Abstract
BackgroundProbiotics such as bifidobacteria have been shown to maintain a healthy intestinal microbial balance and help protect against infections. However, despite these benefits, bifidobacteria still remain poorly understood at the biochemical, physiological and especially the genetic level. Herein we describe, for the first time, the development of a non-invasive luciferase-based reporter system for real-time tracking of Bifidobacterium species in vivo.ResultsThe reporter vector pLuxMC1 is based on the recently described theta-type plasmid pBC1 from B. catenatulatum [1] and the luxABCDE operon from pPL2lux [2]. Derivatives of pLuxMC1, harbouring a bifidobacterial promoter (pLuxMC2) as well as a synthetically derived promoter (pLuxMC3) [3] placed upstream of luxABCDE, were constructed and found to stably replicate in B. breve UCC2003. The subsequent analysis of these strains allowed us to assess the functionality of pLuxMC1 both in vitro and in vivo.ConclusionOur results demonstrate the potential of pLuxMC1 as a real-time, non-invasive reporter system for Bifidobacterium. It has also allowed us, for the first time, to track the colonisation potential and persistence of this probiotic species in real time. An interesting and significant outcome of the study is the identification of the caecum as a niche environment for B. breve UCC2003 within the mouse gastrointestinal tract (GI) tract.
Highlights
Probiotics such as bifidobacteria have been shown to maintain a healthy intestinal microbial balance and help protect against infections
Our results demonstrate the potential of pLuxMC1 as a real-time, non-invasive reporter system for Bifidobacterium
Functionality and stability of pLuxMC1 derivatives To demonstrate the functionality of the pLuxMC1 luciferase reporter system in B. breve UCC2003, the expression profiles of two promoters and associated translational signals were assessed
Summary
Probiotics such as bifidobacteria have been shown to maintain a healthy intestinal microbial balance and help protect against infections. Despite these benefits, bifidobacteria still remain poorly understood at the biochemical, physiological and especially the genetic level. A significant goal of current research is to understand the complex nature of the probiotic interaction with the innate immune system. BMC Microbiology 2008, 8:161 http://www.biomedcentral.com/1471-2180/8/161 of atopic disease, cancer and pathogenesis [9] Despite these potential beneficial properties and a growing industrial and consumer acceptance, bifidobacteria still remain poorly understood at the biochemical, physiological and especially the genetic level [10,11]. Current efforts in the field of bifidobacterial genetics are focusing on developing vectors for the genetic manipulation of the species in vitro [12,13,14]
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