SuperbugsOld drug may hold key to new antibiotics
Scientists have found that an anticonvulsant drug may help in developing a new class of antibiotics. Although dozens of antibiotics target what bacteria do, the scientists have looked at how a certain part of bacteria are created, and they found there is a way of stopping it.
McMaster University scientists have found that an anticonvulsant drug may help in developing a new class of antibiotics. Although dozens of antibiotics target what bacteria do, their study has looked at how a certain part of bacteria are created, and they found there is a way of stopping it.
The discovery is important as there is growing concern worldwide about how antibiotic resistance is making the cures for infections ineffective. The World Health Organization has declared that antibiotic resistance is a major threat to global health security.
A McMaster University release reports that the study found that an anticonvulsant drug called lamotrigine is the first chemical inhibitor of the assembly of ribosomes in bacteria. Ribosomes are the molecular machines in cells that create all proteins. Many antibiotics attack what ribosomes do. The McMaster team found, however, that lamotrigine stopped ribosomes from being created in the first place.
The paper has been published by the open-access journal eLife.
“Ribosome-inhibiting antibiotics have been routinely used for more than fifty years to treat bacterial infections, but inhibitors of bacterial ribosome assembly have waited to be discovered,” said Eric Brown, principal investigator of the study and a professor of biochemistry and biomedical sciences at McMaster’s Michael G. DeGroote Institute for Infectious Disease Research.
“Such molecules would be an entirely new class of antibiotics, which would get around antibiotic resistance of many bacteria. We found lamotrigine works.”
Jonathan Stokes, a Ph.D. student who worked on the paper, added that the team was able to identify the precise target for the lamotrigine within the bacteria, allowing the researchers to be clear in their understanding of ribosome assembly and the therapeutic applications of these types of chemicals.
— Read more in Jonathan M Stokes et al., “Discovery of a small molecule that inhibits bacterial ribosome biogenesis,” eLife (18 September 2014) (DOI: eLife 2014;10.7554/eLife.03574)
