Using DNA sequencing data to quantify T cell fraction and therapy response

Bentham, Robert; Litchfield, Kevin; Watkins, Thomas B.K.; Lim, Emilia L.; Rosenthal, Rachel; Martínez-Ruiz, Carlos; Hiley, Crispin; Bakir, Maise Al; Salgado, Roberto; Moore, David A.; Jamal‐Hanjani, Mariam; Birkbak, Nicolai J.; Escudero, Mickael; Stewart, Grant D.; Rowan, Andrew; Goldman, Jacki; Loo, Peter Van; Stone, Richard; Denner, Tamara; Nye, Emma; Ward, Sophia; Boeing, Stefan; Greco, Maria; Nicod, Jérôme; Puttick, Clare; Enfield, Katey S.S.; Colliver, Emma; Campbell, Brittany; Frankell, Alexander M.; Cook, Daniel E.; Angelova, Mihaela; Magness, Alastair; Bailey, Chris; Toncheva, Antonia; Dijkstra, Krijn K.; Kisistók, Judit; Sokač, Mateo; Pich, Oriol; Demeulemeester, Jonas; Cadieux, Elizabeth Larose; Castignani, Carla; Thakkar, Krupa; Fu, Hongchang; Karasaki, Takahiro; Al‐Sawaf, Othman; Hill, Mark S.; Abbosh, Christopher; Wu, Yin; Veeriah, Selvaraju; Hynds, Robert E.; Georgiou, Andrew; Sunderland, Mariana Werner; Reading, James L.; Quezada, Sergio A.; Peggs, Karl S.; Marafioti, Teresa; Hartley, John A.; Lowe, Helen; Ensell, Leah; Spanswick, Victoria J.; Karamani, Angeliki; Biswas, Dhruva; Beck, Stephan; Chervova, Olga; Tanić, Miljana; Huebner, Ariana; Dietzen, Michelle; Black, James R.; Naceur-Lombardelli, Cristina; Akther, Mita Afroza; Zhai, Hao‐Ran; Kanu, Nnennaya; Summan, Simranpreet; Gimeno-Valiente, Francisco; Chen, Kezhong; Manzano, Elizabeth; Bola, Supreet Kaur; Ghorani, Ehsan; Massy, Marc Robert de; Hoxha, Elena; Hatipoglu, Emine; Chain, Benny; Pearce, David R.; Herrero, Javier; Zaccaria, Simone; Lester, J.F.; Morgan, Fiona J. E.; Kornaszewska, Malgorzata; Attanoos, Richard; Adams, Haydn; Davies, Helen; Shaw, Jacqui A.; Riley, Joan; Primrose, Lindsay; Fennell, Dean A.; Nakas, Apostolos; Rathinam, Sridhar; Plummer, Rachel; Boyles, Rebecca; Tufail, Mohamad; Bajaj, Amrita; Brožík, Jan; Ang, Keng; Chowdhry, Mohammed Fiyaz; Monteiro, William; Marshall, Hilary; Dawson, Alan G.; Busacca, Sara; Marrone, Domenic; Smith, Claire; Anand, Girija; Khan, Sajid; Price, Gillian; Khalil, Mohammed; Kerr, Keith M.; Richardson, Shirley; Cheyne, Heather; Miller, J. Richard; Buchan, Keith; Chetty, Mahendran; Dubois-Marshall, Sylvie; Löck, S.; Gilbert, Kayleigh; Naidu, Babu; Langman, Gerald; Bancroft, Hollie; Kadiri, Salma; Middleton, Gary; Djearaman, Madava; Osman, Aya; Shackleford, Helen; Patel, Akshay J.; Leek, Angela; Totten, Nicola; Hodgkinson, Jack Davies; Rogan, Jane; Moore, Katrina; Waddington, Rachael; Califano, Raffaele; Shah, Rajesh; Krysiak, Piotr; Rammohan, Kendadai; Fontaine, Eustace; Booton, Richard; Evison, Matthew; Moss, Stuart B.; Novasio, Juliette; Joseph, Leena Dennis; Bishop, Paul; Chaturvedi, Anshuman; Doran, Helen; Granato, Felice; Joshi, Vijay; Smith, Elaine; Montero, Ángeles; Crosbie, Philip; Blackhall, Fiona; Priest, Lynsey; Krebs, Matthew; Dive, Caroline; Rothwell, Dominic G.; Kerr, Alastair; Kilgour, Elaine; Baker, Katie; Carter, Mathew; Lindsay, Colin R.; Gomes, Fábio; Tugwood, Jonathan; Pierce, Jackie; Clipson, Alexandra; Schwarz, Roland F.; Kaufmann, Tom L.; Huska, Matthew R.; Szállási, Zoltán; Csabai, István; Dióssy, Miklós; Aerts, Hugo J.W.L.; Fekete, Charles; Royle, Gary; Veiga, Catarina; Skrzypski, Marcin; Lawrence, David; Hayward, Martin; Παναγιωτόπουλος, Νικόλαος; George, Robert; Patrini, Davide; Falzon, Mary; Borg, Elaine; Khiroya, Reena; Ahmed, Asia; Taylor, Magali; Choudhary, Junaid; Janes, Sam M.; Förster, Martin; Ahmad, Tanya; Lee, Siow Ming; Navani, Neal; Scarci, Marco; Gorman, Pat; Bertoja, Elisa; Stephens, Robert; Hoogenboom, Emilie Martinoni; Holding, James W.; Bandula, Steve; Thakrar, Ricky M.; Anand, Radhi; Selvaraju, Kayalvizhi; Wilson, James M.; Hessey, Sonya; Ashford, Paul; Shah, Mansi; Duran, Marcos Vasquez; MacKenzie, Mairead; Wilcox, Maggie; Hackshaw, Allan; Ngai, Yenting; Sharp, Abigail; Rodrigues, Cecília M. P.; Pressey, Oliver; Smith, Sean; Gower, Nicole; Dhanda, Harjot Kaur; Chan, Kitty S.; Chakraborty, Sonal; Ottensmeier, Christian; Chee, Serena; Johnson, Benjamin; Alzetani, Aiman; Cave, Judith; Scarlett, Lydia; Shaw, Emily; Lim, Eric; Sousa, Paulo De; Jordan, Simon; Rice, Alexandra; Raubenheimer, Hilgardt; Bhayani, Harshil; Hamilton, Morag; Ambrose, Lyn; Devaraj, Anand; Chavan, Hema; Begum, Sofina; Buderi, Silviu; Kaniu, Daniel; Malima, Mpho; Booth, Sarah; Nicholson, Andrew G.; Fernandes, Nadia; Deeley, Christopher; Shah, Pratibha; Proli, Chiara; Lau, Kelvin; Sheaff, Michael; Schmid, Peter; Lim, Louise; Conibear, John; Hewish, Madeleine; Danson, Sarah; Bury, Jonathan; Edwards, John F.; Hill, Jennifer; Matthews, Sue; Kitsanta, Yota; Rao, Jagan; Tenconi, Sara; Socci, Laura; Suvarna, Kim; Kibutu, Faith; Fisher, Patricia; Young, Robin; Barker, Joann; Taylor, Fiona; Lloyd, Kirsty; Shackcloth, Michael; Asante-Siaw, Julius; Gosney, John R.; Light, Teresa; Horey, Tracey; Russell, Peter; Papadatos-Pastos, Dionysis; Blyth, Kevin G.; Dick, Craig; Kidd, Andrew; Kirk, Alan; Asif, Mo; Butler, J. A. V.; Bilancia, Rocco; Kostoulas, Nikos; Thomas, Mathew; Wilson, Gareth A.; Swanton, Charles; McGranahan, Nicholas

doi:10.1038/s41586-021-03894-5

Cited by 55 publications

(28 citation statements)

References 59 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These DNA methylation profiles that are able to predict clinical response to immunotherapy have also been extended to melanoma patients ( 5 ). In addition, recent development of sophisticated computational methods allows the inference of T-cell infiltration into tumor samples from whole exome sequencing data, which can predict the response to immune checkpoint inhibitors independently of tumor mutational burden ( 6 ). Finally, the advancement of single-cell technologies also holds great potential to refine the search for predictors of treatment response, personalize patients’ management, and increase the responders to nonresponders’ ratio ( 7-9 ).…”

mentioning

confidence: 99%

Biological and Molecular Factors Predicting Response to Adoptive Cell Therapies in Cancer

Ferrer

Álvarez-Errico

Esteller

2022

JNCI: Journal of the National Cancer Institute

View full text Add to dashboard Cite

Adoptive cell therapy (ACT) constitutes a major breakthrough in cancer management that has expanded in the past years due to impressive results showing durable and even curative responses for some patients with hematological malignancies. ACT leverages antigen specificity and cytotoxic mechanisms of the immune system, particularly relying on the patient´s T lymphocytes to target and eliminate malignant cells. This personalized therapeutic approach exemplifies the success of the joint effort of basic, translational and clinical researchers that has turned the patient´s immune system into a great ally in the search for a cancer cure. Adoptive cell therapies are constantly improving to reach a maximum beneficial clinical response. Despite being very promising therapeutic options for certain types of cancers, mainly melanoma and hematological malignancies, these individualized treatments still present several shortcomings including elevated costs, technical challenges, management of adverse side effects and a limited population of responder patients. Thus, it is crucial to discover and develop reliable and robust biomarkers to specifically and sensitively pinpoint the patients that will benefit the most from ACT, as well as those that are at higher risk of developing potentially serious toxicities. Although unique readouts of infused cell therapy success have not yet been identified, certain characteristics from the adoptive cells, the tumor and/or the tumor microenvironment have been recognized to predict patients' outcome upon ACT. Here, we comment on the importance of biomarkers to predict ACT chances of success to maximize efficacy of treatments and increase patients' survival.

show abstract

mentioning

confidence: 99%

Biological and Molecular Factors Predicting Response to Adoptive Cell Therapies in Cancer

Ferrer

Álvarez-Errico

Esteller

2022

JNCI: Journal of the National Cancer Institute

View full text Add to dashboard Cite

show abstract

“…Furthermore, the results were similar when using the cohort’s optimal TMB cutoff determined by the ROC curve and the Youden index or using log(10)-transformed TMB as a continuous variable (Figure S15). Even when the recently reported score for estimating T-cell infiltration in tumors from WES data 21 was added as a covariate, there remained a significant correlation between irGS and ICI response (Figure S16). Genome subtyping and ICI response analysis by GS-PRACTICE for each of the 13 individual ICI studies comprising the combined 973 patients are described in Figure S17 and Table S4.…”

Section: Resultsmentioning

confidence: 98%

Mutation burden-orthogonal tumor genomic subtypes delineate responses to immune checkpoint therapy

Takamatsu

Hamanishi

Brown

et al. 2021

Preprint

View full text Add to dashboard Cite

Background: In cancer therapy, precise tumor-agnostic biomarkers that predict response to immune checkpoint inhibitors (ICIs) are needed. To explain treatment response differences among tumor types, the application of mutational signatures, patterns of genomic alterations that reflect differences in distinct underlying carcinogenic processes, holds promise but has not been extensively integrated into prediction methodologies. Methods: Based on mutational signature analysis, we developed a stratification for all solid tumors in The Cancer Genome Atlas (TCGA). Then, we developed the Tumor Genomic Subtype Analyzer (TGSA) to classify tumors submitted to whole-exome sequencing. Using existing data from 938 pan-cancer ICI-treated cases with outcomes, we evaluated the subtype-response predictive performance. Results: Systematic analysis on TCGA samples identified eight tumor genomic subtypes, which were characterized by features represented by smoking exposure, ultraviolet light exposure, APOBEC enzyme activity, POLE mutation, mismatch repair deficiency, homologous recombination deficiency, genomic stability, and aging. The former five subtypes were presumed to form an immune-responsive group acting as candidates for ICI therapy because of their high expression of immune-related genes and enrichment in cancer types with FDA approval for ICI monotherapy. In the validation cohort, the samples assigned by TGSA to the immune-reactive subtypes were significantly related to ICI response independent of cancer type and high TMB status. Conclusion: Mutational signature-based tumor subtyping can serve as a tumor-agnostic biomarker for ICI response prediction. The results indicate that the mutational process underlying carcinogenesis affects tumor immunogenicity, and thus sensitivity to ICI.

show abstract

“…then TILs, using morphology, evaluated according to established guidelines, or with immunohistochemistry for CD8, or even by DNAsequencing [10], may one day be used in daily practice in a rational and biological plausible manner.…”

Section: Declaration Of Competing Interestmentioning

confidence: 99%