Generation of an inactivated vaccine for avian pathogenic Escherichia coli using microarrays: A more rational approach to inactivated vaccine design

remains a major pathogen of poultry. Most vaccines are inactivated and produced empirically. Although inactivated vaccines have been produced by culture under conditions of Fe deprivation, no vaccines have been produced which are likely to express all the proteins expressed during infection of antig...

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Bibliographic Details
Published in:Open veterinary journal (Tripoli, Libya) Libya), 2022, Vol.12 (2), p.221-230
Main Authors: Zhou, Xiangmei, Richards, Philip, Windhorst, Daniel, Imre, Ariel, Bukovinski, Agnes, Ruggeri, Jessica, Elazomi, Altayeb, Barrow, Paul
Format: Article
Language:English
Subjects:
Animals
Bacterial Vaccines
chicken
Chickens
Escherichia coli - genetics
Escherichia coli Infections - prevention & control
Escherichia coli Infections - veterinary
gene expression
microarray
Original Research
Poultry Diseases
synthetic medium
vaccine
Vaccines, Inactivated
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Summary:remains a major pathogen of poultry. Most vaccines are inactivated and produced empirically. Although inactivated vaccines have been produced by culture under conditions of Fe deprivation, no vaccines have been produced which are likely to express all the proteins expressed during infection of antigen-presenting cells. The aim was to produce a more protective inactivated vaccine by culturing the avian in a synthetic medium that resembled the environment of the phagolysosome. Global gene expression in a pathogenic avian O78:K80 strain of , harvested from infected avian macrophage-like HD11 cells, was compared by microarray with bacteria cultured in a tissue culture medium. A liquid synthetic medium was produced based on the environmental conditions identified to which the bacteria were exposed intracellularly. A bacterin was produced from this strain and its protective ability was assessed in chickens. The changes in gene expression observed included the use of different electron acceptors and carbon sources such as ethanolamine, β-glucosides, galactonate, dicarboxylic acids, and amino acids, up-regulation of genes associated with Fe and Mn uptake, and up-regulation of type-1 and curli fimbriae, other adhesion genes and down-regulation of sialic acid synthesis genes. The bacterin produced in the synthetic medium was statistically more protective than a bacterin prepared from bacteria cultured in the nutrient broth when tested in vaccinated chickens challenged with a different virulent O78:K80 strain. The approach of using gene expression to produce synthetic media for the generation of more effective bacterins could be used for a number of intracellular bacteria pathogens including Enteroinvasive , , and the group of organisms.
ISSN:2226-4485
2218-6050
DOI:10.5455/OVJ.2022.v12.i2.10