HPV18 E1 Protein Plus α-Galactosylceramide Elicit in Mice CD8+ T Cell Cross-Reactivity Against Cells Expressing E1 from Diverse Human Papillomavirus Types.

CD8+ T cell immune response plays a critical role in the clearance of human papillomavirus (HPV)-infected cells. During the natural history of HPV infection, the E1 protein, an early-expressed helicase highly conserved among papillomaviruses, is involved in the replication of HPV genomes. We have previously shown, in a murine model, that immunization with HPV18 E1 protein combined with α-galactosylceramide elicits a specific CD8+ T cell response. We further proved those findings by analyzing whether CD8+ T cells from mice immunized with α-galactosylceramide plus HPV18 E1 protein could have a cytotoxic effect on cells expressing the carboxyl-terminal domain from the E1 proteins of other HPV types. Interestingly, CD8+ T cells raised against HPV18 E1 antigen presented cross-reactivity against the E1 protein from HPV53, 33, 16, and 31. Poor cross-reactivity was observed for HPV11, and none for HPV6. This outcome may be relevant for the design of broad-spectrum immune-protective agents against HPV infections.

Temperature-mediated recombinant anthrax protective antigen aggregate development: Implications for toxin formation and immunogenicity.

Anthrax vaccines containing recombinant PA (rPA) as the only antigen face a stability issue: rPA forms aggregates in solution after exposure to temperatures ⩾40°C, thus losing its ability to form lethal toxin (LeTx) with Lethal Factor. To study rPA aggregation's impact on immune response, we subjected rPA to several time and temperature combinations. rPA treated at 50°C for 30min formed high mass aggregates when analyzed by gel electrophoresis and failed to form LeTx as measured by a macrophage lysis assay (MLA). Aggregated rPA-formed LeTx was about 30 times less active than LeTx containing native rPA. Mice immunized with heat-treated rPA combined with Al(OH)3 developed antibody titers about 49 times lower than mice immunized with native rPA, as measured by a Toxicity Neutralization Assay (TNA). Enzyme Linked Immunosorbent Assay (ELISA) of the same immune sera showed anti-rPA titers only 2-7 times lower than titers elicited by native rPA. Thus, rPA's ability to form LeTx correlates with its production of neutralizing antibodies, and aggregation significantly impairs the protein's antibody response. However, while these findings suggest MLA has some value as an in-process quality test for rPA in new anthrax vaccines, they also confirm the superiority of TNA for use in vaccine potency.

Use of site-directed mutagenesis to model the effects of spontaneous deamidation on the immunogenicity of Bacillus anthracis protective antigen.

Long-term stability is a desired characteristic of vaccines, especially anthrax vaccines, which must be stockpiled for large-scale use in an emergency situation; however, spontaneous deamidation of purified vaccine antigens has the potential to adversely affect vaccine immunogenicity over time. In order to explore whether spontaneous deamidation of recombinant protective antigen (rPA)--the major component of new-generation anthrax vaccines--affects vaccine immunogenicity, we created a "genetically deamidated" form of rPA using site-directed mutagenesis to replace six deamidation-prone asparagine residues, at positions 408, 466, 537, 601, 713, and 719, with either aspartate, glutamine, or alanine residues. We found that the structure of the six-Asp mutant rPA was not significantly altered relative to that of the wild-type protein as assessed by circular dichroism (CD) spectroscopy and biological activity. In contrast, immunogenicity of aluminum-adjuvanted six-Asp mutant rPA, as measured by induction of toxin-neutralizing antibodies, was significantly lower than that of the corresponding wild-type rPA vaccine formulation. The six-Gln and six-Ala mutants also exhibited lower immunogenicity than the wild type. While the wild-type rPA vaccine formulation exhibited a high level of immunogenicity initially, its immunogenicity declined significantly upon storage at 25°C for 4 weeks. In contrast, the immunogenicity of the six-Asp mutant rPA vaccine formulation was low initially but did not change significantly upon storage. Taken together, results from this study suggest that spontaneous deamidation of asparagine residues predicted to occur during storage of rPA vaccines would adversely affect vaccine immunogenicity and therefore the storage life of vaccines.

Ability of ELISA and a toxin neutralization assay to detect changes in immunogenicity of a recombinant Bacillus anthracis protective antigen vaccine upon storage.

We examined the capability of a mouse immunogenicity assay to detect improper storage of a recombinant protective antigen (rPA)-based anthrax vaccine formulated with an aluminum adjuvant, using ELISA and a toxin neutralization assay (TNA) to measure the antibody response to rPA. The vaccine was stored at 4 °C, room temperature (RT) or 37 °C for one, four and eight weeks and used for immunization, along with freshly prepared vaccine. Results showed that, contrary to ELISA, TNA is suitable to detect a loss of immunogenicity of the rPA vaccine following its exposure to RT for a period of eight weeks and to 37 °C for a period as short as 1 week.

The consistency approach for the quality control of vaccines.

Current lot release testing of conventional vaccines emphasizes quality control of the final product and is characterized by its extensive use of laboratory animals. This report, which is based on the outcome of an ECVAM (European Centre for Validation of Alternative Methods, Institute for Health and Consumer Protection, European Commission Joint Research Centre, Ispra, Italy) workshop, discusses the concept of consistency testing as an alternative approach for lot release testing. The consistency approach for the routine release of vaccines is based upon the principle that the quality of vaccines is a consequence of a quality system and of consistent production of lots with similar characteristics to those lots that have been shown to be safe and effective in humans or the target species. The report indicates why and under which circumstances this approach can be applied, the role of the different stakeholders, and the need for international harmonization. It also gives recommendations for its implementation.

Immunogenicity in mice of anthrax recombinant protective antigen in the presence of aluminum adjuvants.

The only US-licensed anthrax vaccine for human use, as well as several experimental vaccines containing solely purified recombinant protective antigen (rPA), are formulated using aluminum hydroxide (Al(OH)3) as an adjuvant. It has been suggested that effective adjuvanticity of aluminum salts for protein antigens depends, at least partially, on the degree of adsorption of the antigen to the adjuvant. On the other hand, the ease of antigen desorption from the adjuvant in a quantitative fashion may facilitate the assessment of vaccine characteristics in the laboratory. In this regard, aluminum phosphate (AlPO4), although deemed a "weaker" adjuvant than Al(OH)3, appears superior to the latter. To investigate the possibility of formulating rPA vaccines with AlPO4, as well as the significance of the adsorption of this antigen to the aluminum salt for adjuvanticity, we studied the effect of AlPO4 and Al(OH)3 on the induction of anti-rPA antibodies in mice. In a first immunization experiment the adjuvanticity of AlPO4 combined with rPA was examined. Antibodies against rPA were measured using an ELISA. Results indicated that AlPO4 is able to significantly increase the antibody response to rPA, irrespective of its degree of adsorption to the adjuvant. Based on these results, in a second experiment mice were immunized twice, with different formulations of rPA containing either AlPO4 or Al(OH)3, and rPA-antibodies were measured using ELISA and an in vitro toxin neutralization assay. Comparable immune responses to rPA were obtained with both aluminum salts. Additionally, results with AlPO4 as adjuvant confirmed that, in this mouse model, binding of the protein to the adjuvant is not essential for adjuvanticity, whereas the amount of adjuvant has an influence on the antibody response induced.