Wednesday, March 9, 2011

New method for infectious diseases research

 Infectious diseases researchers at Umea University in Sweden are studying the surface properties of bacteria together with materials scientists. Studies of the outermost parts of the cell walls of bacteria yield new information about the chemical composition of structures that are important for the capacity of bacteria to infect organisms. The findings are now being reported in the Journal of Biological Chemistry.


When bacteria infect a host organism, they usually attach to tissue cells. Infectious diseases scientists at Umea University are studying structural details of the outermost layer of bacterial cells in order to find new substances that can prevent bacterial infections. In collaboration with materials researchers at the Department of Chemistry, they describe new methods that facilitate and speed up their studies.


Chemist Madeleine Ramstedt is pursuing research on a material with new properties that prevent bacteria from attaching to its surface. The new material would be optimal for equipment in health care, where biofilms of bacteria can be a source of infection. In her research, Madeleine Ramstedt uses spectroscopic methods, among others, that she is now making available to her colleagues in the research consortium Umea Centre for Microbial Research, UCMR.


Microbiologists Sun Nyunt Wai, Ryoma Nakao, and Bernt Eric Uhlin, together with chemists Jean-François Boily and Madeleine Ramstedt, were investigating whether new physiochemical analysis methods could also be used for microbial studies. The scientists combined so-called cryo-x-ray photoelectron spectroscopy with multivariate analysis. This analysis yields specific patterns of intensity curves depending on the chemical composition of the surface of the material being studied.


"We've succeeded also in analyzing the cell surfaces of bacteria with our x-ray spectroscopy. We found strong patterns that we could clearly relate to different compositions in lipids, sugar, protein, and the polymer peptidoglycan in the cell wall of the bacterium that can affect the capacity of a bacterium to infect an organism," explains Madeleine Ramstedt. "The method makes it possible to analyze the outermost layer, about 10 nanometers from the surface."


"Our method is relatively simple in comparison with other methods in which the extraction of various cell components is needed. This means that with our method the surface of the bacteria can be examined under more natural conditions in an intact bacterial cell."


X-ray photoelectron spectroscopy has previously been used to study bacteria, but only to a limited extent. The Umea scientists have managed to optimize the method. "We shock freeze the bacteria and keep them frozen throughout the analysis. This allows us to assume that they do not change during the examination. Now it's possible to compare the cell walls in similar bacteria that have been treated in different ways or that have changed, for example by developing resistance. With our method we can now compare structures in cell walls in pathogenic bacteria with those of non-pathogenic bacteria, all on a larger scale. Hopefully this new method of analysis will yield more rapid results and provide infectious diseases researchers with new clues for finding new antibiotics," says Madeleine Ramstedt.


UCMR is one of Umea University's strong research environments. The centre is an interdisciplinary research consortium that brings together a number of research teams in microbial research with participation from chemistry, medical and clinical microbiology, molecular biology, physics, and bioinformatics.


Story Source:


The above story is reprinted (with editorial adaptations) from materials provided by Umea universitet, via AlphaGalileo.

Journal Reference:

M. Ramstedt, R. Nakao, S. N. Wai, B. E. Uhlin, J.-F. Boily. Monitoring surface chemistry changes in the bacterial cell wall - multivariate analysis of Cryo-X-ray photoelectron spectroscopy data. Journal of Biological Chemistry, 2011; DOI: 10.1074/jbc.M110.209536

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