Abstract A13: Optimization of a dendritic cell-targeting MIP3α-antigen fusion vaccine in the B16F10 mouse melanoma model

James T. Gordy, K. Luo, R. Markham
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Abstract

Background: The chemokine MIP-3α (CCL20) binds to CCR6 found on immature dendritic cells. Vaccines fusing MIP-3α to gp100 have been shown to be effective in therapeutically alleviating melanoma in mouse models. However, that protection was not complete. To optimize the therapy, our laboratory is exploring two avenues. First, we added agents designed to modulate the tolerogenic tumor microenvironment. Here, we report that neutralizing IL-10 at the tumor site enhances the therapeutic anti-melanoma efficacy of a MIP-3α-gp100 DNA vaccine. Secondly, we are optimizing the antigenic profile of the vaccine to help reduce the probability of immunoediting processes leading to tumor therapy escape. Methods: The current studies utilize the B16F10 syngeneic, transplantable, mouse melanoma model system. The MIP-3α-antigen DNA vaccine is administered intramuscularly (i.m.) into the tibialis muscle, followed immediately by i.m. electroporation. Constructs utilized include MIP-3α fused to gp100 alone or in addition to TRP-2. Vaccinations are given therapeutically, beginning at day 3 or 5 post challenge. Tumor sizes, growth, and survival were all assessed. Treatment responses were characterized by flow cytometric analysis of tumor infiltrate. Vaccine-specific T-cells were delineated by gp10025-33 stimulation followed by intracellular cytokine staining for IFN-γ and assessment by flow cytometry. The mechanism of αIL-10 efficacy was explored by RT-PCR and confirmed with a knockout mouse model. Results: With this therapeutic protocol, we demonstrate for the first time that by either neutralizing IL-10 or adding a second antigen to our construct, we are able to enhance the antitumor efficacy of a MIP-3α-gp100 vaccine, leading to significantly smaller tumors, slower growing tumors, and overall increases in mouse survival. Surprisingly, the additive effects of αIL-10 were not shown to be directly mediated by any T-cell parameter tested, including vaccine-specific tumor infiltrating lymphocytes (TILs), total TILs of either CD4+ or CD8+ subset, regulatory T-cells, granzyme positive T-cells, and others. We discovered, however, that IFNα-4 transcripts in the tumor were significantly upregulated in mice given vaccine and αIL-10 compared to vaccine alone. A mouse model with IFNαR1 knocked out eliminated the protection provided by αIL-10, demonstrating that the additional therapeutic value of αIL-10 is primarily mediated by type-I interferons. The immunologic details of the added TRP2 antigen are currently being explored. Conclusions: Efficient targeting of antigen to immature dendritic cells with a chemokine fusion vaccine offers a potential alternative approach to the ex vivo dendritic cell antigen loading protocols currently undergoing clinical investigation. Adding multiple antigens or combining this approach with an IL-10 neutralizing antibody therapy that modulates the tolerogenic tumor microenvironment both enhance vaccine efficacy. Further potential therapy optimization currently undergoing investigation offers promise for this line of investigation to become a novel melanoma therapy. Citation Format: James T. Gordy, Kun Luo, Richard B. Markham. Optimization of a dendritic cell-targeting MIP3α-antigen fusion vaccine in the B16F10 mouse melanoma model [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2018;6(9 Suppl):Abstract nr A13.
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A13:树突状细胞靶向mip3 α-抗原融合疫苗在B16F10小鼠黑色素瘤模型中的优化
背景:趋化因子MIP-3α (CCL20)与未成熟树突状细胞上发现的CCR6结合。在小鼠模型中,融合MIP-3α与gp100的疫苗已被证明在治疗性缓解黑色素瘤方面是有效的。然而,这种保护并不完全。为了优化治疗,我们的实验室正在探索两种途径。首先,我们添加了旨在调节耐受性肿瘤微环境的药物。在这里,我们报道在肿瘤部位中和IL-10可以增强MIP-3α-gp100 DNA疫苗的抗黑色素瘤疗效。其次,我们正在优化疫苗的抗原谱,以帮助降低免疫编辑过程导致肿瘤治疗逃逸的可能性。方法:本研究采用B16F10同基因、可移植的小鼠黑色素瘤模型系统。mip -3α-抗原DNA疫苗肌内注射(i.m)到胫骨肌,随后立即i.m电穿孔。所使用的构建体包括MIP-3α单独与gp100或与TRP-2融合。疫苗接种是治疗性的,从感染后第3或5天开始。评估肿瘤大小、生长和生存。通过肿瘤浸润的流式细胞术分析来表征治疗效果。通过gp10025-33刺激、细胞内细胞因子IFN-γ染色和流式细胞术评估来描绘疫苗特异性t细胞。采用RT-PCR方法探讨αIL-10的作用机制,并建立敲除小鼠模型进行验证。结果:通过这种治疗方案,我们首次证明,通过中和IL-10或在我们的构建中添加第二抗原,我们能够增强MIP-3α-gp100疫苗的抗肿瘤功效,导致肿瘤显着变小,肿瘤生长缓慢,并且总体上提高了小鼠存活率。令人惊讶的是,αIL-10的累加效应并未被任何测试的t细胞参数直接介导,包括疫苗特异性肿瘤浸润淋巴细胞(til)、CD4+或CD8+亚群的总til、调节性t细胞、颗粒酶阳性t细胞等。然而,我们发现,与单独接种疫苗相比,接种疫苗和αIL-10的小鼠肿瘤中IFNα-4转录物显著上调。敲除IFNαR1的小鼠模型消除了αIL-10提供的保护作用,表明αIL-10的附加治疗价值主要是由i型干扰素介导的。目前正在探索添加的TRP2抗原的免疫学细节。结论:利用趋化因子融合疫苗将抗原有效靶向未成熟树突状细胞,为目前正在进行临床研究的体外树突状细胞抗原加载方案提供了一种潜在的替代方法。添加多种抗原或将这种方法与调节耐受性肿瘤微环境的IL-10中和抗体治疗相结合,都能提高疫苗的效力。目前正在研究的进一步潜在的治疗优化为这条研究路线提供了成为一种新的黑色素瘤治疗方法的希望。引文格式:James T. Gordy, Kun Luo, Richard B. Markham。树突状细胞靶向mip3 α-抗原融合疫苗在B16F10小鼠黑色素瘤模型中的优化[摘要]。摘自:AACR肿瘤免疫学和免疫治疗特别会议论文集;2017年10月1-4日;波士顿,MA。费城(PA): AACR;癌症免疫学杂志,2018;6(9增刊):摘要nr A13。
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