Seguí, E. (E.)

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    Association between PD1 mRNA and response to anti-PD1 monotherapy across multiple cancer types
    (Elsevier BV, 2018) Adamo, B. (B.); Prat, A. (A.); Font, C. (C.); Rodríguez, A. (A.); Garcia-Corbacho, J. (J.); Viñolas, N. (N.); Mellado, B. (B.); Gaba, L. (L.); Seguí, E. (E.); Gonzalez-Cao, M. (María); Perez-Ruiz, E. (Elisabeth); Martin-Algarra, S. (Salvador); Ruiz, G. (G.); Paré, L. (L.); González, B. (B.); Arance, A. (Ana); Galván, P. (P.); Torné, A. (A.); Juan, M. (Manel); Llovet, J.M. (J. M.); Pineda, E. (E.); Teixidó, C. (Cristina); Victoria, I. (I.); Vidal, M. (M.); Cuatrecasas, M. (M.); Reig, Ó. (Ó.); Maurel, J. (J.); Reguart, N. (Noemi); Crespo, G. (Guillermo); Viladot, M. (M.); Muñoz, M. (M.); Pascual, T. (T.); Molina-Vila, M.A. (Miguel Angel)
    Background: We hypothesized that the abundance of PD1 mRNA in tumor samples might explain the differences in overall response rates (ORR) observed following anti-PD1 monotherapy across cancer types. Patients and methods: RNASeqv2 data from 10 078 tumor samples representing 34 different cancer types was analyzed from TCGA. Eighteen immune-related gene signatures and 547 immune-related genes, including PD1, were explored. Correlations between each gene/signature and ORRs reported in the literature following anti-PD1 monotherapy were calculated. To translate the in silico findings to the clinical setting, we analyzed the expression of PD1 mRNA using the nCounter platform in 773 formalin-fixed paraffin embedded (FFPE) tumor samples across 17 cancer types. To test the direct relationship between PD1 mRNA, PDL1 immunohistochemistry (IHC), stromal tumor-infiltrating lymphocytes (sTILs) and ORR, we evaluated an independent FFPE-based dataset of 117 patients with advanced disease treated with anti-PD1 monotherapy. Results: In pan-cancer TCGA, PD1 mRNA expression was found strongly correlated (r > 0.80) with CD8 T-cell genes and signatures and the proportion of PD1 mRNA-high tumors (80th percentile) within a given cancer type was variable (0%–84%). Strikingly, the PD1-high proportions across cancer types were found strongly correlated (r ¼ 0.91) with the ORR following antiPD1 monotherapy reported in the literature. Lower correlations were found with other immune-related genes/signatures, including PDL1. Using the same population-based cutoff (80th percentile), similar proportions of PD1-high disease in a given cancer type were identified in our in-house 773 tumor dataset as compared with TCGA. Finally, the pre-established PD1 mRNA FFPE-based cutoff was found significantly associated with anti-PD1 response in 117 patients with advanced disease (PD1-high 51.5%, PD1-intermediate 26.6% and PD1-low 15.0%; odds ratio between PD1-high and PD1-intermediate/low ¼ 8.31; P < 0.001). In this same dataset, PDL1 tumor expression by IHC or percentage of sTILs was not found associated with response. Conclusions: Our study provides a clinically applicable assay that links PD1 mRNA abundance, activated CD8 T-cells and anti-PD1 efficacy.