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Hijacking bacteria's natural defences to trap and reveal pathogens

   
   
E coli
12 May 2014 11:07:43.047
PA 127/14

Bad bacteria could soon have no place left to hide, thanks to new materials that turn the cell’s own defences against them.

Scientists at The University of Nottingham and GSK Consumer Healthcare have developed a technique that could locate the potential source of an infection by hijacking the normal processes of pathogens, thus revealing their location.

And by using fluorescent markers to tag these cells, they have even been able to detect them by using a simple mobile phone camera.

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Hjacking bacterial machinery

The breakthrough, published in the journal Nature Materials, could offer an easier way of detecting pathogenic bacteria outside of a clinical setting and could be particularly important for the developing world, where access to more sophisticated laboratory techniques is often limited.

The research was led by Professor Cameron Alexander, Head of the Division of Drug Delivery and Tissue Engineering and EPSRC Leadership Fellow in the University’s School of Pharmacy, building on work by PhD student Peter Magennis. Professor Alexander said: “Essentially, we have hijacked some of the metabolic machinery which bacteria use to control their environment, and used it instead to grow polymers which bind strongly to the specific bacteria that produce them.

“The neat thing about this is that the functionality of the polymers grown on the surface of the bacteria is programmed by the cells so that they can recognise their own ’kind’. We used fluorescent labels to light up the polymers and were able to capture this labelling using a mobile phone camera, so in principle it could be possible to use these materials as point-of-care diagnostics for pathogenic bacteria.”

The study has shown that the bacteria helped to synthesise polymers on their own surfaces which not only were different from those made by conventional methods, but which retained a form of ‘structural memory’ of that surface. This means in future it should be possible to make specific detection agents or additives for topical anti-infectives that target a number of harmful bacteria all by a common route.

Rapidly identifying pathogens

“The initial focus of the research was to explore ways to use synthetic polymers to selectively target and bind the bacteria that cause dental cavities and periodontal diseases in order to facilitate their removal from the oral cavity,” said Dr David Churchley, Principal Scientist, Oral Health Category Research and Development, GSK Consumer Healthcare. “As we continued our work, we saw that our research had broader implications and potential for a wider range of uses.”

Rapidly identifying harmful bacteria at the heart of a serious medical or dental condition can be a difficult and costly task. The group’s findings may even lead to new ways of treating bacterial infections. “These types of polymers may be designed to contain antibacterial functionalities so that they specifically bind to and kill bacterial pathogens,” said Dr Klaus Winzer, a microbiologist at The University of Nottingham involved in the study. The selective binding of specific bacterial species and/or strains in current practice requires expensive ‘cold-chain’ reagents such as antibodies which often preclude using these processes outside of a hospital setting or in developing nations.

The new approach, termed ‘bacterial-instructed synthesis’, has the potential for use in the developing world, in the field or in less specialised laboratory settings.

Dr David Bradshaw, Principal Scientist, Oral Health Category Research and Development, GSK Consumer Healthcare, said: “The ingredients used to form the polymers are all easy to obtain, inexpensive and widely available. With the simplicity and accessibility of the chemistry, a number of diagnostic and other applications may be possible.”

The study was funded by a Biotechnology and Biological Sciences Research Council (BBSRC) GSK Consumer Healthcare CASE studentship, and Professor Alexander’s Engineering and Physical Research Council (EPSRC) Leadership Fellowship.

The paper will be accessible on the Nature Materials website at http://dx.doi.org/10.1038/nmat3949

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Notes to editors: The University of Nottinghamhas 43,000 students and is ‘the nearest Britain has to a truly global university, with campuses in China and Malaysia modelled on a headquarters that is among the most attractive in Britain’ (Times Good University Guide 2014). It is also the most popular university among graduate employers, the world’s greenest university, and winner of the Times Higher Education Award for ‘Outstanding Contribution to Sustainable Development’. It is ranked in the World's Top 75 universities by the QS World University Rankings.

Impact: The Nottingham Campaign, its biggest-ever fundraising campaign, is delivering the University’s vision to change lives, tackle global issues and shape the future. More news…

Story credits

More information is available from Professor Cameron Alexander on +44 (0)115 846 7678, cameron.alexander@nottingham.ac.uk
Emma Thorne

Emma Thorne - Media Relations Manager

Email: emma.thorne@nottingham.ac.uk Phone: +44 (0)115 951 5793 Location: University Park

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