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Researchers from the Indian Institute of Science (IISc), Bangalore have found that cholesterol present in human or animal cell membranes actually aids certain bacterial toxins bind together
to kill cells1. Some bacteria produce toxins that can drill nano-sized holes in membranes of human or animal cells thus killing those cells. A number of steps precede the actual drilling by
these pore forming toxins (PFT). The toxins bind to the membrane, find other toxin molecules around them, form ring-like structures and puncture a hole in the membrane. However, scientists
did not yet know the mechanistic details of all these steps. An interdisciplinary team of IISc scientists studied how a PFT called Cytolysin-A works in the bacteria _Escherichia coli_ . They
looked at how this toxin forms a ring-like pore composed of twelve protein molecules in the membrane of red blood cells. Investigating with a supercomputer and a microscope that can
visualise single molecules of the toxin protein on the membrane, they found that cholesterol in the cell membrane acted like a ‘molecular glue’ between neighboring toxin molecules. This was
critical for the formation of pores. Due to the similarity of these toxins to proteins that cause neurodegenerative disorders such as Alzheimer's and Parkinson's, the findings can
potentially be extrapolated to understand mechanisms associated with these diseases as well, the researchers report. "Our finding elucidates the basis for selective targeting of the
toxin to eukaryotic membranes. Molecular engineering of these signatures could advance application of PFTs in cytolytic therapy," they say.
