A community challenge to predict clinical outcomes after immune checkpoint blockade in non-small cell lung cancer

Mike Mason; Óscar Lapuente-Santana; Anni S Halkola; Wenyu Wang; Raghvendra Mall; Xu Xiao; Jacob Kaufman; Jingxin Fu; Jacob Pfeil; Jineta Banerjee; Verena Chung; Han Chang; Scott D Chasalow; Hung Ying Lin; Rongrong Chai; Thomas Yu; Francesca Finotello; Tuomas Mirtti; Mikko I Mäyränpää; Jie Bao; Emmy W Verschuren; Eiman I Ahmed; Michele Ceccarelli; Lance D Miller; Gianni Monaco; Wouter R L Hendrickx; Shimaa Sherif; Lin Yang; Ming Tang; Shengqing Stan Gu; Wubing Zhang; Yi Zhang; Zexian Zeng; Avinash Das Sahu; Yang Liu; Wenxian Yang; Davide Bedognetti; Jing Tang; Federica Eduati; Teemu D Laajala; William J Geese; Justin Guinney; Joseph D Szustakowski; Benjamin G Vincent; David P Carbone

doi:10.1186/s12967-023-04705-3

A community challenge to predict clinical outcomes after immune checkpoint blockade in non-small cell lung cancer

J Transl Med. 2024 Feb 21;22(1):190. doi: 10.1186/s12967-023-04705-3.

Authors

Mike Mason¹, Óscar Lapuente-Santana^#², Anni S Halkola^#³, Wenyu Wang^#⁴, Raghvendra Mall^#^{5

6

7}, Xu Xiao^#^{8

9}, Jacob Kaufman^#^{10

11}, Jingxin Fu^#¹², Jacob Pfeil^#¹³, Jineta Banerjee¹⁴, Verena Chung¹⁴, Han Chang¹, Scott D Chasalow¹, Hung Ying Lin¹, Rongrong Chai¹⁴, Thomas Yu¹⁴, Francesca Finotello^{15

16}, Tuomas Mirtti^{17

18

19

20}, Mikko I Mäyränpää¹⁷, Jie Bao⁴, Emmy W Verschuren²¹, Eiman I Ahmed²², Michele Ceccarelli^{23

24}, Lance D Miller^{25

26}, Gianni Monaco²⁴, Wouter R L Hendrickx^{22

27}, Shimaa Sherif^{22

27}, Lin Yang¹², Ming Tang¹², Shengqing Stan Gu¹², Wubing Zhang¹², Yi Zhang¹², Zexian Zeng¹², Avinash Das Sahu¹², Yang Liu^#¹², Wenxian Yang^#²⁸, Davide Bedognetti^#^{22

27

29}, Jing Tang^#^{4

30}, Federica Eduati^#^{2

31}, Teemu D Laajala^#^{3

17

18

19

32

33}, William J Geese¹, Justin Guinney^#³⁴, Joseph D Szustakowski^#¹, Benjamin G Vincent^#³⁵, David P Carbone^#³⁶

Affiliations

¹ Bristol Myers Squibb, Princeton, NJ, USA.
² Department of Biomedical Engineering, Eindhoven University of Technology, Eindhoven, The Netherlands.
³ Department of Mathematics and Statistics, University of Turku, Turku, Finland.
⁴ Faculty of Medicine, Research Program in Systems Oncology, University of Helsinki, Helsinki, Finland.
⁵ Qatar Computing Research Institute, Hamad Bin Khalifa University, P.O. Box 34110, Doha, Qatar.
⁶ Department of Immunology, St. Jude Children's Research Hospital, P.O. Box 38105, Memphis, TN, USA.
⁷ Biotechnology Research Center, Technology Innovation Institute, P.O. Box 9639, Abu Dhabi, United Arab Emirates.
⁸ School of Informatics, Xiamen University, Xiamen, China.
⁹ National Institute for Data Science in Health and Medicine, Xiamen University, Xiamen, China.
¹⁰ Department of Medicine, Duke University, Durham, NC, USA.
¹¹ The Ohio State University Comprehensive Cancer Center, Columbus, OH, USA.
¹² Dana-Farber Cancer Institute, Boston, MA, USA.
¹³ AbbVie, South San Francisco, CA, USA.
¹⁴ Sage Bionetworks, Seattle, WA, USA.
¹⁵ Institute of Molecular Biology, University of Innsbruck, Innsbruck, Austria.
¹⁶ Digital Science Center (DiSC), University of Innsbruck, Innsbruck, Austria.
¹⁷ Department of Pathology, University of Helsinki and Helsinki University Hospital, Helsinki, Finland.
¹⁸ Research Program in Systems Oncology, University of Helsinki, Helsinki, Finland.
¹⁹ iCAN-Digital Precision Cancer Medicine Flagship, Helsinki, Finland.
²⁰ Department of Biomedical Engineering, School of Medicine, Emory University, Atlanta, GA, USA.
²¹ Institute for Molecular Medicine Finland (FIMM), HiLIFE, University of Helsinki, Helsinki, Finland.
²² Human Immunology Department, Sidra Medicine, P.O. Box 26999, Doha, Qatar.
²³ Department of Electrical Engineering and Information Technology (DIETI), University of Naples "Federico II", 80125, Naples, Italy.
²⁴ BIOGEM Institute of Molecular Biology and Genetics, Via Camporeale, Ariano Irpino, Italy.
²⁵ Department of Cancer Biology, Wake Forest School of Medicine, Winston-Salem, NC, USA.
²⁶ Atrium Health Wake Forest Baptist Comprehensive Cancer Center, Winston-Salem, NC, USA.
²⁷ College of Health and Life Sciences, Hamad Bin Khalifa University, P.O. Box 26999, Doha, Qatar.
²⁸ Aginome Scientific, Xiamen, China.
²⁹ Department of Internal Medicine and Medical Specialties, University of Genoa, Genoa, Italy.
³⁰ Department of Biochemistry and Developmental Biology, Faculty of Medicine, University of Helsinki, Helsinki, Finland.
³¹ Institute for Complex Molecular Systems (ICMS), Eindhoven University of Technology, Eindhoven, The Netherlands.
³² FICAN West Cancer Centre, University of Turku and Turku University Hospital, Turku, Finland.
³³ Department of Pharmacology, Anschutz Medical Campus, University of Colorado, Denver, CO, USA.
³⁴ Tempus Labs, Chicago, IL, USA.
³⁵ Department of Medicine, Division of Hematology, Department of Microbiology and Immunology, Curriculum in Bioinformatics and Computational Biology, Computational Medicine Program, University of North Carolina at Chapel Hill, Chapel Hill, NC, USA.
³⁶ The Ohio State University Comprehensive Cancer Center, Columbus, OH, USA. david.p.carbone@gmail.com.

^# Contributed equally.

Abstract

Background: Predictive biomarkers of immune checkpoint inhibitor (ICI) efficacy are currently lacking for non-small cell lung cancer (NSCLC). Here, we describe the results from the Anti-PD-1 Response Prediction DREAM Challenge, a crowdsourced initiative that enabled the assessment of predictive models by using data from two randomized controlled clinical trials (RCTs) of ICIs in first-line metastatic NSCLC.

Methods: Participants developed and trained models using public resources. These were evaluated with data from the CheckMate 026 trial (NCT02041533), according to the model-to-data paradigm to maintain patient confidentiality. The generalizability of the models with the best predictive performance was assessed using data from the CheckMate 227 trial (NCT02477826). Both trials were phase III RCTs with a chemotherapy control arm, which supported the differentiation between predictive and prognostic models. Isolated model containers were evaluated using a bespoke strategy that considered the challenges of handling transcriptome data from clinical trials.

Results: A total of 59 teams participated, with 417 models submitted. Multiple predictive models, as opposed to a prognostic model, were generated for predicting overall survival, progression-free survival, and progressive disease status with ICIs. Variables within the models submitted by participants included tumor mutational burden (TMB), programmed death ligand 1 (PD-L1) expression, and gene-expression-based signatures. The best-performing models showed improved predictive power over reference variables, including TMB or PD-L1.

Conclusions: This DREAM Challenge is the first successful attempt to use protected phase III clinical data for a crowdsourced effort towards generating predictive models for ICI clinical outcomes and could serve as a blueprint for similar efforts in other tumor types and disease states, setting a benchmark for future studies aiming to identify biomarkers predictive of ICI efficacy.

Trial registration: CheckMate 026; NCT02041533, registered January 22, 2014. CheckMate 227; NCT02477826, registered June 23, 2015.

Keywords: Biomarkers; Crowdsource; Immune checkpoint inhibitor; Non-small cell lung cancer; Predictive model; Programmed death ligand 1; Programmed death-1.

MeSH terms

B7-H1 Antigen
Biomarkers, Tumor
Carcinoma, Non-Small-Cell Lung* / drug therapy
Carcinoma, Non-Small-Cell Lung* / genetics
Humans
Immune Checkpoint Inhibitors / therapeutic use
Lung Neoplasms* / pathology

Substances

Immune Checkpoint Inhibitors
B7-H1 Antigen
Biomarkers, Tumor

Associated data

ClinicalTrials.gov/NCT02041533
ClinicalTrials.gov/NCT02477826