Standardized quantitative RT-PCR assays for quantitation of yellow fever and chimeric yellow fever-dengue vaccines.

Yellow fever-dengue chimeras (CYDs) are being developed currently as live tetravalent dengue vaccine candidates. Specific quantitative assays are needed to evaluate the viral load of each serotype in vaccine batches and biological samples. A quantitative real-time RT-PCR (qRT-PCR) system was developed comprising five one-step qRT-PCRs targeting the E/NS1 junction of each chimera, or the NS5 gene in the yellow fever backbone. Each assay was standardized using in vitro transcribed RNA qualified according to its size and purity, and precisely quantified. A non RNA-extracted virus sample was introduced as external quality control (EQC), as well as 2 extraction controls consisting of 2 doses, 40 and 4,000 GEQ (genomic equivalents), of this EQC extracted in parallel to the samples. Between 6 and 10 GEQ/reaction were reproducibly measured with all assays and similar titers were obtained with the two methods when chimeric virus samples were quantified with the E/NS1- or the NS5-specific assays. Reproducibility of RNA extraction was ensured by automation of the process (yield>or=50%), and infectious virus was isolated in >or=80% of PCR-positive sera from immune monkeys.

Local immunotherapy of spontaneous feline fibrosarcomas using recombinant poxviruses expressing interleukin 2 (IL2).

We tested the canarypox virus vector ALVAC and the genetically attenuated vaccinia virus vector NYVAC as vehicles for achieving local immunomodulation in domestic animals bearing spontaneous tumours. Following intratumoral administration of ALVAC-, or NYVAC-luciferase in dogs with melanoma, it was demonstrated that viral recombinants remained localized along the needle track, with no virus detectable in the periphery of the tumour. Given these distribution characteristics and their well-documented safety profile, ALVAC- or NYVAC-based recombinants expressing feline or human IL2, respectively, were administered to domestic cats, in order to prevent the recurrence of spontaneous fibrosarcomas. In the absence of immunotherapy, tumour recurrence was observed in 61% of animals within a 12-month follow-up period after treatment with surgery and iridium-based radiotherapy. In contrast, only 39 and 28% of cats receiving either NYVAC-human IL2 or ALVAC-feline IL2, respectively, exhibited tumour recurrences. Based on such results, and in the context of ongoing clinical studies conducted in humans, we discuss the utilization of ALVAC- or NYVAC-based recombinants as viable therapeutic modalities for local immunotherapy or therapeutic vaccination against cancer, both in humans and companion animals.

Modulation of the antibody response to the HIV envelope subunit by co-administration of infectious or heat-inactivated canarypoxvirus (ALVAC) preparations.

Poxviruses are large DNA viruses capable of infecting a broad range of animal species. Infection is generally accompanied by an inflammatory response in the host, the extent of which varies considerably with the specific poxvirus and host species. Regarding ALVAC, a poxvirus derived from the canarypox vaccine strain, Kanapox, and which represents a promising immunization vehicle in humans, nothing is known about its inflammatory capacity. The present study was aimed at documenting this issue in rodents, including mice and guinea pigs. It was then attempted to evaluate how such properties could influence the immunogenicity of an antigen concomitantly administered with ALVAC preparations using the HIV envelope subunit, rgp160, as the model immunogen. The results revealed that ALVAC, either infectious or heat-inactivated, induced in both animal species an early inflammatory response, as evidenced by a rapid migration of neutrophils to the site of inoculation. In parallel, the canarypoxvirus was shown to strongly adjuvant the co-administered immunogen, resulting in a marked increase in Env-specific IgG, IgG1 and particularly IgG2(a) serum titers. Of further interest, the heat-inactivated preparation of ALVAC retained this immunostimulatory activity. Whether or not a link between the inflammatory and immunomodulatory properties of ALVAC exists remains to be established, but such features are clearly interesting with respect to the potential use of ALVAC as an immunization vehicle.

Restricted specificity of anti-V3 antibodies induced in humans by HIV candidate vaccines.

We analyzed the fine specificity of anti-V3 antibodies elicited in three different species (human, guinea pig, and macaque) by various HIV candidate vaccines. Following immunization with recombinant canarypox virus expressing gp160MN or with recombinant gp160MN/LAI, this antibody response was shown to be directed against the NH2-terminal region of the V3 loop. Although this response was increased by a prime-boost regimen using immunization with canarypox expressing gp160 followed by an rgp160 boost, its specificity remained restricted mainly to the recognition of this region of the V3 loop. Pepscan analysis of sera confirmed the results obtained by ELISA and allowed the definition of an immunodominant common binding site for these sera located within the sequence NKRKRIHIGPGR. In contrast to these results, a boost with the V3 peptide was shown to broaden the antibody response and pepscan analysis showed that sera from individuals boosted with the V3 synthetic peptide recognize determinants all along the V3 loop. Similar fine specificity of anti-V3 antibodies was obtained in human, guinea pig, and macaque following immunization by a prime-boost regimen using canarypox recombinants expressing gp160 or gp120 and purified rgp160. In contrast, a V3 synthetic peptide boost stimulated the production of antibodies that recognize multiple epitopes within the V3 loop. Because the induction of antibodies that recognize multiple sites in the V3 loop could be of major importance to neutralize different HIV isolates, these results may have implications for the design and selection of HIV candidate vaccines.