Team:Sheffield/Project
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Revision as of 23:21, 26 October 2010
iColi: A multi-pathogen detecting biosensor. Quick, visible and simple. The water industry currently complies with statutory testing requirements, a random testing of water at a number of locations throughout the distribution network from water treatment plants to customers’ homes. This is a slow and intensive process requiring access to a laboratory. Even if a pathogen is detected this is usually too late to stop the pathogen reaching customers’ homes and causing potential infections. iColi will be a solution to this problem allowing water companies to make operation changes to prevent a pathogen reaching customers’ taps. By detecting a multitude of pathogens in a matter of minutes, the testing process becomes more streamlined and allows action to be taken following the discovery of a pathogen in the water. Currently this would best be deployed in service reservoirs where water is stored for approximately 48 hours before being piped to local homes. This allows ample time for samples to be taken, tested with iColi and appropriate action taken. To solve this problem we tried to establish a common link between pathogens which we could exploit to create a biosensor for a variety of waterborne pathogens. This led us to investigate the use of quorum sensing, the communication method of bacteria themselves. To test this principle we settled on a well characterised pathogenic bacteria Vibrio cholarae. Although not a problem in western water supplies, if trials are successful there may be a use for the detection in the developing world to detect cholera in water supplies before they are used. Two different methods were established to attempt to create a biosensor. These will be referred to as the chimeric protein method and the cholera system method. Both rely on the same principles: a quorum sensing molecule activating a pathway which in turn activates a promoter which will be linked to a reporter molecule initially GFP but in final iColi eChromi will be used to give a variety of visible results. Chimeric protein method The cholera quorum sensing molecule CAI-1 is detected by the receptor CqsS, which initiates a phosphorylation cascade through a number of other proteins. This protein has some homology with the E.coli stress response receptor BarA which also initiates a series of phosphorlyations, ultimately phosphorylating the response regulator UvrY. By combining the receptor domain of CqsS with the phosphorylation domain of BarA it was hoped that the E.coli’s natural stress response pathway could be hijacked. In addition if a reporter- GFP is placed downstream of the stress response pga promoter, it was hoped that GFP expression could be induced by the binding of the quorum sensing molecule CAi-1. Cholera system method As previously stated the cholera quorum sensing molecule CAI-1 is detected by CqsS initiating a phosphorylation cascade of proteins LuxO and Lux U which in turn activate the promoter sequences HapR and CsrB. Rather than hijack the E.coli stress response pathway, the whole cholera quorum detection pathway was inserted into E.coli on a plasmid in addition to the promoter sequence for HapR or CsrB with a downstream GFP reporter.
RESULTS References- • ‘CsrA post-translationally represses pgaABCD, responsible for synthesis of a biofilm polysaccharide adhesion of E.coli’ – Xin Wang et al, Molecular Microbiology (2005) 56 (6), 1648-1663. • ‘The pgaABCD locus of E.coli promotes the synthesis of a polysaccharide adhesion required for biofilm formation’- Xin Wang et al, Journal of Bacteriology, May 2004, p2724-2734. • ‘Global regulation by the small RNA-binding protein CsrA and the non-coding RNA molecule CsrB’- Tony Romeo, Molecular Microbiology (1998) 29 (6), 1321-1330. • www.conncoll.edu/ccacad/zimmer/GFP-ww/prasher.html |