Edinburgh scientists devise plan to beat viruses
Scientists have developed a new way to target viruses which could increase the effectiveness of antiviral drugs.
Instead of attacking the virus itself, the method developed at Edinburgh University alters the conditions which viruses need to survive and multiply.
By making the site of infection less hospitable, the virus becomes less able to mutate and build up resistance to drugs.
The experts were also able to target more than one virus at the same time.
Viruses take up residence in host cells within the body, which produce proteins that enable the virus to multiply and survive.
The study, published in the journal Proceedings of the National Academy of Sciences, analysed molecules known as micro-RNAs, which regulate how much of these proteins are made.
The scientists were able to manipulate the micro-RNA levels, which enabled them to control a network of proteins and stop viruses from growing.
Most existing antiviral therapies only work against one virus. However, by adapting the virus host environment the researchers were able to target different types of viruses.
It is hoped that the research could lead to new treatments for patients suffering from a range of infections.
Dr Amy Buck, of the university's centre for immunity, infection and evolution, said: "A problem with current antiviral therapies, which generally target the virus, is that viruses can mutate to become resistant.
"Since new viral strains emerge frequently, and many infections are difficult to diagnose and treat, it is important to find new ways of targeting infection.
"Our hope is that we will be able to use host-directed therapies to supplement the natural immune response and disable viruses by taking away what they need to survive."
Scientists studied the herpes family of viruses, which can also cause cancer. They also looked at the Epstein-Barr virus, and the Semliki Forest virus, which is mainly spread by mosquitoes.
Both viruses have different characteristics. Viruses from the herpes family replicate inside the nuclei of cells, while the Semliki Forest multiplies outside the nucleus of a cell.
The study was funded by the Wellcome Trust and the Biotechnology and Biological Sciences Research Council.