Background: Avian pathogenic Escherichia coli (APEC) is detrimental to poultry health and its zoonotic potential is a food safety concern. Regulation of antimicrobials in food-production animals has put greater focus on enhancing host resistance to bacterial infections through genetics. To better define effective mechanism of host resistance, global gene expression in the spleen of chickens, harvested at two times post-infection (PI) with APEC, was measured using microarray technology, in a design that will enable investigation of effects of vaccination, challenge, and pathology level.Results: There were 1,101 genes significantly differentially expressed between severely infected and non-infected groups on day 1 PI and 1,723 on day 5 PI. Very little difference was seen between mildly infected and non-infected groups on either time point. Between birds exhibiting mild and severe pathology, there were 2 significantly differentially expressed genes on day 1 PI and 799 on day 5 PI. Groups with greater pathology had more genes with increased expression than decreased expression levels. Several predominate immune pathways, Toll-like receptor, Jak-STAT, and cytokine signaling, were represented between challenged and non-challenged groups. Vaccination had, surprisingly, no detectible effect on gene expression, although it significantly protected the birds from observable gross lesions. Functional characterization of significantly expressed genes revealed unique gene ontology classifications during each time point, with many unique to a particular treatment or class contrast.Conclusions: More severe pathology caused by APEC infection was associated with a high level of gene expression differences and increase in gene expression levels. Many of the significantly differentially expressed genes were unique to a particular treatment, pathology level or time point. The present study not only investigates the transcriptomic regulations of APEC infection, but also the degree of pathology associated with that infection. This study will allow for greater discovery into host mechanisms for disease resistance, providing targets for marker assisted selection and advanced drug development.
Bibliographical noteFunding Information:
The authors acknowledge the large group of researchers and students in “Team E. coli“ involved in collecting numerous tissues for this experiment and Michael Kaiser for technical assistance in qPCR validation and mentorship of EB. This work was supported by National Research Initiative Competitive Grant no. 2008-35604-18805 from the USDA National Institute of Food and Agriculture Microbial Genome Program. ES support provided by USDA National Needs Graduate Fellowship Competitive Grant No. 2007-38420-17767 from the National Institute of Food and Agriculture. EB support National Science Foundation Research Experience for Undergraduates DBI-0552371. NB support provided by USDA National Needs Graduate Fellowship Competitive Grant No. 2010-38420-20328.