Calibration of pertussis toxin BRP batch 1 in a standardised CHO cell-based clustering assay.

The European Pharmacopoeia (Ph. Eur.) pertussis toxin (PT) Biological Reference Preparation (BRP) is used as a working standard for safety testing of acellular pertussis vaccines as prescribed in the Ph. Eur. monographs 1356 "Pertussis vaccine (acellular, component, adsorbed)" and 1595 "Pertussis vaccine (acellular, co-purified, adsorbed)". The BRP was calibrated in 2006 in the murine histamine sensitisation test (HIST) against the World Health Organization (WHO) 1st International Standard (IS) for PT. In recent years, there have been increasing efforts to replace the in vivo test with in vitro methods. The Chinese hamster ovary (CHO) cell clustering assay has been used for many years by manufacturers to monitor residual PT activity in detoxified non-adjuvanted bulks. More recently a standardised protocol has been developed for this assay and a PT reference preparation was needed. Due to low stocks, the WHO 1st International Standard for Pertussis Toxin (JNIH-5) needed to be replaced and therefore a joint study between the European Directorate for the Quality of Medicines & HealthCare (EDQM) and WHO was initiated to calibrate the PT BRP for the CHO clustering assay and to replace the IS. The collaborative study involved 14 laboratories from Europe, North America and Asia. The outcome of the study confirmed that the BRP is suitable for use as a reference preparation in the CHO clustering assay. The material was assigned a potency of 1360 IU per vial for the CHO clustering assay.

Transferability study of CHO cell clustering assays for monitoring of pertussis toxin activity in acellular pertussis vaccines.

Current regulations for acellular pertussis (aP) vaccines require that they are tested for the presence of residual or reversion-derived pertussis toxin (PTx) activity using the mouse histamine sensitisation test (HIST). Although a CHO cell clustering assay can be used by manufacturers to verify if sufficient inactivation of the substance has occurred in-process, this assay cannot be used at present for the final product due to the presence of aluminium adjuvants which interfere with mammalian cell cultures. Recently, 2 modified CHO cell clustering assays which accommodate for the adjuvant effects have been proposed as alternatives to the HIST. These modified assays eliminate the adjuvant-induced cytotoxicity either through dilution of the vaccine (called the Direct Method) or by introducing a porous barrier between the adjuvant and the cells (the Indirect Method). Transferability and suitability of these methods for testing of products present on the European market were investigated during a collaborative study organised by the European Directorate for the Quality of Medicines & HealthCare (EDQM). Thirteen laboratories participated in this study which included 4 aP-containing vaccines spiked by addition of PTx. This study also assessed the transferability of a standardised CHO cell clustering assay protocol for use with non-adjuvanted PTx preparations. Results showed that the majority of laboratories were able to detect the PTx spike in all 4 vaccines at concentrations of 4 IU/mL or lower using the Indirect Method. This sensitivity is in the range of the theoretical sensitivity of the HIST. The Direct Method however did not show the expected results and would need additional development work.

Comparison of Three Whole-Cell Pertussis Vaccines in the Baboon Model of Pertussis.

Pertussis is a highly contagious respiratory illness caused by the bacterial pathogen Bordetella pertussis. Pertussis rates in the United States have escalated since the 1990s and reached a 50-year high of 48,000 cases in 2012. While this pertussis resurgence is not completely understood, we previously showed that the current acellular pertussis vaccines do not prevent colonization or transmission following challenge. In contrast, a whole-cell pertussis vaccine accelerated the rate of clearance compared to rates in unvaccinated animals and animals treated with the acellular vaccine. In order to understand if these results are generalizable, we used our baboon model to compare immunity from whole-cell vaccines from three different manufacturers that are approved outside the United States. We found that, compared to clearance rates with no vaccine and with an acellular pertussis vaccine, immunization with any of the three whole-cell vaccines significantly accelerated the clearance of B. pertussis following challenge. Whole-cell vaccination also significantly reduced the total nasopharyngeal B. pertussis burden, suggesting that these vaccines reduce the opportunity for pertussis transmission. Meanwhile, there was no difference in either the duration or in B. pertussis burden between unvaccinated and acellular-pertussis-vaccinated animals, while previously infected animals were not colonized following reinfection. We also determined that transcription of the gene encoding interleukin-17 (IL-17) was increased in whole-cell-vaccinated and previously infected animals but not in acellular-pertussis-vaccinated animals following challenge. Together with our previous findings, these data are consistent with a role for Th17 responses in the clearance of B. pertussis infection.

Acellular pertussis vaccines in China.

In China, whole-cell pertussis (Pw) vaccines were produced in the early 1960s and acellular pertussis (Pa) vaccines were introduced in 1995. Pa vaccines have now almost completely replaced Pw vaccines in the national immunization program. To strengthen the regulation of vaccines used in China, a vaccine lot release system was established in 2001 and Pa vaccines have been included in the system since 2006. This paper mainly described the current status of production and the quality control measures in place for Pa vaccines; and analyses quality control test data accumulated between 2006 and 2010.

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.

Collaborative study for the standardisation of the histamine sensitizing test in mice and the CHO cell-based assay for the residual toxicity testing of acellular pertussis vaccines.

The European Pharmacopoeia (Ph. Eur.) and the World Health Organisation (WHO) require the performance of extensive quality and safety control testing before the release on the market of vaccine products for human use. Safety testing with regard to residual pertussis toxin (PT) in acellular pertussis combination vaccines is performed through assessment of fatal sensitisation of mice to histamine challenge by the vaccine product under test. Currently, use of different in-house procedures and no requirement for the inclusion of a standard reference in each assay render comparisons of results obtained for identical vaccine batches between different control laboratories very difficult. At the initiative of the European Directorate for the Quality of Medicines and HealthCare (EDQM), an international collaborative study was organised for the standardization of the Histamine Sensitizing Test (HIST) in mice and the Chinese Hamster Ovary (CHO)-cell-based assay (performed at the bulk product level) for the residual toxicity testing of acellular pertussis vaccines or acellular pertussis-based combination vaccines. The study was run under the aegis of the Biological Standardisation Programme, jointly supported by the Council of Europe and the European Commission under the project code BSP076. Ten (10) laboratories participated in the study and were requested to perform 3 independent Histamine Sensitizing Tests in mice and to report results of the lethal end-point measurement as prescribed by the Ph. Eur. monographs. Some of them also reported data from an in-house validated CHO-cell-based assay. In addition, some of the laboratories reported concomitantly data obtained by measurement of the drop in temperature induced after the histamine challenge, a method currently under investigation to be added as an alternative end-point for the HIST in the Ph. Eur. monographs for acellular pertussis-based combination vaccines in order to alleviate animal suffering (in application of the 3Rs principle). Based on the results of the collaborative study, a potency of 7500 IU/vial (International Units per vial) was assigned to the current Ph. Eur. Biological Reference Preparation (BRP) for PT. The results of the study also show that 1) intra- and inter-laboratory variations can be improved by the use of a validated standard operating procedure; 2) inclusion in each assay of a standard reference sample, calibrated in IU, can increase comparability of results among laboratories and thus help to reduce repeat testing; 3) a correlation between mortality data and temperature data was observed although, due to the limited number of data sets and the lack of a common method for the temperature end-point, further investigation of this point is required; 4) the CHO-cell-based assay did not yield comparable results and further standardisation of the assay procedure may be investigated in a follow-up project.

An alternative temperature-based histamine-sensitisation test for absence of residual pertussis toxin in acellular pertussis vaccines.

As an extension of the BSP076 study (see the article 'Collaborative Study for the Standardisation of the Histamine Sensitizing Test in Mice and the CHO Cell-based Assay for the Residual Toxicity Testing of Acellular Pertussis Vaccines (BSP076)', page 51 of this issue of Pharmeuropa Bio & Scientific Notes), it was decided to publish the following experimental method for the temperature-based histamine-sensitisation test, validated at the SSI (Statens Serum Institut, Denmark), as a working basis for the growth of the method in individual laboratories.

Kinetics and sensitivity of ELISA IgG pertussis antitoxin after infection and vaccination with Bordetella pertussis in young children.

Sera from 96 young children in a vaccine trial were analysed for kinetics of ELISA IgG anti-pertussis toxin (anti-PT) after a laboratory-verified pertussis infection. The antibody decay curves after infection were biphasic and similar in shape to those after vaccination. The change from a rapid to a slower decay after the peak occurred about 4-5 months from the first day of cough. In a group of children given a two- or a five-component acellular pertussis vaccine the proportion of sera above the tentative cut-off values for anti-PT of 20, 50 or 100 EU/ml 12 months after onset of the infection were 19%, 0% and 0% respectively. Corresponding figures for a whole-cell or placebo vaccine group of infected children were significantly higher, 73%, 39% and 30%, i.e. the antibody decay after infection in young children depends on vaccination status as well as on the pertussis vaccine given. In a large group of non-infected children vaccinated with the same five-component acellular vaccine 13%, 0% and 0% had sera above 20, 50 and 100 EU/ml at 12 months after the third vaccine dose and all were below the minimum level of detection 2 years after vaccination. In conclusion, knowledge about anti-PT kinetics is essential for the interpretation of seroepidemiological data but hardly offers the possibility to establish valid cut-off values for anti-PT in single sample serology. An option would be to identify a grey zone between the positive and negative ends of the distribution for follow-up testing by a second serum.

Modified intra-cerebral challenge assay for acellular pertussis vaccines: comparisons among whole cell and acellular vaccines.

The modified intra-cerebral challenge assay for acellular pertussis vaccines is used in Japan, Korea, China and possibly other Asian countries as the potency assay for routine release of acellular pertussis (aP) and combination vaccines. National reference standards, typically of whole cell pertussis (Pw) vaccine, are in use in these countries, but there is no agreed international reference standard for acellular pertussis vaccines. We report here the results of a collaborative study initiated in September 2006 in which fourteen laboratories performing the modified intra-cerebral challenge assay took part. These laboratories compared their various national references of Pw vaccine, the third International Standard for whole cell pertussis vaccine, a previously studied two-component freeze-dried aP vaccine preparation coded JNIH-3, and four different aP vaccines in combination with diphtheria and tetanus toxoids. The results of this study show that the modified intra-cerebral challenge assay works reliably although there are inter-laboratory variations in potency estimates. Pw and aP vaccines show apparent differences in dose-response lines in some assay systems. This indicates dissimilarity in performance in at least some of these assay systems. Estimates of relative potency for aP vaccines in terms of the Pw vaccine national or in-house reference preparations differ significantly from one another. Different mouse strains were used in each country and the different strains may also differ in their responsiveness to Pw and aP vaccines. Estimates for different types of aP vaccine formulations show less inter-laboratory variation in terms of JNIH-3 than in terms of the third IS for Pw vaccine and the remaining variation is not apparently related to the different mouse strains. This study thus suggests that an aP vaccine standard would improve inter-laboratory agreement. These data do not show significant dissimilarity in dose-response lines between JNIH-3 and the various vaccine products included, irrespective of the differences in aP components. Available data indicate that JNIH-3 is sufficiently stable to serve as an International Standard. On the basis of these results and with the agreement of the participants, it was proposed that JNIH-3 should be established as an International Standard for acellular pertussis vaccine for use in the modified intra-cerebral challenge assay and other protective bioassays, with an assigned activity of 34 International Units (IU) per ampoule. A WHO Working Group on Standardization of Acellular Pertussis Vaccines: potency assay met in Beijing, China, 7-9 November 2007. This group considered the report of this study, the comments of the participants and implications of the use of JNIH-3 as a reference standard and recommended establishment of JNIH-3 as an International Standard. The results of this study and the report of the Working Group were submitted to the Expert Committee on Biological Standardization (ECBS) of WHO which established JNIH-3 as the first International Standard for acellular pertussis vaccine in the modified intra-cerebral challenge assay and other protective bioassays with an assignment of 34IU per ampoule in October 2008.

Collaborative study on a Guinea pig serological method for the assay of acellular pertussis vaccines.

An international collaborative study (coded BSP083) was performed under the aegis of the Biological Standardisation Programme supported by the Council of Europe and the European Commission, with the aim of replacing the in vivo challenge assays for potency determination of combined acellular pertussis (aP) vaccines by a refined procedure also allowing reduction of animal use. This study investigates whether the immunogenicity of aP vaccine components could be assayed in a guinea pig (gp) serology model, using the same vaccine immunising doses as for D and T components potency testing, instead of using separate animals as is currently done. The BSP83 project is a follow up of 3 former collaborative studies (coded BSP019, BSP034 and BSP035) on serological methods for the potency testing of tetanus (T) and diphtheria (D) vaccines for human use. The use of gp instead of mice serology has the advantage of providing a larger volume of good quality antiserum for the assay of several vaccine components in the same sample, hence providing the opportunity for animal sparing. The results of Phase I of the study demonstrated that gp serology may be a useful method for the immunogenicity assay of acellular pertussis vaccines. This was confirmed in Phase II of the study, using 7 different combined aP vaccines in an international collaborative study involving 17 laboratories from both public and private sectors. Clear dose-response relationships were observed for different vaccines by ELISA, for antibodies against aP antigens, i.e. pertussis toxin (PT), filamentous haemagglutinin (FHA), fimbrial agglutinogens-2/3 (Fim 2/3) and pertactin (PRN). Intra- and inter-laboratory variations of aP ELISA results were found to be within an acceptable range. For some combined vaccines, however, the range of vaccine dilutions for immunisation confirmed to be optimal for D and T potency testing may not provide optimal dose-response for all aP components. Method adjustments may thus be required and suitability should therefore be demonstrated for each vaccine combination and product prior to the application of this assay. The results of this study support the use of the gp serological method for the determination of the immunogenicity of aP vaccines. The application of the method for batch release testing of combined D, T and aP vaccines could significantly contribute to the implementation of the 3R principles through reduction of animal use and improved animal welfare, whilst reducing costs. As an outcome of this study, the Group of Experts No. 15 on Sera and Vaccines of the European Pharmacopoeia (Ph. Eur.) decided in February 2009 to include the gp serological assay as an example in the Ph. Eur. General chapter 2.7.16. on acellular pertussis vaccine assay.

WHO Working Group meeting on standardization of acellular pertussis vaccines: Potency assay Beijing, China, 7-9 November 2007.

New acellular pertussis vaccines have recently been developed in China and India. In this context, potency testing and potential improvements of the protective animal models with inclusion of a reference material were recognized as critical issues in the quality assessment of acellular pertussis vaccines. One of these models, namely Modified Intracerebral Challenge Assay (MICA), is currently used as a potency assay in Japan, China and Korea. A collaborative study comparing whole cell references, a candidate acellular pertussis vaccine reference (JNIH-3) and various acellular pertussis products was undertaken in 2006. The results of the collaborative study showed that MICA worked reliably and gave consistent results between laboratories. JNIH-3 was found to give similar dose-response lines to a variety of acellular pertussis vaccines and DTaP formulations, irrespective of the differences in acellular pertussis components. The WHO Working Group agreed that proposal for establishing JNIH-3 as the First International Standard for acellular pertussis vaccine in MICA should be submitted to the Expert Committee on Biological Standardization at its meeting in October 2008.

Improved efficacy of a licensed acellular pertussis vaccine, reformulated in an adjuvant emulsion of liposomes in oil, in a murine model.

The immunogenicities and efficacies of a licensed diphtheria, tetanus, acellular pertussis, and inactivated poliovirus vaccine and the same vaccine formulated in a liposome/oil emulsion adjuvant were compared in a mouse model of pertussis respiratory infection. A single dose of the liposome/oil emulsion-adjuvanted vaccine produced significantly higher antibody levels than one dose of the licensed vaccine and protected mice from Bordetella pertussis infection with an efficacy equivalent to that of three doses of the licensed vaccine.

WHO working group on standardisation and control of acellular pertussis vaccines--report of a meeting held on 16-17 March 2006, St. Albans, United Kingdom.

This report reflects the discussion and conclusions of a WHO group of experts from national regulatory authorities, national control laboratories, vaccine industry and other relevant institutions involved in standardisation and control of acellular pertussis vaccines, held on 16-17 March 2006, in St. Albans, UK. Following previous discussions (Bethesda, 2000; Ferney-Voltaire, 2003; Geneva, 2005) and collection of relevant data for quality control, on the one hand, and clinical evaluation of acellular pertussis vaccines, on the other, this meeting was intended to review the scientific basis for the revision of WHO guidelines adopted in 1996 [Guidelines for the production and control of the acellular pertussis component of monovalent or combined vaccines. In: WHO Expert Committee on Biological Standardisation. Forty-seventh report. Geneva, World Health Organisation, 1998 (WHO Technical Report Series, No. 878), Annex 2]. The discussion on animal protection models, immunogenicity and toxicity testing was focused on three main aspects: value of the assay for the purpose of licensing and/or lot release; validity criteria and potential optimisation of the assays. The group agreed that establishment of JNIH-3 as a potential International Standard (IS) for modified intra-cerebral challenge assay should be under consideration. It was suggested that the inclusion of a reference vaccine, such as JNIH-3 in the intra-nasal challenge model could improve the standardisation of this assay. It was proposed that the development of stable reference vaccines for immunogenicity testing should be encouraged. Further collection of the data from the countries with established lot release of acellular pertussis vaccines will be undertaken to prepare a solid basis for recommendations on toxicity tests. In the context of recommendations for clinical assessment of new vaccines, the group emphasised the importance of comparability studies with antigens that have already undergone efficacy trials in the past. The outline for the section on clinical evaluation of acellular pertussis vaccines was presented and after the consultation further additions were made. Post-marketing surveillance was recognised as an important part of overall vaccine evaluation and a unique opportunity to understand vaccine performance in the population and to establish a link with quality control.

Evaluation of respiratory model employing conventional NIH mice to access the immunity induced by cellular and acellular pertussis vaccines.

The increasing number of pertussis cases reported on the last twenty years and the existence of new acellular vaccines reinforce the need of research for experimental models to assure the quality of available pertussis vaccines. In this study, allotments of whole-cell and acellular pertussis vaccines were tested through the Intranasal Challenge Model (INM) using conventional NIH mice. The results have been compared to those achieved by the "Gold standard" Intracerebral Challenge Model (ICM). In contrast to ICM, INM results did not show intralaboratorial variations. Statistical analysis by Anova and Ancova tests revealed that the INM presented reproducibility and allowed identification and separation of different products, including three-component and four-component accellular pertussis vaccines. INM revealed differences between pertussis vaccines. INM provides lower distress to the mice allowing the reduction of mice number including the possibility of using conventional mice (less expensive) under non-aseptic environment. Thus, INM may be used as an alternative method of verifying the consistence of allotment production, including acellular pertussis vaccines.

Evaluation of respiratory model employing conventional NIH mice to access the immunity induced by cellular and acellular pertussis vaccines

The increasing number of pertussis cases reported on the last twenty years and the existence of new acellular vaccines reinforce the need of research for experimental models to assure the quality of available pertussis vaccines. In this study, allotments of whole-cell and acellular pertussis vaccines were tested through the Intranasal Challenge Model (INM) using conventional NIH mice. The results have been compared to those achieved by the "Gold standard" Intracerebral Challenge Model (ICM). In contrast to ICM, INM results did not show intralaboratorial variations. Statistical analysis by Anova and Ancova tests revealed that the INM presented reproducibility and allowed identification and separation of different products, including three-component and four-component accellular pertussis vaccines. INM revealed differences between pertussis vaccines. INM provides lower distress to the mice allowing the reduction of mice number including the possibility of using conventional mice (less expensive) under non-aseptic environment. Thus, INM may be used as an alternative method of verifying the consistence of allotment production, including acellular pertussis vaccines.

Acellular pertussis vaccines in Japan: past, present and future.

An antivaccine movement developed in Japan as a consequence of increasing numbers of adverse reactions to whole-cell pertussis vaccines in the mid-1970s. After two infants died within 24 h of the vaccination from 1974 to 1975, the Japanese government temporarily suspended vaccinations. Subsequently, the public and the government witnessed the re-emergence of whooping cough, with 41 deaths in 1979. This series of unfortunate events revealed to the public that the vaccine had, in fact, been beneficial. Furthermore, researchers and the Japanese government proceeded to develop safer pertussis vaccines. Japan now has the most experience worldwide with acellular pertussis vaccines, being the first country to have approved their use. This review describes the major events associated with the Japanese vaccination program. The Japanese experience should be valuable to other countries that are considering the development and use of such vaccines.

[Laboratory assessment problems of the efficacy of acellular pertussis vaccines]. / Problemy laboratoryjnej oceny skutecznosci bezkomórkowych szczepionek przeciw krztuscowi.

Although composition of acellular pertussis vaccines is better defined than whole-cell vaccines, differences in the formulation, content, and detoxification of pertussis vaccine antigens led to a unique character of each of differently produced acellular vaccine. Currently used methods for laboratory evaluation of whole-cell pertussis vaccine efficacy were found not suitable for acellular vaccines. There is a strong need to perform analysis and evaluation of the safety and efficacy profiles of acellular pertussis vaccines combined with other vaccine antigens (e.g. Hib) both before and after conjugation. Mechanisms of interactions seen after conjugation inducing weaker immunogenicity or efficacy are still poorly recognized.

[Prevention of pertussis and high expectations concerning vaccines]. / Profilaktyka krztusca a wysokie wymagania wobec szczepionek ochronnych.

The basic vaccine used in the prevention of pertussis is the combined vaccine including a whole cell pertussis component and tetanus and diphtheria toxoids. Although this type of vaccine has been used more than 50 years in USA and more than 40 years in Poland it is still effective what can be evidenced by the decreased number of pertussis cases since the vaccine has been implemented. There are however some evidences that the whole cell vaccine may lead to the acute encephalopathy, fever seizures, hypotonic-hyporeactive episodes, inconsolable crying or anaphylactic reactions. But still is a lack of convincing evidences that the vaccine may be a cause of persistent brain damage. It was also shown that the longer is the period after the last dose of the vaccine the lower effectiveness was observed. Improving the safety of the pertussis vaccine was the reason of introducing the acellular vaccines in the eightieth. All these products contain pertussis toxoid and some of them contain also filamentous hemagglutinin, pertactin and fimbrial agglutinogens. Some published studies have shown that the effectiveness of these vaccines is similar to the whole cells vaccines and that the incidence of some adverse events especially seizures, hypotonic-hyporeactive episodes and inconsolable crying is lower.

Detection of residual pertussis toxin in vaccines using a modified ribosylation assay.

Pertussis toxin (PTx) in its detoxified form is an important component of both whole cell and acellular pertussis vaccines (ACVs). For safety reasons, it is imperative to ensure that the quantity of residual PTx in vaccines does not exceed permissible levels. The majority of the toxic effects of PTx have been attributed to the consequences of PTx-catalyzed ribosylation of the alpha-subunits of signal-transducing guanine-nucleotide-binding proteins. In this report PTx ribosylation activity was determined by an improved enzymatic-high performance liquid chromatography coupled assay using a fluorescein labeled Galpha(i3)C20 peptide. The effect of aluminum salts and other vaccine components on the assay system were also studied. The enzymatic assay system was shown to be a convenient, sensitive method and correlate well with the toxicity observed in vivo by the histamine sensitization assay. This method forms the basis of a new assay which could replace the unsatisfactory animal test currently used in pertussis vaccines control.

A quantitative analysis for the ADP-ribosylation activity of pertussis toxin: an enzymatic-HPLC coupled assay applicable to formulated whole cell and acellular pertussis vaccine products.

The majority of the biological effects of pertussis toxin (PT) are the result of a toxin-catalyzed transfer of an adenosine diphosphate-ribose (ADP-ribose) moiety from NAD(+)to the alpha-subunits of a subset of signal-transducing guanine-nucleotide-binding proteins (G-proteins). This generally leads to an uncoupling of the modified G-protein from the corresponding receptor and the loss of effector regulation. This assay is based on the PT S1 subunit enzymatic transfer of ADP-ribose from NAD to the cysteine moiety of a fluorescent tagged synthetic peptide homologous to the 20 amino acid residue carboxyl-terminal sequence of the alpha-subunit of the G(i3)protein. The tagged peptide and the ADP-ribosylated product were characterized by HPLC/MS and MS/MS for structure confirmation. Quantitation of this characterized ADP-ribosylated fluorescently tagged peptide was by HPLC fluorescence using Standard Addition methodology. The assay was linear over a five hr incubation period at 20 degrees C at PT concentrations between 0.0625 and 4.0 microg/ml and the sensitivity of the assay could be increased several fold by increasing the incubation time to 24 h. Purified S1 subunit of PT exhibited 68.1+/-10.1% of the activity of the intact toxin on a molar basis, whereas the pertussis toxin B oligomer, the genetically engineered toxoid, (PT-9K/129G), and several of the other components of the Bordetella pertussis organism possessed little (<0.6%) or no detectable ribosylation activity. Commonly used pertussis vaccine reference materials, US PV Lot #11, BRP PV 66/303, and BRP PV 88/522, were assayed by this method against Bordetella pertussis Toxin Standard 90/518 and demonstrated to contain, respectively, 0.323+/-0.007, 0.682+/-0.045, and 0.757+/-0.006 microg PT/ml (Mean+/-SEM) or in terms of microg/vial: 3.63, 4.09 and 4.54, respectively. A survey of several multivalent pertussis vaccine products formulated with both whole cell as well as acellular components indicated that products possessed a wide range of ribosylation activities. The pertussis toxin S1 subunit catalyzed ADP- ribosylation of the FAC-Galpha(i3)C20 peptide substrate and its subsequent quantitation by HPLC was demonstrated to be a sensitive and quantitative method for measuring intrinsic pertussis toxin activity. This methodology not only has the potential to be an alternative physicochemical method to replace existing bioassay methodology, but has the added advantage of being a universal method applicable to the assay of pertussis toxin in both whole cell and acellular vaccines as well as bulk and final formulated vaccine products. Acceptance of this method by regulatory agencies and industry as a credible alternative to existing methods would, however, require validation in an international collaborative study against the widely accepted bioassay methods.