Abstract
Arginine finger is a highly conserved and essential residue in many GTPase and AAA+ ATPase enzymes that completes the active site from a distinct protomer, forming contacts with the γ-phosphate of the nucleotide. To date, no pyrophosphatase has been identified that employs an arginine finger fulfilling all of the above properties; all essential arginine fingers are used to catalyze the cleavage of the γ-phosphate. Here, we identify and unveil the role of a conserved arginine residue in trimeric dUTPases that meets all the criteria established for arginine fingers. We found that the conserved arginine adjacent to the P-loop-like motif enables structural organization of the active site for efficient catalysis via its nucleotide coordination, while its direct electrostatic role in transition state stabilization is secondary. An exhaustive structure-based comparison of analogous, conserved arginines from nucleotide hydrolases and transferases revealed a consensus amino acid location and orientation for contacting the γ-phosphate of the substrate nucleotide. Despite the structurally equivalent position, functional differences between arginine fingers of dUTPases and NTPases are explained on the basis of the unique chemistry performed by the pyrophosphatase dUTPases.
Highlights
Protein−protein interactions play crucial roles in ensuring optimal catalytic activity
On the basis of the following properties, we propose that R140 fulfills the requirements of being an Arg finger: (i) It is a highly conserved residue. (ii) Its mutation seriously compromises the catalytic activity. (iii) It emerges from a separate protein subunit that forms the substrate binding site and establishes interactions with the γ-phosphate of the substrate nucleotide triphosphate (NTP)
We showed that the Arg from the fifth motif (R140) fulfills the criteria used to identify Arg fingers, associating this conserved arginine of dUTPases with Arg fingers for the first time
Summary
Protein−protein interactions play crucial roles in ensuring optimal catalytic activity. Interprotomer interactions often modulate the nucleotide triphosphate (NTP) hydrolysis and transfer reaction rates in NTP processing enzymes, e.g., AAA+ enzymes[1] (ATPases associated with various cellular activities), GTPases,[2] polymerases,[3] kinases,[4,5] and dUTPases[6] (DUT) assembled as homo- or heteropolymers. In many of these enzymes, an essential conserved residue, the arginine (Arg) finger, has been identified as a key entity in catalytic rate acceleration. Experimental data established that even the conservative replacement of the Arg finger[7,15] diminished the catalytic rates while maintaining local structural integrity including P-loop coordination
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