Effect of relevant culture parameters on Pertussis Toxin expression by Bordetella pertussis

Whooping cough vaccines are produced using different ranges of cultivation conditions and medium compositions, which are known to influence growth rate, virulence factor production and degradation, as well as the virulence factors' association to the cell. This study quantifies the impact of in...

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Bibliographic Details
Published in:Biologicals 2006-09, Vol.34 (3), p.213-220
Main Authors: Thalen, Marcel, Venema, Marian, van den IJssel, Jan, Berwald, Luc, Beuvery, Coen, Martens, Dirk, Tramper, Johannes
Format: Article
Language:English
Subjects:
antigens
Bordetella pertussis
Bordetella pertussis - drug effects
Bordetella pertussis - growth & development
Bordetella pertussis - metabolism
Carbon - analysis
Culture Media - chemistry
Culture Media - pharmacology
Culture Techniques
Glutathione - analysis
Glutathione - pharmacology
Iron - analysis
Iron - pharmacology
Medium
metabolism
Niacin - analysis
Niacin - pharmacology
Nitrogen - analysis
outer-membrane
Pertussis Toxin - biosynthesis
Pertussis Toxin production
Pertussis Vaccine - biosynthesis
quantification
Sodium - analysis
Sodium - pharmacology
Vaccine
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Summary:Whooping cough vaccines are produced using different ranges of cultivation conditions and medium compositions, which are known to influence growth rate, virulence factor production and degradation, as well as the virulence factors' association to the cell. This study quantifies the impact of individual parameters on Pertussis Toxin (PT) production, using an optimized chemically defined medium as starting point, rather than a complex medium. A number of chemicals that are identified affect both growth rate and virulence factor production, which occur at similar levels in various commonly used production media. Also, degradation by proteolytic activity is shown to be an important parameter to monitor, since it significantly affects the PT yield. Low sodium concentrations, i.e. 50–75 mM rather than the conventional 100–140 mM, significantly increase the growth rate of the organism, the final optical density, as well as the association of PT to the cells. The absolute amount of biomass produced measured as dry weight, is similar for all sodium concentrations tested, contrary to earlier work. While it is known that high iron concentrations inhibit virulence factor production, it is shown here that iron-limited growth results in very high specific PT production. This finding may be used to produce a whole-cell vaccine with little biomass per dose, reducing whole-cell vaccine toxicity. The Bordetella pertussis strain 509 used here produces 30% more PT at 34 than at 37 °C, a commonly used cultivation temperature. The data in this study show that existing production processes for cellular and acellular vaccines can in principle be optimised considerably by taking simple measures.
ISSN:1045-1056
1095-8320
DOI:10.1016/j.biologicals.2005.11.002