Biologists discover bacterial defense mechanism against aggressive oxygen
Proteins are the most important components of our body’s cells. They aid the chemical reactions in the cell, provide structure and support, and facilitate communication within the organism. However, proteins are particularly sensitive to harmful effects from oxygen (oxidation). This is certainly the case for proteins that contain sulfurous components, with the amino acid cysteine as the basis. This is why the cysteine building blocks often occur as pairs, in which the bond between the two sulfur atoms provides protection. But the cell also contains proteins in which the cysteine building blocks appear alone. How these single cysteines have been protected against oxygen has been unclear. Until now. Studying E. coli, the team of scientists, under the leadership of Jean-François Collet of the de Duve Institute (UCLouvain), has identified how two proteins - DsbG and DsbC - form the basis of an ingenious repair mechanism. Should the cysteine building block of a protein become damaged by oxygen, one of the two proteins takes care of repairing the damage.
Oxygen is vital to the respiration of almost all cells. Among other things, the cells use the gas in the process of burning sugars to produce energy. But oxygen is a very aggressive molecule and can do serious harm to the cell’s building blocks. This damage can be compared to the rusting or oxidation of iron. “Sulfurous proteins are extra-sensitive to oxidation,” explains Joris Messens (VIB / the Vrije Universiteit Brussel). “If they become oxidized, they lose their functioning. This research clarifies how the cell arms itself against this event. Scientists have wondered for a long time what the function of DsbG and DsbC is and the difference between them. Now, finally, we have an answer.”
Original publication: Matthieu Depuydt, Stephen E. Leonard, Didier Vertommen, Katleen Denoncin, Pierre Morsomme, Khadija Wahni, Joris Messens, Kate S. Carroll and Jean-François Collet. "A Periplasmic Reducing System Protects Single Cysteine Residues from Oxidation", Science 326, p. 1109-1111.
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