Commentary - Journal of Cellular Immunology (2021) Volume 3, Issue 4
Commentary on “A Vaccine for Photodynamic Immunogenic Cell Death: Tumor Cell Caged b y Cellular Disulfide–Thiol Exchange for Immunotherapy”
Jie Zang, Haiqing Dong*
Key Laboratory of Spine and Spinal Cord Injury Repair, and Regeneration of Ministry of Education, Orthopaedic Department of Tongji Hospital, The Institute for Biomedical Engineering & Nano Science, School of Medicine, Tongji University, Shanghai 200092, China
- *Corresponding Author:
- Haiqing Dong
Received date: June 20, 2021; Accepted date: August 24, 2021
Citation: Zang J, Dong H. Commentary on “A Vaccine for Photodynamic Immunogenic Cell Death: Tumor Cell Caged by Cellular
Disulfide–Thiol Exchange for Immunotherapy”. J Cell Immunol. 2021; 3(4): 294-295.
Copyright: © 2021 Zang J, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Tumor immunotherapy, including monoclonal antibody of immune checkpoint blockade, therapeutic antibody, cancer vaccine and cell therapy, etc., is to restart and maintain the tumor immune cycle, restore the normal antitumor immune response of the body, so as to control and eliminate the tumor [1,2]. Among them, tumor vaccine, which can elicit robust immune response and produce sustained immune memory effect, is particularly favored in the treatment and prevention of tumor recurrence [3,4]. Notably, compared with specific antigen vaccine, whole cell vaccine does not need complex antigen screening and purification process, and can provide all antigens of specific tumor, so it has great prospects [5,6]. Nevertheless, the immune effect of whole cell vaccine is not satisfactory because of its low immunogenicity and limitation efficiency of antigen presentation [7,8].
To solve above issues, Li et al. developed a strategy of caged live cell vaccine (CLCV) based on disulfide-mediated assembly onto the tumor cell surface for photodynamic immunogenic cell death , which not only could convert “cold” tumor cells into a versatile “hot” cell vaccine, but could also exert durable antigen exposure and multidurable immunostimulatory properties. To construct such CLCV system, the authors used thiol-activated bovine serum albumin (BSA) nanoparticles, anchored onto B16F10 tumor cells surface through fast disulfide thiol exchange with thiol groups on the cell surface, as the cage material. Then, Chlorin e6 (Ce6) was chose as an immunogenic cell death (ICD) inducer to integrate with the exposed protein of the cage through hydrophobic interaction, and CpG oligonucleotide was employed as an adjuvant, a TLR9 agonist, to attach on the caged cells surface via electrostatic interactions with cationic BSA (ethylenediamine-modified BSA). Confocal laser scanning microscope images and transmission electron microscopy images directly verified the formation of cage on the cell surface. The authors then examined the necessity of the cell cage in vitro and in vivo. Interestingly, the cell cage at
high concentration could completely restrict the division
and proliferation of B16F10 and still maintain metabolic
activity compared with native B16F10. Similarly, the
authors also confirmed that caged cells at therapeutic
doses could not form tumor by subcutaneous inoculation,
indicating the biosafety of caged cells.
Then, the caged cells integrated Ce6 and CpG to form CLCV. At the cellular level, the authors screened that when the concentration of Ce6 was 1.0 μg·mL-1 and the laser power was 7.85 mW·(cm2)-1 at 650 nm for 3 min, CLCV showed the same slow apoptosis characteristics as naked B16F10 cells, and it was accompanied by increased expression of HSP70 on the cells surface, compared with native cells. The author confirmed that the formation of cell cages greatly improved the phagocytosis of BMDC to live cells vaccines through flow analysis. Besides, under the combined action of CpG in the cage and photodynamics, CLCV significantly induced the maturation of bone marrow-derived dendritic cells (BMDC) with the expression of co-stimulatory signals (such as CD40 CD80 CD86 and MHC-II) and the secretion of inflammatory cytokines (TNF-α and IL-12). Notably, photoactivated CLCV could sustain exposure of immunogenic tumor antigens and promote migration to lymph nodes, thereby enhancing the mutation of DC and stimulating T cell responses in vivo. Most strikingly, this
CLCV plus laser irradiation protected 75% of the mice
against tumor initiation and significantly increased the
population of CD3+CD8+ T cell in tumor. Together, all evidence highlights the promising of the strategy of CLCV in developing novel vaccine platform.
It has been reported that ICD is a distinctive form of cell death, which could release tumor-associated antigens (TAAs) and danger-associated molecular patterns (DAMPs) in situ, thereby converting dying cancer cells into regional vaccines to evoke systemic anti-tumor immunity [10,11]. However, in situ regional vaccines are often affected by the tumor-suppressive microenvironment, which prevents the effective presentation of antigens to immune cells. Li et al. proposed novelty strategy of in vitro cage tumor cell framework with ICD-inducing modality that does not rely on in situ tumor cells and can effectively avoid the negative influence of tumor-suppressive microenvironment to vaccine. Compared with hydrogels [12,13] and microneedle patch [14,15] that have been used to co-deliver whole tumor cells or lysates with other adjuvants, tumor cell caged strategy is a novel concept in vaccine construction. It would be interesting to see whether this strategy has a broad effect to evoke effective T effector response in preventive and established various tumor models.
This work was financially supported through grants from the National Natural Science Foundation of China (31771090).
- Antoni, Ribas, Jedd, D, Wolchok, Cancer
immunotherapy using checkpoint blockade. Science. 2018 Mar 23; 359(6382):1350-1355.
- Klevorn LE, Teague RM, Adapting Cancer
Immunotherapy Models for the Real World. Trends
Immunol. 2016 Apr 1; 37(6):354-363.
- Finn OJ. The dawn of vaccines for cancer prevention.
Nat Rev Immunol. 2018 Dec 27; 18(3):183-194.
- Banchereau J, Palucka K. Immunotherapy: Cancer
vaccines on the move. Nat Rev Clin Oncol. 2018 Sep 12;15(1):9-10.
- Kajihara M, Takakura K, Ohkusa T, Koido S. The impact
of dendritic cell-tumor fusion cells on cancer vaccines -
past progress and future strategies. Immunotherapy. 2015
Oct 28; 7(10):1111-1122.
- Yi L, Hui S. The tumor protection effect of high frequency administration of whole tumor cell vaccine and enhanced efficacy by the protein component from Agrocybe aegerita. Int J Clin Exp Med. 2015 Jul 30; 8(5):6914-6925.
- Han Q, Wang Y, Pang M, Zhang J. STAT3-blocked
whole-cell hepatoma vaccine induces cellular and humoral
immune response against HCC. J Exp Clin Cancer Res.
2017 Nov 7; 36(1):156.
- Luo L, Lv M, Zhuang X, Zhang Q, Qiao T. Irradiation
increases the immunogenicity of lung cancer cells and
irradiation-based tumor cell vaccine elicits tumor-specific
T cell responses in vivo. Onco Targets Ther. 2019 Jun 14;
- Wen Y, Liu Y, Guo F, Han Y, Qiu Q, Li Y, et al. A
vaccine for photodynamic immunogenic cell death:
tumor cell caged by cellular disulfide–thiol exchange for
immunotherapy. Biomaterials Science. 2021; 9(3):973–
- Galluzzi L, Buque A, Keep O, Zitvogel L, Kroemer G.
Immunogenic cell death in cancer and infectious disease.
Nat Rev Immunol. 2017 Oct 17; 17(2):97-111.
- Krysko DV, Garg AD, Kaczmarek A, Krysko O, Agostinis
P, Vandenabeele P. Agostinis, and P. Vandenabeele,
Immunogenic cell death and DAMPs in cancer therapy.
Nat Rev Cancer. 2012 Nov 15; 12(12):860-875.
- Roth GA, Gale EC, Alcántara-Hernández M, Luo W,
Axpe E, Verma R, et al. Injectable Hydrogels for Sustained
Codelivery of Subunit Vaccines Enhance Humoral
Immunity. ACS Cent Sci. 2020 Sep 16; 6(10):1800-1812.
- Yin Y, Li X, Ma H, Zhang J, Yu D, Zhao R, Yu S,
et al. In Situ Transforming RNA Nanovaccines from
Polyethylenimine Functionalized Graphene Oxide
Hydrogel for Durable Cancer Immunotherapy. Nano Lett.
2021 Feb 17; 21(5):2224-2231.
- Ye Y, Wang C, Zhang X, Hu Q, Zhang Y, Liu Q, et al.
A melanin-mediated cancer immunotherapy patch. Sci
Immunol. 2017 Nov 10; 2(17):eaan5692.
- Tran KT, Gavitt TD, Farrell NJ, Curry EJ, Mara
AB, Patel A, et al. Transdermal microneedles for the
programmable burst release of multiple vaccine payloads.
Nat Biomed Eng. 2020 Nov 23:1-10.