Methicillin-resistant Staphylococcus aureus, or MRSA, is the bug responsible for several infections in humans ranging from superficial to life-threatening which are difficult to treat because of antibiotic resistance. Now for the first time the scientists have shown that S. aureus, a spherical bacterium with no propulsive tail or appendages, may be capable of a form of ‘active’ motility and moving independently.
Motility is central to bacterial behaviours, such as biofilm formation, virulence and host colonisation so the discovery, published in Scientific Reports could have implications for future clinical treatments.
Dr Steve Diggle from The University of Nottingham’s School of Life Sciences, said: “Our research has focused on observing the formation of dendrites – branch-like structures that emerge from the central colony of bacteria. Using high powered microscopy, we saw that the bacteria can spread across the surface of an agar plate in structures that we have called ‘comets’. These advance outwards and precede the formation of dendrites. We have observed and photographed the comets ‘seeding’ cells behind them, without losing mass, which then grow into observable dendrites.
“After 8 hours of colony growth, the comet heads are the main source of movement. Cells in the tail follow the comet heads for a while while bacteria further away no longer move. Our time-lapse video shows the whole remarkable process.”
The researchers found the comet heads are composed of aggregates of S. aureus cells held together by a matrix of slime and display no observable pili or flagella (propulsive tails or appendages). They also observed that under certain conditions, comets can also etch the agar, leaving behind tracks. The moving S. aureus colonies are also capable of avoiding other colonies. The study also showed that the addition of fluid is not able to effectively move comet heads, but can easily move the cells in the comet ‘tails’.
Dr Eric Pollitt, who also performed the research, said: “It is amazing how the S. aureus cells can stick together and then stay together whilst moving over distances that are incredibly vast compared to the size of the individual cells.”
The team believes these newly observed and time-lapse photographed behaviours are consistent with active motility, and most closely resemble gliding motility. The revelations could inform research into new ways to tackle S.aureus infection as the underlying motility mechanism(s) of the bacteria could be a target for future vaccines and inhibitory pharmaceutical compounds.
The researchers conclude that if S.aureus has true motility as indicated by this work, it would be the first example of a Gram-positive bacteria with a typical Gram-positive cell wall moving without flagella or pili. This begs the question of whether other Gram-positive organisms may also be motile in a similar way and opens the way for further research in the area.
The full research paper is available here.
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Notes to editors: The University of Nottingham has 43,000 students and is ‘the nearest Britain has to a truly global university, with a “distinct” approach to internationalisation, which rests on those full-scale campuses in China and Malaysia, as well as a large presence in its home city.’ (Times Good University Guide 2016). It is also one of the most popular universities in the UK among graduate employers and the winner of ‘Research Project of the Year’ at the Times Higher Education Awards 2014. It is ranked in the world’s top 75 by the QS World University Rankings 2015/16, and 8th in the UK by research power according to the Research Excellence Framework 2014. It has been voted the world’s greenest campus for three years running, according to Greenmetrics Ranking of World Universities.
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