Abstract
Overcoming lysogenization defect (OLD) proteins constitute a family of uncharacterized nucleases present in bacteria, archaea, and some viruses. These enzymes contain an N-terminal ATPase domain and a C-terminal Toprim domain common amongst replication, recombination, and repair proteins. The in vivo activities of OLD proteins remain poorly understood and no definitive structural information exists. Here we identify and define two classes of OLD proteins based on differences in gene neighborhood and amino acid sequence conservation and present the crystal structures of the catalytic C-terminal regions from the Burkholderia pseudomallei and Xanthamonas campestris p.v. campestris Class 2 OLD proteins at 2.24 Å and 1.86 Å resolution respectively. The structures reveal a two-domain architecture containing a Toprim domain with altered architecture and a unique helical domain. Conserved side chains contributed by both domains coordinate two bound magnesium ions in the active site of B. pseudomallei OLD in a geometry that supports a two-metal catalysis mechanism for cleavage. The spatial organization of these domains additionally suggests a novel mode of DNA binding that is distinct from other Toprim containing proteins. Together, these findings define the fundamental structural properties of the OLD family catalytic core and the underlying mechanism controlling nuclease activity.
Highlights
Phosphoryl transfer reactions are critical for the synthesis and processing of nucleic acids [1]
While the N-terminal region containing the ATPase domain is dispensable for these activities, its presence mediates higher ordered oligomerization of Class 2 Overcoming lysogenization defect (OLD) proteins (Supplementary Figure S1E and F)
We suspect that the ATPase domain may act in a regulatory capacity, controlling how and when the catalytic C-terminal region accesses substrates
Summary
Phosphoryl transfer reactions are critical for the synthesis and processing of nucleic acids [1]. The observed catalytic activity of RNA [5,6] coupled with the presence of two metal ions in the refined structures of alkaline phosphatase [7] and the Klenow fragment with DNA [8] led to the generalized mechanistic hypothesis that metals can substitute for protein side chains in phosphoryl transfer reactions and act as the required general acid and base [9] In this scheme, one metal (metal A) deprotonates the nucleophile while the other (metal B) stabilizes the pentavalent transition state intermediate [2]. Structural characterization of phosphorylhydrolases is necessary for understanding the underlying catalytic strategy employed in each case
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