Pseudocowpox virus, a novel vector to enhance the therapeutic efficacy of antitumor vaccination

Objective

Antitumor viral vaccines, and more particularly poxviral vaccines, represent an active field for clinical development and translational research. To improve the efficacy and treatment outcome, new viral vectors are sought, with emphasis on their abilities to stimulate innate immunity, to display tumor antigens and to induce a specific T‐cell response.

Methods

We screened for a new poxviral backbone with improved innate and adaptive immune stimulation using IFN‐α secretion levels in infected PBMC cultures as selection criteria. Assessment of virus effectiveness was made in vitro and in vivo.

Results

The bovine pseudocowpox virus (PCPV) stood out among several poxviruses for its ability to induce significant secretion of IFN‐α. PCPV produced efficient activation of human monocytes and dendritic cells, degranulation of NK cells and reversed MDSC‐induced T‐cell suppression, without being offensive to activated T cells. A PCPV‐based vaccine, encoding the HPV16 E7 protein (PCPV‐E7), stimulated strong antigen‐specific T‐cell responses in TC1 tumor‐bearing mice. Complete regression of tumors was obtained in a CD8⁺ T‐cell‐dependent manner after intratumoral injection of PCPV‐E7, followed by intravenous injection of the cancer vaccine MVA‐E7. PCPV also proved active when injected repeatedly intratumorally in MC38 tumor‐bearing mice, generating tumor‐specific T‐cell responses without encoding a specific MC38 antigen. From a translational perspective, we demonstrated that PCPV‐E7 effectively stimulated IFN‐γ production by T cells from tumor‐draining lymph nodes of HPV⁺‐infected cancer patients.

Conclusion

We propose PCPV as a viral vector suitable for vaccination in the field of personalised cancer vaccines, in particular for heterologous prime‐boost regimens.

Oncolytic properties of non-vaccinia poxviruses

Vaccinia virus, a member of the Poxviridae family, has been extensively used as an oncolytic agent and has entered late stage clinical development. In this study, we evaluated the potential oncolytic properties of other members of the Poxviridae family. Numerous tumor cell lines were infected with ten non-vaccinia poxviruses to identify which virus displayed the most potential as an oncolytic agent. Cell viability indicated that tumor cell lines were differentially susceptible to each virus. Raccoonpox virus was the most potent of the tested poxviruses and was highly effective in controlling cell growth in all tumor cell lines. To investigate further the oncolytic capacity of the Raccoonpox virus, we have generated a thymidine kinase (TK)-deleted recombinant Raccoonpox virus expressing the suicide gene FCU1. This TK-deleted Raccoonpox virus was notably attenuated in normal primary cells but replicated efficiently in numerous tumor cell lines. In human colon cancer xenograft model, a single intratumoral inoculation of the recombinant Raccoonpox virus, in combination with 5-fluorocytosine administration, produced relevant tumor growth control. The results demonstrated significant antitumoral activity of this new modified Raccoonpox virus armed with FCU1 and this virus could be considered to be included into the growing armamentarium of oncolytic virotherapy for cancer.

Abstract LB-287: Pseudocowpox: A next generation viral vector for cancer immunotherapy

Engineered viral vectors are effective approaches to stimulate anti-tumor immunity, and change the tumor immune environment. Several viruses and strains have been developed to express tumor antigens and cytokines, and corresponding products are in advanced clinical trials. However, novel viral strains with improved immunogenic properties are sought. In this perspective, we screened a variety of poxviridae potentially usable in humans: Cowpox (CPX), Pseudocowpox (PCPV), Parapoxvirus Ovis (ORF), Myxoma virus (MYX), Swinepox (SWP), Yaba-like disease virus (YLDV), Raccoonpox (RCN), Cotia virus (CTV), and compared them to the well-established vaccine strain Modified Virus Ankara (MVA), and oncolytic Vaccinia Virus, strain Copenhagen (VV). Both in vitro with human primary immune cells, and in vivo with syngeneic mouse tumor models, PCPV proved to be a very promising vector for immunotherapy. Compared with MVA, PCPV induced a 1000-fold higher expression of IFN-alpha in human PBMCs, whereas SWPV and ORF displayed a lower 10 to 100-fold induction. Other viruses (i.e. VV, RCN, CTV, or MYX) did not raise the IFN-alpha level. PCPV was also shown to increase the level of GM-CSF, and to be safe for PBMCs, in contrast to ORF which displayed some cytotoxic effects. When tested for its capacity to trigger the expression of CD86, a co-stimulatory factor for T-cell activation, PCPV was shown to be superior than MVA in primary moDCs. Furthermore, PCPV treatment increased CD86 expression in human CD163+CD206+ “M2”-type macrophages derived from CD14+ monocytes, suggesting a shift to an antigen-presenting phenotype. In these cells, PCPV increased significantly the secretion of IL-18, IL-6 and IP-10, signing a conversion towards a less suppressive macrophage phenotype. Last, incubation of PCPV in a co-culture model overcame the immunosuppressive effect of MDSCs on human autologous CD8+ T. A GFP-encoding recombinant PCPV vector was generated, and we could demonstrate that PCPV was capable of infecting human primary immune cells, comparably to recombinant MVA vectors, except for activated T cells. A recombinant PCPV encoding for the HPV E7 protein was generated to assess the anti-tumor activity and immunogenicity in a syngeneic murine tumor model. Like MVA-E7, PCPV-E7 induced a strong cellular response (ELISPOT on splenocytes, and frequency of antigen-specific short-lived effector cells), but PCPV-E7 displayed a different cytokine/chemokine profile at the site of injection, with increased levels of pro-immune cytokines including IP-10, IFN-gamma, GM-CSF, IL-18, MIP-1 alpha, MIP-1 beta, IL-12 and IL-6. When injected intratumorally into fast growing MC-38 tumors, PCPV led to tumor control. Analysis of tumors infiltrates showed that PCPV treatment led to higher levels of neutrophils and decreased the frequency of MHCIIlo TAMs. Our data demonstrate that PCPV might display better properties than current viral vectors, in terms of local response and priming activity, of ability to induce effector T cells and to reshape the tumor infiltration profiles. It has the same capacity as other poxviruses to encode and deliver large genetic payload, which will be useful for designing advanced anti-tumor vaccines.

Citation Format: Karola Rittner, Marine Ricordel, Caroline Tosch, Christine Thioudellet, Christelle Remy-Ziller, Marie-Christine Claudepierre, Chantal Hoffmann, Doris Schmitt, Benoit Sansas, Johann Foloppe, Philippe Erbs, Nathalie Silvestre, Kaïdre Bendjama, Eric Quemeneur. Pseudocowpox: A next generation viral vector for cancer immunotherapy [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr LB-287.

Cowpox Virus: A New and Armed Oncolytic Poxvirus

Oncolytic virus therapy has recently been recognized as a promising new therapeutic approach for cancer treatment. In this study, we are proposing for the first time to evaluate the in vitro and in vivo oncolytic capacities of the Cowpox virus (CPXV). To improve the tumor selectivity and oncolytic activity, we developed a thymidine kinase (TK)-deleted CPXV expressing the suicide gene FCU1, which converts the non-toxic prodrug 5-fluorocytosine (5-FC) into cytotoxic 5-fluorouracil (5-FU) and 5-fluorouridine-5′-monophosphate (5-FUMP). This TK-deleted virus replicated efficiently in human tumor cell lines; however, it was notably attenuated in normal primary cells, thus displaying a good therapeutic index. Furthermore, this new recombinant poxvirus rendered cells sensitive to 5-FC. In vivo, after systemic injection in mice, the TK-deleted variant caused significantly less mortality than the wild-type strain. A biodistribution study demonstrated high tumor selectivity and low accumulation in normal tissues. In human xenograft models of solid tumors, the recombinant CPXV also displayed high replication, inducing relevant tumor growth inhibition. This anti-tumor effect was improved by 5-FC co-administration. These results demonstrated that CPXV is a promising oncolytic vector capable of expressing functional therapeutic transgenes.