Evaluation of whole-cell and acellular pertussis vaccines effectiveness in clearance of experimental B. pertussis infection in mice

The study is based on assumption that B. pertussis strains harbouring different allele variants of genes encoding subunit S1 of pertussis toxin and pertactin might be eliminated with different efficiency from lung tissue of mice which were immunized with whole-cell and acellular pertussis vaccines. It has been assumed that strains containing combinations of genes alleles which were not prevalent since 1990-ties are consisting of mutated strains in respect to pertussis toxin subunit S1 and pertactin, and are capable to decrease efficiency of pertussis vaccines. Experiments performed in vivo dealt with activity of tested vaccines against B. pertussis strains of different combinations of ptxS1/prn. The study indicated for lowered efficiency of whole-cell and acellular pertussis vaccines in elimination of mutated strains of B. pertussis from animal lung tissue in comparison with strains currently used for vaccine production.     

Modern strains of Bordetella pertussis: immunobiological properties and vaccine improvement

Strains of B. pertussis isolated from patients in Moscow in 2001-2005 as well as strains included in locally produced diphtheria-tetanus-whole cell pertussis (DTP) vaccine were studied. Nucleotide sequences in genes of pertactin and S1-subunit of pertussis toxin of isolated strains, their immunobiological properties and opportunity to use for producing of the acellular pertussis vaccine were determined. Genes of pertactin and S1-subunit of pertussis toxin in the isolated wild strains differed from the same genes in strains included in the local DTP vaccine. Majority of the isolated strains belonged to serotype 1.0.3 and were markedly virulent.     

The new strategy for allele identification of the genes coding for pertussis toxin subunit S1 (ptx S1) and pertactin (prn) in Bordetella pertussis

Bordetella pertussis strains demonstrate polymorphism in toxin subunit S1 (PT S1) and pertactin (Prn), which belong to major protective antigens of the pathogen. Changes in the distribution of particular alleles of ptxS1 and prn genes in local B. pertussis populations have been proposed as possible factors influencing the vaccination effectiveness. We have developed a new methodology for the identification of the alleles, which eliminates the necessity of DNA sequencing. The approach is based on the evaluation of the number of sequence repeats and detection of specific nucleotides at polymorphic sites of the genes, and utilizes products of their full or partial PCR amplification. The approach is available for a laboratory with standard equipment. The total conformity of the strategy with the DNA sequencing-based approach was proved on the full set of reference strains and a group of Polish clinical isolates. The new methodology was used to investigate a collection of 120 Polish B. pertussis strains isolated from the 1960s to 2001. Similarly to findings from other countries and to earlier Polish data, the tendency to change the vaccine types of PT S1 and Prn by the antigenically different ones was observed.     

Molecular typing of the strains of Bordetella pertussis circulating in St. Petersburg during an outbreak of the disease

Growth of the whooping-cough morbidity during the last years in Russia and other countries with 40-year-long history of immunization gave rise to significant interest of researchers to variability of the Bordetella pertussis population. Comparative assay of the genomes of the B. pertussis strains circulating in St. Petersburg in 1998-2000 and strains used to produce domestic vaccines AKDS was performed using the pulse-field electrophoresis and sequencing. It was found that most strains of B. pertussis circulating during this period were distinguished from the vaccine strains by the DNA-profile and structure of genes involved in encoding of biosynthesis of the S1 subunit of the whooping-cough toxin (ptxS1) and pertactin (prn). It was shown that 62% of wild-type strains had electrophoretic profiles IV alpha and IV beta, whereas vaccine strains had electrophoretic profiles II and III. Circulation of strains with profiles IV alpha and IV beta was found to correlate with the whooping-cough morbidity rate in vaccinated children. Our results and data of other researchers were compared and analyzed.     

Comparison of real-time PCR and pyrosequencing for typing Bordetella pertussis toxin subunit 1 variants

We describe two newly developed methods for rapid typing of the pertussis toxin subunit 1 gene (ptxS1). A real-time PCR assay based on hybridization probes and a Pyrosequencing assay were developed and the specificity, sensitivity, cost, hands-on time and post-assay data processing were compared to Sanger sequencing. Both methods enabled discrimination of all four allelic variants, correctly identified all ptxS1 alleles of 143 strains tested and proved suitable for large-scale screening of B. pertussis strains.     

Genetic and antigenic analysis of Bordetella pertussis isolates recovered from clinical cases in Ontario, Canada, before and after the introduction of the acellular pertussis vaccine

Sixty-eight Bordetella pertussis isolates (obtained between 1994 and 2004 from the province of Ontario in Canada) were compared by the following phenotypic and genetic analyses: serotyping; pulsed-field gel electrophoresis; and partial DNA sequence analysis of their pertactin, pertussis toxin, and fimbriae genes. Although temporal genetic variations were observed among the isolates, which is consistent with the current view that B. pertussis evolves over time, no specific antigenic or genetic type was detected in 48 isolates collected shortly after the introduction of the acellular pertussis vaccine. Further surveillance with clinical data and isolates collected periodically will be required to ensure that any genetic divergence that could affect vaccine efficacy will not be occurring.     

Analysis of chosen parameters of immuno response in mice immunized with whole-cell or acellular pertussis vaccines and challenged with B. pertussis strains harbouring different ptxS1/prn allele genes combinations

Studies concerned evaluation of differences between parameters of cell-mediated immunity in mice, induced with whole-cell and acellular pertussis vaccines with subsequent challenge with B. pertussis strains harbouring different ptxS1/prn allele genes. In the study, concentrations of IFN-gamma/Il-2 and 1l-4/Il-5 in supernatants of cultured mice splenocytes have been determined to evaluate differences in Th1 or Th2 lymphocytes subpopulation response. Simultaneously, studies of intracellular expression of genes encoding of Il-2, Il-12, IFN-gamma and Il-4, Il-5, Il-10, Il-13 in mice splenocytes, and genes encoding factors involved in inflammatory process in the lung tissue (GM-CSF, TNF-alpha, Il-1beta, Il-6 i TGF-beta) have been performed on RNA level. The obtained results, confirmed high polarization of immunological response toward Th1 in mice immunized with DTP vaccine with whole-cell pertussis component, and toward Th2 in mice immunized with acellular pertussis vaccine. Inflammatory process in the lung tissue was more pronounced in animals immunized with whole-cell pertussis vaccine. There were no quantitative differences of analysed factors involved in the immune response among mice challenged B. pertussis strains containing different ptxS1/prn composition.     

Molecular aspects of Bordetella pertussis pathogenesis.

The molecular mechanisms of Bordetella virulence are now well understood, and many virulence factors have been identified and characterized at the molecular level. These virulence factors can be grouped into two major categories: adhesins, such as filamentous hemagglutinin, pertactin and fimbriae, and toxins, such as pertussis toxin, adenylate cyclase, dermonecrotic toxin and tracheal cytotoxin. The production of most virulence factors is coordinately regulated by a two-component signal transduction system composed of the regulator BvgA and the sensor protein BvgS. The adhesins and toxins act in concert to establish infection. Some adhesins exert their effects synergically or are redundant functioning only in the absence of another adhesin, illustrating the importance of adhesion in infection. Most virulence factors are secreted into the culture supernatant or exposed at the surface of the bacterial cell. A notable exception is dermonecrotic toxin, which remains in the cytoplasmic compartment of bacterial cells. Most virulence factors are produced by all of the three major Bordetella species, B. pertussis, B. parapertussis and B. bronchiseptica. However, some, such as pertussis toxin and the tracheal colonization factor, are only produced by B. pertussis. Our understanding of Bordetella virulence at the molecular level has led to the development of new acellular vaccines against whooping cough, and of genetically attenuated B. pertussis strains to be used as recombinant live bacterial vaccine vectors for homologous and heterologous protection.     

Molecular cloning of pertussis toxin genes.

We have cloned a 4.5 kb EcoRI/BamHI DNA fragment from Bordetella pertussis which contains at least two genes responsible for expression of pertussis toxin. The S4 subunit of the toxin was isolated by high pressure liquid chromatography and the NH2-terminal amino acid sequence determined. Using a mixed synthetic oligonucleotide probe designed by reverse translation of a portion of the protein sequence, a cloned DNA fragment was identified which contains the coding information for at least the S4 structural subunit of the toxin. Sequence analyses indicate that the mature protein is derived by proteolytic cleavage of a precursor molecule. Southern blot analyses of Tn5-induced B. pertussis toxin-deficient mutants show that the Tn5 DNA is inserted 1.3 kb downstream from the S4 subunit gene. This second gene could code for another subunit required for assembly of the mature toxin or a non-structural transport protein, possibly in the same polycistronic operon. The molecular cloning of pertussis toxin genes provides the basis for development of a safer recombinant "new generation" vaccine for whooping cough.     

Bordetella pertussis serotypes in Canada.

A study was done to determine the major antigenic factors of Bordetella pertussis strains isolated throughout Canada and whether these isolates have the same antigenic structure as the bacilli in the currently used vaccines. Testing for the major pertussis antigens, factors 1, 2 and 3, was conducted with 440 freshly isolated strains of B. pertussis received from seven canadian provinces between August 1976 and February 1978 and six batches of pertussis vaccine or immunizing agents containing pertussis vaccine. With the aid of specific antisera prepared in rabbits, the antigenic factors were detected by a slide agglutination technique. Almost all (98.9%) of the pertussis strains examined were serotype 1,3.All six batches of pertussis vaccine or immunizing agents containing pertussis vaccine proved to be rich in each of the three main pertussis agglutinogens.     

Construction of the genetically attenuated bacteria Bordetella pertussis devoid of dermonecrotic toxin activity and producing modified nontoxic pertussis toxin form

The recombinant modified (attenuated) bacteria A. pertussis were constructed. These bacteria contained knockout mutation of the dnt gene and produced nontoxic pertussis toxin derivative. The immunological properties of the mutant bacteria B. pertussis strain KS were studied. The recombinant bacteria B. pertussis strain KS were found to be devoid of dermonecrotic toxin activity, conserved the structure of the mutant dnt gene in condition of cultivation on selective growth media, and long-term survival in laboratory animal organism. Intranasal immunization of mice with living bacteria B. pertussis, attenuated strain KS provided protection of animals from virulent strains of the pertussis. The efficiency of the protection was comparable with protection efficiency provided by standard corpuscular pertussis vaccine OSO-3.     

Genetic verification of Bordetella pertussis seed strains used for production of Japanese acellular pertussis vaccines

In Japan, the Bordetella pertussis strain Tohama provided by the National Institute of Health, Japan has been used for the production of acellular pertussis (aP) vaccines since 1981. In the present study, in order to verify the genetic consistency of B. pertussis vaccine seed strains, we analyzed the genetic properties of the working seeds obtained from five Japanese vaccine manufacturers, and compared them with those of B. pertussis Tohama reference strains (NIID L-7 and ATCC BAA-589). Genetic analyses with pulsed-field gel electrophoresis and allele typing showed 100% genetic identity among the five seed strains and the Tohama reference strains. In addition, Southern blot analyses revealed the absence of four orthologous genes (BB0537, BB0920, BB1149 and BB4885), which are specifically absent in the strain Tohama, and in the genome of all seed strains tested, suggesting that the regions of difference (RD11–RD14) are absent in their genomes. Consequently, no genetic difference was observed among the working seeds and Tohama reference strains. Our observations indicate that B. pertussis seed strains for Japanese aP vaccine production are genetically comparable with B. pertussis Tohama.     

The Bordetella pertussis virulence factor P.69 pertactin retains its immunological properties after overproduction in Escherichia coli

Bordetella pertussis is re-emerging in several countries with a high vaccine uptake. Analysis of clinical isolates revealed antigenic divergence between vaccine strains and circulating strains with respect to P.69 pertactin. Polymorphisms in P.69 pertactin are mainly limited to regions comprised of amino acid repeats, designated region 1 and region 2. Region 1 flanks the RGD motif involved in adherence. Although antibodies against P.69 pertactin are implicated in protective immunity, little is known about the structure and location of its epitopes. Previously we described the localization of mainly linear epitopes of both human sera and mouse monoclonal antibodies (mAbs). To study the location of conformational epitopes and to investigate the effect of variation in P.69 pertactin on vaccine efficacy, we cloned, expressed, and purified 3 naturally occurring P.69 pertactin variants, 3 mutants in which the variable regions are missing, 3 N-terminal mutants and 1 C-terminal deletion mutant. Here, we describe the procedure to clone, express, and purify up to 0.1mg P.69 pertactin and its derivatives per 1 ml Escherichia coli culture.     

Restriction analysis of Bordetella pertussis DNA isolated from patients with whooping cough in 1968 and 1995-98 and B. pertussis used for production of national vaccine strains

The genotypic and serotypic analysis of B. pertussis strains isolated from the nasopharynx of children with whooping cough in the years 1968 and 1995-98 and B. pertussis vaccine strains was the aim of this study. The genotyping of the examined strains was done by electrophoretic division of DNA in pulsed field. The 3 types (A, B, C) and 2 subtypes (A1 and A2) of DNA restriction patterns were determined for the B. pertussis strains isolated in 1968. The 2 types (D and E) and 10 subtypes (D1-D10) of DNA restriction patterns were identified for B. pertussis strains from the years 1995-98. The DNA restriction patterns of B. pertussis strains isolated in the years 1968 and 1995-98 were not identical what was the evidence of the fact that in the sixties and nineties whooping cough was caused by different B. pertussis clones. The different DNA profiles were also observed for vaccine strains as well as for vaccine strains and current isolates. Differences in DNA patterns of vaccine strains and B. pertussis strains isolated in the years 1995-98 indicated a relationship possibility in some cases while lack of relationship between these strains in other cases. Serotyping of the examined B. pertussis strains was performed by the agglutination method with the sera against B. pertussis agglutinogens 1, 2 and 3. Most strains--15 (75%) isolated in 1968 possessed only agglutinogens 1 and 3. Serotype 1, 2, 3 was most frequently observed among isolates from the years 1995-98. This study indicates the expediency of periodical change of B. pertussis vaccine strains in the aspect of whooping cough resurgence in the years 1994-95 and 1997-98.     

The development of a new generation of pertussis vaccine

The results of the weight gain test on mice have shown that acellular pertussis vaccine is less toxic than the pertussis component of adsorbed diphtheria-pertussis-tetanus (DPT) vaccine due to a lower content of endotoxin in the acellular vaccine; but the leukocytosis-promoting and histamine-sensitizing activities of JNIH-6 and adsorbed DPT vaccines are indicative of incomplete inactivation of Bordetella pertussis toxin. The content of incompletely inactivated B. pertussis toxin is practically the same in both preparations, constituting 1/100-1/200 of the calculated initial activity. For this reason, the use of the new pertussis vaccine also involves a risk of development of serious postvaccinal reactions and/or complications caused by this toxin. Search for the optimum method of inactivation of B. pertussis main toxin should be continued. As shown by the enzyme immunoassay, acellular pertussis vaccine used in the same immunizing dose as adsorbed DPT vaccine induces a more intensive immune response to hemagglutinin and B. pertussis toxin. This is due to higher residual toxicity of the corpuscular component of adsorbed DPT vaccine. Induction of antibodies to B. pertussis toxin has been shown to decrease in response to injection of acellular pertussis vaccine containing a certain residual amount of incompletely inactivated B. pertussis toxin.     

Protective immunity against Bordetella pertussis by a recombinant DNA vaccine and the effect of coinjection with a granulocyte-macrophage colony stimulating factor gene

A recombinant pertussis DNA vaccine was described here with its immunogenicity and the ability to induce protection against B. pertussis infection in mice. Three immunodominant antigen gene fragments of pertussis, pertussis toxin subunit 1 (pts1), fragments of pertactin (prn) and filamentous hemagglutinin (fha), were recombined as fragment pts1-prn-fha named ppf, and it was cloned to plasmid pVAX1 as pVAX1/ppf. Compared to those injected with pVAX1, the mice injected with pVAX1/ppf significantly elicited more antigen specific antibody anti-PTS1, anti-PRN, anti-FHA and cytokine IL-10, IFN-gamma. When pGM-CSF was coinjected with pVAX1/ppf, the mice showed significantly increases of the three antibodies and cytokine IL-10, IL-4, IFN-gamma and TNF-alpha compared to those injected with pVAX1 only. The mice in group pVAX1/ppf & pGM-CSF, in particular; induced much more anti-PTS1, IL-4 and TNF-alpha than those in group pVAX1/ppf. In the intracerebral mouse protection test, the mice immunized with pVAX1/ppf or pVAX1/ppf & pGM-CSF induced protection to a lethal dose of B. pertussis. The results indicate that recombinant DNA vaccine and pGM-CSF coinjection can induce protective immunity against B. pertussis, demonstrating a valuable method to prevent pertussis.     

Isolation of hemolytic cultures of Bordetella pertussis intended for the production of acellular pertussis preparations and the characterization of their biological properties

The heterogeneity of the population of B. pertussis laboratory strains with respect to the capacity of individual clones to lyse erythrocytes has been established. The complete or partial reduction of the antigens under study in nonhemolytic bacteria has been shown. The use of hemolytic cultures for the preparation of acellular pertussis vaccine makes it possible to increase the content of B. pertussis toxin in these vaccines.     

Lipopolysaccharides in a traditional pertussis vaccine

Analysis of the lipopolysaccharide (LPS, endotoxin) in cell sonicates of four Danish vaccine strains of Bordetella pertussis (3803, 3825, 3843 and 3860) and of purified strain 3803 LPS in sodium dodecyl sulphate-polyacrylamide gel electrophoresis by silver staining, showed identical profiles. The LPS profile revealed a dominant, brownish LPS II band and a minor, faster-migrating, black-stained LPS I band. However, the ratio of LPS I to LPS II in the preparation of purified LPS differed slightly from the cell sonicates. Using marker LPS, the molecular weights of LPS I and LPS II were estimated at 5.4 and 6.0 kD, respectively. Seven different lots of whole cell pertussis vaccine were assayed for LPS in the Limulus Amoebocyte Lysate test and were found to contain 0.9-2.8 micrograms LPS/ml. No significant difference in the content of LPS in similar dilutions of the individual strains was observed. In addition, the distribution of free and cell-bound LPS in four pertussis vaccines was investigated. Most of the LPS was found to exist as free LPS. During several months, the course of both LPS and pertussis toxin (Pt) release in freshly killed B. pertussis preparations was followed. In the first few weeks, 35-50% of the LPS was released and after 5-6 months of storage 60-80% had been released. In contrast, less than 10% of the biologically active pertussis toxin was released during the experimental period. The possibility of producing a safer whole cell pertussis vaccine by reducing the amount of free LPS without reducing the protective value correspondingly is discussed.