Broiler chickens and early life programming: Microbiome transplant-induced cecal community dynamics and phenotypic effects.

The concept of successional trajectories describes how small differences in initial community composition can magnify through time and lead to significant differences in mature communities. For many animals, the types and sources of early-life exposures to microbes have been shown to have significant and long-lasting effects on the community structure and/or function of the microbiome. In modern commercial poultry production, chicks are reared as a single age cohort and do not directly encounter adult birds. This scenario is likely to initiate a trajectory of microbial community development that is significantly different than non-industrial settings where chicks are exposed to a much broader range of environmental and fecal inocula; however, the comparative effects of these two scenarios on microbiome development and function remain largely unknown. In this work, we performed serial transfers of cecal material through multiple generations of birds to first determine if serial transfers exploiting the ceca in vivo, rather than the external environment or artificial incubations, can produce a stable microbial community. Subsequently, we compared microbiome development between chicks receiving this passaged, i.e. host-selected, cecal material orally, versus an environmental inoculum, to test the hypothesis that the first exposure of newly hatched chicks to microbes determines early GI microbiome structure and may have longer-lasting effects on bird health and development. Cecal microbiome dynamics and bird weights were tracked for a two-week period, with half of the birds in each treatment group exposed to a pathogen challenge at 7 days of age. We report that: i) a relatively stable community was derived after a single passage of transplanted cecal material, ii) this cecal inoculum significantly but ephemerally altered community structure relative to the environmental inoculum and PBS controls, and iii) either microbiome transplant administered at day-of-hatch appeared to have some protective effects against pathogen challenge relative to uninoculated controls. Differentially abundant taxa identified across treatment types may inform future studies aimed at identifying strains associated with beneficial phenotypes.

The cecal microbiome of commercial broiler chickens varies significantly by season.

Next-generation DNA sequencing is rapidly becoming a powerful tool for food animal management. One valuable use of this technology is to re-examine long-standing observations of performance differences associated with animal husbandry practices to better understand how these differences may be modulated by the gastrointestinal (GI) microbiome. The influences of environmental parameters such as air temperature and relative humidity on broiler chicken performance have commonly been observed, but how the GI microbiome may respond to seasonal environmental changes remains largely unknown. The purposes of this study were therefore to: (1) characterize the cecal microflora of commercial broilers (N = 87) collected at harvest across all 4 seasons, and (2) identify any significant changes of the GI microbiome and specific taxa according to season and Campylobacter status. Finding taxa with significant positive or negative correlations with Campylobacter could be useful by identifying indicator or antagonistic taxa and could also inform inferences regarding the ecological niche of Campylobacter. Whole GI tracts were removed from commercial broilers representing 87 independent flocks between April 2013 and May 2014 in the U.S. state of Georgia. Intact ceca were separated, cultured for Campylobacter and cecal contents were frozen. The cecal microbiome was characterized using barcoded sequencing of 16S rRNA genes on the Illumina MiSeq platform. The composition of the microbiome measured at processing was generally not affected by Campylobacter status but was most significantly affected by season of grow-out. Significantly fewer bacterial genera were found in winter than spring or summer. Bacterial genera with prior evidence for both positive or negative influences on gut health outcomes were significantly less abundant in the fall. Identifying specific members of the GI microbiota that vary according to season may help develop novel interventions to improve husbandry practices and growth performance.