Research performed in collaboration between the University of Copenhagen and the Technical University of Denmark (DTU) focus on a new form of treatment - so-called antivirulence therapy - based on marine bacteria producing Staphylococcus inhibiting compounds.
"The marine compounds effectively inhibit the ability of staphylococci to form toxins and camouflage proteins that prevent our immune system from reacting to an infection. At the same time, marine compounds appear to paralyse a sophisticated communication system that provides staphylococci the opportunity to undertake a coordinated attack on the organism," says Anita Nielsen, PhD. She has published new results in PLOS ONE with Professor Hanne Ingmer from the Department for Veterinary Disease Biology at the University of Copenhagen's Faculty of Health and Medical Sciences.
In the United States, resistant staphylococci cause more deaths than AIDS on an annual basis. Antivirulence therapy protects the body's natural bacterial flora and disarms, so to speak, infectious staphylococci bacteria. In this way, the body's immune system potentially gets a chance to defend itself against infection – and, in the long term, this form of treatment can mean that patients experience fewer harmful side effects.
Potent compound from the Solomon Islands
The researchers have analysed compounds extracted from marine bacteria collected from all over the world on the Galathea 3 expedition, which took place from August 2006 until April 2007. One particular compound, Solonamid B, isolated from a marine bacterium found near the Solomon Islands, is of particular interest.
"Solonamid B inhibits the ability of staphylococci to produce various toxins that break down our blood cells. White blood cells in particular are important in this context, because they participate in the fight against invasive bacteria during an infection. When Solonamid B is added to bacteria, it reduces their toxin production so only a fifth of the white blood cells die that would otherwise succumb to the staphylococci toxins," says Professor Hanne Ingmer.
It has required demanding laboratory work to analyse the compounds that can form the basis for antivirulence therapy in the future. Purification and identification of the Solonamid B used for the cell studies were undertaken in collaboration with DTU. Researchers at DTU extracted the compounds that researchers at University of Copenhagen subsequently tested biologically. Future experiments will show whether the antivirulence compounds also work in animals and human beings.
Researchers often take inspiration from nature, since animals and plants may contain interesting compounds that can inspire the development of pharmaceuticals in the laboratory.
The world's oceans contain enormous biodiversity - and it is a tantalising idea that the sea's biomass contains the pharmaceuticals of the future. But marine organisms are often difficult to obtain, and researchers are entering unknown waters since this research area is relatively new.
Anita Nielsen's PhD project arose by a formalised collaboration between The Technical University of Denmark and the University of Copenhagen. Discovery of bioactive marine bacteria and natural products and their use to promote human health and safety is financed by The Strategic Research Councils Programme Commission for Food, Health and Welfare.