Composition of acellular pertussis and combination vaccines: a general review.

Since the development and introduction of the acellular pertussis vaccine in Japan in the early eighties, we have come a long way in using this component in combination with other vaccines. However, the basic problem in development of an effective and safe pertussis vaccine is that the antigens to induce complete protection against clinical pertussis and the precise mechanism by which pertussis vaccine confers immunity is yet unknown. Hence, the composition of future acellular pertussis vaccine remains an open issue. Recently, acellular pertussis vaccine has been licensed for the booster doses in the U.S.A. and for primary immunization of infants in Italy and Germany. A multicentric trial has been carried out to compare the serological response and adverse reactions of 13 acellular pertussis vaccines. These vaccines contained one or more of the four components, i.e. FHA, PT, 69 kDa OMP and fimbriae. All vaccines were associated with substantially fewer and less adverse reactions and were more immunogenic with respect to antibodies against the added antigens. DTP vaccines in the near future will have combinations of other components and the key antigen for combination will be acellular pertussis component which is going to replace whole cell pertussis component in DTP vaccines. In view of this, manufacturers like ourselves from the developing countries are still groping in the dark, uncertain whether we should have a single component acellular pertussis vaccine or multicomponent one. This will have a major impact on the cost of production, the final cost of the combination vaccines and the regulatory issues that we will have to tackle in view of the recent thinking on harmonization in the pharmaceutical industry.     

Development of acellular pertussis vaccines.

In 1974, the authors reported the isolation and characterization of protective antigens of Bordetella pertussis in mice. With this information, an acellular pertussis vaccine was developed, composed mainly of pertussis toxin (PT) and filamentous haemagglutinin (FHA). Substances causing side effects, especially lipopoly sacahoride (LPS) or endotoxin that cause fever, were removed, and detoxification of the PT by formaldehyde with retention of potency was achieved. In 1981, an acellular pertussis vaccine called the "Adsorbed Purified Pertussis Vaccine" was approved in Japan, in place of the whole-cell pertussis vaccine. The acellular pertussis vaccine has been widely accepted as safer and more efficacious in Japan. Since 1981, intense surveillance has shown that there are only rare adverse reactions and that pertussis has virtually been eliminated in Japan. Evaluation of active immunization with highly purified and pharmacologically inert PT and FHA and passive immunization with polyclonal and monoclonal antibodies, provide quantitative data about the vaccine-induced immunity in mice. Finally, it was discovered that the PT toxoid in the vaccine is the major and essential protective antigen. The toxoid of PT should be sufficient for protection against pertussis.     

Acellular and whole cell pertussis vaccines protect against the lethal effects of intracerebral challenge by two different T-cell dependent humoral routes

Athymic (nu/nu) and euthymic (+/nu) BALB/c mice were immunized with a whole cell pertussis vaccine or with an acellular vaccine which contained detoxified pertussis toxin (PT) and filamentous hemagglutinin (FHA). Only the euthymic mice were protected against intracerebral challenge with virulent Bordetella pertussis which implies involvement of T-cells. As a cell transfer from mice immunized with whole cell or acellular vaccine prior to the challenge did not protect naive euthymic recipients, cellular immunity seems to be non-protective as an effector mechanism. Mice could be protected passively against a challenge by administration of immune sera. Therefore, T-cell dependent humoral immune responses to B. pertussis appear to be crucial for protection. The humoral response was further studied with athymic and euthymic mice. In euthymic mice the whole cell vaccine induced antibodies to FHA, pililipopolysaccharides (LPS) and an outer membrane protein (OMP) preparation, whereas the acellular vaccine induced antibodies to PT, FHA and OMP. Both IgM and IgG could be detected. From the nude mice only those immunized with the whole cell vaccine showed an antibody response which consisted of low titres of IgM directed to LPS. Sera from both +/nu and nu/nu mice immunized with the whole cell vaccine were bactericidal in vitro. These data demonstrate that in the mouse model protection to intracerebral challenge with B. pertussis is T-cell dependent as is the humoral response to PT, FHA, OMP and pili. The T-independent B-cell activation by the whole cell preparation is due to the presence of LPS.(ABSTRACT TRUNCATED AT 250 WORDS)     

DTaP vaccines from north american vaccine (NAVA): composition and critical parameters.

NAVA's acellular pertussis vaccine is based on highly purified pertussis toxin (PT) inactivated with H(2)O(2). PT was analysed using advanced biochemical methodology including mass spectroscopy (LC/MS), yielding mass and peptide mapping information on the subunits. Pertactin, adenylate cyclase, and Fim 1, 2 were below detection levels and only trace amounts of filamentous haemagglutinin (FHA) have been identified as a minor impurity. The vaccine does not induce anti-FHA antibodies during the course of a 3-dose primary immunization series in infants. B and T cell epitopes are preserved to a higher extent after H(2)O(2)detoxification when compared with chemical inactivation with formaldehyde, thus providing new information explaining why vaccines employing formaldehyde detoxified PT may need additional pertussis components added to induce high levels of protection. Anti-PT antibodies generated by NAVA diphtheria, tetanus, and acellular pertussis vaccine (DTaP) showed a positive correlation with protection against WHO-defined pertussis. The safety profiles for these vaccines showed low reactogenicity with no serious adverse events due to the vaccines.     

Overview of recent clinical trials of acellular pertussis vaccines.

The evidence from pre-licensure studies does not suggest that there are clinically important differences in reactogenicity between acellular vaccines. The merits of different acellular products will therefore have to be compared on efficacy criteria. Ideally, acellular vaccines with the minimum antigen content necessary to ensure optimum protection should be used in order to avoid administration of superfluous antigens to children and to simplify licensing and batch release procedures.On the basis of the evidence so far available it seems unlikely that monocomponent pertussis toxin (PT) vaccines provide optimal protection and that multicomponent vaccines are needed to achieve a level of disease control that approaches that of a good whole-cell vaccine. It is unclear whether all two component vaccines containing PT and filamentous haemagglutinin (FHA) have similar efficacy but on the available evidence the safest option for policy makers would seem to be to use a vaccine with at least three components, PT+FHA+pertactin. There is now good evidence that the five component vaccine which contains agglutinogens 2 and 3 in addition to PT/FHA and pertactin provides the best protection and is the only acellular vaccine whose efficacy matches that of a good whole cell vaccine. However, the public health advantage of the five component vaccine over other acellular vaccines may not become apparent until they have been in routine use for some decades and their ability to protect against transmission as well as clinical pertussis has emerged.The decision to replace an effective whole-cell vaccine by an acellular vaccine for primary immunisation needs careful consideration. Apart from the probable sacrifice of efficacy for reduced reactogenicity (at least for vaccines which do not contain agglutinogens 2 and 3) there is the question of value for money and the ease with which acellular DTP vaccines can be combined with conjugate polysaccharide vaccines such as Haemophilus influenzae type b.Whatever the decision of policy makers, the need for continued follow up of trial cohorts and active surveillance of the efficacy and safety of those acellular vaccines that are introduced into routine use must be accorded a high priority.     

The purification and characterization of an acellular pertussis vaccine

An acellular pertussis vaccine manufactured by Biken was investigated for purity, potency and toxicity. The vaccine was composed of almost equal proportions of pertussis toxin (PT) and filamentous hemagglutinin (FHA). The purity of the vaccine was 97-99%. The protective effects of component vaccines containing various ratios of PT and FHA were tested and it was found that the ratio of 1:1 provided the most effective vaccine.     

Physico-chemical analysis of Bordetella pertussis antigens.

Physico-chemical methods are being developed for use in the control and standardization of acellular pertussis vaccines and their individual components. We have compared native and detoxified preparations of the B. pertussis antigens, pertussis toxin (PT), filamentous haemagglutinin (FHA), and the 69-kDa outer membrane protein (P69) using circular dichroism (CD), fluorescence spectroscopy, SDS-PAGE and FPLC gel filtration chromatography. Upon aldehyde detoxification, PT underwent a large change in its intrinsic fluorescence maximum (8-10 nm red-shift) and a large increase in its apparent size, detected by chromatography. Polyacrylamide gels showed individual subunits of the same apparent molecular weight (M(r)) as well as some polypeptides of higher M(r). FHA also changed conformation (5-nm red-shift in intrinsic fluorescence) upon aldehyde detoxification, with a resultant increase in the M(r)of its major constituent. The P69 protein appeared quite robust to formaldehyde treatment as measured by the same methods. Its near-UV CD spectrum contains a prominent tryptophan band; so this method may be more suitable for observing differences in conformation. We also examined an aluminium-desorbed DTaP preparation by these methods. When used in conjunction with immunochemical and toxicological assays, these methods are informative and useful in the characterization of candidate standards and should be valuable methods for ensuring the consistency of manufactured vaccines.     

Purification and immunogenicity of a recombinant Bordetella pertussis S1S3FHA fusion protein expressed by Streptococcus gordonii

Acellular pertussis vaccines typically consist of antigens isolated from Bordetella pertussis, and pertussis toxin (PT) and filamentous hemagglutinin (FHA) are two prominent components. One of the disadvantages of a multiple-component vaccine is the cost associated with the production of the individual components. In this study, we constructed an in-frame fusion protein consisting of PT fragments (179 amino acids of PT subunit S1 and 180 amino acids of PT subunit S3) and a 456-amino-acid type I domain of FHA. The fusion protein was expressed by the commensal oral bacterium Streptococcus gordonii. The fusion protein was secreted into the culture medium as an expected 155-kDa protein, which was recognized by a polyclonal anti-PT antibody, a monoclonal anti-S1 antibody, and a monoclonal anti-FHA antibody. The fusion protein was purified from the culture supernatant by affinity and gel permeation chromatography. The immunogenicity of the purified fusion protein was assessed in BALB/c mice by performing parenteral and mucosal immunization experiments. When given parenterally, the fusion protein elicited a very strong antibody titer against the FHA type I domain, a moderate titer against native FHA, and a weak titer against PT. When given mucosally, it elicited a systemic response and a mucosal response to FHA and PT. In Western blots, the immune sera recognized the S1, S3, and S2 subunits of PT. These data collectively indicate that fragments of the pertussis vaccine components can be expressed in a single fusion protein by S. gordonii and that the fusion protein is immunogenic. This multivalent fusion protein approach may be used in designing a new generation of acellular pertussis vaccines.     

Purification and Immunogenicity of a Recombinant Bordetella pertussis S1S3FHA Fusion Protein Expressed by Streptococcus gordonii

Acellular pertussis vaccines typically consist of antigens isolated from Bordetella pertussis, and pertussis toxin (PT) and filamentous hemagglutinin (FHA) are two prominent components. One of the disadvantages of a multiple-component vaccine is the cost associated with the production of the individual components. In this study, we constructed an in-frame fusion protein consisting of PT fragments (179 amino acids of PT subunit S1 and 180 amino acids of PT subunit S3) and a 456-amino-acid type I domain of FHA. The fusion protein was expressed by the commensal oral bacterium Streptococcus gordonii. The fusion protein was secreted into the culture medium as an expected 155-kDa protein, which was recognized by a polyclonal anti-PT antibody, a monoclonal anti-S1 antibody, and a monoclonal anti-FHA antibody. The fusion protein was purified from the culture supernatant by affinity and gel permeation chromatography. The immunogenicity of the purified fusion protein was assessed in BALB/c mice by performing parenteral and mucosal immunization experiments. When given parenterally, the fusion protein elicited a very strong antibody titer against the FHA type I domain, a moderate titer against native FHA, and a weak titer against PT. When given mucosally, it elicited a systemic response and a mucosal response to FHA and PT. In Western blots, the immune sera recognized the S1, S3, and S2 subunits of PT. These data collectively indicate that fragments of the pertussis vaccine components can be expressed in a single fusion protein by S. gordonii and that the fusion protein is immunogenic. This multivalent fusion protein approach may be used in designing a new generation of acellular pertussis vaccines.     

Acellular pertussis vaccines: neutralization by immune sera of the lethality of pertussis toxin and viable Bordetella pertussis for chick embryos.

Vaccines containing acellular pertussis components, either separate or combined with other microbial antigens, were evaluated for specific immune responses in guinea-pigs and mice. The capacity of sera to protect chick embryos from the lethal effect of pertussis toxin was independent of the Chinese hamster ovary cell clumping neutralization titre and the antigen binding ELISA anti-toxin titre. Direct correlations did not exist between ELISA titres to Pt, FHA, fimbria or 69 kDa and capacity to prevent killing of embryos by different strains of Bordetella pertussis. With the exception of one combination vaccine product, addition of foreign microbial antigens to acellular pertussis vaccines did not significantly alter capacity of the sera to protect embryos against toxin or bacteria.     

Approaches to the control of acellular pertussis vaccines.

The quality control of acellular pertussis vaccines presents particular problems related to the differences in composition and method of detoxification used in the various type of preparation. These vaccines are not amenable to potency assay by the active mouse protection test used for whole-cell pertussis vaccines and assurance of protective activity is problematic.In contrast, monitoring of these vaccines for safety is relatively straightforward and is centred on assays for the lipooligosaccharide endotoxin, active pertussis toxin and absence of reversion to toxicity of detoxified product. The absence of heat-labile toxin, tracheal cytotoxin and adenyl cyclase toxin is assumed provided that adequate validation of the process has been performed.Confirmation of the antigenic content of the detoxified bulk components is difficult to achieve by conventional binding assays based on monoclonal antibodies because of changes in accessibility of reactive sites post-toxoiding. However, single radial diffusion assay using polyclonal antisera permits estimation of pertussis toxoid (PT), filamentous haemagglutinin (FHA) and pertactin (P69). Dot blot immunoassay can be used for the fimbrial agglutinogens 2 and 3 (Fim 2 and 3) and potentially could also be used to check the composition of final filling lots for PT, FHA, P69 and Fim 2 and 3.Gel electrophoresis and immunoblotting can be applied to monitor purity of purified bulk components and the characteristics of these change after chemical detoxification. Electron microscopy provides a useful semi-quantitative supporting method for checking purity of bulk components. Physico-chemical examination, particularly CD and fluorescence spectroscopy, offer a means of monitoring the consistency of detoxified bulk components.No completely satisfactory method is available for monitoring potency. Immunogenicity assays may be useful for checking consistency but do not necessarily correlate with protection. At present, active protection against aerosol challenge offers the best prospect of a functional assay.     

百日咳杆菌69KDa外膜蛋白的分离纯化及生物学特性研究

本文发展了一种从百日咳杆菌Ⅰ相菌株中纯化６９ＫＤａ外膜蛋白的简易方法,将细菌体经加热浸提、乙醇沉淀蛋白、ＤＥＡＥ－Ｓｅｐｈａｄｅｘ Ａ５０柱层析精制而成。用ＳＤＳ－ＰＡＧＥ、免疫印迹、光密度仪扫描分析,证明纯化制剂为均一的、特异性的６９ＫＤａ外膜蛋白,其收率为５４．２％,纯度达９９．２％,每微克６９ＫＤａ蛋白制剂中的内毒素含量低于０．８５ＥＵ;ＰＴ残留量小于０．１０５ｎｇ。抗６９ＫＤａ蛋白抗血清能     

Non-pertussis components of combination vaccines: problems with potency testing.

Vaccines comprising combinations of diphtheria, tetanus and pertussis (DTP) with Haemophilus influenzae type b polysaccharide-protein conjugate (Hib), inactivated poliomyelitis virus (IPV) and hepatitis B virus (HBV) are already available, and new combinations using acellular pertussis components in a triple vaccine (DTaP) are under development. Evidence to date has shown that control of the efficacy, safety and stability of combination vaccines cannot be based on information already available on the individual components or existing licensed formulations. Several examples of immunological interference between components of a combination vaccine have been observed both in clinical trials and in laboratory tests. Examples of these for D, T and Hib components in DTP and DTaP combinations have been investigated.     

Construction of Bordetella pertussis strains that overproduce genetically inactivated pertussis toxin.

Nontoxic analogs of pertussis toxin (PT), produced by in vitro mutagenesis of the tox operon, are immunogenic and protective against infection by Bordetella pertussis. The moderate levels of PT production by B. pertussis, however, make it the limiting antigen in the formulation of multicomponent, acellular, recombinant whooping cough vaccines. To increase production of the highly detoxified Lys9Gly129 PT analog by B. pertussis, additional copies of the mutated tox operon were integrated into the bacterial chromosome at the tox or fha locus by unmarked allelic exchange. Recombinant strains produced in this way secreted elevated levels of the PT analog proportional to gene dosage. The strains were stable during 10-liter fermentations, and yields of up to 80 mg of PT analog per liter were obtained under production-scale conditions. The nontoxic analog was purified and shown to be indistinguishable from material obtained from a B. pertussis strain that contained only a single copy of the toxLys9Gly129 operon. Such strains are therefore suitable for large-scale, industrial production of an acellular whooping cough vaccine containing a genetically detoxified PT analog.     

Construction of Bordetella pertussis strains that overproduce genetically inactivated pertussis toxin.

Nontoxic analogs of pertussis toxin (PT), produced by in vitro mutagenesis of the tox operon, are immunogenic and protective against infection by Bordetella pertussis. The moderate levels of PT production by B. pertussis, however, make it the limiting antigen in the formulation of multicomponent, acellular, recombinant whooping cough vaccines. To increase production of the highly detoxified Lys9Gly129 PT analog by B. pertussis, additional copies of the mutated tox operon were integrated into the bacterial chromosome at the tox or fha locus by unmarked allelic exchange. Recombinant strains produced in this way secreted elevated levels of the PT analog proportional to gene dosage. The strains were stable during 10-liter fermentations, and yields of up to 80 mg of PT analog per liter were obtained under production-scale conditions. The nontoxic analog was purified and shown to be indistinguishable from material obtained from a B. pertussis strain that contained only a single copy of the toxLys9Gly129 operon. Such strains are therefore suitable for large-scale, industrial production of an acellular whooping cough vaccine containing a genetically detoxified PT analog.     

The cell mediated and humoral immune response to vaccination with acellular and whole cell pertussis vaccine in adult humans.

The cell mediated immune response (CMI) against pertussis antigens following vaccination with the traditional Danish whole cell pertussis vaccine (WC-P) and the Japanese acellular pertussis vaccine (A-PV) JNIH-3 was studied in four adult human volunteers. Vaccination with the A-PV induced an in vitro proliferative response of peripheral blood lymphocytes to pertussis toxin (PT) subunits S2-S4, S3-S4 and S5 and the filamentous hemagglutinin (FHA), and a better serological response to native PT, detoxified PT (dPT) and FHA than the WC-PV. The induced CMI and serological response were followed over a period of 17 weeks, and were not seen to decline during this period. Further, an in vitro proliferative response to Bordetella pertussis agglutinogen 2 and 3 were demonstrated using lymphocytes from recently and not-so-recently pertussis-vaccinated adults.     

Evaluation of a guinea pig model to assess interference in the immunogenicity of different components of a combination vaccine comprising diphtheria, tetanus and acellular pertussis (DTaP) vaccine and haemophilus influenzae type b capsular polysaccharide conjugate vaccine.

A guinea pig model to assess the immunogenicity of a combination vaccine containing diphtheria, tetanus and acellular pertussis (DTaP) vaccine and Haemophilus influenzae type b (Hib) capsular polysaccharide conjugated to tetanus toxoid (HibT) was evaluated comparatively with the mouse immunogenicity test to study the effect of combining these antigens on the immunogenicity of various components. The immunogenicity test in mice was performed by subcutaneous injection of groups of 10 animals twice at an interval of four weeks with 1/10 of a single human dose of various formulations of combination vaccines, DTaP or HibT vaccine. The animals were bled at 4 and 6 weeks and IgG or total antibodies to various components were determined by ELISA or RIA. The guinea pig immunogenicity model included groups of animals injected subcutaneously twice at an interval of six weeks with 1.5 times the single human dose of various formulations. The animals were bled at 4, 6 and 8 weeks and serum samples were tested for antibodies to various components by ELISA, RIA and/or neutralization tests. Additionally, potency of tetanus and diphtheria components was assessed as per the US Food and Drug Administration's regulations. Aluminium phosphate (AIPO(4)) adsorbed HibT vaccine or HibT as a combination with AIPO(4)adsorbed DTaP vaccine showed significant increases in IgG antibodies to tetanus toxin in mice as well increased tetanus antitoxin levels in guinea pigs as compared to soluble HibT vaccine. In general, combining DTaP and HibT vaccines did not affect the antibody levels to tetanus and diphtheria toxoids whereas DTaP-HibT combination vaccine elicited significantly lower IgG antibodies to pertussis toxin and filamentous haemagglutinin than DTaP vaccine alone, particularly after first injection. Mice showed similar Hib antibody responses for the combination and HibT alone whereas guinea pigs consistently showed lower anamnestic responses to Hib for combination formulations than for HibT alone. Reducing the amount of HibT and/or tetanus toxoid in the combination formulations reduced this suppression of Hib antibody response in guinea pigs. Suppression of Hib antibody response in combination vaccines has also been reported from recent clinical trials. Based on the results from this study, it appears that the guinea pig model may be able to predict the human response to various components of combination vaccines.     

百日咳丝状血凝素酶联免疫检测法的建立

目的建立百日咳组分疫苗丝状血凝素(FHA)抗原含量监控的ELISA检测法。方法制备的多克隆抗血清,经辛酸硫酸铵法纯化抗体,用过碘酸钠氧化法辣根过氧化物酶标记,以棋盘滴定法确定最佳包被抗体及酶标抗体的浓度配伍,建立了双抗体夹心ELISA检测法。结果对双抗体夹心ELISA法的特异性、最佳线性范围、检测限度、精密度、准确度、测定限量、适用性的一系列验证试验表明,该方法与百日咳组分疫苗中PT和Prn无明显交叉反应,特异性较好。在0至20 ng/mL测量区间有最佳线性,相关系数大于0.99;经实验内12次及不同试验间3次测定16、8、4 ng/mL中的FHA含量,变异系数在0.2%～11.4%间,回收率在96.9%～114.5%间,精密度及准确度验证均符合常规质控要求,因此测定限量为4 ng/mL。结论该方法能有效检测出百日咳杆菌培养上清中的FHA含量,可用于百日咳组分疫苗生产过程的中间品质量控制。     

Identification of immunodominant epitopes in the filamentous hemagglutinin of Bordetella pertussis

The filamentous hemagglutinin (FHA) of Bordetella pertussis is a principal adhesin, which plays a key role in the colonization of the upper respiratory tract. FHA is also a protective antigen, which has been incorporated in the new generation of acellular vaccines against whooping cough. The protein is synthesized as a large 367-kDa precursor, which is then processed into a 220-kDa secreted polypeptide. To optimize the use of this protein for vaccine purposes it would be helpful to define the regions encompassing immunodominant epitopes. Twelve recombinant plasmids have been generated encoding fusion proteins between fragments of the matured-secreted 220-kDa form of FHA and the vector-encoded phage MS2 polymerase. Protein extracts of the resulting recombinant clones have been tested for reactivity with sera from 20 patients convalescent from whooping cough, and two human standard sera. The results indicate the presence of an immunodominant B cell epitope in the polypeptide coded by a 1-kb DNA fragment encompassing positions 5781-6800 of the published sequence. These results suggest that the identified fragment should be conserved in the formulation of vaccines against pertussis.     

The effects of purified components of Bordetella pertussis in the weight gain test for the toxicity testing of pertussis vaccines

The effects of highly purified preparations of three Bordetella pertussis components--pertussis toxin (PT), lipopolysaccharide (LPS) and filamentous haemagglutinin (FHA)--were examined in the mouse weight gain test, a toxicity test for pertussis vaccine. When these components were administered alone, PT enhanced initial weight gains of the mice, LPS produced an initial weight loss and FHA had no detectable effect on the weights of the mice. However, testing the components in combinations revealed that the effect of PT and LPS together was not simply the sum of their individual effects. This combination generally produced lower weights than LPS alone, particularly in the later stages of the test.