Abstract
DNA phosphorothioation is widespread among prokaryotes, and might function to restrict gene transfer among different kinds of bacteria. There has been little investigation into the structural mechanism of the DNA phosphorothioation process. DndA is a cysteine desulfurase which is involved in the first step of DNA phosphorothioation. In this study, we determined the crystal structure of Streptomyces lividans DndA in complex with its covalently bound cofactor PLP, to a resolution of 2.4 Å. Our structure reveals the molecular mechanism that DndA employs to recognize its cofactor PLP, and suggests the potential binding site for the substrate L-cysteine on DndA. In contrast to previously determined structures of cysteine desulfurases, the catalytic cysteine of DndA was found to reside on a β strand. This catalytic cysteine is very far away from the presumable location of the substrate, suggesting that a conformational change of DndA is required during the catalysis process to bring the catalytic cysteine close to the substrate cysteine. Moreover, our in vitro enzymatic assay results suggested that this conformational change is unlikely to be a simple result of random thermal motion, since moving the catalytic cysteine two residues forward or backward in the primary sequence completely disabled the cysteine desulfurase activity of DndA.
Highlights
DNA phosphorothioation is a unique type of epigenetic modification which occurs on the DNA backbone
DNA phosphorothioation was first discovered in Streptomyces lividans [1,2], and was later found to widely exist in many other kinds of bacteria [3,4]
Structure determination and overall structure of DndA To understand the molecular basis of how DndA performs its function, we tried crystallization on both full length wild type (WT) Streptomyces lividans DndA and a C327S point mutant in which the catalytic cysteine, Cys327, was replaced by a serine
Summary
DNA phosphorothioation is a unique type of epigenetic modification which occurs on the DNA backbone During this process, a sulfur atom replaces a non-bridging oxygen atom of the phosphodiester backbone of DNA. Five proteins (DndA, DndB, DndC, DndD, and DndE) encoded by the dnd gene locus are necessary and sufficient for the process of DNA phosphorothioation in Streptomyces lividans [2,6]. Among these five proteins, DndA has been found to be a cysteine desulfurase, catalyzing the removal of sulfur from the substrate Lcysteine and reconstituting the iron-sulfur cluster in DndC. It has been suggested that the DndA-catalyzed sulfur mobilization is the first step during the DNA phosphorothioation procedure [7]
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