Literature DB >> 35552618

Tumor-Derived Lysophosphatidic Acid Blunts Protective Type I Interferon Responses in Ovarian Cancer.

Chang-Suk Chae1, Tito A Sandoval1, Sung-Min Hwang1, Eun Sil Park2, Paolo Giovanelli3,4, Deepika Awasthi1, Camilla Salvagno1, Alexander Emmanuelli1,3, Chen Tan1, Vidyanath Chaudhary5, Julia Casado6,7, Andrew V Kossenkov8, Minkyung Song9, Franck J Barrat3,5, Kevin Holcomb1, E Alfonso Romero-Sandoval10, Dmitriy Zamarin11, David Pépin12,13, Alan D D'Andrea13, Anniina Färkkilä6,7, Juan R Cubillos-Ruiz1,3,14.   

Abstract

Lysophosphatidic acid (LPA) is a bioactive lipid enriched in the tumor microenvironment of immunosuppressive malignancies such as ovarian cancer. Although LPA enhances the tumorigenic attributes of cancer cells, the immunomodulatory activity of this phospholipid messenger remains largely unexplored. Here, we report that LPA operates as a negative regulator of type I interferon (IFN) responses in ovarian cancer. Ablation of the LPA-generating enzyme autotaxin (ATX) in ovarian cancer cells reprogrammed the tumor immune microenvironment, extended host survival, and improved the effects of therapies that elicit protective responses driven by type I IFN. Mechanistically, LPA sensing by dendritic cells triggered PGE2 biosynthesis that suppressed type I IFN signaling via autocrine EP4 engagement. Moreover, we identified an LPA-controlled, immune-derived gene signature associated with poor responses to combined PARP inhibition and PD-1 blockade in patients with ovarian cancer. Controlling LPA production or sensing in tumors may therefore be useful to improve cancer immunotherapies that rely on robust induction of type I IFN. SIGNIFICANCE: This study uncovers that ATX-LPA is a central immunosuppressive pathway in the ovarian tumor microenvironment. Ablating this axis sensitizes ovarian cancer hosts to various immunotherapies by unleashing protective type I IFN responses. Understanding the immunoregulatory programs induced by LPA could lead to new biomarkers predicting resistance to immunotherapy in patients with cancer. See related commentary by Conejo-Garcia and Curiel, p. 1841. This article is highlighted in the In This Issue feature, p. 1825. ©2022 American Association for Cancer Research.

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Year:  2022        PMID: 35552618      PMCID: PMC9357054          DOI: 10.1158/2159-8290.CD-21-1181

Source DB:  PubMed          Journal:  Cancer Discov        ISSN: 2159-8274            Impact factor:   38.272


  65 in total

Review 1.  Dendritic cell rehab: new strategies to unleash therapeutic immunity in ovarian cancer.

Authors:  Chang-Suk Chae; Eli Teran-Cabanillas; Juan R Cubillos-Ruiz
Journal:  Cancer Immunol Immunother       Date:  2017-02-18       Impact factor: 6.968

Review 2.  Interferons α and β in cancer: therapeutic opportunities from new insights.

Authors:  Ernest C Borden
Journal:  Nat Rev Drug Discov       Date:  2019-03       Impact factor: 84.694

3.  Antitumor activity and safety of pembrolizumab in patients with advanced recurrent ovarian cancer: results from the phase II KEYNOTE-100 study.

Authors:  U A Matulonis; R Shapira-Frommer; A D Santin; A S Lisyanskaya; S Pignata; I Vergote; F Raspagliesi; G S Sonke; M Birrer; D M Provencher; J Sehouli; N Colombo; A González-Martín; A Oaknin; P B Ottevanger; V Rudaitis; K Katchar; H Wu; S Keefe; J Ruman; J A Ledermann
Journal:  Ann Oncol       Date:  2019-07-01       Impact factor: 32.976

4.  The Role of Prostaglandin E(2) in Tumor-Associated Immunosuppression.

Authors:  Dingzhi Wang; Raymond N DuBois
Journal:  Trends Mol Med       Date:  2015-12-17       Impact factor: 11.951

5.  PARP Inhibitor Efficacy Depends on CD8+ T-cell Recruitment via Intratumoral STING Pathway Activation in BRCA-Deficient Models of Triple-Negative Breast Cancer.

Authors:  Constantia Pantelidou; Olmo Sonzogni; Mateus De Oliveria Taveira; Anita K Mehta; Aditi Kothari; Dan Wang; Tanvi Visal; Michelle K Li; Jocelin Pinto; Jessica A Castrillon; Emily M Cheney; Peter Bouwman; Jos Jonkers; Sven Rottenberg; Jennifer L Guerriero; Gerburg M Wulf; Geoffrey I Shapiro
Journal:  Cancer Discov       Date:  2019-04-23       Impact factor: 39.397

6.  Autotaxin is induced by TSA through HDAC3 and HDAC7 inhibition and antagonizes the TSA-induced cell apoptosis.

Authors:  Song Li; Baolu Wang; Yan Xu; Junjie Zhang
Journal:  Mol Cancer       Date:  2011-02-12       Impact factor: 27.401

7.  Evaluation of serum ATX and LPA as potential diagnostic biomarkers in patients with pancreatic cancer.

Authors:  Jiang Chen; Hongyu Li; Wenda Xu; Xiaozhong Guo
Journal:  BMC Gastroenterol       Date:  2021-02-10       Impact factor: 3.067

Review 8.  The Expression Regulation and Biological Function of Autotaxin.

Authors:  Xiaotian Zhang; Mengmiao Li; Nan Yin; Junjie Zhang
Journal:  Cells       Date:  2021-04-19       Impact factor: 6.600

9.  Autotaxin impedes anti-tumor immunity by suppressing chemotaxis and tumor infiltration of CD8+ T cells.

Authors:  Elisa Matas-Rico; Elselien Frijlink; Irene van der Haar Àvila; Apostolos Menegakis; Maaike van Zon; Andrew J Morris; Jan Koster; Fernando Salgado-Polo; Sander de Kivit; Telma Lança; Antonio Mazzocca; Zoë Johnson; John Haanen; Ton N Schumacher; Anastassis Perrakis; Inge Verbrugge; Joost H van den Berg; Jannie Borst; Wouter H Moolenaar
Journal:  Cell Rep       Date:  2021-11-16       Impact factor: 9.423

Review 10.  Regulation of Tumor Immunity by Lysophosphatidic Acid.

Authors:  Sue Chin Lee; Mélanie A Dacheux; Derek D Norman; Louisa Balázs; Raul M Torres; Corinne E Augelli-Szafran; Gábor J Tigyi
Journal:  Cancers (Basel)       Date:  2020-05-10       Impact factor: 6.639
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  1 in total

Review 1.  Nanotechnological approaches for diagnosis and treatment of ovarian cancer: a review of recent trends.

Authors:  Haigang Ding; Juan Zhang; Feng Zhang; Yan Xu; Wenqing Liang; Yijun Yu
Journal:  Drug Deliv       Date:  2022-12       Impact factor: 6.819
  1 in total

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