Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity

Joonhee Park; Jay Daniels; Tim Wartewig; Kimberly G. Ringbloom; Maria Estela Martinez-Escala; Sara Choi; Jane J. Thomas; Peter G. Doukas; Jingyi Yang; Caroline Snowden; Calvin Law; Yujin Lee; Katie Lee; Yancong Zhang; Carly Conran; Kyle Tegtmeyer; Samuel H. Mo; David R. Pease; Balaji Jothishankar; Pui Yan Kwok; Farah R. Abdulla; Barbara Pro; Abner Louissaint; Titus J. Boggon; Jeffrey Sosman; Joan Guitart; Deepak Rao; Jürgen Ruland; Jaehyuk Choi

doi:10.1182/blood.2020009655

Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity

Joonhee Park, Jay Daniels, Tim Wartewig, Kimberly G. Ringbloom, Maria Estela Martinez-Escala, Sara Choi, Jane J. Thomas, Peter G. Doukas, Jingyi Yang, Caroline Snowden, Calvin Law, Yujin Lee, Katie Lee, Yancong Zhang, Carly Conran, Kyle Tegtmeyer, Samuel H. Mo, David R. Pease, Balaji Jothishankar, Pui Yan KwokFarah R. Abdulla, Barbara Pro, Abner Louissaint, Titus J. Boggon, Jeffrey Sosman, Joan Guitart, Deepak Rao, Jürgen Ruland^*, Jaehyuk Choi^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Cutaneous T-cell lymphomas (CTCLs) are a clinically heterogeneous collection of lymphomas of the skin-homing T cell. To identify molecular drivers of disease phenotypes, we assembled representative samples of CTCLs from patients with diverse disease subtypes and stages. Via DNA/RNA-sequencing, immunophenotyping, and ex vivo functional assays, we identified the landscape of putative driver genes, elucidated genetic relationships between CTCLs across disease stages, and inferred molecular subtypes in patients with stage-matched leukemic disease. Collectively, our analysis identified 86 putative driver genes, including 19 genes not previously implicated in this disease. Two mutations have never been described in any cancer. Functionally, multiple mutations augment T-cell receptor–dependent proliferation, highlighting the importance of this pathway in lymphomagenesis. To identify putative genetic causes of disease heterogeneity, we examined the distribution of driver genes across clinical cohorts. There are broad similarities across disease stages. Many driver genes are shared by mycosis fungoides (MF) and Sezary syndrome (SS). However, there are significantly more structural variants in leukemic disease, leading to highly recurrent deletions of putative tumor suppressors that are uncommon in early-stage skin-centered MF. For example, TP53 is deleted in 7% and 87% of MF and SS, respectively. In both human and mouse samples, PD1 mutations drive aggressive behavior. PD1 wild-type lymphomas show features of T-cell exhaustion. PD1 deletions are sufficient to reverse the exhaustion phenotype, promote a FOXM1-driven transcriptional signature, and predict significantly worse survival. Collectively, our findings clarify CTCL genetics and provide novel insights into pathways that drive diverse disease phenotypes.

Original language	English (US)
Pages (from-to)	1225-1236
Number of pages	12
Journal	Blood
Volume	138
Issue number	14
DOIs	https://doi.org/10.1182/blood.2020009655
State	Published - Oct 7 2021

Funding

J.C. was supported, in part, by National Institutes of Health (NIH), National Cancer Institute (NCI), grants K08-CA191019-01A1 and National Institute of Allergy and Infectious Diseases Extramural Activities 1DP2AI136599-01), the Skin Cancer Foundation, the Leukemia Research Foundation, the Doris Duke Charitable Foundation, and the Damon Runyon Foundation (DRCRF# CI-84-16, DDCF# 2016095, DDCF CRM Award). J.D. was supported in part by NIH, NCI training grant T32 CA009560. J.R. was supported by research grants from the Deutsche Forschungsgemeinschaft (DFG; German Research Foundation; Project-ID 210592381-SFB 1054; Project-ID 360372040-SFB 1335; Project-ID 395357507-SFB 1371; Project-ID 369799452-TRR 237; and RU 695/9-1) and the European Research Council under the European Union's Horizon 2020 research and innovation program (grant agreement 834154). D.R. was supported, in part, by NIH, National Institute of Arthritis and Musculoskeletal and Skin Diseases grants K080AR072791 and P30AR070253 and the Doris Duke Charitable Foundation. The authors thank the patients, the Northwestern Skin Disease Research Center, the Flow Cytometry Core, the Northwestern University Research Computing Services, and Admera Health for invaluable contributions. J.C. was supported, in part, by National Institutes of Health (NIH), National Cancer Institute (NCI), grants K08-CA191019-01A1 and National Institute of Allergy and Infectious Diseases Extramural Activities 1DP2AI136599-01), the Skin Cancer Foundation, the Leukemia Research Foundation, the Doris Duke Charitable Foundation, and the Damon Runyon Foundation (DRCRF# CI-84-16, DDCF# 2016095, DDCF CRM Award). J.D. was supported in part by NIH, NCI training grant T32 CA009560. J.R. was supported by research grants from the Deutsche Forschungsgemeinschaft (DFG; German Research Foundation; Project-ID 210592381-SFB 1054; Project-ID 360372040-SFB 1335; Project-ID 395357507-SFB 1371; Project-ID 369799452-TRR 237; and RU 695/9-1) and the European Research Council under the European Union's Horizon 2020 research and innovation program (grant agreement 834154). D.R. was supported, in part, by NIH, National Institute of Arthritis and Musculoskeletal and Skin Diseases grants K080AR072791 and P30AR070253 and the Doris Duke Charitable Foundation.

ASJC Scopus subject areas

Biochemistry
Immunology
Hematology
Cell Biology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1182/blood.2020009655

Cite this

Park, J., Daniels, J., Wartewig, T., Ringbloom, K. G., Martinez-Escala, M. E., Choi, S., Thomas, J. J., Doukas, P. G., Yang, J., Snowden, C., Law, C., Lee, Y., Lee, K., Zhang, Y., Conran, C., Tegtmeyer, K., Mo, S. H., Pease, D. R., Jothishankar, B., ... Choi, J. (2021). Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity. Blood, 138(14), 1225-1236. https://doi.org/10.1182/blood.2020009655

@article{b926c147705946958ec413fe393e2fb9,

title = "Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity",

abstract = "Cutaneous T-cell lymphomas (CTCLs) are a clinically heterogeneous collection of lymphomas of the skin-homing T cell. To identify molecular drivers of disease phenotypes, we assembled representative samples of CTCLs from patients with diverse disease subtypes and stages. Via DNA/RNA-sequencing, immunophenotyping, and ex vivo functional assays, we identified the landscape of putative driver genes, elucidated genetic relationships between CTCLs across disease stages, and inferred molecular subtypes in patients with stage-matched leukemic disease. Collectively, our analysis identified 86 putative driver genes, including 19 genes not previously implicated in this disease. Two mutations have never been described in any cancer. Functionally, multiple mutations augment T-cell receptor–dependent proliferation, highlighting the importance of this pathway in lymphomagenesis. To identify putative genetic causes of disease heterogeneity, we examined the distribution of driver genes across clinical cohorts. There are broad similarities across disease stages. Many driver genes are shared by mycosis fungoides (MF) and Sezary syndrome (SS). However, there are significantly more structural variants in leukemic disease, leading to highly recurrent deletions of putative tumor suppressors that are uncommon in early-stage skin-centered MF. For example, TP53 is deleted in 7% and 87% of MF and SS, respectively. In both human and mouse samples, PD1 mutations drive aggressive behavior. PD1 wild-type lymphomas show features of T-cell exhaustion. PD1 deletions are sufficient to reverse the exhaustion phenotype, promote a FOXM1-driven transcriptional signature, and predict significantly worse survival. Collectively, our findings clarify CTCL genetics and provide novel insights into pathways that drive diverse disease phenotypes.",

author = "Joonhee Park and Jay Daniels and Tim Wartewig and Ringbloom, {Kimberly G.} and Martinez-Escala, {Maria Estela} and Sara Choi and Thomas, {Jane J.} and Doukas, {Peter G.} and Jingyi Yang and Caroline Snowden and Calvin Law and Yujin Lee and Katie Lee and Yancong Zhang and Carly Conran and Kyle Tegtmeyer and Mo, {Samuel H.} and Pease, {David R.} and Balaji Jothishankar and Kwok, {Pui Yan} and Abdulla, {Farah R.} and Barbara Pro and Abner Louissaint and Boggon, {Titus J.} and Jeffrey Sosman and Joan Guitart and Deepak Rao and J{\"u}rgen Ruland and Jaehyuk Choi",

note = "Publisher Copyright: {\textcopyright} 2021 American Society of Hematology",

year = "2021",

month = oct,

day = "7",

doi = "10.1182/blood.2020009655",

language = "English (US)",

volume = "138",

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journal = "Blood",

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Park, J, Daniels, J, Wartewig, T, Ringbloom, KG, Martinez-Escala, ME, Choi, S, Thomas, JJ, Doukas, PG, Yang, J, Snowden, C, Law, C, Lee, Y, Lee, K, Zhang, Y, Conran, C, Tegtmeyer, K, Mo, SH, Pease, DR, Jothishankar, B, Kwok, PY, Abdulla, FR, Pro, B, Louissaint, A, Boggon, TJ, Sosman, J, Guitart, J, Rao, D, Ruland, J & Choi, J 2021, 'Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity', Blood, vol. 138, no. 14, pp. 1225-1236. https://doi.org/10.1182/blood.2020009655

TY - JOUR

T1 - Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity

AU - Park, Joonhee

AU - Daniels, Jay

AU - Wartewig, Tim

AU - Ringbloom, Kimberly G.

AU - Martinez-Escala, Maria Estela

AU - Choi, Sara

AU - Thomas, Jane J.

AU - Doukas, Peter G.

AU - Yang, Jingyi

AU - Snowden, Caroline

AU - Law, Calvin

AU - Lee, Yujin

AU - Lee, Katie

AU - Zhang, Yancong

AU - Conran, Carly

AU - Tegtmeyer, Kyle

AU - Mo, Samuel H.

AU - Pease, David R.

AU - Jothishankar, Balaji

AU - Kwok, Pui Yan

AU - Abdulla, Farah R.

AU - Pro, Barbara

AU - Louissaint, Abner

AU - Boggon, Titus J.

AU - Sosman, Jeffrey

AU - Guitart, Joan

AU - Rao, Deepak

AU - Ruland, Jürgen

AU - Choi, Jaehyuk

PY - 2021/10/7

Y1 - 2021/10/7

N2 - Cutaneous T-cell lymphomas (CTCLs) are a clinically heterogeneous collection of lymphomas of the skin-homing T cell. To identify molecular drivers of disease phenotypes, we assembled representative samples of CTCLs from patients with diverse disease subtypes and stages. Via DNA/RNA-sequencing, immunophenotyping, and ex vivo functional assays, we identified the landscape of putative driver genes, elucidated genetic relationships between CTCLs across disease stages, and inferred molecular subtypes in patients with stage-matched leukemic disease. Collectively, our analysis identified 86 putative driver genes, including 19 genes not previously implicated in this disease. Two mutations have never been described in any cancer. Functionally, multiple mutations augment T-cell receptor–dependent proliferation, highlighting the importance of this pathway in lymphomagenesis. To identify putative genetic causes of disease heterogeneity, we examined the distribution of driver genes across clinical cohorts. There are broad similarities across disease stages. Many driver genes are shared by mycosis fungoides (MF) and Sezary syndrome (SS). However, there are significantly more structural variants in leukemic disease, leading to highly recurrent deletions of putative tumor suppressors that are uncommon in early-stage skin-centered MF. For example, TP53 is deleted in 7% and 87% of MF and SS, respectively. In both human and mouse samples, PD1 mutations drive aggressive behavior. PD1 wild-type lymphomas show features of T-cell exhaustion. PD1 deletions are sufficient to reverse the exhaustion phenotype, promote a FOXM1-driven transcriptional signature, and predict significantly worse survival. Collectively, our findings clarify CTCL genetics and provide novel insights into pathways that drive diverse disease phenotypes.

AB - Cutaneous T-cell lymphomas (CTCLs) are a clinically heterogeneous collection of lymphomas of the skin-homing T cell. To identify molecular drivers of disease phenotypes, we assembled representative samples of CTCLs from patients with diverse disease subtypes and stages. Via DNA/RNA-sequencing, immunophenotyping, and ex vivo functional assays, we identified the landscape of putative driver genes, elucidated genetic relationships between CTCLs across disease stages, and inferred molecular subtypes in patients with stage-matched leukemic disease. Collectively, our analysis identified 86 putative driver genes, including 19 genes not previously implicated in this disease. Two mutations have never been described in any cancer. Functionally, multiple mutations augment T-cell receptor–dependent proliferation, highlighting the importance of this pathway in lymphomagenesis. To identify putative genetic causes of disease heterogeneity, we examined the distribution of driver genes across clinical cohorts. There are broad similarities across disease stages. Many driver genes are shared by mycosis fungoides (MF) and Sezary syndrome (SS). However, there are significantly more structural variants in leukemic disease, leading to highly recurrent deletions of putative tumor suppressors that are uncommon in early-stage skin-centered MF. For example, TP53 is deleted in 7% and 87% of MF and SS, respectively. In both human and mouse samples, PD1 mutations drive aggressive behavior. PD1 wild-type lymphomas show features of T-cell exhaustion. PD1 deletions are sufficient to reverse the exhaustion phenotype, promote a FOXM1-driven transcriptional signature, and predict significantly worse survival. Collectively, our findings clarify CTCL genetics and provide novel insights into pathways that drive diverse disease phenotypes.

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JO - Blood

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Integrated genomic analyses of cutaneous T-cell lymphomas reveal the molecular bases for disease heterogeneity

Abstract

Funding

ASJC Scopus subject areas

UN SDGs

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