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.

Antibodies to an interfering epitope in hepatitis C virus E2 can mask vaccine-induced neutralizing activity.

UNLABELLED: Hepatitis C virus (HCV) neutralization occurring at the E2 region 412-426 (EP-I) could be enhanced when antibodies directed specifically to the E2 region 434-446 (EP-II) were removed from serum samples of persistently infected patients and vaccinated chimpanzees, a phenomenon of so-called antibody interference. Here, we show that this type of interference can be observed in individuals after immunization with recombinant E1E2 proteins. One hundred twelve blinded serum samples from a phase I, placebo-controlled, dose escalation trial using recombinant HCV E1E2 with MF59C.1 adjuvant in healthy HCV-negative adults were tested in enzyme-linked immunosorbent assay for binding reactivity to peptides representing the E2 regions 412-426 (EP-I) and 434-446 (EP-II). All samples were subsequently tested for neutralizing activity using cell-culture HCV 1a(H77)/2a chimera, HCV pseudotype particles (HCVpp) H77, and HCVpp HCV-1 after treatment to remove EP-II-specific antibodies or mock treatment with a control peptide. Among the 112 serum samples, we found 22 double positive (EP-I and EP-II), 6 EP-II positive only, 14 EP-I positive only, and 70 double negative. Depleting EP-II antibodies from double-positive serum samples increased 50% inhibitory dose (ID50) neutralizing antibody titers (up to 4.9-fold) in up to 72% of samples (P ≤ 0.0005), contrasting with ID50 neutralization titer increases in 2 of 70 double-negative samples (2.9%; P > 0.5). In addition, EP-I-specific antibody levels in serum samples showed a significant correlation with ID50 neutralization titers when EP-II antibodies were removed (P < 0.0003). CONCLUSION: These data show that antibodies to the region 434-446 are induced during immunization of individuals with recombinant E1E2 proteins, and that these antibodies can mask effective neutralizing activity from EP-I-specific antibodies. Elicitation of EP-II-specific antibodies with interfering capacity should be avoided in producing an effective cross-neutralizing vaccine aimed at the HCV envelope proteins.

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.

Use of human MonoMac6 cells for development of in vitro assay predictive of adjuvant safety in vivo.

Subunit vaccines composed of recombinant or purified antigens have a good safety record but are poorly immunogenic and require adjuvants to activate innate immunity and facilitate antigen specific immune response. Of the many adjuvant formulations that are under development, very few are licensed mainly due to concerns about adverse side effects. The goal of our study was to develop in vitro assays that could predict toxicity of adjuvants in vivo. Pro-inflammatory cytokines IL-ß, IL-6, TNF-α, and IL-8 were measured in human primary monocytes and the monocytoid cell line, MonoMac 6 (MM6), activated with a panel of TLR agonists or with adjuvants. A 0.5 EU/ml dose of Standard for endotoxin (previously shown to provide a margin between pyrogenic and non-pyrogenic substances in rabbits) was used as a comparator to establish a "safety threshold". FSL-1, Pam3CSK4, flagellin, and R848 TLR agonists but not Alum, MF59, Poly I:C, or MPL adjuvants induced cytokines in MM6 cells above the safety threshold. To confirm the predictive value of the in vitro assays, FSL-1 and flagellin were injected intramuscularly into New Zealand White (NZW) rabbits. Both TLR agonists induced fever within 6-8h post-injection followed 24-48 h later by increased C reactive protein (CRP). Importantly, an early peak in plasma prostaglandin E2 (PGE(2)) levels preceded rise in body temperature. In vitro production of PGE(2) in monocytes and MM6 cells was found following treatments with various TLR agonists but not with alum, MF59, MPL, or Poly I:C adjuvants. Together, our studies demonstrated a strong correlation between production of pro-inflammatory cytokines above a "safety threshold" and production of PGE(2)in vitro and an increase in body temperature in rabbits. The developed human cell based assays could provide an important tool for early screening of new molecular moieties and adjuvant formulations and may assist in selection of safer products.

Feasibility of the use of ELISA in an immunogenicity-based potency test of anthrax vaccines.

Complexities of lethal challenge animal models have prompted the investigation of immunogenicity assays as potency tests of anthrax vaccines. An ELISA was used to measure the antibody response to protective antigen (PA) in mice immunized once with a commercially available (AVA) or a recombinant PA vaccine (rPAV) formulated in-house with aluminum hydroxide. Results from the anti-PA ELISA were used to select a single dose appropriate for the development of a potency test. Immunization with 0.2 mL of AVA induced a measurable response in the majority of animals. This dose was located in the linear range of the vaccine dose-antibody response curve. In the case of rPAV, practical limitations prevented the finding of the best single dose for the potency testing of purified vaccines. In additional immunogenicity experiments neither the magnitude of the response to a single dose of vaccine, nor the estimation of the dose necessary to induce a measurable response were able to consistently detect brief exposure of vaccines to potentially damaging temperatures. However, differences detected for rPAV in the proportion of mice responding to the same dose of treated and untreated vaccine suggested that further assay development to increase the sensitivity of the latter design may be warranted.

Reduction of immunogenicity of anthrax vaccines subjected to thermal stress, as measured by a toxin neutralization assay.

We report that a toxin neutralization assay (TNA) can detect a decrease in the immunogenicity of anthrax vaccines as a consequence of brief exposure to elevated temperature. This attribute of TNA may help in adopting immunogenicity as a replacement of the current potency test, which involves protection from lethal challenge.

Application of bioluminescence imaging to the prediction of lethality in vaccinia virus-infected mice.

To find an alternative endpoint for the efficacy of antismallpox treatments, bioluminescence was measured in live BALB/c mice following lethal challenge with a recombinant WR vaccinia virus expressing luciferase. Intravenous vaccinia immunoglobulin treatments were used to confer protection on a proportion of animals. Using known lethality outcomes in 200 animals and total fluxes recorded daily in live animals, we performed univariate receiver operating characteristic (ROC) curve analysis to assess whether lethality can be predicted based on bioluminescence. Total fluxes in the spleens on day 3 and in the livers on day 5 generated accurate predictive models; the area under the ROC curve (AUC) was 0.91. Multiple logistic regression analysis utilizing a linear combination of six measurements: total flux in the liver on days 2, 3, and 5; in the spleen on days 1 and 3; and in the nasal cavity on day 4 generated the most accurate predictions (AUC = 0.96). This model predicted lethality in 90% of animals with only 10% of nonsurviving animals incorrectly predicted to survive. Compared with bioluminescence, ROC analysis with 25% and 30% weight loss as thresholds accurately predicted survival on day 5, but lethality predictions were low until day 9. Collectively, our data support the use of bioimaging for lethality prediction following vaccinia virus challenge and for gaining insight into protective mechanisms conferred by vaccines and therapeutics.

Antibody induced by immunization with the Jeryl Lynn mumps vaccine strain effectively neutralizes a heterologous wild-type mumps virus associated with a large outbreak.

Recent mumps outbreaks in older vaccinated populations were caused primarily by genotype G viruses, which are phylogenetically distinct from the genotype A vaccine strains used in the countries affected by the outbreaks. This finding suggests that genotype A vaccine strains could have reduced efficacy against heterologous mumps viruses. The remote history of vaccination also suggests that waning immunity could have contributed to susceptibility. To examine these issues, we obtained consecutive serum samples from children at different intervals after vaccination and assayed the ability of these samples to neutralize the genotype A Jeryl Lynn mumps virus vaccine strain and a genotype G wild-type virus obtained during the mumps outbreak that occurred in the United States in 2006. Although the geometric mean neutralizing antibody titers against the genotype G virus were approximately one-half the titers measured against the vaccine strain, and although titers to both viruses decreased with time after vaccination, antibody induced by immunization with the Jeryl Lynn mumps vaccine strain effectively neutralized the outbreak-associated virus at all time points tested.

Antibodies to the A27 protein of vaccinia virus neutralize and protect against infection but represent a minor component of Dryvax vaccine--induced immunity.

The smallpox vaccine Dryvax, which consists of replication-competent vaccinia virus, elicits antibodies that play a major role in protection. Several vaccinia proteins generate neutralizing antibodies, but their importance for protection is unknown. We investigated the potency of antibodies to the A27 protein of the mature virion in neutralization and protection experiments and the contributions of A27 antibodies to Dryvax-induced immunity. Using a recombinant A27 protein (rA27), we confirmed that A27 contains neutralizing determinants and that vaccinia immune globulin (VIG) derived from Dryvax recipients contains reactivity to A27. However, VIG neutralization was not significantly reduced when A27 antibodies were removed, and antibodies elicited by an rA27 enhanced the protection conferred by VIG in passive transfer experiments. These findings demonstrate that A27 antibodies do not represent the major fraction of neutralizing activity in VIG and suggest that immunity may be augmented by vaccines and immune globulins that include strong antibody responses to A27.

Real-time, quantitative PCR assays for the detection of virus-specific DNA in samples with mixed populations of polyomaviruses.

Mixtures of polyomaviruses can be present in the central nervous system, the gastrointestinal tract, the genitourinary tract, blood, and urban sewage. We have developed 12 primer/probe sets (four per virus) for real-time, quantitative PCR assays (TaqMan) that can specifically detect BKV, JCV, and SV40 genomes present in mixtures of these viruses. The specificities of these primer/probe sets were determined by evaluating their level of interaction with the DNA from other polyomaviruses and their ability to estimate the number of copies of homologous viral DNA in blinded samples of defined mixtures of three polyomaviral DNAs. Three early region and three late region primer/probe sets determined, within a two-fold range, the number of copies of their respective DNAs. Four sets of SV40 primer/probes also detected 1.1-2.4 copies of SV40 DNA per COS-1 cell, cells estimated to contain a single copy of SV40 DNA. Three JCV primer/probe sets detected 3.7-4.2 copies per cell of JCV DNA in the JCV-transformed cell line M1-HR, cells estimated to contain between 0.5 and 1 copy of the JCV genome. We suggest that the virus-specific primer/probe sets in this study be considered sufficiently characterized to initiate the quantification of polyomavirus DNA in biological samples.

Human immunodeficiency virus (HIV) gp41 escape mutants: cross-resistance to peptide inhibitors of HIV fusion and altered receptor activation of gp120.

Human immunodeficiency virus (HIV) infects cells by fusing with cellular membranes. Fusion occurs when the envelope glycoprotein (Env) undergoes conformational changes while binding to cellular receptors. Fusogenic changes involve assembly of two heptad repeats in the ectodomain of the gp41 transmembrane subunit to form a six-helix bundle (6HB), consisting of a trimeric N heptad repeat (N-HR) coiled-coil core with three antiparallel C heptad repeats (C-HRs) that pack in the coiled-coil grooves. Peptides corresponding to the N-and C-HRs (N and C peptides, respectively) interfere with formation of the 6HB in a dominant-negative manner and are emerging as a new class of antiretroviral therapeutics for treating HIV infection. We generated an escape mutant virus with resistance to an N peptide and show that early resistance involved two mutations, one each in the N- and C-HRs. The mutations conferred resistance not only to the selecting N peptide but also to C peptides, as well as other types of N-peptide inhibitors. Moreover, the N-HR mutation altered sensitivity to soluble CD4. Biophysical studies suggest that the 6HB with the resistance mutations is more stable than the wild-type 6HB and the 6HB formed by inhibitor binding to either wild-type or mutant C-HR. These findings provide new insights into potential mechanisms of resistance to HIV peptide fusion inhibitors and dominant-negative inhibitors in general. The results are discussed in the context of current models of Env-mediated membrane fusion.

Validation of an anti-PA-ELISA for the potency testing of anthrax vaccine in mice.

The potency test for the anthrax vaccine currently licensed for human use in the United States (Anthrax Vaccine Adsorbed) involves the protection of actively immunized guinea pigs from a lethal challenge with a virulent strain of Bacillus anthracis. Lethal challenge tests entail the use of specialized containment facilities for the safe and secure handling of the challenge strain. This potential difficulty, plus humane considerations, have prompted us to investigate non-lethal, alternative immunogenicity assays that could be considered as potency tests not only for the current vaccine, but also for vaccines under development. Immunogenicity tests will require suitable measurement of an antibody response to relevant antigens, by methods such as enzyme linked immunosorbent assay (ELISA) or a toxin neutralization assay. Any assay chosen for this purpose should be adequately validated and reproducible by other laboratories. Validation of an analytical procedure requires the demonstration that the assay is suitable for its intended purpose. The objective of this work was to study the performance of an anti-PA-ELISA designed to assess the antibody response to anthrax vaccines in mice. Validation studies were performed according to the guidelines of the International Conference of Harmonization (ICH), and we have established the working range of the assay (37-1159 EU/mL) on the bases of the following parameters: linearity (20-1159 EU/mL; r2=0.99; p-value=0.21), accuracy (91-118% recovery), precision (< or =20%CV, repeatability; < or =9 and < or =21%CV, intermediate precision per day and per analyst, respectively), detection limit (5 EU/mL), and quantification limit (37 EU/mL). We believe that assay specificity and the above characteristics are adequate to allow this ELISA to be considered for use in a mouse immunogenicity (potency) test of anthrax vaccines, and for the standardization of reagents.