Autotaxin suppresses cytotoxic T cells via LPAR5 to promote anti–PD-1 resistance in non–small cell lung cancer
Jessica M. Konen, … , Jianjun Zhang, Don L. Gibbons
Jessica M. Konen, … , Jianjun Zhang, Don L. Gibbons
Published September 1, 2023
Citation Information: J Clin Invest. 2023;133(17):e163128. https://doi.org/10.1172/JCI163128.
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Research Article Immunology Oncology

Autotaxin suppresses cytotoxic T cells via LPAR5 to promote anti–PD-1 resistance in non–small cell lung cancer

Abstract

Non–small cell lung cancers that harbor concurrent KRAS and TP53 (KP) mutations are immunologically warm tumors with partial responsiveness to anti–PD-(L)1 blockade; however, most patients observe little or no durable clinical benefit. To identify novel tumor-driven resistance mechanisms, we developed a panel of KP murine lung cancer models with intrinsic resistance to anti–PD-1 and queried differential gene expression between these tumors and anti–PD-1–sensitive tumors. We found that the enzyme autotaxin (ATX), and the metabolite it produces, lysophosphatidic acid (LPA), were significantly upregulated in resistant tumors and that ATX directly modulated antitumor immunity, with its expression negatively correlating with total and effector tumor-infiltrating CD8+ T cells. Pharmacological inhibition of ATX, or the downstream receptor LPAR5, in combination with anti–PD-1 was sufficient to restore the antitumor immune response and efficaciously control lung tumor growth in multiple KP tumor models. Additionally, ATX was significantly correlated with inflammatory gene signatures, including a CD8+ cytolytic score in multiple lung adenocarcinoma patient data sets, suggesting that an activated tumor-immune microenvironment upregulates ATX and thus provides an opportunity for cotargeting to prevent acquired resistance to anti–PD-1 treatment. These data reveal the ATX/LPA axis as an immunosuppressive pathway that diminishes the immune checkpoint blockade response in lung cancer.

Authors

Jessica M. Konen, B. Leticia Rodriguez, Haoyi Wu, Jared J. Fradette, Laura Gibson, Lixia Diao, Jing Wang, Stephanie Schmidt, Ignacio I. Wistuba, Jianjun Zhang, Don L. Gibbons

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Figure 3

Enpp2/ATX is upregulated with PD-(L)1 resistance in KP murine models and cytolytic gene signature in patients with human lung adenocarcinoma.

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Enpp2/ATX is upregulated with PD-(L)1 resistance in KP murine models an...
(A) Previously published transcriptomics from IgG or anti–PD-L1–treated 344SQ tumors were analyzed at week 5 (response) and week 7 (resistance) (17). DEGs between treatments at each time point (225 total) were analyzed for directionality, and we focused on DEGs that changed in directionality between time points (dashed box). (B) The top DEGs from A were analyzed via quantitative PCR in 344SQPD1S1 and 344SQPD1R2 cells and are graphed relative to 344SQPD1S1. Arrows denote genes changing in the same direction as the microarray. All genes except those marked “NS” are significantly different at P < 0.05, by t test. (C) The 344SQPD1S and 344SQPD1R cells (top) and tumors (bottom) were analyzed via Western blotting for Enpp2/ATX expression. Actin densitometric values were normalized to the corresponding actin band and then to the first lane. (D) Representative ATX IHC images in anti–PD-L1– or IgG-treated 344SQPD1S1 and 344SQPD1R2 (top) or KPIgG and KPPDL1 (bottom) tumors. Scale bars: 50 μm; insets zoomed 200%. (E) Conditioned media from 344SQPD1S and 344SQPD1R models were analyzed for LPA via ELISA. **P < 0.01, by 1-way ANOVA. (F) ENPP2 expression in lung adenocarcinoma patients with lung adenocarcinoma was correlated with a previously described T cell cytolytic score (CYT) (62) in BATTLE-2 (top) and TCGA Firehouse Legacy (bottom) data sets. (G) ENPP2 expression in TCGA Firehouse Legacy samples was correlated with a previously published inflammatory gene signature (33) (rho cutoff, 0.4; FDR, 0.05). (H and I) Analysis of ENPP2 in the MD Anderson ICON data set. (H) Correlation of ENPP2 with the CYT score as described in F. (I) ENPP2 expression was compared across ICON patients grouped as having a low, neutral, or high CYT score. *P < 0.05 and ****P < 0.0001, by Wilcoxon’s rank-sum testing.