Literature DB >> 30838815

CD47 Blockade and Cowpea Mosaic Virus Nanoparticle In Situ Vaccination Triggers Phagocytosis and Tumor Killing.

Chao Wang1,2, Nicole F Steinmetz1,2,3.   

Abstract

Contemporary immunotherapies, e.g., those that target the CTLA-4 and PD-1/PD-L1 axis, act on T cells to reinstate their antitumor activity. An alternative, and possibly more powerful approach is to target and reprogram the innate immune system within the tumor microenvironment. To this end, blockade of CD47 has been demonstrated as an attractive approach. Blockade of CD47 inhibits antiphagocytic signals therefore inducing macrophage phagocytosis of cancer cells. CD47 blockade also primes antitumor T-cell responses by either activating antigen-presenting cells or inhibiting interactions between CD47 on cancer cells and the matricellular protein thrombospondin-1 on T cells. Here, a combination immunotherapy is identified using cowpea mosaic virus (CPMV) in situ vaccination and CD47-blocking antibodies. The CPMV in situ vaccine synergizes with CD47 blockade, because CPMV in situ vaccination activates the innate immune system, leading to recruitment and activation of phagocytes. Therefore, the combination therapy targets monocytes and boosts their ability of cancer cell phagocytosis, in turn priming the adaptive immune system leading to a potent antitumor immune response. This work presents a novel strategy to promote macrophage activity to kill tumor cells, and hold promise to enhance T cells targeted immunotherapies by inducing both innate and adaptive arms of immune system.
© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Entities:  

Keywords:  breast cancer; cancer immunotherapy; cytotoxicity; ovarian cancer; plant virus

Mesh:

Substances:

Year:  2019        PMID: 30838815      PMCID: PMC6633909          DOI: 10.1002/adhm.201801288

Source DB:  PubMed          Journal:  Adv Healthc Mater        ISSN: 2192-2640            Impact factor:   9.933


  42 in total

1.  Semimature stage: a checkpoint in a dendritic cell maturation program that allows for functional reversion after signal-regulatory protein-alpha ligation and maturation signals.

Authors:  Deborah Braun; Laurent Galibert; Toshiharu Nakajima; Hirohisa Saito; Van Vu Quang; Manuel Rubio; Marika Sarfati
Journal:  J Immunol       Date:  2006-12-15       Impact factor: 5.422

2.  Combination of anthracyclines and anti-CD47 therapy inhibit invasive breast cancer growth while preventing cardiac toxicity by regulation of autophagy.

Authors:  Yismeilin R Feliz-Mosquea; Ashley A Christensen; Adam S Wilson; Brian Westwood; Jasmina Varagic; Giselle C Meléndez; Anthony L Schwartz; Qing-Rong Chen; Lesley Mathews Griner; Rajarshi Guha; Craig J Thomas; Marc Ferrer; Maria J Merino; Katherine L Cook; David D Roberts; David R Soto-Pantoja
Journal:  Breast Cancer Res Treat       Date:  2018-07-28       Impact factor: 4.872

3.  CD47 in the tumor microenvironment limits cooperation between antitumor T-cell immunity and radiotherapy.

Authors:  David R Soto-Pantoja; Masaki Terabe; Arunima Ghosh; Lisa A Ridnour; William G DeGraff; David A Wink; Jay A Berzofsky; David D Roberts
Journal:  Cancer Res       Date:  2014-10-08       Impact factor: 12.701

4.  Monoclonal antibody against human ovarian tumor-associated antigens.

Authors:  L G Poels; D Peters; Y van Megen; G P Vooijs; R N Verheyen; A Willemen; C C van Niekerk; P H Jap; G Mungyer; P Kenemans
Journal:  J Natl Cancer Inst       Date:  1986-05       Impact factor: 13.506

5.  Tropism of CPMV to Professional Antigen Presenting Cells Enables a Platform to Eliminate Chronic Infections.

Authors:  Amy M Wen; Nga Le; Xin Zhou; Nicole F Steinmetz; Daniel L Popkin
Journal:  ACS Biomater Sci Eng       Date:  2015-10-20

6.  Plant virus particles carrying tumour antigen activate TLR7 and Induce high levels of protective antibody.

Authors:  Jantipa Jobsri; Alex Allen; Deepa Rajagopal; Michael Shipton; Kostya Kanyuka; George P Lomonossoff; Christian Ottensmeier; Sandra S Diebold; Freda K Stevenson; Natalia Savelyeva
Journal:  PLoS One       Date:  2015-02-18       Impact factor: 3.240

7.  Selective Blockade of the Ubiquitous Checkpoint Receptor CD47 Is Enabled by Dual-Targeting Bispecific Antibodies.

Authors:  Elie Dheilly; Valéry Moine; Lucile Broyer; Susana Salgado-Pires; Zoë Johnson; Anne Papaioannou; Laura Cons; Sébastien Calloud; Stefano Majocchi; Robert Nelson; François Rousseau; Walter Ferlin; Marie Kosco-Vilbois; Nicolas Fischer; Krzysztof Masternak
Journal:  Mol Ther       Date:  2017-02-01       Impact factor: 11.454

8.  Slow-Release Formulation of Cowpea Mosaic Virus for In Situ Vaccine Delivery to Treat Ovarian Cancer.

Authors:  Anna E Czapar; Brylee David B Tiu; Frank A Veliz; Jonathan K Pokorski; Nicole F Steinmetz
Journal:  Adv Sci (Weinh)       Date:  2018-02-21       Impact factor: 16.806

9.  CD47 blockade triggers T cell-mediated destruction of immunogenic tumors.

Authors:  Xiaojuan Liu; Yang Pu; Kyle Cron; Liufu Deng; Justin Kline; William A Frazier; Hairong Xu; Hua Peng; Yang-Xin Fu; Meng Michelle Xu
Journal:  Nat Med       Date:  2015-08-31       Impact factor: 53.440

10.  PD-1 expression by tumour-associated macrophages inhibits phagocytosis and tumour immunity.

Authors:  Sydney R Gordon; Roy L Maute; Ben W Dulken; Gregor Hutter; Benson M George; Melissa N McCracken; Rohit Gupta; Jonathan M Tsai; Rahul Sinha; Daniel Corey; Aaron M Ring; Andrew J Connolly; Irving L Weissman
Journal:  Nature       Date:  2017-05-17       Impact factor: 49.962
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  17 in total

Review 1.  Advances in engineering local drug delivery systems for cancer immunotherapy.

Authors:  Peter Abdou; Zejun Wang; Qian Chen; Amanda Chan; Daojia R Zhou; Vivienne Gunadhi; Zhen Gu
Journal:  Wiley Interdiscip Rev Nanomed Nanobiotechnol       Date:  2020-04-07

2.  Using nanoparticles for in situ vaccination against cancer: mechanisms and immunotherapy benefits.

Authors:  Michael-Joseph Gorbet; Akansha Singh; Chenkai Mao; Steven Fiering; Ashish Ranjan
Journal:  Int J Hyperthermia       Date:  2020-12       Impact factor: 3.914

3.  Cowpea Mosaic Virus Nanoparticles and Empty Virus-Like Particles Show Distinct but Overlapping Immunostimulatory Properties.

Authors:  Chao Wang; Veronique Beiss; Nicole F Steinmetz
Journal:  J Virol       Date:  2019-10-15       Impact factor: 5.103

Review 4.  Cancer biologics made in plants.

Authors:  Matthew Dent; Nobuyuki Matoba
Journal:  Curr Opin Biotechnol       Date:  2019-11-27       Impact factor: 9.740

Review 5.  The pharmacology of plant virus nanoparticles.

Authors:  Christian Isalomboto Nkanga; Nicole F Steinmetz
Journal:  Virology       Date:  2021-01-28       Impact factor: 3.616

Review 6.  Viral nanoparticles for drug delivery, imaging, immunotherapy, and theranostic applications.

Authors:  Young Hun Chung; Hui Cai; Nicole F Steinmetz
Journal:  Adv Drug Deliv Rev       Date:  2020-06-27       Impact factor: 15.470

Review 7.  Plant Virus Nanoparticles for Anti-cancer Therapy.

Authors:  Srividhya Venkataraman; Paul Apka; Erum Shoeb; Uzma Badar; Kathleen Hefferon
Journal:  Front Bioeng Biotechnol       Date:  2021-12-15

8.  Exosome-liposome hybrid nanoparticle codelivery of TP and miR497 conspicuously overcomes chemoresistant ovarian cancer.

Authors:  Longxia Li; Di He; Qianqian Guo; Zhiyoung Zhang; Dan Ru; Liting Wang; Ke Gong; Fangfang Liu; Yourong Duan; He Li
Journal:  J Nanobiotechnology       Date:  2022-01-25       Impact factor: 10.435

Review 9.  Combining nanomedicine and immune checkpoint therapy for cancer immunotherapy.

Authors:  Christine E Boone; Lu Wang; Aayushma Gautam; Isabel G Newton; Nicole F Steinmetz
Journal:  Wiley Interdiscip Rev Nanomed Nanobiotechnol       Date:  2021-07-22

10.  The let-7 family of microRNAs suppresses immune evasion in head and neck squamous cell carcinoma by promoting PD-L1 degradation.

Authors:  Dan Yu; Xueshibojie Liu; Guanghong Han; Yan Liu; Xue Zhao; Di Wang; Xiaomin Bian; Tingting Gu; Lianji Wen
Journal:  Cell Commun Signal       Date:  2019-12-27       Impact factor: 5.712
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