Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Antagonizing Integrin β3 Increases Immunosuppression in Cancer.

Literature DB >> 27216180

Antagonizing Integrin β3 Increases Immunosuppression in Cancer.

Xinming Su¹, Alison K Esser¹, Sarah R Amend¹, Jingyu Xiang¹, Yalin Xu¹, Michael H Ross¹, Gregory C Fox¹, Takayuki Kobayashi¹, Veronica Steri², Kirsten Roomp³, Francesca Fontana¹, Michelle A Hurchla¹, Brett L Knolhoff⁴, Melissa A Meyer⁴, Elizabeth A Morgan⁵, Julia C Tomasson¹, Joshua S Novack¹, Wei Zou⁶, Roberta Faccio⁷, Deborah V Novack⁸, Stephen D Robinson², Steven L Teitelbaum⁶, David G DeNardo⁴, Jochen G Schneider⁹, Katherine N Weilbaecher¹⁰.

Abstract

Integrin β3 is critical for tumor invasion, neoangiogenesis, and inflammation, making it a promising cancer target. However, preclinical and clinical data of integrin β3 antagonists have demonstrated no benefit or worse outcomes. We hypothesized that integrin β3 could affect tumor immunity and evaluated tumors in mice with deletion of integrin β3 in macrophage lineage cells (β3KOM). β3KOM mice had increased melanoma and breast cancer growth with increased tumor-promoting M2 macrophages and decreased CD8(+) T cells. Integrin β3 antagonist, cilengitide, also enhanced tumor growth and increased M2 function. We uncovered a negative feedback loop in M2 myeloid cells, wherein integrin β3 signaling favored STAT1 activation, an M1-polarizing signal, and suppressed M2-polarizing STAT6 activation. Finally, disruption of CD8(+) T cells, macrophages, or macrophage integrin β3 signaling blocked the tumor-promoting effects of integrin β3 antagonism. These results suggest that effects of integrin β3 therapies on immune cells should be considered to improve outcomes. Cancer Res; 76(12); 3484-95. ©2016 AACR. ©2016 American Association for Cancer Research.

Entities: CellLine Chemical Disease Gene Species

Mesh：

Substances：

Year: 2016 PMID： 27216180 PMCID： PMC4944657 DOI： 10.1158/0008-5472.CAN-15-2663

Source DB: PubMed Journal: Cancer Res ISSN： 0008-5472 Impact factor: 12.701

44 in total

Review 1. Macrophage plasticity and polarization: in vivo veritas.

Authors: Antonio Sica; Alberto Mantovani
Journal: J Clin Invest Date: 2012-03-01 Impact factor: 14.808

2. Phase II study of cilengitide (EMD 121974, NSC 707544) in patients with non-metastatic castration resistant prostate cancer, NCI-6735. A study by the DOD/PCF prostate cancer clinical trials consortium.

Authors: Ajjai Alva; Susan Slovin; Stephanie Daignault; Michael Carducci; Robert Dipaola; Ken Pienta; David Agus; Kathleen Cooney; Alice Chen; David C Smith; Maha Hussain
Journal: Invest New Drugs Date: 2010-11-04 Impact factor: 3.850

Review 3. Macrophages and therapeutic resistance in cancer.

Authors: Brian Ruffell; Lisa M Coussens
Journal: Cancer Cell Date: 2015-04-06 Impact factor: 31.743

4. CXCR4 regulates growth of both primary and metastatic breast cancer.

Authors: Matthew C P Smith; Kathryn E Luker; Joel R Garbow; Julie L Prior; Erin Jackson; David Piwnica-Worms; Gary D Luker
Journal: Cancer Res Date: 2004-12-01 Impact factor: 12.701

5. Dissection of platelet and myeloid cell defects by conditional targeting of the beta3-integrin subunit.

Authors: Elizabeth A Morgan; Jochen G Schneider; Timothy E Baroni; Ozge Uluçkan; Emanuela Heller; Michelle A Hurchla; Hongju Deng; Desiree Floyd; Andrew Berdy; Julie L Prior; David Piwnica-Worms; Steven L Teitelbaum; F Patrick Ross; Katherine N Weilbaecher
Journal: FASEB J Date: 2009-11-20 Impact factor: 5.191

6. Cilengitide combined with standard treatment for patients with newly diagnosed glioblastoma with methylated MGMT promoter (CENTRIC EORTC 26071-22072 study): a multicentre, randomised, open-label, phase 3 trial.

Authors: Roger Stupp; Monika E Hegi; Thierry Gorlia; Sara C Erridge; James Perry; Yong-Kil Hong; Kenneth D Aldape; Benoit Lhermitte; Torsten Pietsch; Danica Grujicic; Joachim Peter Steinbach; Wolfgang Wick; Rafał Tarnawski; Do-Hyun Nam; Peter Hau; Astrid Weyerbrock; Martin J B Taphoorn; Chiung-Chyi Shen; Nalini Rao; László Thurzo; Ulrich Herrlinger; Tejpal Gupta; Rolf-Dieter Kortmann; Krystyna Adamska; Catherine McBain; Alba A Brandes; Joerg Christian Tonn; Oliver Schnell; Thomas Wiegel; Chae-Yong Kim; Louis Burt Nabors; David A Reardon; Martin J van den Bent; Christine Hicking; Andriy Markivskyy; Martin Picard; Michael Weller
Journal: Lancet Oncol Date: 2014-08-19 Impact factor: 41.316

7. Requirement of vascular integrin alpha v beta 3 for angiogenesis.

Authors: P C Brooks; R A Clark; D A Cheresh
Journal: Science Date: 1994-04-22 Impact factor: 47.728

8. Interleukin-4 induces expression of the integrin alpha v beta 3 via transactivation of the beta 3 gene.

Authors: S Kitazawa; F P Ross; K McHugh; S L Teitelbaum
Journal: J Biol Chem Date: 1995-02-24 Impact factor: 5.157

9. Acquisition of T regulatory function in cathepsin L-inhibited T cells by eye-derived CTLA-2alpha during inflammatory conditions.

Authors: Sunao Sugita; Shintaro Horie; Orie Nakamura; Kazuichi Maruyama; Hiroshi Takase; Yoshihiko Usui; Masaru Takeuchi; Kazumi Ishidoh; Masato Koike; Yasuo Uchiyama; Christoph Peters; Yoshimi Yamamoto; Manabu Mochizuki
Journal: J Immunol Date: 2009-10-15 Impact factor: 5.422

10. Acute depletion of endothelial β3-integrin transiently inhibits tumor growth and angiogenesis in mice.

Authors: Veronica Steri; Tim S Ellison; Aleksander Maksym Gontarczyk; Katherine Weilbaecher; Jochen G Schneider; Dylan Edwards; Marcus Fruttiger; Kairbaan M Hodivala-Dilke; Stephen Douglas Robinson
Journal: Circ Res Date: 2013-10-08 Impact factor: 17.367

31 in total

1. Systemic Delivery of Tumor-Targeted Bax-Derived Membrane-Active Peptides for the Treatment of Melanoma Tumors in a Humanized SCID Mouse Model.

Authors: Anastassia Karageorgis; Michaël Claron; Romain Jugé; Caroline Aspord; Fabien Thoreau; Claire Leloup; Jérôme Kucharczak; Joël Plumas; Maxime Henry; Amandine Hurbin; Pascal Verdié; Jean Martinez; Gilles Subra; Pascal Dumy; Didier Boturyn; Abdel Aouacheria; Jean-Luc Coll
Journal: Mol Ther Date: 2017-02-01 Impact factor: 11.454

2. Inhibition of the Stromal p38MAPK/MK2 Pathway Limits Breast Cancer Metastases and Chemotherapy-Induced Bone Loss.

Authors: Bhavna Murali; Qihao Ren; Xianmin Luo; Douglas V Faget; Chun Wang; Radia Marie Johnson; Tina Gruosso; Kevin C Flanagan; Yujie Fu; Kathleen Leahy; Elise Alspach; Xinming Su; Michael H Ross; Barry Burnette; Katherine N Weilbaecher; Morag Park; Gabriel Mbalaviele; Joseph B Monahan; Sheila A Stewart
Journal: Cancer Res Date: 2018-08-09 Impact factor: 12.701

3. Exosomal αvβ6 integrin is required for monocyte M2 polarization in prostate cancer.

Authors: Huimin Lu; Nicholas Bowler; Larry A Harshyne; D Craig Hooper; Shiv Ram Krishn; Senem Kurtoglu; Carmine Fedele; Qin Liu; Hsin-Yao Tang; Andrew V Kossenkov; William K Kelly; Kerith Wang; Rhonda B Kean; Paul H Weinreb; Lei Yu; Anindita Dutta; Paolo Fortina; Adam Ertel; Maria Stanczak; Flemming Forsberg; Dmitry I Gabrilovich; David W Speicher; Dario C Altieri; Lucia R Languino
Journal: Matrix Biol Date: 2018-03-09 Impact factor: 11.583

4. Retinoic acid inducible gene-I slows down cellular senescence through negatively regulating the integrin β3/p38 MAPK pathway.

Authors: Junmei Zhao; Xinyi Jiang; Li Yan; Jian Lin; Hezhou Guo; Shanhe Yu; Baixin Ye; Jiang Zhu; Wu Zhang
Journal: Cell Cycle Date: 2019-10-09 Impact factor: 4.534

5. Bone-Induced Expression of Integrin β3 Enables Targeted Nanotherapy of Breast Cancer Metastases.

Authors: Michael H Ross; Alison K Esser; Gregory C Fox; Anne H Schmieder; Xiaoxia Yang; Grace Hu; Dipanjan Pan; Xinming Su; Yalin Xu; Deborah V Novack; Thomas Walsh; Graham A Colditz; Gabriel H Lukaszewicz; Elizabeth Cordell; Joshua Novack; James A J Fitzpatrick; David L Waning; Khalid S Mohammad; Theresa A Guise; Gregory M Lanza; Katherine N Weilbaecher
Journal: Cancer Res Date: 2017-08-30 Impact factor: 12.701

6. Integrin αvβ8-expressing tumor cells evade host immunity by regulating TGF-β activation in immune cells.

Authors: Naoki Takasaka; Robert I Seed; Anthony Cormier; Andrew J Bondesson; Jianlong Lou; Ahmed Elattma; Saburo Ito; Haruhiko Yanagisawa; Mitsuo Hashimoto; Royce Ma; Michelle D Levine; Jean Publicover; Rashaun Potts; Jillian M Jespersen; Melody G Campbell; Fraser Conrad; James D Marks; Yifan Cheng; Jody L Baron; Stephen L Nishimura
Journal: JCI Insight Date: 2018-10-18

7. Peroxisome proliferator-activated receptor γ (PPARγ) induces the gene expression of integrin α_Vβ₅ to promote macrophage M2 polarization.

Authors: Qinyu Yao; Jia Liu; Zihui Zhang; Fan Li; Chao Zhang; Baochang Lai; Lei Xiao; Nanping Wang
Journal: J Biol Chem Date: 2018-09-04 Impact factor: 5.157

8. TREM2 Modulation Remodels the Tumor Myeloid Landscape Enhancing Anti-PD-1 Immunotherapy.

Authors: Martina Molgora; Ekaterina Esaulova; William Vermi; Jinchao Hou; Yun Chen; Jingqin Luo; Simone Brioschi; Mattia Bugatti; Andrea Salvatore Omodei; Biancamaria Ricci; Catrina Fronick; Santosh K Panda; Yoshiko Takeuchi; Matthew M Gubin; Roberta Faccio; Marina Cella; Susan Gilfillan; Emil R Unanue; Maxim N Artyomov; Robert D Schreiber; Marco Colonna
Journal: Cell Date: 2020-08-11 Impact factor: 41.582

9. The Phenotypic Effects of Exosomes Secreted from Distinct Cellular Sources: a Comparative Study Based on miRNA Composition.

Authors: Scott Ferguson; Sera Kim; Christine Lee; Michael Deci; Juliane Nguyen
Journal: AAPS J Date: 2018-04-30 Impact factor: 4.009

10. Targeted Therapy to β3 Integrin Reduces Chemoresistance in Breast Cancer Bone Metastases.

Authors: Gregory C Fox; Xinming Su; Jennifer L Davis; Yalin Xu; Kristin A Kwakwa; Michael H Ross; Francesca Fontana; Jingyu Xiang; Alison K Esser; Elizabeth Cordell; Kristen Pagliai; Ha X Dang; Jothilingam Sivapackiam; Sheila A Stewart; Christopher A Maher; Suzanne J Bakewell; James A J Fitzpatrick; Vijay Sharma; Samuel Achilefu; Deborah J Veis; Gregory M Lanza; Katherine N Weilbaecher
Journal: Mol Cancer Ther Date: 2021-03-30 Impact factor: 6.261