Campylobacter jejuni transmission and colonisation in broiler chickens is inhibited by Faecal Microbiota Transplantation.

BACKGROUND: Campylobacter jejuni , the most frequent cause of foodborne bacterial infection, is found on around 70% of retail chicken. As such there is a need for effective controls in chicken production. Microbial-based controls such as probiotics are attractive to the poultry industry, but of limited efficacy. Furthermore, as commercially-produced chickens have no maternal contact, their pioneer microbiome is likely to come from the hatchery environment. Early delivery of microbials that lead to a more u0026{prime]natural avian′ microbiome may, therefore, improve bird health and reduce susceptibility to C.jejuni colonisation. A faecal microbiota transplant (FMT) was used to transfer a mature cecal microbiome to newly-hatched broiler chicks and its effects on C.jejuni challenge assessed. We used both a seeder-bird infection model that mimics natural bird-to-bird infection alongside a direct-challenge model. We used a 16S rRNA gene sequencing-based approach to characterize the transplant material itself alongside changes to the chicken microbiome following FMT. RESULTS: FMT changes the composition of the chicken intestinal microbiome. We observed little change in species richness following FMT compared to untreated samples, but there is an increase in phylogenetic diversity within those species. The most significant difference in the ceca is an increase in Lactobacilli, although not a major component of the transplant material, suggesting the FMT results in a change in the intestinal milieu as much as a direct change to the microbiome. Upon direct challenge, FMT resulted in lower initial intestinal colonisation with C.jejuni . More significantly, in a seeder-bird challenge of infection transmission, FMT reduced transmission and intestinal colonisation until common UK retail age of slaughter. In a repeat experiment, transmission was completely blocked following FMT treatment. Delayed FMT administration at 7 days of-age had limited effect on colonisation and transmission. CONCLUSIONS: We show that transfer of a whole mature microbiome to newly-hatched chicks reduces transmission and colonisation of C.jejuni . This indicates that modification of the broiler chick microbiome can reduce intestinal colonisation of C.jejuni to levels projected to lead to lower the human infection rate. We believe these findings offer a way to identify key taxa or consortia that are effective in reducing C.jejuni colonisation and improving broiler gut health.