Inhibition of murine K-BALB and CT26 tumour growth using a Semliki Forest virus vector with enhanced expression of IL-18

The enhanced Semliki Forest virus vector (SFV10-E), an RNA-based suicide expression vector system, expresses foreign genes at levels up to 10x higher than the original SFV10 vector. This vector has been used previously to express interleukin-12 for a tumour treatment study in a BALB/c murine model. Interleukin-18, an IFN-gamma-inducing cytokine, plays a key role in the early induction of T helper1 (Th1) cell-mediated immune responses in addition to anti-angiogenic activity. In this study, the murine IL-18 gene along with an Ig-kappa leader sequence was cloned into the SFV10-E vector. The pSFV10-E-IL-18 construct was characterised in vitro for levels of expression and secretion, and the production of biologically active IL-18 was confirmed. An in vivo tumour treatment study using high titre rSFV10-E-IL-18 virus-like particles to treat subcutaneous K-BALB and CT26 tumours in BALB/c mice demonstrated therapeutic efficacy including the disappearance of tumour cells in a minority of treated animals. Tumour regression was associated with induction of avascular and suppurative necrosis.

Inhibition of angiogenesis by a Semliki Forest virus vector expressing VEGFR-2 reduces tumour growth and metastasis in mice

Inhibition of tumour angiogenesis has been shown to restrict primary tumour growth and metastatic spread. This study examines the active induction of immune responses against tumour endothelial cells following immunization with recombinant Semliki Forest virus (rSFV) particles encoding murine vascular endothelial growth factor receptor-2 (VEGFR-2). This approach was tested in two murine tumour models, CT26 colon carcinoma and 4T1 metastasizing mammary carcinoma. Tumour growth and metastatic spread were shown to be significantly inhibited in mice that were prophylactically vaccinated or therapeutically treated with rSFV particles coding for VEGFR-2. Microvessel density analysis showed that immunization with rSFV led to significant inhibition of tumour angiogenesis. Therapeutic efficacy was found to be associated with the induction of an antibody response against VEGFR-2. Co-immunization of mice with rSFV particles encoding VEGFR-2 and interleukin (IL)-12 completely abrogated both the antibody response and the antitumour effect. However, co-immunization of mice with VEGFR-2 and IL-4 encoding particles was shown both to induce higher titres of anti-VEGFR-2 antibodies and lead to enhanced survival following tumour challenge when compared to mice vaccinated with VEGFR-2 particles alone. These findings indicate that active immunization with rSFV particles coding for VEGFR-2 can break immunological tolerance and could potentially be used as part of a novel treatment for cancer.

Regression of mouse tumours and inhibition of metastases following administration of a Semliki Forest virus vector with enhanced expression of IL-12

The Semliki Forest virus (SFV) vector is an RNA-based suicide expression vector that has been used experimentally for tumour therapy. Recently, a new enhanced vector pSFV10-E has been developed that expresses foreign genes at levels up to 10 times higher than the original vector. Interleukin-12 (IL-12), an immunomodulatory cytokine, plays a key role in the induction of T-helper1 responses. The two IL-12 gene subunits were cloned from mouse splenocytes and inserted into the pSFV10-E and pSFV10 (non-enhanced) vectors. Both constructs expressed and secreted biologically active murine IL-12. Administration of high titre rSFV10-E-IL12 particles intratumourally to treat implanted K-BALB tumours in BALB/c mice demonstrated complete tumour regression in comparison to control or rSFV10-IL12 treated groups. High titre rSFV10-E-IL12 particles were also effective in the CT26 tumour model. Histological and immunohistochemical studies revealed tumour necrosis in addition to aggressive influx of CD4+ and CD8+ T cells and other immune cells. Furthermore, inhibition of primary tumour growth and lung metastases of a metastatic (4T1) tumour model indicated the potential of high titres of rSFV10-E-IL12 particles as an efficient antitumour therapeutic agent.

Treatment of rapidly growing K-BALB and CT26 mouse tumours using Semliki Forest virus and its derived vector

To assess the potential of immune stimulation in combination with apoptosis induction by Semliki Forest virus (SFV) and its derived vector for tumour treatment, we have utilized the poorly immunogenic and rapidly growing K-BALB and CT26 murine tumour models. Both cell lines underwent apoptosis and expressed viral antigen when infected with the SFV4 strain of SFV, or recombinant SFV (rSFV) virus-like particles (VLPs) encoding the p62-6k viral structural proteins. VLPs were used to immunize groups of BALB/c and BALB/c nu/nu mice prior to subcutaneous tumour induction and treatment. Direct intratumoral injection of VLPs or SFV4 resulted in an immediate and intense inflammatory reaction in immunized groups that was not observed in naive groups until day 5 of treatment, and was not observed in nu/nu groups. A significantly higher level of tumour growth inhibition was observed in immunocompetent groups than in athymic mice. For K-BALB tumours, SFV4 treated groups showed greater inhibition than that observed in VLP-treated groups, with immunization prior to treatment enhancing the overall antitumour effect and immune response. No significant difference was observed in CT26 tumours between VLP and SFV4-treated groups, but prior immunization considerably enhanced the antitumoural response. It is concluded that use of the inherent apoptosis-inducing capability of SFV or its vector, by perfusion in combination with immune stimulation, may have potential for the treatment of rapidly growing tumours.

A recombinant Semliki Forest virus particle vaccine encoding the prME and NS1 proteins of louping ill virus is effective in a sheep challenge model

This study has examined the efficacy following intramuscular administration of a recombinant Semliki Forest virus (rSFV) vaccine, encoding the prME and NS1 proteins of louping ill virus (LIV), in sheep. Administration of rSFV-LIV vaccine resulted in transient detection at the injection site and draining lymph node only and no dissemination to distal sites. In addition, the recombinant vaccine offered complete protection against subcutaneous challenge with LIV, and partial protection following intranasal administration of LIV. Protected animals had no pathological changes normally associated with LIV infection, and had developed high antibody titres. In contrast, the two animals not protected exhibited classical clinical signs and neuropathological lesions of LIV infection. These findings indicate that rSFV-based vaccines have the potential to be developed as effective prototype vaccines for LIV.

Self-replicative RNA vaccines elicit protection against influenza A virus, respiratory syncytial virus, and a tickborne encephalitis virus

In genetic vaccination, recipients are immunized with antigen-encoding nucleic acid, usually DNA. This study addressed the possibility of using the recombinant alpha virus RNA molecule, which replicates in the cytoplasm of transfected cells, as a novel approach for genetic vaccination. Mice were immunized with recombinant Semliki Forest virus RNA-encoding envelope proteins from one of 3 viruses: influenza A virus, a tickborne flavivirus (louping ill virus), or respiratory syncytial virus (RSV). Serologic analyses showed that antigen-specific antibody responses were elicited. IgG isotyping indicated that predominantly Th1 type immune responses were induced after immunization with RSV F protein-encoding RNA, which is relevant for protection against RSV infection. Challenge infection showed that RNA immunization had elicited significant levels of protection against the 3 model virus diseases.

Recombinant Semliki Forest virus particles expressing louping ill virus antigens induce a better protective response than plasmid-based DNA vaccines or an inactivated whole particle vaccine

Louping ill virus (LIV) infection of mice was used as a model to evaluate the protective efficacy of Semliki Forest virus (SFV)-based vaccines in comparison to a standard DNA vaccine and a commercial chemically inactivated vaccine. The recombinant SFV-based vaccines consisted of suicidal particles and a naked layered DNA/RNA construct. The nucleic acid vaccines expressed the spike precursor prME and the nonstructural protein 1 (NS1) antigens of LIV. Three LIV strains of graded virulence for mice were used for challenge. One of these was a naturally occurring antibody escape variant. All vaccines tested induced humoral immunity but gave varying levels of protection against lethal challenge. Only recombinant SFV particles administered twice gave full protection against neuronal degeneration and encephalitis induced by two of the three challenge strains, and partial protection against the highly virulent strain, whereas the other vaccines tested gave lower levels of partial protection.

Recombinant Semliki Forest virus particles encoding the prME or NS1 proteins of louping ill virus protect mice from lethal challenge

Recombinant Semliki Forest virus (rSFV) vaccines encoding louping ill virus (LIV) genes prME and NS1 were examined. Cells transfected with rSFV-prME RNA showed correct processing of the precursor prME and the release into the medium of M and E proteins in particulate form, whilst rSFV-NS1-transfected cells secreted glycosylated, heat-labile NS1 dimers. Mice immunized with rSFV particles produced antibodies against prME and NS1 that were mainly of the IgG2a subtype, indicating that a T-helper 1 immune response was induced. Immunization with prME- or NS1-encoding particles induced T-cell proliferation. Mice vaccinated intraperitoneally (i.p.) with rSFV-prME and/or rSFV-NS1 were significantly protected from lethal i.p. challenge by two strains of LIV, the virulent LI/31 strain, from which the commercial LIV vaccine is derived, and the less-virulent LI/I antibody-escape variant. Intranasal (i.n.) vaccination was protective for rSFV-prME only against LI/31 challenge and not against challenge with LI/I. Immunization with rSFV-NS1 was protective against i.p. and i.n. challenge with both virus strains when given i.p., but was not protective when given i.n. For unvaccinated mice infected with LIV, all animals showing clinical signs had severe degenerative and inflammatory lesions in the central nervous system. None of the rSFV-vaccinated mice that survived challenge showed central nervous system pathology, with the exception of mild leptomeningitis in a minority of LI/31-infected mice. This suggests that protection following immunization with rSFV must occur at early stages of LIV infection.

Immunization with recombinant Semliki Forest virus induces protection against influenza challenge in mice

The replicon of Semliki Forest virus (SFV) offers the possibility to direct high-level, transient expression of heterologous proteins in vivo. We initiated studies to determine the possibility of employing the SFV expression system for recombinant vaccine purposes. Mice immunized with recombinant SFV encoding Influenza A nucleoprotein (NP) or E. coli LacZ developed long-lasting antigen-specific IgG levels and induction of cytotoxic T-cell (CTL) memory that persisted for over one year. Predominantly type 1 T-helper cells were induced as shown by IgG subclass ELISA. Humoral and cell-mediated immune responses could be induced upon delivery by several administration routes and mucosal immunizations induced secretory IgA in the respiratory tract. Development of immune responses against the vector itself did not inhibit boost responses by subsequent immunizations with recombinant SFV. Immunization of mice with vectors encoding the Influenza A virus antigens nucleoprotein (NP) and hemagglutinin (HA) resulted in immune responses that were protective against challenge infection with Influenza virus.

Enhancing immune responses using suicidal DNA vaccines

We describe a DNA vaccine strategy that allows antigens to be produced in vivo in the context of an alphaviral replicon. Mice immunized with such vectors developed humoral and cellular immune responses at higher levels than mice that received a conventional DNA vaccine vector. Immunized animals acquired protective immunity to lethal influenza challenge. Compared with traditional DNA vaccine strategies in which vectors are persistent and the expression constitutive, the expression mediated by the alphaviral vector was transient and lytic. As a result, biosafety risks such as chromosomal integration, and the induction of immunological tolerance, could be circumvented.