TY - THES A1 - Ye, Mingyu T1 - Immunotherapy with Vaccinia virus co-expressing tumor-associated antigens and mouse IL-2 cytokine in mice with mammary cancer T1 - Immuntherapie von Brustkrebs in tumortragenden Mäusen mit genetisch modifizierten Vaccinia Viren, die simultan Interleukin-2 und tumorassoziierte Antigene exprimieren N2 - Interleukin 2 (IL-2) was the first cytokine applied for cancer treatment in human history. It has been approved as monotherapy for renal cell carcinoma and melanoma by the FDA and does mediate the regression of the tumors in patients. One of the possible mechanisms is that the administration of IL-2 led to T lymphocytes expansion, including CD4+ and CD8+ T cells. In addition, a recent study demonstrated that antigen-specific T cells could also be expanded through the induction of IL-2, which plays a crucial role in mediating tumor regression. However, despite the long-term and extensive use of IL-2 in the clinic, the ratio of patients who get a complete response was still low, and only about one-fifth of patients showed objective tumor regression. Therefore, the function of IL-2 in cancer treatment should continue to be optimized and investigated. A study by Franz O. Smith et al. has shown that the combination treatment of IL-2 and tumor-associated antigen vaccine has a strong trend to increased objective responses compared to patients with melanoma receiving IL-2 alone. Peptide vaccines are anti-cancer vaccines able to induce a powerful tumor antigenspecific immune response capable of eradicating the tumors. According to the type of antigens, peptide vaccines can be classified into two distinct categories: Tumor-associated antigens (TAA) vaccine and tumor-specific neoantigens (TSA) vaccine. Currently, Peptide vaccines are mainly investigated in phase I and phase II clinical trials of human cancer patients with various advanced cancers such as lung cancer, gastrointestinal tumors, and breast cancers. Vaccinia virus (VACV) is one of the safest viral vectors, which has been wildly used in cancer treatment and pathogen prevention. As an oncolytic vector, VACV can carry multiple large foreign genes, which enable the virus to introduce diagnostic and therapeutic agents without dramatically reducing the viral replication. Meanwhile, the recombinant vaccinia virus (rVACV) can be easily generated by homologous recombination. Here, we used the vaccinia virus as the therapeutic cancer vector, expressing mouse Interleukin 2 (IL-2) and tumor-associated antigens simultaneously to investigate the combined effect of anti-tumor immune response in the 4T1 mouse tumor model. As expected, the VACV driven mIL-2 expression remarkably increased both CD4+ and CD8+ populations in vivo, and the virus-expressed tumor-associated peptides successfully elicited theantigen-specific T cell response to inhibit the growth of tumors. Furthermore, the experiments with tumor-bearing animals showed that the mIL-2 plus tumor antigens expressing VACV vector gave a better anti-cancer response than the mIL-2 alone expressing vector. The combinations did significantly more inhibit tumor growth than mIL-2 treatment alone. Moreover, the results confirmed our previous unpublished data that the mIL-2 expression driven by synthetic early/late promoter in the Lister strain VACV could enhance the tumor regression in the 4T1 mouse model. N2 - Interleukin 2 (IL-2) war das erste Zytokin in der Geschichte des Menschen, das zur Krebsbehandlung eingesetzt wurde. Es ist von der FDA als Monotherapie für Nierenzellkarzinome und Melanome zugelassen und kann bei Patienten die Rückbildung von Tumorerkrankungen fördern. Einer der möglichen Mechanismen ist, dass die Verabreichung von IL-2 zu einer T-Zell- Expansion führte. Darüber hinaus zeigte eine aktuelle Studie, dass auch antigenspezifische T- Zellen vermehrt werden können, was eine entscheidende Rolle bei der Vermittlung der Tumorregression spielt. Trotz des langjährigen und umfangreichen Einsatzes von IL-2 in der Klinik war der Anteil der Patienten, die eine komplette Antwort Zeigten, jedoch immer noch gering, und nur etwa ein Fünftel der Patienten weist eine objektive Tumorregression auf. Daher sollte die Funktion von IL-2 in der Krebsbehandlung weiter optimiert und untersucht werden. Eine Studie von Franz O. Smith et al. hat gezeigt, dass die Kombinationsbehandlung von IL-2 und tumorassoziiertem Antigenimpfstoff im Vergleich zu Melanomapatienten, die IL-2 allein erhalten, einen starken Trend zu verstärkten objektiven Reaktionen aufweist. Peptidimpfstoff ist ein Anti- Krebs-Impfstoff, der in der Lage ist, eine starke tumorantigenspezifische Immunantwort zu induzieren, die die Tumore ausrotten kann. Je nach Art der Antigene kann es in zwei verschiedene Kategorien eingeteilt werden: Impfstoff gegen tumorassoziierte Antigene (TAA) und Impfstoff gegen tumorspezifische Neoantigene (TSA). Derzeit werden Peptidimpfstoffe hauptsächlich in klinischen Studien in Phasen I und II an Patienten mit verschiedenen fortgeschrittenen Krebsarten wie Lungenkrebs, Magen-Darm-Tumoren und Brustkrebs untersucht ... KW - Immunotherapy KW - Vaccinia virus Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-253095 ER - TY - JOUR A1 - Goncharova, Elena P. A1 - Ruzhenkova, Julia S. A1 - Petrov, Ivan S. A1 - Shchelkunov, Sergey N. A1 - Zenkova, Marina A. T1 - Oncolytic virus efficiency inhibited growth of tumour cells with multiple drug resistant phenotype in vivo and in vitro JF - Journal of Translational Medicine N2 - Background Tumour resistance to a wide range of drugs (multiple drug resistant, MDR) acquired after intensive chemotherapy is considered to be the main obstacle of the curative treatment of cancer patients. Recent work has shown that oncolytic viruses demonstrated prominent potential for effective treatment of diverse cancers. Here, we evaluated whether genetically modified vaccinia virus (LIVP-GFP) may be effective in treatment of cancers displaying MDR phenotype. Methods LIVP-GFP replication, transgene expression and cytopathic effects were analysed in human cervical carcinomas KB-3-1 (MDR−), KB-8-5 (MDR+) and in murine melanoma B-16 (MDR−), murine lymphosarcomas RLS and RLS-40 (MDR+). To investigate the efficacy of this therapy in vivo, we treated immunocompetent mice bearing murine lymphosarcoma RLS-40 (MDR+) (6- to 8-week-old female CBA mice; n = 10/group) or melanoma B-16 (MDR−) (6- to 8-week-old female C57Bl mice; n = 6/group) with LIVP-GFP (5 × 107 PFU of virus in 0.1 mL of IMDM immediately and 4 days after tumour implantation). Results We demonstrated that LIVP-GFP replication was effective in human cervical carcinomas KB-3-1 (MDR−) and KB-8-5 (MDR+) and in murine melanoma B-16 (MDR−), whereas active viral production was not detected in murine lymphosarcomas RLS and RLS-40 (MDR+). Additionally, it was found that in tumour models in immunocompetent mice under the optimized regimen intratumoural injections of LIVP-GFP significantly inhibited melanoma B16 (33 % of mice were with complete response after 90 days) and RLS-40 tumour growth (fourfold increase in tumour doubling time) as well as metastasis. Conclusion The anti-tumour activity of LIVP-GFP is a result of direct oncolysis of tumour cells in case of melanoma B-16 because the virus effectively replicates and destroys these cells, and virus-mediated activation of the host immune system followed by immunologically mediated destruction of of tumour cells in case of lymphosarcoma RLS-40. Thus, the recombinant vaccinia virus LIVP-GFP is able to inhibit the growth of malignant cells with the MDR phenotype and tumour metastasis when administered in the early stages of tumour development. KW - Multiple drug resistance KW - Vaccinia virus KW - Cancer KW - Human and murine cancer cells KW - Melanoma B16 KW - Oncolytic action KW - Virotherapy KW - Interleukin IL-6 KW - Immunotherapy Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-165714 VL - 14 IS - 241 ER -