Scientists at Imperial College London have identified four new
proteins that act as receptors for an essential signalling molecule in
bacteria such as MRSA.
The receptors are thought to play an important role in enabling
bacteria to respond to their environment. Their discovery provides
scientists with vital clues in the hunt for new antibiotics, which are
increasingly in need as bacteria become resistant to existing
treatments.
The bacterium Staphylococcus aureus causes life-threatening diseases in hospital patients and in previously healthy people. Methicillin-resistant S. aureus strains, known as MRSA, are especially difficult to treat due to their antibiotic resistance.
Scientists are eager to understand the chemical processes that allow
bacteria to respond to changes in their environment. Interfering with
these processes could help prevent bacteria from surviving inside the
human body.
A recently discovered molecule called c-di-AMP appears to play a
vital role as a messenger in many bacteria, carrying signals between
parts of the cell. There is evidence that strains with more c-di-AMP are
more resistant to antibiotics. But until now, very little was known
about what processes in cells are regulated by c-di-AMP.
“What makes this molecule special and a bit different from others
like it is that there is now growing evidence that many bacteria need to
produce this molecule in order to grow and divide, so it’s an essential
component of the cell,” said Dr Angelika Gründling from the MRC Centre
for Molecular Bacteriology and Infection at Imperial College London, who
led the new study in collaboration with Dr Vincent Lee from the
University of Maryland USA.
Signalling molecules work by binding to specific receptor proteins,
which act as switches for cellular functions. “So the real key to
understanding what pathways are controlled by c-di-AMP, and therefore
help us to understand why this molecule is important for the growth of
bacteria, is to find these target proteins,” Dr Gründling said.
In the new study, published in Proceedings of the National Academy of Sciences, Dr Gründling and her colleagues pinpointed four receptors for c-di-AMP in S. aureus. Similar proteins are found in many other bacterial species, several of which can also cause disease in humans.
Dr Rebecca Corrigan, a postdoctoral researcher at Imperial who worked
on the study, said: “This is really exciting news for the field, as we
now have the first clues as to which cellular pathways we need to focus
on in order to understand why this molecule is so important for the
growth of S. aureus.”
“We hope that these findings can be exploited in the future to
develop new antibiotics that target the cellular pathways controlled by
c-di-AMP. Such drugs might be effective against a broad spectrum of
bacteria.”
Dr Gründling added: “There is now also increasing evidence that S. aureus strains with high c-di-AMP levels show increased resistance to methicillin-type antibiotics. This indicates that c-di-AMP might help bacteria to better survive antibiotic treatment and by inhibiting c-di-AMP synthesis we might be able to increase the effectiveness of certain antibiotics.”
This research project was funded by the Wellcome Trust, European Research Council and EMBO.
R.M. Corrigan et al. ‘Systematic identification of conserved bacterial c-di-AMP receptor proteins’ PNAS, 13 May 2013.
Source: AlphaGalileo