Your search keyword '"In situ vaccine"' showing total 128 results

1. Physicochemical Cues Steering Spiky Mn/MoOx Nanocarriers to Mimic Oncolytic Virus for Potentiating Cancer Immunotherapy.

Author

Zhao, Liying, Zhao, Xiaomin, Zhang, Wei, Miao, Yuhang, Wang, Xin, and Deng, Dawei

Subjects

*BIOMIMETIC synthesis, *BIOLOGICAL systems, *BIOSYNTHESIS, *ONCOGENIC viruses, *CANCER vaccines

Abstract

The approval of oncolytic viruses as antigen‐agnostic cancer vaccines provides a paradigm shift for immunotherapy. However, a delicate balance between safety and immunogenicity whether native or engineered oncolytic viruses remains elusive and further compounded by oncolysis‐induced immunosuppression. To address these dilemmas, the de novo design and synthesis of oncolytic viruses‐inspired nanoplatform are proposed by emulating desirable nanostructure and bioactivity for effective cancer immunotherapy. Initially, the influence of MoOx nanoparticles with varying physical morphologies on siRNA transfection are explored, wherein the virus‐inspired MoOx nanoparticles with spiky surfaces (Spi‐MoOx) are well positioned to serve as siRNA vectors to present the highest transfection efficacy. Given the preexisting immune suppression, defect engineering is incorporated into Spi‐MoOx through Mn dopants (Spi‐Mn/MoOx), in an effort to participate in tumor adaptation to hypoxia and maximize the oncolytic potency, while retaining favorable safety profiles. More importantly, the engineered oncolytic viruses hold considerable promise to function as a universal platform that enables any gene to be modulated precisely, allowing the selective activation of various pathways. Collectively, the study offers insights into the biomimetic synthesis and bioactivity of biological system through manipulating the physicochemical cues, while carrying significant implications to propel artificial oncolytic agents from the laboratory to clinical settings. [ABSTRACT FROM AUTHOR]

Published

2024

2. Neo-adjuvant radiation and intratumoral immunotherapy followed by surgery-NARIS trial for extremity soft tissue sarcoma.

Author

Ge, Yu-Chen, Min, Li-Mei, Liu, Qin, Wang, Xiao-Lu, Wang, Shou-Feng, Chen, Jun, Kong, Wen-Tao, Wu, Su-Jia, Zhou, Guang-Xin, Wang, Ting-Ting, Liu, Bao-Rui, and Li, Ru-Tian

Abstract

Extremity soft tissue sarcoma (ESTS) is a rare malignant nonepithelial disease, calling for combined modality treatments with surgery to further improve local control rates and long-term survival, especially in patients with multiple local recurrences with or without risk of amputation. In this double-arm, open-label, Phase II clinical trial, we will enroll 30 patients with pathologically confirmed ESTS without nodal involvement or distant metastases. Patients are randomly assigned to the combination treatment group or the radiation monotherapy group. Additionally, tumor and biological samples will be obtained directly before and after neoadjuvant therapy, allowing for studies of immune response and primary drug resistance mechanisms. Clinical Trial Registration:ChiCTR2200060659 (http://www.chictr.org.cn) (ClinicalTrials.gov). Article highlights A combined modality treatments with preoperative radiation therapy and intratumoral immunotherapy for patients with extremity soft tissue sarcomas is proposed. The clinical benefit will rely on the enhancement of immune effects and reduction of related toxicities. Neoadjuvant radiation has a comparable effect on local control and long-term survival with adjuvant radiotherapy after prolonged follow-up. Still, it has significant advantages of less late toxicity and potential benefits from de-escalated surgery, especially for patients with borderline resectable extremity soft tissue sarcomas. Neoadjuvant radiotherapy with hypofractionated regimens has a shorter course of treatment since the total dose is split into larger doses given per fraction compared with standard fractionation. Notably, hypofractionated radiotherapy can facilitate antigen presentation and regulate immune function. Intratumoural injection of antitumor immunomodulator can increase therapeutic effectiveness by mediating agent accumulation in the tumor microenvironment and tumor-draining lymph nodes and may also enhance anti-tumor immunity in combination with radiotherapy. Furthermore, intratumoral immunotherapy is expected to decrease systemic immune exposure while keeping the therapeutic benefits of local control. The nRS group (neoadjuvant radiotherapy alone before surgery) will serve as a control, contrasting the nRIS group (neoadjuvant radiotherapy plus immunotherapy before surgery) in further studies. This study will access radiologic and pathological responses for efficacy evaluation and collect biological samples such as blood draws, stool samples and tumor tissues before and after neoadjuvant therapy for comprehensive mechanistic study. Research team was multidisciplinary and consisted of radiation and medical oncologists, musculoskeletal oncologic surgeons, interventional radiologists, nuclear medicine physicians and specialized pathologists. [ABSTRACT FROM AUTHOR]

Published

2024

3. A tumor‐targeting nano‐adjuvant for in situ vaccine based on ultrasound therapy.

Author

Cui, Linjie, Yao, Haochen, Xue, Fuxin, Sun, Jiali, Ren, Xitong, Zheng, Mengfei, Liu, Zhilin, and Tang, Zhaohui

Subjects

ULTRASONIC imaging, IMMUNOLOGICAL adjuvants, IMMUNOLOGIC memory, GLUTAMIC acid, CANCER vaccines

Abstract

Ultrasound‐generated antigens combined with TLR7/8 agonists as adjuvants have demonstrated significant anti‐tumor efficacy as an in‐situ vaccine. However, the use of TLR7/8 agonists can cause severe inflammatory responses. In this study, we present a novel tumor‐targeting nano‐adjuvant termed aPDL1‐PLG/R848 NPs, which are composed of aPDL1 antibody, Fc‐III‐4C peptide linker (Fc‐linker) and poly(L‐glutamic acid)‐grafted‐R848. Under ultrasound irradiation, antigen‐presenting cells activate immune mechanisms in vivo under dual stimulation of in situ antigens and immune adjuvants. The strategy inhibits primary tumor growth and induces a strong antigen‐specific immune memory effect to prevent tumor recurrence in vivo. This work offers a safe and potent platform for an in situ cancer vaccine based on ultrasound therapy. [ABSTRACT FROM AUTHOR]

Published

2024

4. Reversing cancer immunoediting phases with a tumor-activated and optically reinforced immunoscaffold

Author

Xinchao Li, Xiuqi Liang, Wangxian Fu, Rui Luo, Miaomiao Zhang, Xiaorong Kou, Yi Zhang, Yingjie Li, Dongxue Huang, Yanjie You, Qinjie Wu, and Changyang Gong

Subjects

Hydrogel, Immunoscaffold, In situ vaccine, Photothermal therapy, Immunoediting phases, Materials of engineering and construction. Mechanics of materials, TA401-492, Biology (General), QH301-705.5

Abstract

In situ vaccine (ISV) is a promising immunotherapeutic tactic due to its complete tumoral antigenic repertoire. However, its efficiency is limited by extrinsic inevitable immunosuppression and intrinsic immunogenicity scarcity. To break this plight, a tumor-activated and optically reinforced immunoscaffold (TURN) is exploited to trigger cancer immunoediting phases regression, thus levering potent systemic antitumor immune responses. Upon response to tumoral reactive oxygen species, TURN will first release RGX-104 to attenuate excessive immunosuppressive cells and cytokines, and thus immunosuppression falls and immunogenicity rises. Subsequently, intermittent laser irradiation-activated photothermal agents (PL) trigger abundant tumor antigens exposure, which causes immunogenicity springs and preliminary infiltration of T cells. Finally, CD137 agonists from TURN further promotes the proliferation, function, and survival of T cells for durable antitumor effects. Therefore, cancer immunoediting phases reverse and systemic antitumor immune responses occur. TURN achieves over 90 % tumor growth inhibition in both primary and secondary tumor lesions, induces potent systemic immune responses, and triggers superior long-term immune memory in vivo. Taken together, TURN provides a prospective sight for ISV from the perspective of immunoediting phases.

Published

2024

5. In situ chemoimmunotherapy hydrogel elicits immunogenic cell death and evokes efficient antitumor immune response

Author

Qin Liu, Rui Xu, Jingwen Shen, Yaping Tao, Jingyi Shao, Yaohua Ke, and Baorui Liu

Subjects

Chemoimmunotherapy, Hydrogel, Nab-PTX, TLR7 agonist, In situ vaccine, Medicine

Abstract

Abstract Background Chemoimmunotherapy has shown promising advantages of eliciting immunogenic cell death and activating anti-tumor immune responses. However, the systemic toxicity of chemotherapy and tumor immunosuppressive microenvironment limit the clinical application. Methods Here, an injectable sodium alginate hydrogel (ALG) loaded with nanoparticle albumin-bound-paclitaxel (Nab-PTX) and an immunostimulating agent R837 was developed for local administration. Two murine hepatocellular carcinoma and breast cancer models were established. The tumor-bearing mice received the peritumoral injection of R837/Nab-PTX/ALG once a week for two weeks. The antitumor efficacy, the immune response, and the tumor microenvironment were investigated. Results This chemoimmunotherapy hydrogel with sustained-release character was proven to have significant effects on killing tumor cells and inhibiting tumor growth. Peritumoral injection of our hydrogel caused little harm to normal organs and triggered a potent antitumor immune response against both hepatocellular carcinoma and breast cancer. In the tumor microenvironment, enhanced immunogenic cell death induced by the combination of Nab-PTX and R837 resulted in 3.30-fold infiltration of effector memory T cells and upregulation of 20 biological processes related to immune responses. Conclusions Our strategy provides a novel insight into the combination of chemotherapy and immunotherapy and has the potential for clinical translation.

Published

2024

6. A tumor‐targeting nano‐adjuvant for in situ vaccine based on ultrasound therapy

Author

Linjie Cui, Haochen Yao, Fuxin Xue, Jiali Sun, Xitong Ren, Mengfei Zheng, Zhilin Liu, and Zhaohui Tang

Subjects

immunotherapy, in situ vaccine, R848 nanoparticles, tumor‐targeting, ultrasound therapy, Chemistry, QD1-999, Biology (General), QH301-705.5

Abstract

Abstract Ultrasound‐generated antigens combined with TLR7/8 agonists as adjuvants have demonstrated significant anti‐tumor efficacy as an in‐situ vaccine. However, the use of TLR7/8 agonists can cause severe inflammatory responses. In this study, we present a novel tumor‐targeting nano‐adjuvant termed aPDL1‐PLG/R848 NPs, which are composed of aPDL1 antibody, Fc‐III‐4C peptide linker (Fc‐linker) and poly(L‐glutamic acid)‐grafted‐R848. Under ultrasound irradiation, antigen‐presenting cells activate immune mechanisms in vivo under dual stimulation of in situ antigens and immune adjuvants. The strategy inhibits primary tumor growth and induces a strong antigen‐specific immune memory effect to prevent tumor recurrence in vivo. This work offers a safe and potent platform for an in situ cancer vaccine based on ultrasound therapy.

Published

2024

7. In Vivo Fate of Cowpea Mosaic Virus In Situ Vaccine: Biodistribution and Clearance

Author

de Oliveira, Jessica Fernanda Affonso, Chan, Soo Khim, Omole, Anthony O, Agrawal, Vanshika, and Steinmetz, Nicole F

Subjects

Cancer, Immunization, Biotechnology, Vaccine Related, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Infection, Good Health and Well Being, Humans, Animals, Dogs, Mice, Comovirus, Tissue Distribution, Cancer Vaccines, Immunotherapy, Kinetics, Antibodies, Mammals, cowpea mosaic virus, in situ vaccine, translational research, biodistribution, clearance, shedding, Nanoscience & Nanotechnology

Abstract

Cowpea mosaic virus (CPMV) is a nucleoprotein nanoparticle that functions as a highly potent immunomodulator when administered intratumorally and is used as an in situ vaccine. CPMV in situ vaccination remodels the tumor microenvironment and primes a highly potent, systemic, and durable antitumor immune response against the treated and untreated, distant metastatic sites (abscopal effect). Potent efficacy was demonstrated in multiple tumor mouse models and, most importantly, in canine cancer patients with spontaneous tumors. Data indicate that presence of anti-CPMV antibodies are not neutralizing and that in fact opsonization leads to enhanced efficacy. Plant viruses are part of the food chain, but to date, there is no information on human exposure to CPMV. Therefore, patient sera were tested for the presence of immunoglobulins against CPMV, and indeed, >50% of deidentified patient samples tested positive for CPMV antibodies. To get a broader sense of plant virus exposure and immunogenicity in humans, we also tested sera for antibodies against tobacco mosaic virus (>90% patients tested positive), potato virus X (

Published

2022

8. The Defined TLR3 Agonist, Nexavant, Exhibits Anti-Cancer Efficacy and Potentiates Anti-PD-1 Antibody Therapy by Enhancing Immune Cell Infiltration.

Author

Lee, Seung-Hwan, Choi, Young-Ho, Kang, Soon Myung, Lee, Min-Gyu, Debin, Arnaud, Perouzel, Eric, Hong, Seung-Beom, and Kim, Dong-Ho

Subjects

*THERAPEUTIC use of antineoplastic agents, *BIOLOGICAL models, *ANIMAL experimentation, *IMMUNE system, *CELL motility, *CELLULAR signal transduction, *TREATMENT effectiveness, *QUALITY control, *NIVOLUMAB, *TUMORS, *T cells, *ESTERASES, *IMMUNOTHERAPY, *MICE, *EVALUATION

Abstract

Simple Summary: Nexavant, a newly reported TLR3 agonist, has advantages over Poly(I:C) in terms of quality control and pre-clinical efficacy. Here, we further investigated the physicochemical properties, downstream signaling pathways, anti-cancer efficacy, and mechanism of action of Nexavant. The Nexavant was homogenous in solution and less sensitive to RNase A, and showed thermostability compared with Poly(I:C). Unlike Poly(I:C), which activates TLR3, RIG-I, and MDA5, Nexavant only activated TLR3 and RIG-I, not MDA5. The administration of Nexavant via either the intratumoral route or the intranasal route suppressed tumor growth in various cancer models. Combination therapy with anti-PD-1 antibodies resulted in better, synergistic tumor growth inhibition compared to the respective monotherapies. This study demonstrated that Nexavant could be more suitable for clinical use than Poly(I:C) and applied as an anti-cancer agent in the presence or absence of anti-PD-1 antibodies. Nexavant was reported as an alternative to the TLR3 agonist of Poly(I:C) and its derivatives. The physicochemical properties, signaling pathways, anti-cancer effects, and mechanisms of Nexavant were investigated. The distinctive characteristics of Nexavant compared to that of Poly(I:C) were demonstrated by precise quantification, enhanced thermostability, and increased resistance to RNase A. Unlike Poly(I:C), which activates TLR3, RIG-I, and MDA5, Nexavant stimulates signaling through TLR3 and RIG-I but not through MDA5. Compared to Poly(I:C), an intratumoral Nexavant treatment led to a unique immune response, immune cell infiltration, and suppression of tumor growth in various animal cancer models. Nexavant therapy outperformed anti-PD-1 antibody treatment in all the tested models and showed a synergistic effect in combinational therapy, especially in well-defined cold tumor models. The effect was similar to that of nivolumab in a humanized mouse model. Intranasal instillation of Nexavant led to the recruitment of immune cells (NK, CD4+ T, and CD8+ T) to the lungs, suppressing lung metastasis and improving animal survival. Our study highlighted Nexavant's defined nature for clinical use and unique signaling pathways and its potential as a standalone anti-cancer agent or in combination with anti-PD-1 antibodies. [ABSTRACT FROM AUTHOR]

Published

2023

9. Antibody landscape of C57BL/6 mice cured of B78 melanoma via a combined radiation and immunocytokine immunotherapy regimen.

Author

Hoefges, Anna, McIlwain, Sean J., Erbe, Amy K., Mathers, Nicholas, Xu, Angie, Melby, Drew, Tetreault, Kaitlin, Le, Trang, Kim, Kyungmann, Pinapati, Richard S., Garcia, Bradley H., Patel, Jigar, Heck, Mackenzie, Feils, Arika S., Tsarovsky, Noah, Hank, Jacquelyn Ann, Morris, Zachary Scott, Ong, Irene M., and Sondel, Paul Mark

Subjects

LABORATORY mice, IMMUNE serums, IMMUNOLOGIC memory, PEPTIDES, AMINO acid sequence

Abstract

Sera of immune mice that were previously cured of their melanoma through a combined radiation and immunocytokine immunotherapy regimen consisting of 12 Gy of external beam radiation and the intratumoral administration of an immunocytokine (anti-GD2 mAb coupled to IL-2) with long-term immunological memory showed strong antibody-binding against melanoma tumor cell lines via flow cytometric analysis. Using a high-density wholeproteome peptide array (of 6.090.593 unique peptides), we assessed potential protein-targets for antibodies found in immune sera. Sera from 6 of these cured mice were analyzed with this high-density, whole-proteome peptide array to determine specific antibody-binding sites and their linear peptide sequence. We identified thousands of peptides that were targeted by these 6 mice and exhibited strong antibody binding only by immune (after successful cure and rechallenge), not naïve (before tumor implantation) sera and developed a robust method to detect these differentially targeted peptides. Confirmatory studies were done to validate these results using 2 separate systems, a peptide ELISA and a smaller scale peptide array utilizing a slightly different technology. To the best of our knowledge, this is the first study of the full set of germline encoded linear peptide-based proteome epitopes that are recognized by immune sera from mice cured of cancer via radio-immunotherapy. We furthermore found that although the generation of B-cell repertoire in immune development is vastly variable, and numerous epitopes are identified uniquely by immune serum from each of these 6 immune mice evaluated, there are still several epitopes and proteins that are commonly recognized by at least half of the mice studied. This suggests that every mouse has a unique set of antibodies produced in response to the curative therapy, creating an individual “fingerprint.” Additionally, certain epitopes and proteins stand out as more immunogenic, as they are recognized by multiple mice in the immune group. [ABSTRACT FROM AUTHOR]

Published

2023

10. Enhanced systemic tumor suppression by in situ vaccine combining radiation and OX40 agonist with CpG therapy

Author

Zhichen Sun, Yanhong Chu, Jie Xiao, Yueling Yang, Fanyan Meng, Xinyue Wang, Yanbing Dong, Junmeng Zhu, Yirong Wu, Lanqun Qin, Yaohua Ke, Baorui Liu, and Qin Liu

Subjects

TLR9 agonist, OX40 agonist, Radiation, In situ vaccine, Tumor microenvironment, Medicine

Abstract

Abstract Background In situ tumor vaccine has been gradually becoming a hot research field for its advantage of achieving personalized tumor therapy without prior antigen identification. Various in situ tumor vaccine regimens have been reported to exert considerable antitumor efficacy in preclinical and clinical studies. However, the design of in situ tumor vaccines still needs further optimization and the underlying immune mechanism also waits for deeper investigation. Methods A novel triple in situ vaccine strategy that combining local radiation with intratumoral injection of TLR9 agonist CpG and OX40 agonist was established in this sturdy. Local and abscopal antitumor efficacy as well as survival benefit were evaluated in the bilateral tumors and pulmonary metastasis model of B16F10 melanoma. In situ vaccine-induced immune responses and immune-associated variation in tumor environment were further investigated using multiparameter flow cytometry and RNA sequencing. Base on the analysis, the RT + CpG + αOX40 triple in situ vaccine was combined with checkpoint blockade therapy to explore the potential synergistic antitumor efficacy. Results Enhanced tumor suppression was observed with minimal toxicity in both treated and untreated abscopal tumors after receiving RT + CpG + αOX40 triple vaccine. The introduction of local radiation and OX40 agonist benefit more to the inhibition of local and abscopal lesions respectively, which might be partially attributed to the increase of effector memory T cells in the tumor microenvironment. Further analysis implied that the triple in situ vaccine did not only activate the microenvironment of treated tumors, with the upregulation of multiple immune-associated pathways, but also enhanced systemic antitumor responses, thus achieved superior systemic tumor control and survival benefit. Moreover, the triple in situ vaccine synergized with checkpoint blockade therapy, and significantly improved the therapeutic effect of anti-programmed cell death protein (PD)-1 antibody. Conclusion This triple combining in situ vaccine induced intensive antitumor responses, mediated effective systemic tumor control and survival benefit, and displayed impressive synergistic antitumor effect with checkpoint blockade therapy. These data preliminary confirmed the efficacy, feasibility and safety of the triple combining in situ vaccine, suggesting its great application potential as both monotherapy and a part of combined immunotherapeutic regimens in clinical scenario.

Published

2023

11. Inactivated Cowpea Mosaic Virus in Combination with OX40 Agonist Primes Potent Antitumor Immunity in a Bilateral Melanoma Mouse Model.

Author

Koellhoffer, Edward, Mao, Chenkai, Beiss, Veronique, Wang, Lu, Fiering, Steven, Boone, Christine, and Steinmetz, Nicole

Subjects

OX40 agonist, UV inactivation, cancer immunotherapy, combination therapy, cowpea mosaic virus (CPMV), in situ vaccine, Animals, Cancer Vaccines, Comovirus, Disease Models, Animal, Dogs, Humans, Immunotherapy, Melanoma, Mice, Tumor Microenvironment

Abstract

Viral immunotherapies are being recognized in cancer treatment, with several currently approved or undergoing clinical testing. While contemporary approaches have focused on oncolytic viral therapies, our efforts center on the development of plant virus-based cancer immunotherapies. In a previous work, we demonstrated the potent efficacy of the cowpea mosaic virus (CPMV), a plant virus that does not replicate in animals, applied as an in situ vaccine. CPMV is an immunostimulatory drug candidate, and intratumoral administration remodels the tumor microenvironment leading to activation of local and systemic antitumor immunity. Efficacy has been demonstrated in multiple tumor mouse models and canine cancer patients. As wild-type CPMV is infectious toward various legumes and because shedding of infectious virus from patients may be an agricultural concern, we developed UV-inactivated CPMV (termed inCPMV) which is not infectious toward plants. We report that as a monotherapy, wild-type CPMV outperforms inCPMV in mouse models of dermal melanoma or disseminated colon cancer. Efficacy of inCPMV is less than that of CPMV and similar to that of RNA-free CPMV. Immunological investigation using knockout mice shows that inCPMV does not signal through TLR7 (toll-like receptor); structure-function studies indicate that the RNA is highly cross-linked and therefore unable to activate TLR7. Wild-type CPMV signals through TLR2, -4, and -7, whereas inCPMV more closely resembles RNA-free CPMV which signals through TLR2 and -4 only. The structural features of inCPMV explain the increased potency of wild-type CPMV through the triple pronged TLR activation. Strikingly, when inCPMV is used in combination with an anti-OX40 agonist antibody (administered systemically), exceptional efficacy was demonstrated in a bilateral B16F10 dermal melanoma model. Combination therapy, with in situ vaccination applied only into the primary tumor, controlled the progression of the secondary, untreated tumors, with 10 out of 14 animals surviving for at least 100 days post tumor challenge without development of recurrence or metastatic disease. This study highlights the potential of inCPMV as an in situ vaccine candidate and demonstrates the power of combined immunotherapy approaches. Strategic immunocombination therapies are the formula for success, and the combination of in situ vaccination strategies along with therapeutic antibodies targeting the cancer immunity cycle is a particularly powerful approach.

Published

2022

12. Plant Viral Nanoparticle Conjugated with Anti-PD-1 Peptide for Ovarian Cancer Immunotherapy.

Author

Gautam, Aayushma, Beiss, Veronique, Wang, Chao, Wang, Lu, and Steinmetz, Nicole

Subjects

anti-PD-1 blockade, cancer immunotherapy, checkpoint inhibitor therapy, cowpea mosaic virus, in situ vaccine, Amino Acid Sequence, Animals, B7-H1 Antigen, Cancer Vaccines, Comovirus, Disease Models, Animal, Female, Humans, Immunotherapy, Mice, Nanoparticles, Ovarian Neoplasms, Peptides, Plant Viruses, Vaccines, Virus-Like Particle, Xenograft Model Antitumor Assays

Abstract

Immunotherapy holds tremendous potential in cancer therapy, in particular, when treatment regimens are combined to achieve synergy between pathways along the cancer immunity cycle. In previous works, we demonstrated that in situ vaccination with the plant virus cowpea mosaic virus (CPMV) activates and recruits innate immune cells, therefore reprogramming the immunosuppressive tumor microenvironment toward an immune-activated state, leading to potent anti-tumor immunity in tumor mouse models and canine patients. CPMV therapy also increases the expression of checkpoint regulators on effector T cells in the tumor microenvironment, such as PD-1/PD-L1, and we demonstrated that combination with immune checkpoint therapy improves therapeutic outcomes further. In the present work, we tested the hypothesis that CPMV could be combined with anti-PD-1 peptides to replace expensive antibody therapies. Specifically, we set out to test whether a multivalent display of anti-PD-1 peptides (SNTSESF) would enhance efficacy over a combination of CPMV and soluble peptide. Efficacy of the approaches were tested using a syngeneic mouse model of intraperitoneal ovarian cancer. CPMV combination with anti-PD-1 peptides (SNTSESF) resulted in increased efficacy; however, increased potency against metastatic ovarian cancer was only observed when SNTSESF was conjugated to CPMV, and not added as a free peptide. This can be explained by the differences in the in vivo fates of the nanoparticle formulation vs. the free peptide; the larger nanoparticles are expected to exhibit prolonged tumor residence and favorable intratumoral distribution. Our study provides new design principles for plant virus-based in situ vaccination strategies.

Published

2021

13. In situ chemoimmunotherapy hydrogel elicits immunogenic cell death and evokes efficient antitumor immune response

Author

Liu, Qin, Xu, Rui, Shen, Jingwen, Tao, Yaping, Shao, Jingyi, Ke, Yaohua, and Liu, Baorui

Published

2024

14. Cyclophosphamide augments the efficacy of in situ vaccination in a mouse melanoma model.

Author

Tsarovsky, Noah, Felder, Mildred, Heck, Mackenzie, Slowinski, Jacob, Rasmussen, Kayla, VandenHeuvel, Sabrina, Zaborek, Jen, Morris, Zachary S., Erbe, Amy K., Sondel, Paul M., and Rakhmilevich, Alexander L.

Subjects

REGULATORY T cells, LABORATORY mice, IMMUNOLOGIC memory, CYCLOPHOSPHAMIDE, TUMOR growth

Abstract

Introduction: We have previously shown that an intratumoral (IT) injection of the hu14.18-IL2 immunocytokine (IC), an anti-GD2 antibody linked to interleukin 2, can serve as an in situ vaccine and synergize with local radiotherapy (RT) to induce T cell-mediated antitumor effects. We hypothesized that cyclophosphamide (CY), a chemotherapeutic agent capable of depleting T regulatory cells (Tregs), would augment in situ vaccination. GD2+ B78 mouse melanoma cells were injected intradermally in syngeneic C57BL/6 mice. Methods: Treatments with RT (12Gy) and/or CY (100 mg/kg i.p.) started when tumors reached 100-300 mm³ (day 0 of treatment), followed by five daily injections of IT-IC (25 mcg) on days 5-9. Tumor growth and survival were followed. In addition, tumors were analyzed by flow cytometry. Results: Similar to RT, CY enhanced the antitumor effect of IC. The strongest antitumor effect was achieved when CY, RT and IC were combined, as compared to combinations of IC+RT or IC+CY. Flow cytometric analyses showed that the combined treatment with CY, RT and IC decreased Tregs and increased the ratio of CD8+ cells/Tregs within the tumors. Moreover, in mice bearing two separate tumors, the combination of RT and IT-IC delivered to one tumor, together with systemic CY, led to a systemic antitumor effect detected as shrinkage of the tumor not treated directly with RT and IT-IC. Cured mice developed immunological memory as they were able to reject B78 tumor rechallenge. Conclusion: Taken together, these preclinical results show that CY can augment the antitumor efficacy of IT-IC, given alone or in combination with local RT, suggesting potential benefit in clinical testing of these combinations. [ABSTRACT FROM AUTHOR]

Published

2023

15. Enhanced systemic tumor suppression by in situ vaccine combining radiation and OX40 agonist with CpG therapy.

Author

Sun, Zhichen, Chu, Yanhong, Xiao, Jie, Yang, Yueling, Meng, Fanyan, Wang, Xinyue, Dong, Yanbing, Zhu, Junmeng, Wu, Yirong, Qin, Lanqun, Ke, Yaohua, Liu, Baorui, and Liu, Qin

Subjects

*CANCER vaccines, *VACCINES, *TUMOR microenvironment, *IMMUNOLOGIC memory, *RNA sequencing, *HYPEROPIA

Abstract

Background: In situ tumor vaccine has been gradually becoming a hot research field for its advantage of achieving personalized tumor therapy without prior antigen identification. Various in situ tumor vaccine regimens have been reported to exert considerable antitumor efficacy in preclinical and clinical studies. However, the design of in situ tumor vaccines still needs further optimization and the underlying immune mechanism also waits for deeper investigation. Methods: A novel triple in situ vaccine strategy that combining local radiation with intratumoral injection of TLR9 agonist CpG and OX40 agonist was established in this sturdy. Local and abscopal antitumor efficacy as well as survival benefit were evaluated in the bilateral tumors and pulmonary metastasis model of B16F10 melanoma. In situ vaccine-induced immune responses and immune-associated variation in tumor environment were further investigated using multiparameter flow cytometry and RNA sequencing. Base on the analysis, the RT + CpG + αOX40 triple in situ vaccine was combined with checkpoint blockade therapy to explore the potential synergistic antitumor efficacy. Results: Enhanced tumor suppression was observed with minimal toxicity in both treated and untreated abscopal tumors after receiving RT + CpG + αOX40 triple vaccine. The introduction of local radiation and OX40 agonist benefit more to the inhibition of local and abscopal lesions respectively, which might be partially attributed to the increase of effector memory T cells in the tumor microenvironment. Further analysis implied that the triple in situ vaccine did not only activate the microenvironment of treated tumors, with the upregulation of multiple immune-associated pathways, but also enhanced systemic antitumor responses, thus achieved superior systemic tumor control and survival benefit. Moreover, the triple in situ vaccine synergized with checkpoint blockade therapy, and significantly improved the therapeutic effect of anti-programmed cell death protein (PD)-1 antibody. Conclusion: This triple combining in situ vaccine induced intensive antitumor responses, mediated effective systemic tumor control and survival benefit, and displayed impressive synergistic antitumor effect with checkpoint blockade therapy. These data preliminary confirmed the efficacy, feasibility and safety of the triple combining in situ vaccine, suggesting its great application potential as both monotherapy and a part of combined immunotherapeutic regimens in clinical scenario. [ABSTRACT FROM AUTHOR]

Published

2023

16. Antibody landscape of C57BL/6 mice cured of B78 melanoma via a combined radiation and immunocytokine immunotherapy regimen

Author

Anna Hoefges, Sean J. McIlwain, Amy K. Erbe, Nicholas Mathers, Angie Xu, Drew Melby, Kaitlin Tetreault, Trang Le, Kyungmann Kim, Richard S. Pinapati, Bradley H. Garcia, Jigar Patel, Mackenzie Heck, Arika S. Feils, Noah Tsarovsky, Jacquelyn Ann Hank, Zachary Scott Morris, Irene M. Ong, and Paul Mark Sondel

Subjects

high-density peptide array, melanoma, in situ vaccine, radio-immunotherapy, antibody, cancer, Immunologic diseases. Allergy, RC581-607

Abstract

Sera of immune mice that were previously cured of their melanoma through a combined radiation and immunocytokine immunotherapy regimen consisting of 12 Gy of external beam radiation and the intratumoral administration of an immunocytokine (anti-GD2 mAb coupled to IL-2) with long-term immunological memory showed strong antibody-binding against melanoma tumor cell lines via flow cytometric analysis. Using a high-density whole-proteome peptide array (of 6.090.593 unique peptides), we assessed potential protein-targets for antibodies found in immune sera. Sera from 6 of these cured mice were analyzed with this high-density, whole-proteome peptide array to determine specific antibody-binding sites and their linear peptide sequence. We identified thousands of peptides that were targeted by these 6 mice and exhibited strong antibody binding only by immune (after successful cure and rechallenge), not naïve (before tumor implantation) sera and developed a robust method to detect these differentially targeted peptides. Confirmatory studies were done to validate these results using 2 separate systems, a peptide ELISA and a smaller scale peptide array utilizing a slightly different technology. To the best of our knowledge, this is the first study of the full set of germline encoded linear peptide-based proteome epitopes that are recognized by immune sera from mice cured of cancer via radio-immunotherapy. We furthermore found that although the generation of B-cell repertoire in immune development is vastly variable, and numerous epitopes are identified uniquely by immune serum from each of these 6 immune mice evaluated, there are still several epitopes and proteins that are commonly recognized by at least half of the mice studied. This suggests that every mouse has a unique set of antibodies produced in response to the curative therapy, creating an individual “fingerprint.” Additionally, certain epitopes and proteins stand out as more immunogenic, as they are recognized by multiple mice in the immune group.

Published

2023

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

Author

Wang, Chao, Beiss, Veronique, and Steinmetz, Nicole F

Subjects

Biomedical and Clinical Sciences, Immunology, Infectious Diseases, Nanotechnology, Vaccine Related, Bioengineering, Immunization, Cancer, Infection, Adjuvants, Immunologic, Animals, Antigen-Presenting Cells, Cancer Vaccines, Comovirus, Cytokines, Disease Models, Animal, Female, Immunotherapy, Mice, Ovarian Neoplasms, Survival Rate, Vaccination, Vaccines, Virus-Like Particle, Virion, empty virus-like nanoparticle, immunotherapy, in situ vaccine, ovarian cancer, plant virus nanoparticle, Biological Sciences, Agricultural and Veterinary Sciences, Medical and Health Sciences, Virology, Agricultural, veterinary and food sciences, Biological sciences, Biomedical and clinical sciences

Abstract

Cowpea mosaic virus (CPMV) is a plant virus that has been developed for multiple biomedical and nanotechnology applications, including immunotherapy. Two key platforms are available: virus nanoparticles (VNPs) based on the complete CMPV virion, including the genomic RNA, and virus-like nanoparticles (VLPs) based on the empty CPMV (eCPMV) virion. It is unclear whether these platforms differ in terms of immunotherapeutic potential. We therefore compared their physicochemical properties and immunomodulatory activities following in situ vaccination of an aggressive ovarian tumor mouse model (ID8-Defb29/Vegf-A). In physicochemical terms, CPMV and eCPMV were very similar, and both significantly increased the survival of tumor-bearing mice and showed promising antitumor efficacy. However, they demonstrated distinct yet overlapping immunostimulatory effects due to the presence of virus RNA in wild-type particles, indicating their suitability for different immunotherapeutic strategies. Specifically, we found that the formulations had similar effects on most secreted cytokines and immune cells, but the RNA-containing CPMV particles were uniquely able to boost populations of potent antigen-presenting cells, such as tumor-infiltrating neutrophils and activated dendritic cells. Our results will facilitate the development of CPMV and eCPMV as immunotherapeutic vaccine platforms with tailored responses.IMPORTANCE The engagement of antiviral effector responses caused by viral infection is essential when using viruses or virus-like particles (VLPs) as an immunotherapeutic agent. Here, we compare the chemophysical and immunostimulatory properties of wild-type cowpea mosaic virus (CPMV) (RNA containing) and eCPMV (RNA-free VLPs) produced from two expression systems (agrobacterium-based plant expression system and baculovirus-insect cell expression). CPMV and eCPMV could each be developed as novel adjuvants to overcome immunosuppression and thus promote tumor regression in ovarian cancer (and other tumor types). To our knowledge, this is the first study to define the immunotherapeutic differences between CPMV and eCPMV, which is essential for the further development of biomedical applications for plant viruses and the selection of rational combinations of immunomodulatory reagents.

Published

2019

18. Plant Virus-Like Particle In Situ Vaccine for Intracranial Glioma Immunotherapy.

Author

Kerstetter-Fogle, Amber, Shukla, Sourabh, Wang, Chao, Beiss, Veronique, Harris, Peggy LR, Sloan, Andrew E, and Steinmetz, Nicole F

Subjects

CPMV, immunotherapy, in situ vaccine, intracranial glioma, viral nanoparticles, Oncology and Carcinogenesis

Abstract

Despite aggressive multi-modality treatment with surgery, radiation and chemotherapies, malignant glioma inevitably recurs and has dismal survival rates. Recent progress in immunotherapy has led to a resurgence of interest, and immunotherapies are being investigated for treatment of glioma. However, the unique brain anatomy and a highly immunosuppressive glioma microenvironment pose significant challenges to achieving efficacy. Thus, there is a critical need for assessment of next-generation immunotherapies for glioma. In this study, we have investigated the efficacy of the nanoparticle platform technology based on plant-derived Cowpea mosaic virus like particles (empty CPMV or eCPMV) to instigate a potent immune response against intracranial glioma. CPMV immunotherapy has been shown to efficiently reverse the immunosuppressive tumor microenvironments in pre-clinical murine models of dermal melanoma and metastatic melanoma, metastatic breast cancer, intraperitoneal ovarian cancer and in canine patients with oral melanoma. In the present study, we demonstrate that in situ administration of CPMV immunotherapy in the setting of glioma can effectively recruit unique subset of effector innate and adaptive immune cells to the brain parenchyma while reducing immune suppressive cellular population, leading to regression of intracranial glioma. The in situ CPMV nanoparticle vaccine offers a potent yet safe and localized immunotherapy for intracranial glioma.

Published

2019

19. Freeze-Drying To Produce Efficacious CPMV Virus-like Particles

Author

Zheng, Yi, Lee, Parker W, Wang, Chao, Thomas, Linda D, Stewart, Phoebe L, Steinmetz, Nicole F, and Pokorski, Jonathan K

Subjects

Cancer, Infectious Diseases, Genetics, Vaccine Related, Good Health and Well Being, Cancer Vaccines, Capsid, Capsid Proteins, Comovirus, Cryoelectron Microscopy, Freeze Drying, Humans, Melanoma, Plants, Vaccines, Virus-Like Particle, Virion, Virus-like particle, immunotherapy, in situ vaccine, therapeutic protein, lyophilization, Nanoscience & Nanotechnology

Abstract

In situ cancer vaccination that uses immune stimulating agents is revolutionizing the way that cancer is treated. In this realm, viruses and noninfectious virus-like particles have gained significant traction in reprogramming the immune system to recognize and eliminate malignancies. Recently, cowpea mosaic virus-like particles (VLPs) have shown exceptional promise in their ability to fight a variety of cancers. However, the current methods used to produce CPMV VLPs rely on agroinfiltration in plants. These protocols remain complicated and labor intensive and have the potential to introduce unwanted immunostimulatory agents, like lipopolysaccharides. This Letter describes a simple "post-processing" method to remove RNA from wild-type CPMV, while retaining the structure and function of the capsid. Lyophilization was able to eject encapsulated RNA to form lyo-eCPMV and, when purified, eliminated nearly all traces of encapsulated RNA. Lyo-eCPMV was characterized by cryo-electron microscopy single particle reconstruction to confirm the structural integrity of the viral capsid. Finally, lyo-eCPMV showed  equivalent anticancer efficacy as eCPMV, produced by agroinfiltration, when using an invasive melanoma model. These results describe a straightforward method to prepare CPMV VLPs from infectious virions.

Published

2019

20. Sulfate Radical Based In Situ Vaccine Boosts Systemic Antitumor Immunity via Concurrent Activation of Necroptosis and STING Pathway.

Author

Huang Y, Zou J, Huo J, Zhang M, and Yang Y

Subjects

Animals, Mice, Cell Line, Tumor, Humans, Signal Transduction drug effects, Tumor Microenvironment drug effects, Immunotherapy, Manganese chemistry, Nanoparticles chemistry, Immunogenic Cell Death drug effects, Neoplasms therapy, Neoplasms immunology, Neoplasms pathology, Necroptosis drug effects, Cancer Vaccines immunology, Sulfates chemistry, Membrane Proteins metabolism

Abstract

In situ vaccine (ISV) can provoke systemic anti-tumor immunity through the induction of immunogenic cell death (ICD). The development of ISV technology has been restricted by the limited and suboptimal ICD driven tumor antigen production which are currently relying on chemo-drugs, photo-/radio-sensitizers, oncolytic-virus and immunostimulatory agents. Herein, a sulfate radical (SO 4 ·- ) based ISV is reported that accomplishes superior tumor immunotherapy dispense from conventional approaches. The ISV denoted as P-Mn-LDH is constructed by intercalating peroxydisulfate (PDS, a precursor of SO 4 ·- ) into manganese layered double hydroxide nanoparticles (Mn-LDH). This design allows the stabilization of PDS under ambient condition, but triggers a Mn 2+ mediated PDS decomposition in acidic tumor microenvironment (TME) to generate in situ SO 4 ·- . Importantly, it is found that the SO 4 ·- radicals not only effectively kill cancer cells, but also induce a necroptotic cell death pathway, leading to robust ICD signaling for eliciting adaptive immunity. Further, the P-Mn-LDH can activate the stimulator of interferon genes (STING) pathway to further boost anti-tumor immunity. Collectively, the P-Mn-LDH based ISV exhibited potent activity in inhibiting tumor growth and lung metastasis. When combined with immune checkpoint inhibitor, significant inhibition of distant tumors is achieved. This study underpins the promise of SO 4 ·- based vaccine technology for cancer immunotherapy., (© 2024 Wiley‐VCH GmbH.)

Published

2024

21. Engineered Carrier-Free Nanosystem-Induced In Situ Therapeutic Vaccines for Potent Cancer Immunotherapy.

Author

Zhang M, Zhao Y, Lv B, Jiang H, Li Z, and Cao J

Subjects

Animals, Mice, Humans, Pentacyclic Triterpenes chemistry, Pentacyclic Triterpenes pharmacology, Cell Line, Tumor, Neoplasms therapy, Neoplasms immunology, Tumor Microenvironment drug effects, Nanoparticles chemistry, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Antineoplastic Agents therapeutic use, Phototherapy, Apoptosis drug effects, Infrared Rays, Immunotherapy, Cancer Vaccines chemistry, Cancer Vaccines immunology

Abstract

In situ vaccines that can stimulate tumor immune response have emerged as a breakthrough in antitumor therapy. However, the immunosuppressed tumor microenvironment and insufficient infiltration of immune cells lead to ineffective antitumor immunity. Hence, a biomimetic carrier-free nanosystem (BCC) to induce synergistic phototherapy/chemotherapy-driven in situ vaccines was designed. A carrier-free nanosystem was developed using phototherapeutic reagents CyI and celastrol as raw materials. In vitro and in vivo studies have shown that under NIR light irradiation, BCC-mediated photo/chemotherapy not only accelerates the release of drugs to deeper parts of tumors, achieving timing and light-controlled drug delivery to result in cell apoptosis, but also effectively stimulates the antitumor response to induce in situ vaccine, which could invoke long-lasting antitumor immunity to inhibit tumor metastasis and eliminate distant tumor. This therapeutic strategy holds promise for priming robust innate and adaptive immune responses, arresting cancer progression, and inducing tumor dormancy.

Published

2024

22. Near-infrared photoimmunotherapy as a complementary modality to in situ vaccine in a preclinical pancreatic cancer model.

Author

Yaku, Hiroaki, Takahashi, Ken, Okada, Hirokazu, Kobiyama, Kouji, Shiokawa, Masahiro, Uza, Norimitsu, Kodama, Yuzo, Ishii, Ken J., and Seno, Hiroshi

Subjects

*CYTOTOXIC T cells, *PANCREATIC cancer, *IMMUNOLOGIC memory, *TOLL-like receptors, *CARCINOMA in situ

Abstract

Pancreatic cancer is one of the most refractory malignancies. In situ vaccines (ISV), in which intratumorally injected immunostimulatory adjuvants activate innate immunity at the tumor site, utilize tumor-derived patient-specific antigens, thereby allowing for the development of vaccines in patients themselves. Near-infrared photoimmunotherapy (NIR-PIT) is a novel therapy that selectively kills cancer cells exclusively in the NIR-irradiated region. Extending our previous research showing that ISV using the unique nanoparticulate Toll-like receptor 9 (TLR9) ligand K3-SPG induced effective antitumor immunity, here we incorporated NIR-PIT into K3-SPG-ISV so that local tumor destruction by NIR-PIT augments the antitumor effect of ISV. In the mouse model of pancreatic cancer, the combination of K3-SPG-ISV and CD44-targeting NIR-PIT showed synergistic systemic antitumor effects and enhanced anti-programmed cell death-1 (PD-1) blockade. Mechanistically, strong intratumoral upregulation of interferon-related genes and dependency on CD8+ T cells were observed, suggesting the possible role of interferon and cytotoxic T cell responses in the induction of antitumor immunity. Importantly, this combination induced immunological memory in therapeutic and neoadjuvant settings. This study represents the first attempt to integrate NIR-PIT with ISV, offering a promising new direction for cancer immunotherapy, particularly for pancreatic cancer. • Synergistic potential of NIR-PIT with conventional ISV is demonstrated. • NIR-PIT/ISV synergistically induces systemic antitumor effects. • NIR-PIT/ISV induces immunological memory in therapeutic and neoadjuvant settings. • NIR-PIT/ISV enhances the efficacy of PD-1 blockade therapy. • Potential application of this combination in pancreatic cancer is expected. [ABSTRACT FROM AUTHOR]

Published

2024

23. A recent perspective on designing tumor vaccines for tumor immunology.

Author

Cao, Shougen, Jia, Wenyu, Zhao, Yifan, Liu, Heng, Cao, Jie, and Li, Zequn

Subjects

*CANCER vaccines, *TUMOR antigens, *IMMUNE recognition, *VACCINE development, *VACCINE effectiveness

Abstract

• This article focuses on different types of tumor vaccine platforms, from basic research to clinical trials. • Combining the therapeutic tumor vaccine platform with other methods is summarized. • The challenges and opportunities of therapeutic tumor vaccine against diseases are discussed. With the rapid development of immunotherapy, therapeutic tumor vaccines, which aim to enhance the immunogenicity of tumor cells and activate the patient's immune system to kill tumor cells, as well as eliminate or inhibit tumor growth, have drawn increasing attention in the field of tumor therapy. However, due to the lack of immune cell infiltration, low immunogenicity, immune escape and other problems, the efficacy of tumor vaccine is often limited. Researchers have developed a variety of strategies to enhance tumor immune recognition, such as improving the immunogenicity of tumor antigens, selecting a suitable vaccine platform, or combining tumor vaccines with other anticancer treatments. In this review, we will deliberate on how to overcome the problem of therapeutic tumor vaccines, and discuss the up-to-date progress and achievements in the tumor vaccine development, as well as their future in cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2024

24. Using Radiation Therapy to Prime and Propagate an Anti-tumor Immune Response Against Brain Tumors.

Author

Onate, Alejandro J., Clark, Paul A., and Morris, Zachary S.

Abstract

Immunotherapies have demonstrated efficacy and survival benefits in some patients suffering from brain tumors; however, most do not respond and new approaches to enhance anti-tumor immunotherapeutic responses in the brain are needed. Radiotherapy remains a commonly used cancer treatment modality and can augment immunotherapeutic responses through multiple mechanisms. Recent preclinical studies may provide insight on how to optimally combine radiation and immunotherapies to maximize treatment efficacy. Unique aspects of the brain tumor microenvironment may play a critical role in limiting the successful application of immunotherapies in this location. Emerging studies suggest that such limits may be redressed through combination of immunotherapies with radiation therapy. In these settings, the latter may play a critical role in immunomodulating both tumor cells and the radiated brain tumor microenvironment. This review analyzes recent developments in combining radiation and immunotherapies to prime and better propagate anti-tumor immune response against brain tumors. [ABSTRACT FROM AUTHOR]

Published

2022

25. Ultrasound-Activatable In Situ Vaccine for Enhanced Antigen Self- and Cross-Presentation to Overcome Cancer Immunotherapy Resistance.

Author

Chen G, Wang Y, Mo L, Xu X, Zhang X, Yang S, Huang R, Li R, Zhang L, and Zhang B

Abstract

Insufficient antigen self-presentation of tumor cells and ineffective antigen cross-presentation by dendritic cells (DCs) contribute to diminished immune recognition and activation, which cause resistance to immunotherapies. Herein, we present an ultrasound-activatable in situ vaccine by utilizing a hybrid nanovesicle composed of a thylakoid (TK)/platelet (PLT) membrane and a liposome encapsulating DNA methyltransferase inhibitor zebularine (Zeb) and sonosensitizer hematoporphyrin monomethyl ether (HMME). Upon local exposure to ultrasound, reactive oxygen species (ROS) are generated and induce the sequential release of the payloads. Zeb can efficiently inhibit tumor DNA hypermethylation, promoting major histocompatibility complex class I (MHC-I) molecules-mediated antigen self-presentation to improve immune recognition. Meanwhile, the catalase on the TK membrane can decompose the tumoral overexpressed H 2 O 2 into O 2 , which boosts the generation of ROS and the destruction of tumor cells, resulting in the in situ antigen release and cross-presentation of tumor antigens by DCs. This in situ vaccine simultaneously promotes antigen self-presentation and cross-presentation, resulting in heightened antitumor immunity to overcome resistance.

Published

2024

26. Radiation Augments the Local Anti-Tumor Effect of In Situ Vaccine With CpG-Oligodeoxynucleotides and Anti-OX40 in Immunologically Cold Tumor Models.

Author

Pieper, Alexander A., Zangl, Luke M., Speigelman, Dan V., Feils, Arika S., Hoefges, Anna, Jagodinsky, Justin C., Felder, Mildred A., Tsarovsky, Noah W., Arthur, Ian S., Brown, Ryan J., Birstler, Jen, Le, Trang, Carlson, Peter M., Bates, Amber M., Hank, Jacquelyn A., Rakhmilevich, Alexander L., Erbe, Amy K., Sondel, Paul M., Patel, Ravi B., and Morris, Zachary S.

Subjects

MELANOMA, REGULATORY T cells, TUMOR-infiltrating immune cells, CPG nucleotides, BREAST cancer, VACCINE effectiveness

Abstract

Introduction: Combining CpG oligodeoxynucleotides with anti-OX40 agonist antibody (CpG+OX40) is able to generate an effective in situ vaccine in some tumor models, including the A20 lymphoma model. Immunologically "cold" tumors, which are typically less responsive to immunotherapy, are characterized by few tumor infiltrating lymphocytes (TILs), low mutation burden, and limited neoantigen expression. Radiation therapy (RT) can change the tumor microenvironment (TME) of an immunologically "cold" tumor. This study investigated the effect of combining RT with the in situ vaccine CpG+OX40 in immunologically "cold" tumor models. Methods: Mice bearing flank tumors (A20 lymphoma, B78 melanoma or 4T1 breast cancer) were treated with combinations of local RT, CpG, and/or OX40, and response to treatment was monitored. Flow cytometry and quantitative polymerase chain reaction (qPCR) experiments were conducted to study differences in the TME, secondary lymphoid organs, and immune activation after treatment. Results: An in situ vaccine regimen of CpG+OX40, which was effective in the A20 model, did not significantly improve tumor response or survival in the "cold" B78 and 4T1 models, as tested here. In both models, treatment with RT prior to CpG+OX40 enabled a local response to this in situ vaccine, significantly improving the anti-tumor response and survival compared to RT alone or CpG+OX40 alone. RT increased OX40 expression on tumor infiltrating CD4+ non-regulatory T cells. RT+CpG+OX40 increased the ratio of tumor-infiltrating effector T cells to T regulatory cells and significantly increased CD4+ and CD8+ T cell activation in the tumor draining lymph node (TDLN) and spleen. Conclusion: RT significantly improves the local anti-tumor effect of the in situ vaccine CpG+OX40 in immunologically "cold", solid, murine tumor models where RT or CpG+OX40 alone fail to stimulate tumor regression. [ABSTRACT FROM AUTHOR]

Published

2021

27. Tumor eradicated by combination of imiquimod and OX40 agonist for in situ vaccination.

Author

Yanhong Chu, Rutian Li, Lingyu Qian, Fangcen Liu, Ruihan Xu, Fanyan Meng, Yaohua Ke, Jie Shao, Lixia Yu, Qin Liu, and Baorui Liu

Abstract

Various cancer vaccines have been developed to generate and amplify antigen-specific T cell responses against malignancy. Among them, in situ vaccination is one of the most practical types as it can trigger immune responses without previous antigen identification. Here we reported a novel in situ vaccine by intratumoral injection of imiquimod and OX40 agonist. In mice bearing hepatic carcinoma, both the injected tumor and the noninjected tumor in the distant lesion of the same mice were suppressed after vaccination. Further studies found that this in situ vaccine triggered systemic tumor-specific responses, with one-fold increase of effector memory T cells properties and stronger toxicity of lymphocytes in spleen. Besides, we found that imiquimod upregulated the expression of OX40 on CD4+ T cells and thus enhanced the effectiveness of OX40 agonist. Five immune-positive-related pathways were activated after vaccination. This in situ vaccine caused little harm to normal organs and provided long-term protection against the same syngeneic tumor rechallenge. Due to its effectiveness, feasibility and safety, this strategy could potentially be applied to various types of late-stage solid tumors and worthy of further clinical research. [ABSTRACT FROM AUTHOR]

Published

2021

28. Radiation Augments the Local Anti-Tumor Effect of In Situ Vaccine With CpG-Oligodeoxynucleotides and Anti-OX40 in Immunologically Cold Tumor Models

Author

Alexander A. Pieper, Luke M. Zangl, Dan V. Speigelman, Arika S. Feils, Anna Hoefges, Justin C. Jagodinsky, Mildred A. Felder, Noah W. Tsarovsky, Ian S. Arthur, Ryan J. Brown, Jen Birstler, Trang Le, Peter M. Carlson, Amber M. Bates, Jacquelyn A. Hank, Alexander L. Rakhmilevich, Amy K. Erbe, Paul M. Sondel, Ravi B. Patel, and Zachary S. Morris

Subjects

In situ vaccine, cold tumor models, OX40 agonist, CpG – oligonucleotides, radiation therapy, radioimmunotherapy, Immunologic diseases. Allergy, RC581-607

Abstract

IntroductionCombining CpG oligodeoxynucleotides with anti-OX40 agonist antibody (CpG+OX40) is able to generate an effective in situ vaccine in some tumor models, including the A20 lymphoma model. Immunologically “cold” tumors, which are typically less responsive to immunotherapy, are characterized by few tumor infiltrating lymphocytes (TILs), low mutation burden, and limited neoantigen expression. Radiation therapy (RT) can change the tumor microenvironment (TME) of an immunologically “cold” tumor. This study investigated the effect of combining RT with the in situ vaccine CpG+OX40 in immunologically “cold” tumor models.MethodsMice bearing flank tumors (A20 lymphoma, B78 melanoma or 4T1 breast cancer) were treated with combinations of local RT, CpG, and/or OX40, and response to treatment was monitored. Flow cytometry and quantitative polymerase chain reaction (qPCR) experiments were conducted to study differences in the TME, secondary lymphoid organs, and immune activation after treatment.ResultsAn in situ vaccine regimen of CpG+OX40, which was effective in the A20 model, did not significantly improve tumor response or survival in the “cold” B78 and 4T1 models, as tested here. In both models, treatment with RT prior to CpG+OX40 enabled a local response to this in situ vaccine, significantly improving the anti-tumor response and survival compared to RT alone or CpG+OX40 alone. RT increased OX40 expression on tumor infiltrating CD4+ non-regulatory T cells. RT+CpG+OX40 increased the ratio of tumor-infiltrating effector T cells to T regulatory cells and significantly increased CD4+ and CD8+ T cell activation in the tumor draining lymph node (TDLN) and spleen.ConclusionRT significantly improves the local anti-tumor effect of the in situ vaccine CpG+OX40 in immunologically “cold”, solid, murine tumor models where RT or CpG+OX40 alone fail to stimulate tumor regression.

Published

2021

29. In Situ Vaccination as a Strategy to Modulate the Immune Microenvironment of Hepatocellular Carcinoma

Author

Isabella Lurje, Wiebke Werner, Raphael Mohr, Christoph Roderburg, Frank Tacke, and Linda Hammerich

Subjects

hepatocellular carcinoma (HCC), immunotherapy, in situ vaccine, dendritic cells (DC), tumor microenvironment, Immunologic diseases. Allergy, RC581-607

Abstract

Hepatocellular Carcinoma (HCC) is a highly prevalent malignancy that develops in patients with chronic liver diseases and dysregulated systemic and hepatic immunity. The tumor microenvironment (TME) contains tumor-associated macrophages (TAM), cancer-associated fibroblasts (CAF), regulatory T cells (Treg) and myeloid-derived suppressor cells (MDSC) and is central to mediating immune evasion and resistance to therapy. The interplay between these cells types often leads to insufficient antigen presentation, preventing effective anti-tumor immune responses. In situ vaccines harness the tumor as the source of antigens and implement sequential immunomodulation to generate systemic and lasting antitumor immunity. Thus, in situ vaccines hold the promise to induce a switch from an immunosuppressive environment where HCC cells evade antigen presentation and suppress T cell responses towards an immunostimulatory environment enriched for activated cytotoxic cells. Pivotal steps of in situ vaccination include the induction of immunogenic cell death of tumor cells, a recruitment of antigen-presenting cells with a focus on dendritic cells, their loading and maturation and a subsequent cross-priming of CD8+ T cells to ensure cytotoxic activity against tumor cells. Several in situ vaccine approaches have been suggested, with vaccine regimens including oncolytic viruses, Flt3L, GM-CSF and TLR agonists. Moreover, combinations with checkpoint inhibitors have been suggested in HCC and other tumor entities. This review will give an overview of various in situ vaccine strategies for HCC, highlighting the potentials and pitfalls of in situ vaccines to treat liver cancer.

Published

2021

30. In Situ Vaccination as a Strategy to Modulate the Immune Microenvironment of Hepatocellular Carcinoma.

Author

Lurje, Isabella, Werner, Wiebke, Mohr, Raphael, Roderburg, Christoph, Tacke, Frank, and Hammerich, Linda

Subjects

REGULATORY T cells, MYELOID-derived suppressor cells, HEPATOCELLULAR carcinoma, CYTOTOXIC T cells, ANTIGEN presentation, TUMOR antigens

Abstract

Hepatocellular Carcinoma (HCC) is a highly prevalent malignancy that develops in patients with chronic liver diseases and dysregulated systemic and hepatic immunity. The tumor microenvironment (TME) contains tumor-associated macrophages (TAM), cancer-associated fibroblasts (CAF), regulatory T cells (Treg) and myeloid-derived suppressor cells (MDSC) and is central to mediating immune evasion and resistance to therapy. The interplay between these cells types often leads to insufficient antigen presentation, preventing effective anti-tumor immune responses. In situ vaccines harness the tumor as the source of antigens and implement sequential immunomodulation to generate systemic and lasting antitumor immunity. Thus, in situ vaccines hold the promise to induce a switch from an immunosuppressive environment where HCC cells evade antigen presentation and suppress T cell responses towards an immunostimulatory environment enriched for activated cytotoxic cells. Pivotal steps of in situ vaccination include the induction of immunogenic cell death of tumor cells, a recruitment of antigen-presenting cells with a focus on dendritic cells, their loading and maturation and a subsequent cross-priming of CD8+ T cells to ensure cytotoxic activity against tumor cells. Several in situ vaccine approaches have been suggested, with vaccine regimens including oncolytic viruses, Flt3L, GM-CSF and TLR agonists. Moreover, combinations with checkpoint inhibitors have been suggested in HCC and other tumor entities. This review will give an overview of various in situ vaccine strategies for HCC, highlighting the potentials and pitfalls of in situ vaccines to treat liver cancer. [ABSTRACT FROM AUTHOR]

Published

2021

31. 原位疫苗：肿瘤免疫治疗的新思路.

Author

朱军梦 and 刘宝瑞

Abstract

Copyright of Chinese Journal of Cancer Biotherapy is the property of Editorial Office of Chinese Journal of Cancer Biotherapy and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

32. Magnetic covalent organic framework-based nanoadjuvant for multi-amplify sonodynamic antitumor therapy effect.

Author

Wang, Dianwei, Li, Tong, Lin, Lin, Meng, Meng, Hao, Kai, Guo, Zhaopei, Chen, Jie, Tian, Huayu, and Chen, Xuesi

Subjects

IRON oxide nanoparticles, IRON oxides, EXCHANGE reactions, MAGNETIC nanoparticles, TREATMENT effectiveness, NANOPARTICLE size, METALLOPORPHYRINS

Abstract

Superior sonosensitizer and targeted delivery of sonosensitizer are critical factors in determining the effectiveness of sonodynamic therapy (SDT). We developed magnetic targeting covalent organic framework (COF) nanoparticles to act as sonosensitizer and nanoadjuvant to multi-amplify the SDT effect at tumor sites. First, core-shell Fe 3 O 4 @COF nanoparticles with uniform size were prepared by "molecule exchange method" based on imine exchange reaction and further cationized, finally loaded with unmethylated cytosine-phosphate-guanine (CpG) adjuvant. The structural confinement of the porphyrin-based COF enhanced the sonodynamic performance, and the Fe 3 O 4 endowed the COF with chemodynamic effect to enhance SDT effect. More importantly, the superparamagnetism of Fe 3 O 4 could enable magnetic COF nanoparticles to actively target tumor sites, which further increased the treatment effect of SDT against simulated deep-seated tumors. Because of the presence of CpG adjuvant, this nanoplatform could be used as an in situ vaccine to achieve effective tumor immunotherapy to further amplify the treatment effect. This innovative method of preparing COF with core-shell structure and the enhanced SDT strategy effectively inhibited tumor growth and prevented tumor recurrence and metastasis, providing a new reference for clinical application. [Display omitted] • Porphyrin-based core-shell magnetic COF nanoparticles could be used as an efficient sonosensitizer. • The target delivery of sonosensitizer and chemodynamic effect were achieved, which would enhance SDT. • Magnetic COF nanoparticles loaded with CpG adjuvant could act as a nano-adjuvant to enhance the immune response. [ABSTRACT FROM AUTHOR]

Published

2024

33. Reversing cancer immunoediting phases with a tumor-activated and optically reinforced immunoscaffold.

Author

Li X, Liang X, Fu W, Luo R, Zhang M, Kou X, Zhang Y, Li Y, Huang D, You Y, Wu Q, and Gong C

Abstract

In situ vaccine (ISV) is a promising immunotherapeutic tactic due to its complete tumoral antigenic repertoire. However, its efficiency is limited by extrinsic inevitable immunosuppression and intrinsic immunogenicity scarcity. To break this plight, a tumor-activated and optically reinforced immunoscaffold (TURN) is exploited to trigger cancer immunoediting phases regression, thus levering potent systemic antitumor immune responses. Upon response to tumoral reactive oxygen species, TURN will first release RGX-104 to attenuate excessive immunosuppressive cells and cytokines, and thus immunosuppression falls and immunogenicity rises. Subsequently, intermittent laser irradiation-activated photothermal agents (PL) trigger abundant tumor antigens exposure, which causes immunogenicity springs and preliminary infiltration of T cells. Finally, CD137 agonists from TURN further promotes the proliferation, function, and survival of T cells for durable antitumor effects. Therefore, cancer immunoediting phases reverse and systemic antitumor immune responses occur. TURN achieves over 90 % tumor growth inhibition in both primary and secondary tumor lesions, induces potent systemic immune responses, and triggers superior long-term immune memory in vivo . Taken together, TURN provides a prospective sight for ISV from the perspective of immunoediting phases., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work., (© 2024 The Authors.)

Published

2024

34. In situ vaccination caused by diverse irradiation-driven cell death programs.

Author

Wang Y, Li Y, Yang Y, Swift M, Zhang Z, Wu S, Sun Y, and Yang K

Subjects

Humans, Cell Death, Immunotherapy, Immune System, Vaccination, Neoplasms therapy

Abstract

Interest surrounding the effect of irradiation on immune activation has exponentially grown within the last decade. This includes work regarding mechanisms of the abscopal effect and the success achieved by combination of radiotherapy and immunotherapy. It is hypothesized that irradiation triggers the immune system to eliminate tumors by inducing tumor cells immunogenic cell death (ICD) in tumor cells. Activation of the ICD pathways can be exploited as an in situ vaccine. In this review, we provide fundamental knowledge of various forms of ICD caused by irradiation, describe the relationship between various cell death pathways and the immune activation effect driven by irradiation, and focus on the therapeutic value of exploiting these cell death programs in the context of irradiation. Furthermore, we summarize the immunomodulatory effect of different cell death programs on combinative radiotherapy and immunotherapy. In brief, differences in cell death programs significantly impact the irradiation-induced immune activation effect. Evaluating the transition between them will provide clues to develop new strategies for radiotherapy and its combination with immunotherapy., Competing Interests: Competing Interests: The authors have declared that no competing interest exists., (© The author(s).)

Published

2024

35. Laser-Activatable In Situ Vaccine Enhances Cancer-Immunity Cycle.

Author

Wang Z, You T, Su Q, Deng W, Li J, Hu S, Shi S, Zou Z, Xiao J, and Duan X

Subjects

Humans, Female, B7-H1 Antigen metabolism, T-Lymphocytes, Immunotherapy methods, Lasers, Cell Line, Tumor, Breast Neoplasms, Vaccines

Abstract

The immune response in cancer reflects a series of carefully regulated events; however, current tumor immunotherapies typically address a single key aspect to enhance anti-tumor immunity. In the present study, a nanoplatform (Fe 3 O 4 @IR820@CpG)-based immunotherapy strategy that targets the multiple key steps in cancer-immunity cycle is developed: 1) promotes the release of tumor-derived proteins (TDPs), including tumor-associated antigens and pro-immunostimulatory factors), in addition to the direct killing effect, by photothermal (PTT) and photodynamic therapy (PDT); 2) captures the released TDPs and delivers them, together with CpG (a Toll-like receptor 9 agonist) to antigen-presenting cells (APCs) to promote antigen presentation and T cell activation; 3) enhances the tumor-killing ability of T cells by combining with anti-programmed death ligand 1 antibody (α-PD-L1), which collectively advances the outstanding of the anti-tumor effects on colorectal, liver and breast cancers. The broad-spectrum anti-tumor activity of Fe 3 O 4 @IR820@CpG with α-PD-L1 demonstrates that optimally manipulating anti-cancer immunity not singly but as a group provides promising clinical strategies., (© 2023 Wiley-VCH GmbH.)

Published

2023

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

Author

Chao Wang, Beiss, Veronique, and Steinmetz, Nicole F.

Subjects

*MOSAIC viruses, *VIRUS-like particles, *COWPEA, *PLANT viruses, *NANOPARTICLES, *NANOCARRIERS

Abstract

Cowpea mosaic virus (CPMV) is a plant virus that has been developed for multiple biomedical and nanotechnology applications, including immunotherapy. Two key platforms are available: virus nanoparticles (VNPs) based on the complete CMPV virion, including the genomic RNA, and virus-like nanoparticles (VLPs) based on the empty CPMV (eCPMV) virion. It is unclear whether these platforms differ in terms of immunotherapeutic potential. We therefore compared their physicochemical properties and immunomodulatory activities following in situ vaccination of an aggressive ovarian tumor mouse model (ID8-Defb29/Vegf-A). In physicochemical terms, CPMV and eCPMV were very similar, and both significantly increased the survival of tumor-bearing mice and showed promising antitumor efficacy. However, they demonstrated distinct yet overlapping immunostimulatory effects due to the presence of virus RNA in wild-type particles, indicating their suitability for different immunotherapeutic strategies. Specifically, we found that the formulations had similar effects on most secreted cytokines and immune cells, but the RNA-containing CPMV particles were uniquely able to boost populations of potent antigen-presenting cells, such as tumor-infiltrating neutrophils and activated dendritic cells. Our results will facilitate the development of CPMV and eCPMV as immunotherapeutic vaccine platforms with tailored responses. [ABSTRACT FROM AUTHOR]

Published

2019

37. Albumin pre-opsonized membrane-active iPep nanomedicine potentiates chemo to immunotherapy of cancer.

Author

Ji, Shuangshuang, Huang, Liu, Chang, Shiwei, Sun, Xingwei, Liu, Hanjie, Li, Ang, Jin, Yong, and Fei, Hao

Subjects

*ANTIMICROBIAL peptides, *ALBUMINS, *CANCER vaccines, *PEPTIDES, *IMMUNOTHERAPY, *SERUM albumin

Abstract

Chemotherapy-conjugated immunotherapy in clinical oncology conceptually resembles the combined effects of cytoreduction and immunostimulation in membrane targeted cell killings mediated by pore-forming proteins or host defense peptides. Of the similar concept, targeting cancer cell membrane using membrane active peptides is a hopeful therapeutic modality but had long been hindered from in vivo application. Here we report an enabling strategy of pre-opsonizing a membrane penetrating Ir-complexed octa-arginine peptide (iPep) with serum albumin via intrinsic amphipathicity-driven bimodal interactions into nanoparticles (NP). We found that NP triggered stress-mediated 4T1 cell oncosis which induced potent immunological activation, surpassing several well-known immunogenic medicines. Vested with albumin-enhanced in vivo tumor targeting specificity and pharmacokinetic properties, NP showed combined chemo to immunotherapies of s. c. tumors in mice, with decreased percentages of MDSC, Treg, M2-like macrophage and improved infiltration of CTLs in tumor site, caused complete regression of 4T1 and CT26 tumors, outperforming clinical medicines. In a challenging orthotopic breast cancer model, boost i. v. injections of NP acted as in situ tumor vaccine that drastically enhanced 4T1-specific cellular and humoral immunities to reverse disease progression. Thus, with combined effects of direct cytoreduction, immune activation and tumor vaccine, iPep-NP presents the promise and potential of a new modality of cancer medicine. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

38. Oncolytic Viruses: Therapeutics With an Identity Crisis

Author

Caroline J. Breitbach, Brian D. Lichty, and John C. Bell

Subjects

Oncolytic virus, Oncolytic immunotherapy, In situ vaccine, Immune checkpoint inhibitors, Medicine, Medicine (General), R5-920

Abstract

Oncolytic viruses (OV) are replicating viral therapeutics for the treatment of cancer and have been in laboratory development for about twenty years. Recently, the FDA approved Imlygic, a herpes virus based therapeutic for the treatment of melanoma and thus OVs have entered a new era where they are a weapon in the armament of the oncologist. OVs are unique therapeutics with multiple mechanisms of therapeutic activity. The exact path for their development and eventual uptake by pharmaceutical companies is somewhat clouded by an uncertain identity. Are they vaccines, tumour lysing therapeutics, inducers of innate immunity, gene therapy vectors, anti-vascular agents or all of the above? Should they be developed as stand-alone loco-regional therapeutics, systemically delivered tumour hunters or immune modulators best tested as combination therapeutics? We summarize data here supporting the idea, depending upon the virus, that OVs can be any or all of these things. Pursuing a “one-size fits all” approach is counter-productive to their clinical development and instead as a field we should build on the strengths of individual virus platforms.

Published

2016

39. Tumor eradicated by combination of imiquimod and OX40 agonist forin situvaccination

Author

Fangcen Liu, Yanhong Chu, Ruihan Xu, Qin Liu, Yaohua Ke, Jie Shao, Fanyan Meng, Baorui Liu, Lixia Yu, Lingyu Qian, and Rutian Li

Subjects

CD4-Positive T-Lymphocytes, Agonist, Cancer Research, medicine.drug_class, T-Lymphocytes, OX40 agonist, T cell, Antineoplastic Agents, Spleen, Imiquimod, Injections, Intralesional, Cancer Vaccines, Mice, Basic and Clinical Immunology, Immune system, Antigen, Antineoplastic Combined Chemotherapy Protocols, Tumor Microenvironment, medicine, Animals, Tumor microenvironment, Membrane Glycoproteins, business.industry, Liver Neoplasms, Vaccination, Original Articles, General Medicine, Receptors, OX40, immune responses, in situ vaccine, medicine.anatomical_structure, Toll-Like Receptor 7, Oncology, Cancer research, Female, Original Article, Immunotherapy, business, Immunologic Memory, medicine.drug

Abstract

Various cancer vaccines have been developed to generate and amplify antigen‐specific T cell responses against malignancy. Among them, in situ vaccination is one of the most practical types as it can trigger immune responses without previous antigen identification. Here we reported a novel in situ vaccine by intratumoral injection of imiquimod and OX40 agonist. In mice bearing hepatic carcinoma, both the injected tumor and the noninjected tumor in the distant lesion of the same mice were suppressed after vaccination. Further studies found that this in situ vaccine triggered systemic tumor‐specific responses, with one‐fold increase of effector memory T cells properties and stronger toxicity of lymphocytes in spleen. Besides, we found that imiquimod upregulated the expression of OX40 on CD4+ T cells and thus enhanced the effectiveness of OX40 agonist. Five immune‐positive‐related pathways were activated after vaccination. This in situ vaccine caused little harm to normal organs and provided long‐term protection against the same syngeneic tumor rechallenge. Due to its effectiveness, feasibility and safety, this strategy could potentially be applied to various types of late‐stage solid tumors and worthy of further clinical research., We explore an immunotherapy approach with agonistic anti OX40, which is an important TNFSF receptor on surface of activated T cells. The main result of the paper is imiquimod induce an additive effect on T cell antitumor activity, when combined with OX40 agonist immunotherapy. It was strikingly interesting this effect was shown to generate memory T cells with a long lasting immunity in rechallenged animals.

Published

2021

40. "Closed-Loop" O 2 -Economizer Induced In Situ Therapeutic Vaccine against Hypoxic Tumors.

Author

Zhao Y, Zhang M, Lv B, Xue G, Jiang H, Chen G, Ma Y, Sun Y, and Cao J

Subjects

Humans, Oxygen metabolism, Phototherapy, Hypoxia, Photosensitizing Agents pharmacology, Photosensitizing Agents therapeutic use, Antigens, Neoplasm, Cell Line, Tumor, Tumor Microenvironment, Photochemotherapy, Cancer Vaccines therapeutic use, Nanoparticles

Abstract

Therapeutic tumor vaccines, which use tumor antigens to stimulate a cancer patient's immune system to eventually kill the tumor tissues, have emerged as one of the most attractive strategies in anticancer research. Especially, exploring in situ vaccines has become a potential field in cancer immunotherapy. However, due to the hypoxic tumor microenvironment, the generation of tumor antigens is always mild and not sufficient. Hence, in this study, we designed a closed-loop mitochondrial oxygen-economizer (TPCA) to induce enhanced phototherapy-driven in situ vaccines. The O 2 -economizer was developed by the integration of the photosensitizer CyI and the mitochondrial inhibitor atovaquone into the PAMAM dendrimer. In vitro and in vivo studies showed that TPCA could enter the mitochondria through (3-propylcarboxyl) triphenylphosphine bromide (TPP) and effectively restrict the respiration of tumor cells to reduce tumor hypoxia, thus providing continuous oxygen for enhanced iodinated cyanine dye mediated photodynamic therapy, which could further induce in situ vaccines for ablating the primary tumor directly and inhibiting the tumor metastasis and recurrence. Furthermore, the antitumor mechanism revealed that O 2 -economizer-based oxygen-boosted PDT elicited immunogenic cancer cell death with enhanced exposure and release of DAMPs and altered the immunosuppressive tumor microenvironment with increased recruitment of T cells in tumors, thereby inducing in situ vaccines and provoking the systematic antitumor responses against CT26 tumors. This study will provide innovative approaches for local, abscopal, and metastatic tumor treatment.

Published

2023

41. Combining brachytherapy and immunotherapy to achieve in situ tumor vaccination: A review of cooperative mechanisms and clinical opportunities.

Author

Patel, Ravi B., Baniel, Claire C., Sriramaneni, Raghava N., Bradley, Kristin, Markovina, Stephanie, and Morris, Zachary S.

Subjects

*RADIOISOTOPE brachytherapy, *IMMUNOTHERAPY, *CANCER vaccines, *CANCER treatment, *IMMUNE response

Abstract

Abstract As immunotherapies continue to emerge as a standard component of treatment for a variety of cancers, the imperative for testing these in combination with other standard cancer therapies grows. Radiation therapy may be a particularly well-suited partner for many immunotherapies. By modulating immune tolerance and functional immunogenicity at a targeted tumor site, radiation therapy may serve as a method of in situ tumor vaccination. In situ tumor vaccination is a therapeutic strategy that seeks to convert a patient's own tumor into a nidus for enhanced presentation of tumor-specific antigens in a way that will stimulate and diversify an antitumor T cell response. The mechanisms whereby radiation may impact immunotherapy are diverse and include its capacity to simultaneously elicit local inflammation, temporary local depletion of suppressive lymphocyte lineages, enhanced tumor cell susceptibility to immune response, and immunogenic tumor cell death. Emerging data suggest that each of these mechanisms may display a distinct dose–response profile, making it challenging to maximize each of these effects using external beam radiation. Conversely, the highly heterogenous and conformal dose distribution achieved with brachytherapy may be optimal for enhancing the immunogenic capacity of radiation at a tumor site while minimizing off-target antagonistic effects on peripheral immune cells. Here, we review the immunogenic effects of radiation, summarize the clinical rationale and data supporting the use of radiation together with immunotherapies, and discuss the rationale and urgent need for further preclinical and clinical investigation specifically of brachytherapy in combination with immunotherapies. Harnessing these immunomodulatory effects of brachytherapy may offer solutions to overcome obstacles to the efficacy of immunotherapies in immunologically "cold" tumors while potentiating greater response in the context of immunologically "hot" tumors. [ABSTRACT FROM AUTHOR]

Published

2018

42. Radiation and Anti-Cancer Vaccines: A Winning Combination.

Author

Cadena, Alexandra, Cushman, Taylor R., Anderson, Clark, Barsoumian, Hampartsoum B., Welsh, James W., and Cortez, Maria Angelica

Subjects

CANCER vaccines, ANTINEOPLASTIC agents, CANCER radiotherapy, TOLL-like receptors, DNA damage

Abstract

The emerging combination of radiation therapy with vaccines is a promising new treatment plan in the fight against cancer. While many cancer vaccines such as MUC1, p53 CpG oligodeoxynucleotide, and SOX2 may be great candidates for antitumor vaccination, there still remain many investigations to be done into possible vaccine combinations. One fruitful partnership that has emerged are anti-tumor vaccines in combination with radiation. Radiation therapy was previously thought to be only a tool for directly or indirectly damaging DNA and therefore causing cancer cell death. Now, with much preclinical and clinical data, radiation has taken on the role of an in situ vaccine. With both cancer vaccines and radiation at our disposal, more and more studies are looking to combining vaccine types such as toll-like receptors, viral components, dendritic-cell-based, and subunit vaccines with radiation. While the outcomes of these combinatory efforts are promising, there is still much work to be covered. This review sheds light on the current state of affairs in cancer vaccines and how radiation will bring its story into the future. [ABSTRACT FROM AUTHOR]

Published

2018

43. Intratumoral immunotherapy: using the tumor as the remedy.

Author

Marabelle, A., Tselikas, L., de Baere, T., and Houot, R.

Subjects

*CANCER immunotherapy, *LIGANDS (Biochemistry), *MONOCLONAL antibodies, *ANTINEOPLASTIC agents, *CANCER cells, *CANCER vaccines

Abstract

Immune checkpoint-targeted monoclonal antibodies directed at Programmed Death Receptor 1 (PD-1), Programmed Death Ligand 1 (PD-L1) and Cytotoxic T-Lymphocyte Associated Protein 4 (CTLA-4) are currently revolutionizing the prognosis of many cancers. By blocking co-inhibitory receptors expressed by antitumor T cells, these antibodies can break the immune tolerance against tumor cells and allow the generation of durable cancer immunity. Benefits in overall survival over conventional therapies have been demonstrated for patients treated with these immunotherapies, leading to multiple approvals of such therapies by regulatory authorities. However, only a minority of patients develop an objective tumor response with long-term survival benefits. Moreover, the systemic delivery of immunotherapies can be responsible for severe auto-immune toxicities. This risk increases dramatically with anti-PD(L)1 and anti-CTLA-4 combinations and currently hampers the development of triple combination immunotherapies. In addition, the price of these novel treatments is probably too high to be reimbursed by health insurances for all the potential indications where immunotherapy has shown activity (i.e. in more than 30 different cancer types). Intratumoral immunotherapy is a therapeutic strategy which aims to use the tumor as its own vaccine. Upon direct injections into the tumor, a high concentration of immunostimulatory products can be achieved in situ, while using small amounts of drugs. Local delivery of immunotherapies allows multiple combination therapies, while preventing significant systemic exposure and off-target toxicities. Despite being uncertain of the dominant epitopes of a given cancer, one can therefore trigger an immune response against the relevant neo-antigens or tumor-associated antigens without the need for their characterization. Such immune stimulation can induce a strong priming of the cancer immunity locally while generating systemic (abscopal) tumor responses, thanks to the circulation of properly activated antitumor immune cells. While addressing many of the current limitations of cancer immunotherapy development, intratumoral immunotherapy also offers a unique opportunity to better understand the dynamics of cancer immunity by allowing sequential and multifocal biopsies at every tumor injection. [ABSTRACT FROM AUTHOR]

Published

2017

44. In situ vaccination using unique TLR9 ligand K3-SPG induces long-lasting systemic immune response and synergizes with systemic and local immunotherapy

Author

Okada, Hirokazu and Okada, Hirokazu

Published

2022

45. Interaktionen von Strahlen- und Immuntherapie.

Author

Rückert, Michael, Deloch, Lisa, Fietkau, Rainer, Frey, Benjamin, and Gaipl, Udo

Abstract

Copyright of Der Onkologe is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2017

46. The Potency of Cowpea Mosaic Virus Particles for Cancer In Situ Vaccination Is Unaffected by the Specific Encapsidated Viral RNA.

Author

Jung E, Chung YH, Mao C, Fiering SN, and Steinmetz NF

Subjects

Animals, Dogs, Mice, RNA, Viral genetics, Disease Models, Animal, Cytokines, Vaccination, Comovirus physiology, Cancer Vaccines, Melanoma

Abstract

Plant virus nanoparticles can be used as drug carriers, imaging reagents, vaccine carriers, and immune adjuvants in the formulation of intratumoral in situ cancer vaccines. One example is the cowpea mosaic virus (CPMV), a nonenveloped virus with a bipartite positive-strand RNA genome with each RNA packaged separately into identical protein capsids. Based on differences in their densities, the components carrying RNA-1 (6 kb) denoted as the bottom (B) component or carrying RNA-2 (3.5 kb) denoted as the middle (M) component can be separated from each other and from a top (T) component, which is devoid of any RNA. Previous preclinical mouse studies and canine cancer trials used mixed populations of CPMV (containing B, M, and T components), so it is unclear whether the particle types differ in their efficacies. It is known that the CPMV RNA genome contributes to immunostimulation by activation of TLR7. To determine whether the two RNA genomes that have different sizes and unrelated sequences cause different immune stimulation, we compared the therapeutic efficacies of B and M components and unfractionated CPMV in vitro and in mouse cancer models. We found that separated B and M particles behaved similarly to the mixed CPMV, activating innate immune cells to induce the secretion of pro-inflammatory cytokines such as IFNα, IFNγ, IL-6, and IL-12, while inhibiting immunosuppressive cytokines such as TGF-β and IL-10. In murine models of melanoma and colon cancer, the mixed and separated CPMV particles all significantly reduced tumor growth and prolonged survival with no significant difference. This shows that the specific RNA genomes similarly stimulate the immune system even though B particles have 40% more RNA than M particles; each CPMV particle type can be used as an effective adjuvant against cancer with the same efficacy as native mixed CPMV. From a translational point of view, the use of either B or M component vs the mixed CPMV formulation offers the advantage that separated B or M alone is noninfectious toward plants and thus provides agronomic safety.

Published

2023

47. In Situ Vaccination Following Intratumoral Injection of IL2 and Poly-l-lysine/Iron Oxide/CpG Nanoparticles to a Radiated Tumor Site.

Author

Zhang Y, Rahman MM, Clark PA, Sriramaneni RN, Havighurst T, Kerr CP, Zhu M, Jones J, Wang X, Kim K, Gong S, and Morris ZS

Subjects

Humans, Animals, Mice, Interleukin-2, Polylysine, Injections, Intralesional, CD8-Positive T-Lymphocytes, Antibodies, Vaccination, Cell Line, Tumor, Tumor Microenvironment, Neoplasms drug therapy, Nanoparticles

Abstract

The in situ vaccine effect of radiation therapy (RT) has been shown to be limited in both preclinical and clinical settings, possibly due to the inadequacy of RT alone to stimulate in situ vaccination in immunologically "cold" tumor microenvironments (TMEs) and the mixed effects of RT in promoting tumor infiltration of both effector and suppressor immune cells. To address these limitations, we combined intratumoral injection of the radiated site with IL2 and a multifunctional nanoparticle (PIC). The local injection of these agents produced a cooperative effect that favorably immunomodulated the irradiated TME, enhancing the activation of tumor-infiltrating T cells and improving systemic anti-tumor T cell immunity. In syngeneic murine tumor models, the PIC+IL2+RT combination significantly improved the tumor response, surpassing the single or dual combinations of these treatments. Furthermore, this treatment led to the activation of tumor-specific immune memory and improved abscopal effects. Our findings suggest that this strategy can be used to augment the in situ vaccine effect of RT in clinical settings.

Published

2023

48. Radiation and Anti-Cancer Vaccines: A Winning Combination

Author

Alexandra Cadena, Taylor R. Cushman, Clark Anderson, Hampartsoum B. Barsoumian, James W. Welsh, and Maria Angelica Cortez

Subjects

radiotherapy, in situ vaccine, cancer, immunotherapy, viral vaccines, protein/peptide vaccines, toll-like receptors, Medicine

Abstract

The emerging combination of radiation therapy with vaccines is a promising new treatment plan in the fight against cancer. While many cancer vaccines such as MUC1, p53 CpG oligodeoxynucleotide, and SOX2 may be great candidates for antitumor vaccination, there still remain many investigations to be done into possible vaccine combinations. One fruitful partnership that has emerged are anti-tumor vaccines in combination with radiation. Radiation therapy was previously thought to be only a tool for directly or indirectly damaging DNA and therefore causing cancer cell death. Now, with much preclinical and clinical data, radiation has taken on the role of an in situ vaccine. With both cancer vaccines and radiation at our disposal, more and more studies are looking to combining vaccine types such as toll-like receptors, viral components, dendritic-cell-based, and subunit vaccines with radiation. While the outcomes of these combinatory efforts are promising, there is still much work to be covered. This review sheds light on the current state of affairs in cancer vaccines and how radiation will bring its story into the future.

Published

2018

49. Plant Viral Nanoparticle Conjugated with Anti-PD-1 Peptide for Ovarian Cancer Immunotherapy

Author

Aayushma Gautam, Veronique Beiss, Nicole F. Steinmetz, Chao Wang, and Lu Wang

Subjects

QH301-705.5, medicine.medical_treatment, Comovirus, checkpoint inhibitor therapy, Cancer Vaccines, Catalysis, B7-H1 Antigen, Plant Viruses, Inorganic Chemistry, Mice, Cancer immunotherapy, Immunity, medicine, Animals, Humans, Amino Acid Sequence, Vaccines, Virus-Like Particle, Biology (General), Physical and Theoretical Chemistry, QD1-999, Molecular Biology, Spectroscopy, Ovarian Neoplasms, Tumor microenvironment, Innate immune system, cancer immunotherapy, biology, Chemistry, Communication, Organic Chemistry, General Medicine, Immunotherapy, medicine.disease, Xenograft Model Antitumor Assays, Immune checkpoint, Computer Science Applications, in situ vaccine, Disease Models, Animal, cowpea mosaic virus, biology.protein, Cancer research, Nanoparticles, Female, Antibody, Ovarian cancer, anti-PD-1 blockade, Peptides

Abstract

Immunotherapy holds tremendous potential in cancer therapy, in particular, when treatment regimens are combined to achieve synergy between pathways along the cancer immunity cycle. In previous works, we demonstrated that in situ vaccination with the plant virus cowpea mosaic virus (CPMV) activates and recruits innate immune cells, therefore reprogramming the immunosuppressive tumor microenvironment toward an immune-activated state, leading to potent anti-tumor immunity in tumor mouse models and canine patients. CPMV therapy also increases the expression of checkpoint regulators on effector T cells in the tumor microenvironment, such as PD-1/PD-L1, and we demonstrated that combination with immune checkpoint therapy improves therapeutic outcomes further. In the present work, we tested the hypothesis that CPMV could be combined with anti-PD-1 peptides to replace expensive antibody therapies. Specifically, we set out to test whether a multivalent display of anti-PD-1 peptides (SNTSESF) would enhance efficacy over a combination of CPMV and soluble peptide. Efficacy of the approaches were tested using a syngeneic mouse model of intraperitoneal ovarian cancer. CPMV combination with anti-PD-1 peptides (SNTSESF) resulted in increased efficacy; however, increased potency against metastatic ovarian cancer was only observed when SNTSESF was conjugated to CPMV, and not added as a free peptide. This can be explained by the differences in the in vivo fates of the nanoparticle formulation vs. the free peptide; the larger nanoparticles are expected to exhibit prolonged tumor residence and favorable intratumoral distribution. Our study provides new design principles for plant virus-based in situ vaccination strategies.

Published

2021

50. Post-irradiation intratumoral heterogeneity modulates response to immune checkpoint inhibition therapy in a murine melanoma model.

Author

Wang, Jie, Sud, Shivani, Qu, Yanli, Li, Liantao, Zhang, Jiajie, Marron, David, Knape, Nicole Michelle, Kim, Isaiah James, Wagner, Kyle Thomas, Zhang, Tian, Zhao, Yuxia, Guo, Genyan, and Wang, Andrew Z.

Subjects

*IMMUNE checkpoint inhibitors, *IPILIMUMAB, *IMMUNE response, *MELANOMA, *HETEROGENEITY, *LABORATORY mice

Abstract

The underlying mechanism for radiation as a potentiator of immune checkpoint inhibition (ICI) is unclear. We developed a novel murine model to investigate the effects of post-irradiation intratumoral heterogeneity (ITH) on response to ICI. Parental mouse melanoma B16F10 cells were irradiated in vitro (5Gy x 3 fractions), then an a priori determined number of resulting colonies were implanted in C57BL/6J immunocompetent mice creating syngeneic models of unirradiated (parental) and irradiated tumors with low (irradiated-L) and high (irradiated-H) ITH. Mice were treated with placebo, α-PD-L1, α-CTLA-4 or dual ICI. Murine tumors underwent whole exome sequencing (WES). Clinically correlated paired pre- and post-irradiation patient rectal adenocarcinoma samples underwent WES. Irradiated-L tumors showed increased tumor mutational burden (TMB) and a sustained decrease in ITH. Irradiated-L tumors were predicted to express five neoantigens with high variant allele frequency/clonal distribution. Mice with irradiated-L and irradiated-H versus parental B16F10 tumors demonstrated longer overall survival with dual ICI. Only mice with irradiated-L tumors experienced an overall survival benefit with single agent ICI. Clinically correlated rectal adenocarcinoma samples showed similarly increased TMB and decreased ITH following irradiation. Post-irradiation ITH modulates ICI response in a murine melanoma model. Irradiation may offer a mechanism to widen the therapeutic window of ICI. [ABSTRACT FROM AUTHOR]

Published

2023