The effect of pH on the production of pertussis toxin by Bordetella pertussis.

The production of pertussis toxin by Bordetella pertussis was increased by controlling the pH at 7.0 through the addition of sulfuric acid. The more commonly used hydrochloric acid and Tris buffer were observed to be detrimental to toxin yields.     

Production of cell mass and pertussis toxin by Bordetella pertussis.

The cultivation of Bordetella pertussis affects production of pertussis toxin and biomass. Comparison of batch mode, chemostat operation and pHstat-turbidostatic control showed that productivities for the continuous process were greater than that for the batch operation. Continuous operation in balanced growth at the maximum specific growth rate, provided by the pHstat, resulted in the maximum specific production rate. Because of the strong association of pertussis toxin synthesis and cell growth, the concentration of toxin in the effluent of the continuous processes was greater than the maximum obtained in the batch bioprocess. An expanded Luedeking-Piret model of product formation kinetics fits the observed chemostat data and demonstrates that the production of pertussis toxin from the culture of B. pertussis is predominantly growth associated.     

Review of the biology of Bordetella pertussis.

Bordetella pertussis produces a complex array of adhesins, aggressins and toxins that are presumed to be important in the colonisation of its human host and in ensuring its survival and propagation. The organism also has highly sophisticated mechanisms for regulating virulence factor expression, in response to environmental signals or by reversible mutations. Despite the rapidly increasing knowledge of these aspects of the biology of B. pertussis, our understanding of the pathogenesis of whooping cough is still far from clear. In defining the role of individual factors, reliance has to be placed on in vitro assays or animal models of the human infection, particularly in the mouse, where different conditions may prevail. Some clues to pathogenic mechanisms may be provided by considering other bordetellae, especially B. parapertussis, B. bronchiseptica and B. avium, their similar, but not identical, range of virulence factors and the common features of the diseases caused by these species in their respective hosts. The bordetellae are usually defined as obligate, non-invasive parasites of the respiratory tracts of warm-blooded animals, including birds, with a predilection for the respiratory ciliated epithelium. This definition has been challenged by a number of recent observations. For example, the ability of Bordetella spp. to regulate virulence factor expression in response to external signals strongly suggests that they have alternative habitats where such regulation would be an advantage. These habitats may be intracellular, since it has been shown that B. pertussis, B. parapertussis and B. bronchiseptica can invade and survive within host cells, or they may be in other sites within the same or different hosts. Recent DNA fingerprinting studies of B. pertussis have revealed hitherto unsuspected heterogeneity amongst isolates which could be reflected in antigenic differences between strains. Some of these new perspectives on Bordetella pathogenicity may have implications for pertussis vaccine development.     

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.     

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.     

Immunity to Bordetella pertussis.

Bordetella pertussis exploits extracellular and intracellular niches in the respiratory tract and a variety of immune evasion strategies to prolong its survival in the host. This article reviews evidence of complementary roles for cellular and humoral immunity in protection. It discusses the effector mechanisms of bacterial elimination, the strategies employed by the bacteria to subvert protective immune responses and the immunological basis for systemic and neurological responses to infection and vaccination.     

Standardization of acellular pertussis vaccines.

In comparison with the current whole cell pertussis vaccine, the new generation of acellular pertussis vaccines opens new opportunities to improve the standardization of the product, because well defined and characterized components are used in these new products.However, different compositions, purification and inactivation methods are used by different manufacturers. Consequently the various acellular pertussis vaccines in the world are difficult to compare in a meaningful manner using simple laboratory tests. In addition, the absence of a reliable animal model and serological correlates with protection in children are other complicating factors.For that reason it seems that the consistency in manufacturing based on a clinically validated production process is the best way to ensure the safety and efficacy of routinely produced acellular pertussis vaccines.Laboratory tests to monitor the antigen content, purity, safety and immunogenicity seem to be the best approach to standardize this new generation of pertussis vaccines against homologous standard vaccines with known clinical efficacy and safety and to support the consistency in manufacture.     

Structure of Bordetella pertussis peptidoglycan.

Bordetella pertussis Tohama phases I and III were grown to the late-exponential phase in liquid medium containing [3H]diaminopimelic acid and treated by a hot (96 degrees C) sodium dodecyl sulfate extraction procedure. Washed sodium dodecyl sulfate-insoluble residue from phases I and III consisted of complexes containing protein (ca. 40%) and peptidoglycan (60%). Subsequent treatment with proteinase K yielded purified peptidoglycan which contained N-acetylglucosamine, N-acetylmuramic acid, alanine, glutamic acid, and diaminopimelic acid in molar ratios of 1:1:2:1:1 and less than 2% protein. Radiochemical analyses indicated that 3H added in diaminopimelic acid was present in peptidoglycan-protein complexes and purified peptidoglycan as diaminopimelic acid exclusively and that pertussis peptidoglycan was not O acetylated, consistent with it being degraded completely by hen egg white lysozyme. Muramidase-derived disaccharide peptide monomers and peptide-cross-linked dimers and higher oligomers were isolated by molecular-sieve chromatography; from the distribution of these peptidoglycan fragments, the extent of peptide cross-linking of both phase I and III peptidoglycan was calculated to be ca. 48%. Unambiguous determination of the structure of muramidase-derived peptidoglycan fragments by fast atom bombardment-mass spectrometry and tandem mass spectrometry indicated that the pertussis peptidoglycan monomer fraction was surprisingly homogeneous, consisting of greater than 95% N-acetylglucosaminyl-N-acetylmuramyl-alanyl-glutamyl-diaminopimelyl++ +-alanine.     

Molecular genetic characteristics of the B. pertussis strains isolated in different periods of the pertussis epidemic process

Despite the fact that the mass immunization of the children population with the DPTs vaccine has been carried out in the Russian Federation since 1959, the pertussis infection persists to be one of the pressing problems for the children population. Although the vaccination coverage of the children population with pertussis vaccines is high in Russia, at present time the pertussis incidence rates are increasing among schoolchildren and remain high among infants younger than 12 months old. Many researchers believe that the variability of the genetic structure of the pertussis causative agent may be one of the causes of increasing pertussis incidence rates. This investigation provides the molecular genetic characteristics of 97 B. pertussis strains isolated in pertussis patients in Moscow in different periods of pertussis epidemic process since the 1950s up to present time. It shows the changes in the structures of genes, which are encoding the main protective antigens of the pertussis microbe that are the pertussis toxin (ptxS1) and the pertactin (pm). The structurre of the ptxS1 and pm gene of the B. pertussis vaccine strains was compared with the structures of these genes in the B. pertussis strains isolated from the pertussis patients at present time and also in past years. All B. pertussis strains isolated in the prevaccination period (1948-1959) and most strains (95%) isolated during the first twenty years of the mass immunization in Russia are characterized by the presence of the so called "vaccine" alleles of the pertussis toxin and pertactin genes that are ptxS1 B or ptxS1 D and pm 1 alleles that corresponds to the genetic structure of the vaccine producing strains. In the early 1970s the B. pertussis strains of another toxin and pertactin genetic structures with so-called "non-vaccinal" alleles ptxS1 A and pm 3 (pm 2 since 1980s) began to appear. The B. pertussis strains with "non-vaccinal" alleles have completely displaced the "old" strains. At present time in Moscow the pertussis disease is caused by the B. pertussis strains bearing ptxS1 A and pm 2 or pm 3 alleles of pertussis toxin and pertactin genes. There was no correlation between the genotype and serotype. Thus, the structure of the B. pertussis toxin and pertactin genes in strains which have been isolated since the 1980s up to now differs from the structure of these genes in strains which are used for producing DPTs vaccine. The data obtained in this investigation suggest that the genetic structure specificity of circulating B. pertussis strains that are producing the disease at present time should be used as one of the criteria for selecting vaccine producing strains.     

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.     

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.