Your search keyword '"whole tumor cell vaccine"' showing total 10 results

1. Allogeneic "Zombie Cell" as Off‐The‐Shelf Vaccine for Postsurgical Cancer Immunotherapy.

Author

Li, Bo, Zhang, Ping, Li, Junlin, Zhou, Rui, Zhou, Minglu, Liu, Chendong, Liu, Xi, Chen, Liqiang, and Li, Lian

Subjects

*T cells, *CANCER vaccines, *TUMOR antigens, *IMMUNOLOGIC memory, *IMMUNOTHERAPY, TUMOR surgery

Abstract

Allogeneic tumor cell vaccines provide off‐the‐shelf convenience but lack patient specificity due to heterogeneity in tumor antigens. Here, allogeneic tumor cell corpses are converted into "zombie cells" capable of assimilating heterogeneous tumor by seizing cancer cells and spreading adjuvant infection. This causes pseudo‐oncolysis of tumors, transforming them into immunogenic targets for enhanced phagocytosis. It is shown that in postoperative tumor models, localized delivery of premade "zombie cells" through stepwise gelation in resection cavity consolidates tumor surgery. Compared to analogous vaccines lacking "seizing" or "assimilating" capability, "zombie cell" platform effectively mobilizes T cell response against residual tumors, and establishes immunological memory against tumor re‐challenge, showing less susceptibility to immune evasion. Despite using allogeneic sources, "zombie cell" platform functions as generalizable framework to produce long‐term antitumor immunity in different tumor models, showing comparable effect to autologous vaccine. Together, with the potential of off‐the‐shelf availability and personalized relevance to heterogenous tumor antigens, this study suggests an alternative strategy for timely therapy after tumor surgery. [ABSTRACT FROM AUTHOR]

Published

2024

2. Allogeneic 'Zombie Cell' as Off‐The‐Shelf Vaccine for Postsurgical Cancer Immunotherapy

Author

Bo Li, Ping Zhang, Junlin Li, Rui Zhou, Minglu Zhou, Chendong Liu, Xi Liu, Liqiang Chen, and Lian Li

Subjects

biomedical engineering, cell delivery, localized therapy, postsurgical immunotherapy, whole tumor cell vaccine, Science

Abstract

Abstract Allogeneic tumor cell vaccines provide off‐the‐shelf convenience but lack patient specificity due to heterogeneity in tumor antigens. Here, allogeneic tumor cell corpses are converted into “zombie cells” capable of assimilating heterogeneous tumor by seizing cancer cells and spreading adjuvant infection. This causes pseudo‐oncolysis of tumors, transforming them into immunogenic targets for enhanced phagocytosis. It is shown that in postoperative tumor models, localized delivery of premade “zombie cells” through stepwise gelation in resection cavity consolidates tumor surgery. Compared to analogous vaccines lacking “seizing” or “assimilating” capability, “zombie cell” platform effectively mobilizes T cell response against residual tumors, and establishes immunological memory against tumor re‐challenge, showing less susceptibility to immune evasion. Despite using allogeneic sources, “zombie cell” platform functions as generalizable framework to produce long‐term antitumor immunity in different tumor models, showing comparable effect to autologous vaccine. Together, with the potential of off‐the‐shelf availability and personalized relevance to heterogenous tumor antigens, this study suggests an alternative strategy for timely therapy after tumor surgery.

Published

2024

3. Augmented interferon regulatory factor 7 axis in whole tumor cell vaccines prevents tumor recurrence by inducing interferon gamma-secreting B cells

Author

Nabeel Kajihara, Yoshino Tanaka, Riko Takeuchi, Takuto Kobayashi, Masafumi Tanji, Tsukasa Ataka, Shiho Nakano, Taisho Yamada, Akinori Takaoka, Yoshinori Hasegawa, Ken-Ichiro Seino, and Haruka Wada

Subjects

B cell, IFNγ, Irf7, vaccine, whole tumor cell vaccine, Immunologic diseases. Allergy, RC581-607, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

ABSTRACTAmong cancer immunotherapy, which has received great attention in recent years, cancer vaccines can potentially prevent recurrent tumors by using the exquisite power and specificity of the immune system. Specifically, whole tumor cell vaccines (WTCVs) based on surgically resected tumors have been considered to elicit robust anti-tumor immune responses by exposing various tumor-associated antigens to host immunity. However, most tumors have little immunogenicity because of immunoediting by continuous interactions with host immunity; thus, preparing WTCVs based on patient-derived non-modified tumors cannot prevent tumor onset. Hence, the immunogenicity of tumor cells must be improved for effective WTCVs. In this study, we indicate the importance of the interferon regulatory factor 7 (Irf7) axis, including Irf7 and its downstream factors, within tumor cells in regulating immunogenicity. Indeed, WTCVs that augmented the Irf7 axis have exerted remarkable recurrence-preventive effects when vaccinated after tumor inactivation by radiation. Most notably, vaccination with murine colon cancer cells that enhanced the Irf7 axis prevented the development of challenged tumors in all mice and resulted in a 100% survival rate during the observation period. Furthermore, the mechanism leading to vaccine effectiveness was mediated by interferon-gamma-producing B cells. This study provides novel insights into how to enhance tumor immunogenicity and use WTCVs as recurrence prophylaxis.

Published

2023

4. Microneedle-assisted vaccination combined with autophagy regulation for antitumor immunotherapy.

Author

Yang, Dan, Chen, Minglong, Sun, Ying, Shi, Chaonan, Wang, Wenhao, Zhao, Wanchen, Wen, Ting, Liu, Ting, Fu, Jintao, Lu, Chao, Wu, Chuanbin, Quan, Guilan, and Pan, Xin

Subjects

*T cells, *GRANULOCYTE-macrophage colony-stimulating factor, *AUTOPHAGY, *TUMOR antigens, *VOXEL-based morphometry, *CANCER vaccines, *VACCINATION

Abstract

Despite vaccination having the potency to revolutionize disease treatments, some critical issues including lack of safe and effective delivery system, insufficient internalization and ineffective antigen cross-presentation by dendritic cells (DCs) severely hamper its extensive clinical applications. Herein, we developed a whole cell-encapsulated antitumor vaccine microneedle patch (TCV-DMNs) potentiated with transdermal co-delivery of granulocyte-macrophage colony-stimulating factor (GM-CSF) and autophagy promoter (Tat-beclin 1). After transdermal vaccination with TCV-DMNs, GM-CSF released from DMNs serves as a potent adjuvant to recruit and promote the phagocytosis of antigens by DCs. Subsequently, Tat-beclin 1 promoted DCs maturation and MHC-I-mediated cross-presentation via up-regulated autophagy of DCs. We found that vaccination with TCV-DMNs could not only effectively suppress melanoma challenge, but also lead to regression of established malignancies, followed by a relapse-free survival of >40 days. Collectively, whole cell-encapsulated microneedle-assisted transdermal vaccination TCV-DMNs in combination with autophagy regulation could induce a robust antitumor immune response via enhancing transdermal delivery efficiency, promoting antigen internalization and cross-presentation, together with boosting T cell activities. Whole cell-encapsulated microneedle-assisted transdermal vaccination TCV-DMNs in combination with autophagy regulation could induce a robust antitumor immune response via enhancing transdermal delivery efficiency, promoting antigen internalization and cross-presentation. [Display omitted] • Construction of whole cell-encapsulated antitumor vaccine microneedle patch. • Upregulating autophagy promotes tumor antigen internalization. • Upregulating autophagy promotes antigen cross-presentation of dendritic cells. • Autophagy combined with tumor cell vaccines induces a strong immune response. [ABSTRACT FROM AUTHOR]

Published

2023

5. Augmented interferon regulatory factor 7 axis in whole tumor cell vaccines prevents tumor recurrence by inducing interferon gamma-secreting B cells.

Author

Kajihara, Nabeel, Tanaka, Yoshino, Takeuchi, Riko, Kobayashi, Takuto, Tanji, Masafumi, Ataka, Tsukasa, Nakano, Shiho, Yamada, Taisho, Takaoka, Akinori, Hasegawa, Yoshinori, Seino, Ken-Ichiro, and Wada, Haruka

Subjects

*INTERFERON regulatory factors, *CANCER vaccines, *B cells, *DISEASE relapse, *VACCINE effectiveness, *RHEUMATIC fever

Abstract

Among cancer immunotherapy, which has received great attention in recent years, cancer vaccines can potentially prevent recurrent tumors by using the exquisite power and specificity of the immune system. Specifically, whole tumor cell vaccines (WTCVs) based on surgically resected tumors have been considered to elicit robust anti-tumor immune responses by exposing various tumor-associated antigens to host immunity. However, most tumors have little immunogenicity because of immunoediting by continuous interactions with host immunity; thus, preparing WTCVs based on patient-derived non-modified tumors cannot prevent tumor onset. Hence, the immunogenicity of tumor cells must be improved for effective WTCVs. In this study, we indicate the importance of the interferon regulatory factor 7 (Irf7) axis, including Irf7 and its downstream factors, within tumor cells in regulating immunogenicity. Indeed, WTCVs that augmented the Irf7 axis have exerted remarkable recurrence-preventive effects when vaccinated after tumor inactivation by radiation. Most notably, vaccination with murine colon cancer cells that enhanced the Irf7 axis prevented the development of challenged tumors in all mice and resulted in a 100% survival rate during the observation period. Furthermore, the mechanism leading to vaccine effectiveness was mediated by interferon-gamma-producing B cells. This study provides novel insights into how to enhance tumor immunogenicity and use WTCVs as recurrence prophylaxis. [ABSTRACT FROM AUTHOR]

Published

2023

6. Irradiation increases the immunogenicity of lung cancer cells and irradiation-based tumor cell vaccine elicits tumor-specific T cell responses in vivo.

Author

Luo, Lumeng, Lv, Minghe, Zhuang, Xibing, Zhang, Qi, and Qiao, Tiankui

Subjects

*CANCER vaccines, *CANCER cells, *TUMOR antigens, *T cells, *LUNG cancer

Abstract

Background: During the past decades, great efforts have been built to develop lung cancer vaccines. Whole tumor cell lysate (TCL) are ideal sources of antigens for cancer vaccine design, which however have limited efficacy due to insufficient immunogenicity. Recently, radiotherapy has been closely related to immunotherapy. Numerous studies have demonstrated the regulatory effect of irradiation (IR) on tumor immune response. Purpose: To explore the immunogenicity modulation effect of IR on lung cancer cells. Methods: RNA-sequence and qPCR assay was used to evaluate the change of tumor antigens expression after repeated X rays radiation on A549 cells. Vaccine based on TCL of irradiated Lewis lung cancer cells (IR-LLC) was established; therapeutic effect of TCL (IR-LLC) was examined in xenografted tumor model of mice. Flow cytometry was conducted to evaluate the rate of immune cells in spleen; ELISA was used to detect the level of cytokines in plasma. Immunohistochemistry was performed to evaluate the infiltrations of T-cell in tumor tissues; TIMER analysis was used to explore the correlations between tumor antigen expressions and the abundances of immune infiltrates. Results: IR upregulated the expression of tumor antigens in A549 cells. Compared to the control group and unirradiated tumor cell vaccine, TCL(IR-LLC) had a significantly stronger anti-tumor effect in mice bearing with LLC xenografts. TCL(IR-LLC) significantly increased matured DCs and total CD4+ T cells but downregulated Tregs and PD-1+ CD8+ T cells in mice spleen; TCL(IR-LLC) vaccine upregulated the level of IFN-γ and IL-4 while decreased IL-10 in serum; increased infiltrations of CD4+ T-cells and CD8+ T-cells were observed in the tumor issues of mice immunized with TCL(IR-LLC). Tumor antigens including FN1, MFGE8, MMP2, MYL9 may contribute to the enhanced T-cell response. Conclusion: This study confirmed the immunogenicity modulation effect of IR in NSCLC cells, indicating IR might be an effective strategy to enhance the anti-tumor immunity of cancer cell vaccine. [ABSTRACT FROM AUTHOR]

Published

2019

7. Adjuvants for Enhancing the Immunogenicity of Whole Tumor Cell Vaccines.

Author

Chiang, Cheryl Lai-Lai, Kandalaft, Lana E., and Coukos, George

Subjects

*VACCINES, *TUMORS, *IMMUNOGENETICS, *ADJUVANT treatment of cancer, *CYTOKINES

Abstract

Whole tumor cell lysates can serve as excellent multivalent vaccines for priming tumor-specific CD8++ and CD4++ T cells. Whole cell vaccines can be prepared with hypochlorous acid oxidation, UVB-irradiation and repeat cycles of freeze and thaw. One major obstacle to successful immunotherapy is breaking self-tolerance to tumor antigens. Clinically approved adjuvants, including Montanide™™ ISA-51 and 720, and keyhole-limpet proteins can be used to enhance tumor cell immunogenicity by stimulating both humoral and cellular anti-tumor responses. Other potential adjuvants, such as Toll-like receptor agonists (e.g., CpG, MPLA and PolyI:C), and cytokines (e.g., granulocyte-macrophage colony stimulating factor), have also been investigated. [ABSTRACT FROM AUTHOR]

Published

2011

8. Whole tumor antigen vaccines

Author

Chiang, Cheryl Lai-Lai, Benencia, Fabian, and Coukos, George

Subjects

*CANCER vaccines, *TUMOR antigens, *OVARIAN tumors, *CANCER cells, *APOPTOSIS, *DENDRITIC cells, *CANCER immunotherapy

Abstract

Abstract: Although cancer vaccines with defined antigens are commonly used, the use of whole tumor cell preparations in tumor immunotherapy is a very promising approach and can obviate some important limitations in vaccine development. Whole tumor cells are a good source of TAAs and can induce simultaneous CTLs and CD4+ T helper cell activation. We review current approaches to prepare whole tumor cell vaccines, including traditional methods of freeze–thaw lysates, tumor cells treated with ultraviolet irradiation, and RNA electroporation, along with more recent methods to increase tumor cell immunogenicity with HOCl oxidation or infection with replication-incompetent herpes simplex virus. [Copyright &y& Elsevier]

Published

2010

9. Irradiation increases the immunogenicity of lung cancer cells and irradiation-based tumor cell vaccine elicits tumor-specific T cell responses in vivo

Author

Minghe Lv, Xibing Zhuang, Lumeng Luo, Qi Zhang, and Tiankui Qiao

Subjects

0301 basic medicine, medicine.medical_treatment, T cell, OncoTargets and Therapy, 03 medical and health sciences, 0302 clinical medicine, Immune system, Antigen, Medicine, Pharmacology (medical), Original Research, irradiation, business.industry, Immunogenicity, Immunotherapy, Tumor antigen, lung cancer, 030104 developmental biology, medicine.anatomical_structure, Oncology, 030220 oncology & carcinogenesis, Cancer cell, Cancer research, Cancer vaccine, whole tumor cell vaccine, business, tumor antigen

Abstract

Lumeng Luo, Minghe Lv, Xibing Zhuang, Qi Zhang, Tiankui QiaoDepartment of Oncology, Jinshan Hospital, Medical Center of Fudan University, Shanghai 201500, People’s Republic of ChinaBackground: During the past decades, great efforts have been built to develop lung cancer vaccines. Whole tumor cell lysate (TCL) are ideal sources of antigens for cancer vaccine design, which however have limited efficacy due to insufficient immunogenicity. Recently, radiotherapy has been closely related to immunotherapy. Numerous studies have demonstrated the regulatory effect of irradiation (IR) on tumor immune response.Purpose: To explore the immunogenicity modulation effect of IR on lung cancer cells.Methods: RNA-sequence and qPCR assay was used to evaluate the change of tumor antigens expression after repeated X rays radiation on A549 cells. Vaccine based on TCL of irradiated Lewis lung cancer cells (IR-LLC) was established; therapeutic effect of TCL (IR-LLC) was examined in xenografted tumor model of mice. Flow cytometry was conducted to evaluate the rate of immune cells in spleen; ELISA was used to detect the level of cytokines in plasma. Immunohistochemistry was performed to evaluate the infiltrations of T-cell in tumor tissues; TIMER analysis was used to explore the correlations between tumor antigen expressions and the abundances of immune infiltrates.Results: IR upregulated the expression of tumor antigens in A549 cells. Compared to the control group and unirradiated tumor cell vaccine, TCL(IR-LLC) had a significantly stronger anti-tumor effect in mice bearing with LLC xenografts. TCL(IR-LLC) significantly increased matured DCs and total CD4+ T cells but downregulated Tregs and PD-1+ CD8+ T cells in mice spleen; TCL(IR-LLC) vaccine upregulated the level of IFN-γ and IL-4 while decreased IL-10 in serum; increased infiltrations of CD4+ T-cells and CD8+ T-cells were observed in the tumor issues of mice immunized with TCL(IR-LLC). Tumor antigens including FN1, MFGE8, MMP2, MYL9 may contribute to the enhanced T-cell response.Conclusion: This study confirmed the immunogenicity modulation effect of IR in NSCLC cells, indicating IR might be an effective strategy to enhance the anti-tumor immunity of cancer cell vaccine.Keywords: lung cancer, whole tumor cell vaccine, irradiation, tumor antigen, T cell

Published

2019

10. The tumor protection effect of high-frequency administration of whole tumor cell vaccine and enhanced efficacy by the protein component from Agrocybe aegerita.

Author

Liang Y and Sun H

Abstract

Whole tumor cell vaccines have been widely studied and elicits limited immune responses because of the poor immunogenicity. In the present study, we discovered that high-frequency administration of irradiated whole tumor cell vaccine triggered rejection of tumor cells (90% or 100% of the mice that were vaccinated with irradiated H22 cells or S180 respectively were protected), and provided cross-protection and long-term anti-tumor immunity in BALB/c mouse models. The antitumor activity required CD4+, CD8+ T cells and macrophage that was proved in the nude mice and cell depletion mouse models. The adoptive transfer experiment suggested that repeated whole tumor cell vaccination successfully stimulated the anti-tumor response by activation of the immune cells. A high immunization frequency within a short period of time and the presence of glycosylated molecules and nucleic acids on the surface of intact tumor cells were crucial for the successful prevention of tumor growth by whole tumor cell vaccines. Moreover, Yt, the protein component from fungus Agrocybe aegerita, increased whole tumor cell vaccine-mediated tumor rejection and cross-protection effect. These data indicated that the frequency of administration of whole tumor cell vaccines was of critical importance for the efficacy, which needed to be integrated into vaccine strategies for producing potential vaccines.

Published

2015