Inactivated Rabies Virus-Based Ebola Vaccine Preserved by Vaporization Is Heat-Stable and Immunogenic Against Ebola and Protects Against Rabies Challenge.

BACKGROUND: Ebola virus (EBOV) is a highly lethal member of the Filoviridae family associated with human hemorrhagic disease. Despite being a sporadic disease, it caused a large outbreak in 2014-2016 in West Africa and another outbreak recently in the Democratic Republic of Congo. Several vaccine candidates are currently in preclinical and clinical studies but none are stable without cold chain storage. METHODS: We used preservation by vaporization (PBV), a novel processing technology to heat-stabilize FiloRab1 (inactivated rabies-based Ebola vaccine), a candidate Ebola vaccine, and stored the vials at temperatures ranging from 4°C to 50°C for 10 days to 12 months. We immunized Syrian hamsters with the best long-term stable FiloRab1 PBV vaccines and challenged them with rabies virus (RABV). RESULTS: Syrian hamsters immunized with FiloRab1 PBV-processed vaccines stored at temperatures of 4°C and 37°C for 6 months, and at 50°C for 2 weeks, seroconverted against both RABV-G and EBOV-GP. Notably, all of the FiloRab1 PBV vaccines proved to be 100% effective in a RABV challenge model. CONCLUSIONS: We successfully demonstrated that the FiloRab1 PBV vaccines are stable and efficacious for up to 6 months when stored at temperatures ranging from 4°C to 37°C and for up to 2 weeks at 50°C.

Treatment of microscopic pulmonary metastases with recombinant autologous tumor vaccine expressing interleukin 6 and Escherichia coli cytosine deaminase suicide genes.

Poorly immunogenic tumor cells genetically transduced to simultaneously express the cytokine interleukin 6 (IL-6) and the bacterial metabolic suicide gene cytosine deaminase (205-IL6-CD) become highly immunogenic. They are rejected by normal mice without 5-fluorocytosine prodrug treatment. Mice with preexisting wild-type pulmonary micrometastases exhibit prolonged survival and an increased rate of cure when treated with live 205-IL6-CD cells as a therapeutic vaccine. Treatment with these autologous tumor cells producing both the cytokine and the bacterial protein was more effective than treatment with exogenous IL-6 and/or irradiated wild-type tumor cells. Irradiation of the 205-IL6-CD cells significantly reduced their therapeutic efficacy. Therapeutic vaccination with 205-IL6-CD was more effective in animals with wild-type 205 tumor than in animals bearing an unrelated syngeneic tumor. Vaccine efficacy was significantly reduced in animals pretreated with high-dose cyclophosphamide. The results indicate that genetically engineered autologous tumor vaccines may be capable of inducing significant antitumor immunity in hosts of preexisting micrometastatic disease.

Genetically modified tumour vaccines (GMTV) in melanoma clinical trials.

Since melanoma is a model immunogenic malignancy incurable in the disseminated phase of its natural course different immunotherapeutic approaches are tested in clinical trials. A number of tumour vaccines genetically modified (GMTV), with various immunostimulatory factors, are tested in phase I/II clinical trials. These factors include cytokines, tumour antigens (TA), costimulatory molecules or HLA antigens. We have designed a novel, mixed auto/allogeneic cellular melanoma vaccine modified with the IL-6 and the sIL-6R genes. Preclinical studies in a mouse model demonstrated that the IL-6/sIL-6R based vaccine is able to elicit efficient anti-tumour responses, mediated by CD8+ and NK cells, which resulted in inhibition of the tumour growth, metastases formation and prolonged survival of the animals treated. Irradiation of vaccine cells does not only lead to their sterilisation but also causes increased secretion of exogenous IL-6 and sIL-6R. Since January 1996 we have vaccinated more than one hundred metastatic melanoma patients. Promising clinical results (22% CR+PR, 32% SD) and the evidence of immune responses in the vaccinated patients have prompted us to design a phase III clinical trial which is to be open in 2000.

IL-2 gene-modified tumour vaccines: monitoring of IL-2 levels in serum and peritoneal cavity of vaccinated mice.

IL-2 kinetics was assessed in mice vaccinated with irradiated syngeneic tumour vaccines carrying an inserted IL-2 gene and producing constitutively IL-2. For comparison, the kinetics of i.v. administered recombinant IL-2 was also examined. During regular time intervals after the vaccination or administration of recombinant IL-2, samples of serum and peritoneal fluid were collected and examined, using CTLL bioassay or its MTT modification. After i.p. administration of irradiated IL-2-producing plasmacytoma (X63-m-IL-2) vaccine, the levels of IL-2 were substantially higher in the peritoneal fluid than in the serum. Both in the peritoneal fluid and in the serum, the IL-2 level was increasing up to 60 min after administration and then it gradually decreased. The last time point when IL-2 was still detectable both in the peritoneal fluid and in the serum was 30 h. Almost identical results were obtained when the IL-2 levels were detected by the conventional CTLL assay, in which DNA synthesis was monitored by 3H-thymidine labeling, and by the isotope-free MTT modification of the CTLL assay, in which the DNA synthesis was monitored by staining. The MTT modification has the advantage of an isotope-free method. Comparison of two different IL-2-producing vaccines, a murine plasmacytoma X63-m-IL-2, with high IL-2 production, and murine sarcoma MC12-IL-2, with low IL-2 production, revealed that whereas after i.p. administration of the high producers, the peak of IL-2 was reached both in the peritoneal fluid and in the serum after 1 h, the administration of low producers gave the peak level of IL-2 later, 5 h after i.p. administration. Comparison of IL-2 levels obtained after i.p. administration of live and irradiated X63-m-IL-2 vaccine revealed that the irradiated vaccine produced both in vitro and in vivo higher amounts of IL-2. As compared to i.p. administration, the kinetics after i.v. administration of the X63-m-IL-2 vaccine was different. The maximum level of recombinant IL-2 was reached 10 min after administration and IL-2 was undetectable after 5 h. When the injections of recombinant IL-2 were repeated, the elimination of IL-2 from the circulation was substantially faster.