remodeling (ARHGEF3), RNA splicing (U2AF1), T-cell receptor signaling (PTPRN2, RLTPR), and T-cell differentiation (RARA). Our analyses identify recurrent mutations in 4 genes not previously identified in cancer. These include CK1α (encoded by CSNK1A1) (p.S27F; p.S27C), PTPRN2 (p.G526E), RARA (p.G303S), and RLTPR (p.Q575E). Last, we functionally validate CSNK1A1 and RLTPR as putative oncogenes. RLTPR encodes a recently described scaffolding protein in the T-cell receptor signaling pathway. We show that RLTPR (p.Q575E) increases binding of RLTPR to downstream components of the NF-κB signaling pathway, selectively upregulates the NF-κB pathway in activated T cells, and ultimately augments T-cell-receptor-dependent production of interleukin 2 by 34-fold. Collectively, our analysis provides novel insights into CTCL pathogenesis and elucidates the landscape of potentially targetable gene mutations.

[1]  B. Malissen,et al.  The scaffolding function of the RLTPR protein explains its essential role for CD28 co-stimulation in mouse and human T cells , 2016, The Journal of experimental medicine.

[2]  Peter A. Jones,et al.  Targeting the cancer epigenome for therapy , 2016, Nature Reviews Genetics.

[3]  Ryan D. Morin,et al.  Activating mutations in genes related to TCR signaling in angioimmunoblastic and other follicular helper T-cell-derived lymphomas. , 2016, Blood.

[4]  P. Gaulard,et al.  Type II enteropathy-associated T-cell lymphoma features a unique genomic profile with highly recurrent SETD2 alterations , 2016, Nature Communications.

[5]  A. Prasad,et al.  Identification of Gene Mutations and Fusion Genes in Patients with Sézary Syndrome. , 2016, The Journal of investigative dermatology.

[6]  M. Simpson,et al.  Candidate driver genes involved in genome maintenance and DNA repair in Sézary syndrome. , 2016, Blood.

[7]  W. Damsky,et al.  Genetics of Cutaneous T Cell Lymphoma: From Bench to Bedside , 2016, Current Treatment Options in Oncology.

[8]  L. Staudt,et al.  Recurrent activating mutations of CD28 in peripheral T-cell lymphomas , 2016, Leukemia.

[9]  G. Petzold,et al.  Structural basis of lenalidomide-induced CK1α degradation by the CRL4CRBN ubiquitin ligase , 2016, Nature.

[10]  S. Tavazoie,et al.  PTPRN2 and PLCβ1 promote metastatic breast cancer cell migration through PI(4,5)P2‐dependent actin remodeling , 2015, The EMBO journal.

[11]  A. Ferrando,et al.  The mutational landscape of cutaneous T cell lymphoma and Sézary syndrome , 2015, Nature Genetics.

[12]  R. Gibbs,et al.  Genomic profiling of Sézary syndrome identifies alterations of key T cell signaling and differentiation genes , 2015, Nature Genetics.

[13]  H. Aburatani,et al.  Integrated molecular analysis of adult T cell leukemia/lymphoma , 2015, Nature Genetics.

[14]  J. Byrd,et al.  Genomic analyses reveal recurrent mutations in epigenetic modifiers and the JAK–STAT pathway in Sézary syndrome , 2015, Nature Communications.

[15]  Ashley M. Zehnder,et al.  Genomic analysis of mycosis fungoides and Sézary syndrome identifies recurrent alterations in TNFR2 , 2015, Nature Genetics.

[16]  Zhongming Zhao,et al.  Whole-genome sequencing reveals oncogenic mutations in mycosis fungoides. , 2015, Blood.

[17]  J. Snowden,et al.  The role of JAK/STAT signalling in the pathogenesis, prognosis and treatment of solid tumours , 2015, British Journal of Cancer.

[18]  D. Schatz,et al.  Genomic landscape of cutaneous T cell lymphoma , 2015, Nature Genetics.

[19]  A. Rosenwald,et al.  Convergent mutations and kinase fusions lead to oncogenic STAT3 activation in anaplastic large cell lymphoma. , 2015, Cancer cell.

[20]  P. Poulikakos,et al.  Targeting RAS–ERK signalling in cancer: promises and challenges , 2014, Nature Reviews Drug Discovery.

[21]  W. Huber,et al.  Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2 , 2014, Genome Biology.

[22]  Paul Theodor Pyl,et al.  HTSeq – A Python framework to work with high-throughput sequencing data , 2014, bioRxiv.

[23]  Jonathan D. Powell,et al.  Integrating canonical and metabolic signalling programmes in the regulation of T cell responses , 2014, Nature Reviews Immunology.

[24]  K. Mills,et al.  Modulation of T Cell and Innate Immune Responses by Retinoic Acid , 2014, The Journal of Immunology.

[25]  I. Varela,et al.  PLCG1 mutations in cutaneous T-cell lymphomas. , 2014, Blood.

[26]  Min Kyung Sung,et al.  A recurrent inactivating mutation in RHOA GTPase in angioimmunoblastic T cell lymphoma , 2014, Nature Genetics.

[27]  I. Lossos,et al.  Recurrent mutations in epigenetic regulators, RHOA and FYN kinase in peripheral T cell lymphomas , 2014, Nature Genetics.

[28]  O. Nureki,et al.  Somatic RHOA mutation in angioimmunoblastic T cell lymphoma , 2014, Nature Genetics.

[29]  S. Gabriel,et al.  Discovery and saturation analysis of cancer genes across 21 tumor types , 2014, Nature.

[30]  T. Svitkina,et al.  CARMIL leading edge localization depends on a non-canonical PH domain and dimerization , 2013, Nature Communications.

[31]  Mee-Sup Yoon,et al.  XPLN is an endogenous inhibitor of mTORC2 , 2013, Proceedings of the National Academy of Sciences.

[32]  K. Kinzler,et al.  Cancer Genome Landscapes , 2013, Science.

[33]  Justin Guinney,et al.  GSVA: gene set variation analysis for microarray and RNA-Seq data , 2013, BMC Bioinformatics.

[34]  David J. Arenillas,et al.  oPOSSUM-3: Advanced Analysis of Regulatory Motif Over-Representation Across Genes or ChIP-Seq Datasets , 2012, G3: Genes | Genomes | Genetics.

[35]  Steffen Jung,et al.  CKIα ablation highlights a critical role for p53 in invasiveness control , 2011, Nature.

[36]  Victor L. J. Tybulewicz,et al.  Rho family GTPases and their regulators in lymphocytes , 2009, Nature Reviews Immunology.

[37]  Jun Zhang,et al.  Casein kinase 1α governs antigen-receptor-induced NF-κB activation and human lymphoma cell survival , 2009, Nature.

[38]  Anastasia Khvorova,et al.  Experimental validation of the importance of seed complement frequency to siRNA specificity. , 2008, RNA.

[39]  S. Pileri,et al.  Phase II trial of proteasome inhibitor bortezomib in patients with relapsed or refractory cutaneous T-cell lymphoma. , 2007, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[40]  Matthew Meyerson,et al.  Structures of lung cancer-derived EGFR mutants and inhibitor complexes: mechanism of activation and insights into differential inhibitor sensitivity. , 2007, Cancer cell.

[41]  L. Zitvogel,et al.  Cancer despite immunosurveillance: immunoselection and immunosubversion , 2006, Nature Reviews Immunology.

[42]  H. Sanjo,et al.  The Journal of Experimental Medicine CORRESPONDENCE , 2005 .

[43]  Pablo Tamayo,et al.  Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[44]  M. Daly,et al.  PGC-1α-responsive genes involved in oxidative phosphorylation are coordinately downregulated in human diabetes , 2003, Nature Genetics.

[45]  Krister Wennerberg,et al.  XPLN, a Guanine Nucleotide Exchange Factor for RhoA and RhoB, But Not RhoC* , 2002, The Journal of Biological Chemistry.

[46]  P. Chambon,et al.  Crystal structure of a heterodimeric complex of RAR and RXR ligand-binding domains. , 2000, Molecular cell.

[47]  Thomas R. Gingeras,et al.  STAR: ultrafast universal RNA-seq aligner , 2013, Bioinform..

[48]  M. Karin,et al.  Is NF-kappaB a good target for cancer therapy? Hopes and pitfalls. , 2009 .

[49]  Michael Karin,et al.  Is NF-κB a good target for cancer therapy? Hopes and pitfalls , 2009, Nature Reviews Drug Discovery.

[50]  B. Tocqué,et al.  The Saccharomyces cerevisiae SDC25 C-domain gene product overcomes the dominant inhibitory activity of Ha-Ras Asn-17. , 1993, Molecular and cellular biology.