Catherine Moste

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.

AF03-adjuvanted and non-adjuvanted pandemic influenza A (H1N1) 2009 vaccines induce strong antibody responses in seasonal influenza vaccine-primed and unprimed mice.

Pandemic influenza vaccines have been manufactured using the A/California/07/2009 (H1N1) strain as recommended by the World Health Organization. We evaluated in mice the immunogenicity of pandemic (H1N1) 2009 vaccine and the impact of prior vaccination against seasonal trivalent influenza vaccines (TIV) on antibody responses against pandemic (H1N1) 2009. In naïve mice, a single dose of unadjuvanted H1N1 vaccine (3 microg of HA) was shown to elicit hemagglutination inhibition (HI) antibody titers >40, a titer associated with protection in humans against seasonal influenza. A second vaccine dose of pandemic (H1N1) 2009 vaccine strongly increased these titers, which were consistently higher in mice previously primed with TIV than in naïve mice. At a low immunization dose (0.3 microg of HA), the AF03-adjuvanted vaccine elicited higher HI antibody titers than the corresponding unadjuvanted vaccines in both naïve and TIV-primed animals, suggesting a potential for antigen dose-sparing. These results are in accordance with the use in humans of a split-virion inactivated pandemic (H1N1) 2009 vaccine formulated with or without AF03 adjuvant to protect children and young adults against influenza A (H1N1) 2009 infection.

Avian glycan-specific IgM monoclonal antibodies for the detection and quantitation of type A and B haemagglutinins in egg-derived influenza vaccines.

Two IgM monoclonal antibodies (MAbs), Y6F5 and Y13F9, were selected during a screening of clones obtained immunising BALB/c mice with purified envelop proteins of the A/Sydney/5/97 (H3N2) IVR108 influenza strain. These MAbs recognised avian glycans on the haemagglutinin (HA) of the virus. This broad recognition allowed these MAbs to be used as enzyme-labelled secondary antibody reagents in a strain specific enzyme-linked immunosorbent assay (ELISA) in combination with a capture MAb that recognised and allowed the quantitation of the strain specific HA protein present in an egg-produced influenza vaccine. Advantage was taken of these MAbs to develop a universal ELISA in which the MAbs were used both as capture antibody and as enzyme-labelled secondary antibody to detect and quantify the HA protein of any egg-derived influenza vaccine. These avian-glycan specific IgM MAbs may prove to be particularly useful for determining the HA concentration in monovalent egg-derived pandemic influenza vaccines, in which the HA concentration may be lower than 5μg/ml. The HA detection limit in the ELISA assays developed in this study was 1.9μg/ml, as opposed to the 5μg/ml quantitation limit generally accepted for the standard single-radial-immunodiffusion (SRID) assay, the approved technique for quantifying HA content in influenza vaccines. These ELISAs can also be used to quantify influenza HA formulated with emulsion-based or mineral salt adjuvants that could interfere with HA measurement by the SRID assay.

Preparation of genetically engineered A/H5N1 and A/H7N1 pandemic vaccine viruses by reverse genetics in a mixture of Vero and chicken embryo cells

Background  In case of influenza pandemic, a robust, easy and clean technique to prepare reassortants would be necessary.

Characterization and immunogenicity in mice of recombinant influenza haemagglutinins produced in Leishmania tarentolae

The membrane displayed antigen haemagglutinin (HA) from several influenza strains were expressed in the Leishmania tarentolae system. This non-conventional expression system based on a parasite of lizards, can be readily propagated to high cell density (>10(8)cells/mL) in a simple incubator at 26°C. The genes encoding HA proteins were cloned from six influenza strains, among these being a 2009 A/H1N1 pandemic strain from swine origin, namely A/California/07/09(H1N1). Soluble HA proteins were secreted into the cell culture medium and were easily and successfully purified via a His-Tag domain fused to the proteins. The overall process could be conducted in less than 3 months and resulted in a yield of approximately 1.5-5mg of HA per liter of biofermenter culture after purification. The recombinant HA proteins expressed by L. tarentolae were characterized by dynamic light scattering and were observed to be mostly monomeric. The L. tarentolae recombinant HA proteins were immunogenic in mice at a dose of 10μg when administered twice with an oil-in-water emulsion-based adjuvant. These results suggest that the L. tarentolae expression system may be an alternative to the current egg-based vaccine production.

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.

Vero/CHOK1, a novel mixture of cell lines that is optimal for the rescue of influenza A vaccine seeds

Seasonal and pandemic influenza vaccine manufacturing is challenged with a tight production schedule. Reverse genetics constitutes a rapid method for creating viruses. Vero and CHOK1 cells were found to be an appropriate cell mixture for the generation of influenza reassortants by reverse genetics under the constraints of vaccine production, such as the use of regulatory-compliant cells and culture media devoid of components of animal origin. In addition, no further amplification in cell or egg substrates was required, thus reducing the time needed to obtain reassortant seed virus. In parallel, the cloning step was shown to be dramatically improved, permitting the rapid vRNA expression of influenza viruses. In addition, nucleoporation of the cells was conducted to more efficiently target the nucleus and avoid the use of chemical reagents containing proteins of animal origin. In conclusion, the reverse genetics system for influenza A viruses reported in this study was shown to be rapid, simple to perform and totally animal component-free to best comply with the requirements of health authorities for the production of a vaccine seed.

Optimization of influenza A vaccine virus by reverse genetic using chimeric HA and NA genes with an extended PR8 backbone

The yield of influenza antigen production may significantly vary between vaccine strains; for example the A/California/07/09 (H1N1)-X179A vaccine virus, prepared during 2009 influenza pandemic, presented a low antigen yield in eggs compared to other seasonal H1N1 reassortants. In this study a bi-chimeric virus expressing HA and NA genes with A/Puerto Rico/8/34 (H1N1) (PR8) and X179A domains was rescued by reverse genetics using a mixture of Vero/CHOK1 cell lines (Medina et al. [7]). The bi-chimeric virus obtained demonstrated to yield much larger amounts of HA than X179A in eggs as measured by single-radial-immunodiffusion (SRID), the reference method to quantify HA protein in influenza vaccine. Such kind of optimized virus using PR8 backbone derived chimeric glycoproteins could be used as improved seed viruses for vaccine production.

A latex agglutination assay to quantify the amount of hemagglutinin protein in adjuvanted low-dose influenza monovalent vaccines

To formulate inactivated influenza vaccines, the concentration of hemagglutinin (HA) must be accurately determined. The standard test currently used to measure HA in influenza vaccines is the Single Radial Immunodiffusion (SRID) assay. We developed a very rapid, simple and sensitive alternative quantitative HA assay, namely the Latex Agglutination Assay (LAA). The LAA uses the Spherotest® technology, which is based on the agglutination of HA-specific immunoglobulin-coated latex beads. The amount of HA in a sample is calculated from the level of bead agglutination by a simple absorbance measurement at 405nm against a standard curve generated using a monovalent vaccine standard. In less than 2hours, tens of samples could be quantified using the LAA as opposed to 2days for the SRID assay. Ten steps are required to complete an SRID assay as compared to 6 steps for the LAA, from sample preparation through spectrophotometric analysis. Furthermore, the limit of detection of the LAA was found to be approximately 15ng HA/mL, similar to an ELISA, with the quantification of less than 1.8μg HA/mL. The quantification limit of the SRID is usually considered to be approximately 5μg HA/mL. The development of the assay and a comparison of the titers obtained by SRID and LAA for several monovalent vaccines corresponding to various strains were performed. For A/H5N1 and A/H1N1 monovalent vaccines, the LAA was found to be linear and accurate as compared to the SRID. The precision of the LAA was close to that of the standard test, and good reproducibility from one laboratory to another was observed. Moreover, the LAA enabled HA quantification in AlOOH-adjuvanted and in emulsion-adjuvanted low-dose vaccines as well as unadjuvanted vaccines. In conclusion, LAA may be useful to rapidly and accurately measure influenza HA protein in monovalent vaccines, especially in those containing less than 5μg/mL of HA in the presence of an adjuvant.