Literature DB >> 29316433

TIM-3 Regulates CD103+ Dendritic Cell Function and Response to Chemotherapy in Breast Cancer.

Álvaro de Mingo Pulido1, Alycia Gardner2, Shandi Hiebler1, Hatem Soliman3, Hope S Rugo4, Matthew F Krummel5, Lisa M Coussens6, Brian Ruffell7.   

Abstract

Intratumoral CD103+ dendritic cells (DCs) are necessary for anti-tumor immunity. Here we evaluated the expression of immune regulators by CD103+ DCs in a murine model of breast cancer and identified expression of TIM-3 as a target for therapy. Anti-TIM-3 antibody improved response to paclitaxel chemotherapy in models of triple-negative and luminal B disease, with no evidence of toxicity. Combined efficacy was CD8+ T cell dependent and associated with increased granzyme B expression; however, TIM-3 expression was predominantly localized to myeloid cells in both human and murine tumors. Gene expression analysis identified upregulation of Cxcl9 within intratumoral DCs during combination therapy, and therapeutic efficacy was ablated by CXCR3 blockade, Batf3 deficiency, or Irf8 deficiency.
Copyright © 2017 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  TIM-3; breast cancer; chemotherapy; dendritic cells; galectin-9; immunotherapy; paclitaxel

Mesh:

Substances:

Year:  2018        PMID: 29316433      PMCID: PMC5764109          DOI: 10.1016/j.ccell.2017.11.019

Source DB:  PubMed          Journal:  Cancer Cell        ISSN: 1535-6108            Impact factor:   31.743


  66 in total

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Authors:  Laurent Monney; Catherine A Sabatos; Jason L Gaglia; Akemi Ryu; Hanspeter Waldner; Tatyana Chernova; Stephen Manning; Edward A Greenfield; Anthony J Coyle; Raymond A Sobel; Gordon J Freeman; Vijay K Kuchroo
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3.  The evaluation of tumor-infiltrating lymphocytes (TILs) in breast cancer: recommendations by an International TILs Working Group 2014.

Authors:  R Salgado; C Denkert; S Demaria; N Sirtaine; F Klauschen; G Pruneri; S Wienert; G Van den Eynden; F L Baehner; F Penault-Llorca; E A Perez; E A Thompson; W F Symmans; A L Richardson; J Brock; C Criscitiello; H Bailey; M Ignatiadis; G Floris; J Sparano; Z Kos; T Nielsen; D L Rimm; K H Allison; J S Reis-Filho; S Loibl; C Sotiriou; G Viale; S Badve; S Adams; K Willard-Gallo; S Loi
Journal:  Ann Oncol       Date:  2014-09-11       Impact factor: 32.976

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Authors:  Roy S Herbst; Jean-Charles Soria; Marcin Kowanetz; Gregg D Fine; Omid Hamid; Michael S Gordon; Jeffery A Sosman; David F McDermott; John D Powderly; Scott N Gettinger; Holbrook E K Kohrt; Leora Horn; Donald P Lawrence; Sandra Rost; Maya Leabman; Yuanyuan Xiao; Ahmad Mokatrin; Hartmut Koeppen; Priti S Hegde; Ira Mellman; Daniel S Chen; F Stephen Hodi
Journal:  Nature       Date:  2014-11-27       Impact factor: 49.962

6.  Tim-3 mediates phagocytosis of apoptotic cells and cross-presentation.

Authors:  Masafumi Nakayama; Hisaya Akiba; Kazuyoshi Takeda; Yuko Kojima; Masaaki Hashiguchi; Miyuki Azuma; Hideo Yagita; Ko Okumura
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Authors:  Jacob T Jackson; Yifang Hu; Ruijie Liu; Frederick Masson; Angela D'Amico; Sebastian Carotta; Annie Xin; Mary J Camilleri; Adele M Mount; Axel Kallies; Li Wu; Gordon K Smyth; Stephen L Nutt; Gabrielle T Belz
Journal:  EMBO J       Date:  2011-05-17       Impact factor: 11.598

9.  PD-1 blockade induces responses by inhibiting adaptive immune resistance.

Authors:  Paul C Tumeh; Christina L Harview; Jennifer H Yearley; I Peter Shintaku; Emma J M Taylor; Lidia Robert; Bartosz Chmielowski; Marko Spasic; Gina Henry; Voicu Ciobanu; Alisha N West; Manuel Carmona; Christine Kivork; Elizabeth Seja; Grace Cherry; Antonio J Gutierrez; Tristan R Grogan; Christine Mateus; Gorana Tomasic; John A Glaspy; Ryan O Emerson; Harlan Robins; Robert H Pierce; David A Elashoff; Caroline Robert; Antoni Ribas
Journal:  Nature       Date:  2014-11-27       Impact factor: 49.962

10.  TIM-3 does not act as a receptor for galectin-9.

Authors:  Judith Leitner; Armin Rieger; Winfried F Pickl; Gerhard Zlabinger; Katharina Grabmeier-Pfistershammer; Peter Steinberger
Journal:  PLoS Pathog       Date:  2013-03-21       Impact factor: 6.823
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  103 in total

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Journal:  Cancer Cell       Date:  2019-03-18       Impact factor: 31.743

2.  Adoptive cellular therapy with T cells expressing the dendritic cell growth factor Flt3L drives epitope spreading and antitumor immunity.

Authors:  Junyun Lai; Sherly Mardiana; Imran G House; Kevin Sek; Melissa A Henderson; Lauren Giuffrida; Amanda X Y Chen; Kirsten L Todd; Emma V Petley; Jack D Chan; Emma M Carrington; Andrew M Lew; Benjamin J Solomon; Joseph A Trapani; Katherine Kedzierska; Maximilien Evrard; Stephin J Vervoort; Jason Waithman; Phillip K Darcy; Paul A Beavis
Journal:  Nat Immunol       Date:  2020-05-18       Impact factor: 25.606

Review 3.  Targeting novel inhibitory receptors in cancer immunotherapy.

Authors:  Quan-Quan Ding; Joe-Marc Chauvin; Hassane M Zarour
Journal:  Semin Immunol       Date:  2020-12-04       Impact factor: 11.130

Review 4.  Tumor microenvironmental influences on dendritic cell and T cell function: A focus on clinically relevant immunologic and metabolic checkpoints.

Authors:  Kristian M Hargadon
Journal:  Clin Transl Med       Date:  2020-01

Review 5.  Harnessing innate immunity in cancer therapy.

Authors:  Olivier Demaria; Stéphanie Cornen; Marc Daëron; Yannis Morel; Ruslan Medzhitov; Eric Vivier
Journal:  Nature       Date:  2019-10-02       Impact factor: 49.962

6.  Checkpoint Blockade Immunotherapy Induces Dynamic Changes in PD-1-CD8+ Tumor-Infiltrating T Cells.

Authors:  Sema Kurtulus; Asaf Madi; Giulia Escobar; Max Klapholz; Jackson Nyman; Elena Christian; Mathias Pawlak; Danielle Dionne; Junrong Xia; Orit Rozenblatt-Rosen; Vijay K Kuchroo; Aviv Regev; Ana C Anderson
Journal:  Immunity       Date:  2019-01-08       Impact factor: 31.745

7.  Intratumoral Activity of the CXCR3 Chemokine System Is Required for the Efficacy of Anti-PD-1 Therapy.

Authors:  Melvyn T Chow; Aleksandra J Ozga; Rachel L Servis; Dennie T Frederick; Jennifer A Lo; David E Fisher; Gordon J Freeman; Genevieve M Boland; Andrew D Luster
Journal:  Immunity       Date:  2019-05-13       Impact factor: 31.745

8.  Dendritic Cell Paucity Leads to Dysfunctional Immune Surveillance in Pancreatic Cancer.

Authors:  Samarth Hegde; Varintra E Krisnawan; Brett H Herzog; Chong Zuo; Marcus A Breden; Brett L Knolhoff; Graham D Hogg; Jack P Tang; John M Baer; Cedric Mpoy; Kyung Bae Lee; Katherine A Alexander; Buck E Rogers; Kenneth M Murphy; William G Hawkins; Ryan C Fields; Carl J DeSelm; Julie K Schwarz; David G DeNardo
Journal:  Cancer Cell       Date:  2020-03-16       Impact factor: 31.743

Review 9.  Immunological Targets for Immunotherapy: Inhibitory T Cell Receptors.

Authors:  Diwakar Davar; Hassane M Zarour
Journal:  Methods Mol Biol       Date:  2020

Review 10.  Dendritic Cells, the T-cell-inflamed Tumor Microenvironment, and Immunotherapy Treatment Response.

Authors:  Christopher S Garris; Jason J Luke
Journal:  Clin Cancer Res       Date:  2020-04-24       Impact factor: 12.531
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