Collaborative study for the calibration of the replacement International Standard for pertussis toxin for use in histamine sensitisation and CHO cell clustering assays.

Pertussis toxin (PT) in its detoxified form is one of the major protective antigens in vaccines against Bordetella pertussis (whooping cough). Reference preparations of native PT are required for the quality control of pertussis vaccines. Stocks of the first WHO International Standard (IS) for PT (JNIH-5) were low and a replacement was required. One candidate material was donated by a vaccine manufacturer to NIBSC. It was formulated, lyophilised into sealed glass ampoules and coded 15/126. An international collaborative study assessed the suitability of this material to replace JNIH-5. Fourteen laboratories from 12 countries took part in the study. Eleven laboratories performed lethal murine histamine sensitisation assay (HIST), 14 performed Chinese Hamster Ovary (CHO) cell clustering assay. International Units (IU) were assigned to the material using these assays as they were used to assign units to JNIH-5. It was found that, unlike JNIH-5, the activities of 15/126 in HIST and CHO cell assays did not agree and therefore different unitage for each assay was assigned. The preparation 15/126 was established as the Second WHO IS for PT for HIST and CHO cell assays. It was assigned a unitage of 1,881 IU/ampoule in HIST and 680 IU/ampoule in the CHO cell clustering assay.

Assays for Determining Pertussis Toxin Activity in Acellular Pertussis Vaccines.

Whooping cough is caused by the bacterium Bordetella pertussis. There are currently two types of vaccines that can prevent the disease; whole cell vaccines (WCV) and acellular vaccines (ACV). The main virulence factor produced by the organism is pertussis toxin (PTx). This toxin is responsible for many physiological effects on the host, but it is also immunogenic and in its detoxified form is the main component of all ACVs. In producing toxoid for vaccines, it is vital to achieve a balance between sufficiently detoxifying PTx to render it safe while maintaining enough molecular structure that it retains its protective immunogenicity. To ensure that the first part of this balancing act has been successfully achieved, assays are required to accurately measure residual PTx activity in ACV products accurately. Quality control assays are also required to ensure that the detoxification procedures are robust and stable. This manuscript reviews the methods that have been used to achieve this aim, or may have the potential to replace them, and highlights their continuing requirement as vaccines that induce a longer lasting immunity are developed to prevent the re-occurrence of outbreaks that have been observed recently.

An ELISA method to estimate the mono ADP-ribosyltransferase activities: e.g in pertussis toxin and vaccines.

ADP-ribosyltransferase activities have been observed in many prokaryotic and eukaryotic species and viruses and are involved in many cellular processes, including cell signalling, DNA repair, gene regulation and apoptosis. In a number of bacterial toxins, mono ADP-ribosyltransferase is the main cause of host cell cytotoxicity. Several approaches have been used to analyse this biological system from measuring its enzyme products to its functions. By using a mono ADP-ribose binding protein we have now developed an ELISA method to estimate native pertussis toxin mono ADP-ribosyltransferase activity and its residual activities in pertussis vaccines as an example. This new approach is easy to perform and adaptable in most laboratories. In theory, this assay system is also very versatile and could measure the enzyme activity in other bacteria such as Cholera, Clostridium, E. coli, Diphtheria, Pertussis, Pseudomonas, Salmonella and Staphylococcus by just switching to their respective peptide substrates. Furthermore, this mono ADP-ribose binding protein could also be used for staining mono ADP-ribosyl products resolved on gels or membranes.

PLGA nano/micro particles encapsulated with pertussis toxoid (PTd) enhances Th1/Th17 immune response in a murine model.

Poly(lactic-co-glycolic acid) (PLGA) based nano/micro particles were investigated as a potential vaccine platform for pertussis antigen. Presentation of pertussis toxoid as nano/micro particles (NP/MP) gave similar antigen-specific IgG responses in mice compared to soluble antigen. Notably, in cell line based assays, it was found that PLGA based nano/micro particles enhanced the phagocytosis of fluorescent antigen-nano/micro particles by J774.2 murine monocyte/macrophage cells compared to soluble antigen. More importantly, when mice were immunised with the antigen-nano/micro particles they significantly increased antigen-specific Th1 cytokines INF-γ and IL-17 secretion in splenocytes after in vitro re-stimulation with heat killed Bordetalla pertussis, indicating the induction of a Th1/Th17 response. Also, presentation of pertussis antigen in a NP/MP formulation is able to provide protection against respiratory infection in a murine model. Thus, the NP/MP formulation may provide an alternative to conventional acellular vaccines to achieve a more balanced Th1/Th2 immune response.

Effect of different detoxification procedures on the residual pertussis toxin activities in vaccines.

Pertussis toxin (PTx) is a major virulence factor produced by Bordetella pertussis and its detoxified form is one of the major protective antigens in vaccines against whooping cough. Ideally, PTx in the vaccine should be completely detoxified while still preserving immunogenicity. However, this may not always be the case. Due to multilevel reaction mechanisms of chemical detoxification that act on different molecular sites and with different production processes, it is difficult to define a molecular characteristic of a pertussis toxoid. PTx has two functional distinctive domains: the ADP-ribosyltransferase enzymatic subunit S1 (A-protomer) and the host cell binding carbohydrate-binding subunits S2-5 (B-oligomer); and in this study, we investigated the effect of different detoxification processes on these two functional activities of the residual PTx in toxoids and vaccines currently marketed worldwide using a recently developed in vitro biochemical assay system. The patho-physiological activities in these samples were also estimated using the in vivo official histamine sensitisation tests. Different types of vaccines, detoxified by formaldehyde, glutaraldehyde or by both, have different residual functional and individual baseline activities. Of the vaccines tested, PT toxoid detoxified by formaldehyde had the lowest residual PTx ADP-ribosyltransferase activity. The carbohydrate binding results detected by anti-PTx polyclonal (pAb) and anti-PTx subunits monoclonal antibodies (mAb) showed specific binding profiles for toxoids and vaccines produced from different detoxification methods. In addition, we also demonstrated that using pAb or mAb S2/3 as detection antibodies would give a better differential difference between these vaccine lots than using mAbs S1 or S4. In summary, we showed for the first time that by measuring the activities of the two functional domains of PTx, we could characterise pertussis toxoids prepared from different chemical detoxification methods and this study also highlights the potential use of this in vitro biochemical assay system for in-process control.

Characterization of co-purified acellular pertussis vaccines.

Whole-cell pertussis vaccines (WPVs) have been completely replaced by the co-purified acellular vaccines (APVs) in China. To date few laboratory studies were reported for co-purified APVs in terms of their antigenic composition and protective immune responses. To further understand the antigenic composition in co-purified APVs, in the present study 2-dimensional gel electrophoresis-based proteomic technology was used to analyze the composition of co-purified APVs. The results showed that besides the main antigens pertussis toxin (PT) and filamentous hemagglutinin (FHA), co-purified APVs also contained pertactin (PRN), fimbriae (FIM) 2and3 and other minor protein antigens. Of the 9 proteins identified, 3 were differentially presented in products from manufacturer 1 and manufacturer 2. Compared with WPVs and purified APVs, co-purified APVs induced a mixed Th1/Th2 immune response with more toward to a Th1 response than the purified APVs in this study. These results hint that different immune mechanisms might be involved in protection induced by co-purified and purified APVs.

Relationship of immunogenicity to protective potency in acellular pertussis vaccines.

Comparison of the immunogenicity response and resistance to challenge in the modified intracerebral challenge assay induced by various acellular pertussis vaccines showed that these were not closely linked. The immunogenicity assay was effective for confirming the presence of specific antigenic components and was invaluable for detecting minor components present in co-purified vaccines. However, the magnitude of antibody responses was not consistently related to antigen concentration nor did it correlate with protection in the modified intracerebral challenge assay. The immunogenicity assay detected degradation of pertussis toxin and pertactin components but not of filamentous haemagglutinin or fimbriae 2 and 3 in denatured acellular pertussis vaccines. The modified intracerebral challenge assay was effective in detecting antigen degradation in all types of acellular pertussis vaccines including those of European/North American origin but was dominated by the response to pertussis toxin. Aerosol challenge was more sensitive in detecting denaturation of filamentous haemagglutinin or fimbriae. The modified intracerebral challenge assay was the only assay that provided a quantitative indication of protective activity. Both immunogenicity and challenge assays provided useful data on acellular pertussis vaccine properties but were complementary and not alternatives.

Investigation in a murine model of possible mechanisms of enhanced local reactions to post-primary diphtheria-tetanus toxoid boosters in recipients of acellular pertussis-diphtheria-tetanus vaccine.

In recipients primed with acellular pertussis diphtheria-tetanus combined vaccine (DTaP) an increased incidence of severe local reactions with extensive redness/swelling has been reported for each subsequent dose of diphtheria-tetanus based combination vaccine given as a booster. This has been attributed to residual active pertussis toxin (PT) in the primary vaccine. In this study, we investigated the possible contribution of the A-subunit enzymatic activity and the B-oligomer carbohydrate binding activity of residual PT in DTaP to local reactions in a murine model using Japanese DTaP batches produced before and after the introduction of a test for reversion of pertussis toxoid to toxin. Residual PT activity was correlated with the B-oligomer carbohydrate binding activity. The in vivo mouse footpad swelling model assay indicated that the B-oligomer carbohydrate binding activity and possibly other factors were associated with intensified sensitization to local reaction following diphtheria toxoid booster.

An international collaborative study of the effect of active pertussis toxin on the modified Kendrick test for acellular pertussis vaccines.

Speculation that the Japanese modified intra-cerebral challenge assay, which is used in several countries for control of acellular pertussis vaccines, depends on the presence of small amounts of active pertussis toxin led to an assumption that it may not be appropriate for highly toxoided or genetically detoxified vaccines. Consequently, at the recommendation of a World Health Organisation AD Hoc Working Group on mouse protection models for testing and control of acellular pertussis vaccine, the effect of pertussis toxin on the modified intra-cerebral challenge assay (modified Kendrick, MICA) was evaluated in an international collaborative study. Results of this study showed that for genetically detoxified vaccines both with and without active pertussis toxin the MICA clearly distinguished mice vaccinated with acellular vaccines from unvaccinated mice and gave a significant dose-response relationship. However, vaccine samples containing active pertussis toxin (5 or 50 ng/single human dose) appeared to be more potent than the equivalent sample without active pertussis toxin. Similar results were also given by two respiratory infection models (intranasal and aerosol) included in the study. The results also indicated that the effect of pertussis toxin may vary depending on mouse strain.

Protein coated microcrystals formulated with model antigens and modified with calcium phosphate exhibit enhanced phagocytosis and immunogenicity.

Protein-coated microcrystals (PCMCs) were investigated as potential vaccine formulations for a range of model antigens. Presentation of antigens as PCMCs increased the antigen-specific IgG responses for all antigens tested, compared to soluble antigens. When compared to conventional aluminium-adjuvanted formulations, PCMCs modified with calcium phosphate (CaP) showed enhanced antigen-specific IgG responses and a decreased antigen-specific IgG1:IgG2a ratio, indicating the induction of a more balanced Th1/Th2 response. The rate of antigen release from CaP PCMCs, in vitro, decreased strongly with increasing CaP loading but their immunogenicity in vivo was not significantly different, suggesting the adjuvanticity was not due to a depot effect. Notably, it was found that CaP modification enhanced the phagocytosis of fluorescent antigen-PCMC particles by J774.2 murine monocyte/macrophage cells compared to soluble antigen or soluble PCMCs. Thus, CaP PCMCs may provide an alternative to conventional aluminium-based acellular vaccines to provide a more balanced Th1/Th2 immune response.

Confocal microscopy study of pertussis toxin and toxoids on CHO-cells.

Pertussis toxin in its detoxified form is a major component of all current acellular pertussis vaccines. Here we report the membrane translocation and internalization activities of pertussis toxin and various pertussis toxoids using Chinese hamster ovary cells and confocal microscopy based on indirect immunofluorescence labeling. Chemically detoxified pertussis toxoids were able to translocate/internalize into cells at the concentration about 1,000 times higher than the native toxin. Pertussis toxoids detoxified with different procedures (glutaraldehyde, glutaraldehyde plus formaldehyde, hydrogen peroxide or genetic mutation) showed differences in fluorescence intensity under the same condition, indicating toxoids from different detoxification methods may have different translocation/internalization activities on cells.

A CpG-containing oligodeoxynucleotide adjuvant for acellular pertussis vaccine improves the protective response against Bordetella pertussis.

We investigated the adjuvant effect of CpG ODN alone or in combination with aluminum hydroxide on the immune response to the three main antigens presented in current acellular pertussis vaccines: pertussis toxoid, filamentous haemagglutinin and pertactin. The development of protection in mice was investigated for the intra-peritoneal and intra-nasal immunisation routes. The results showed that CpG ODN alone, or in combination with aluminum hydroxide, gave enhancement in anti-pertussis toxin, anti- filamentous haemagglutinin and especially anti-pertactin titers after mucosal immunisation. Higher macrophage NO levels indicating activation were found when the antigens were co-formulated with CpG ODN. Vaccines containing CpG ODN gave enhanced humoral and CMI responses with a shift toward Th-1 and increased protection against challenge infection with B.pertussis in mice.

Evaluation of an in vitro assay system as a potential alternative to current histamine sensitization test for acellular pertussis vaccines.

The histamine sensitization test (HIST) is a lethal test for batch release of acellular pertussis or its combination vaccines (ACV). Large numbers of animals have been used and it is difficult to standardize. Therefore there is an urgent need to develop an in vitro alternative to HIST. An in vitro test system has been developed as a potential alternative to HIST, to examine both the functional domains of PT based on a combination of enzyme coupled-HPLC (E-HPLC) and carbohydrate binding assays. We describe here an international collaborative study, which involved sixteen laboratories from 9 countries to assess the methodology transferability of the in vitro test system and its suitability for the testing of three different types of ACV products that are currently used worldwide. This study also evaluated further the relationship between the in vivo activity by HIST and the in vitro assay system. The results showed that the methodology of the E-HPLC and carbohydrate binding assays are transferable between laboratories worldwide and is suitable for the three types of ACV products included in the study. Although direct correlation between the in vitro assay system and the in vivo HIST (temperature reduction assay) for each individual vaccine lot cannot be established due to the large variation in the HIST results, the observation that the mean estimates of the in vitro and in vivo activities gave the same rank order of the three vaccine types included in the study is encouraging. The in vitro systems provide reproducible product specific profiles which supports their use as a potential alternative to the HIST.

An in vitro assay system as a potential replacement for the histamine sensitisation test for acellular pertussis based combination vaccines.

The histamine sensitisation test (HIST) for pertussis toxin is currently an official batch release test for acellular pertussis containing combination vaccines in Europe and North America. However, HIST, being a lethal endpoint assay, often leads to repeated tests due to large variations in test performance. Although a more precise HIST test based on measurement of temperature reduction after the histamine challenge is used in Asian countries, this test still uses animals. An in vitro test system based on a combination of enzyme coupled-HPLC and carbohydrate-binding assays with results analysed by a mathematical formula showed a good agreement with the in vivo HIST results based on measurement of temperature reduction after histamine challenge. The new in vitro test system was shown to be a potential alternative to the current in vivo HIST.

Laboratory investigation of immune responses to acellular pertussis vaccines when used for boosting adolescents after primary immunisation with whole cell pertussis vaccines: a comparison with data from clinical study.

The lack of unequivocal immunological correlates of human protection and an absence of a validated animal model for acellular pertussis vaccines, compounded by limited opportunity to undertake efficacy studies in humans and laboratory evaluation side by side, has made it difficult to compare vaccines and formulations. In the present study, the effect on the booster response to pertussis in adolescents primed in infancy with whole cell pertussis vaccine, of three low dose acellular pertussis/diphtheria/tetanus toxoid (TdPa) formulations with or without inactivated poliomyelitis vaccine (IPV) components, was investigated. To assess the relationship between laboratory vaccine evaluation and clinical trial performance, parallel evaluation of the same TdPa vaccines were carried out in a mouse booster model with whole cell pertussis vaccine priming. Prior to boosting, the clinical subjects had low cell mediated immune responses (CMI) responses to pertussis vaccine components. After boosting, all TdPa formulations stimulated CMI responses to the pertussis vaccine components assessed. The booster responses to the pertussis antigens remained skewed towards Th1 type even though acellular pertussis vaccines were used. In general the antibody and CMI responses to pertussis antigens in the mouse model followed the trend seen in the human subjects. Protection against aerosol challenge with virulent Bordetella pertussis was related to the magnitude of the antibody and CMI responses in the mouse model. As in the human subjects, the responses remained skewed towards Th1 type.