Substrate analogs that trap the 2'-phospho-ADP-ribosylated RNA intermediate of the Tpt1 (tRNA 2'-phosphotransferase) reaction pathway.

The enzyme Tpt1 removes an internal RNA 2'-PO4 via a two-step reaction in which: (i) the 2'-PO4 attacks NAD+ to form an RNA-2'-phospho-(ADP-ribose) intermediate and nicotinamide; and (ii) transesterification of the ADP-ribose O2″ to the RNA 2'-phosphodiester yields 2'-OH RNA and ADP-ribose-1″,2″-cyclic phosphate. Because step 2 is much faster than step 1, the ADP-ribosylated RNA intermediate is virtually undetectable under normal circumstances. Here, by testing chemically modified nucleic acid substrates for activity with bacterial Tpt1 enzymes, we find that replacement of the ribose-2'-PO4 nucleotide with arabinose-2'-PO4 selectively slows step 2 of the reaction pathway and results in the transient accumulation of high levels of the reaction intermediate. We report that replacing the NMN ribose of NAD+ with 2'-fluoroarabinose (thereby eliminating the ribose O2″ nucleophile) results in durable trapping of RNA-2'-phospho-(ADP-fluoroarabinose) as a "dead-end" product of step 1. Tpt1 enzymes from diverse taxa differ in their capacity to use ara-2″F-NAD+ as a substrate.

Structure-Function Analysis of the Phosphoesterase Component of the Nucleic Acid End-Healing Enzyme Runella slithyformis HD-Pnk.

Runella slithyformis HD-Pnk is the prototype of a family of dual 5' and 3' nucleic acid end-healing enzymes that phosphorylate 5'-OH termini and dephosphorylate 2',3'-cyclic-PO4, 3'-PO4, and 2'-PO4 ends. HD-Pnk is composed of an N-terminal HD phosphohydrolase module and a C-terminal P-loop polynucleotide kinase module. Here, we probed the phosphoesterase activity of HD-Pnk by querying its ability to hydrolyze non-nucleic acid phosphoester substrates and by conducting a mutational analysis of conserved amino acid constituents of the HD domain. We report that HD-Pnk catalyzes vigorous hydrolysis of p-nitrophenylphosphate (Km = 3.13 mM; kcat = 27.8 s-1) using copper as its metal cofactor. Mutagenesis identified Gln28, His33, His73, Asp74, Lys77, His94, His127, Asp162, and Arg166 as essential for p-nitrophenylphosphatase and DNA 3' phosphatase activities. Structural modeling places these residues at the active site, wherein His33, His73, Asp74, His94, and His127 are predicted to coordinate a binuclear metal complex and Lys77 and Arg166 engage the scissile phosphate. HD-Pnk homologs are distributed broadly (and exclusively) in bacteria, usually in a two-gene cluster with a putative ATP-dependent polynucleotide ligase (LIG). We speculate that HD-Pnk and LIG comprise the end-healing and end-sealing components of a bacterial nucleic acid repair pathway.IMPORTANCE 5'-end healing and 3'-end healing are key steps in nucleic acid break repair in which 5'-OH ends are phosphorylated by a polynucleotide kinase, and 3'-PO4 or 2',3'-cyclic-PO4 ends are hydrolyzed by a phosphoesterase to generate 5'-PO4 and 3'-OH termini needed for joining by DNA and RNA ligases. This study interrogates, biochemically and via mutagenesis, the phosphoesterase activity of Runella slithyformis HD-Pnk, a bifunctional bacterial 5'- and 3'-end-healing enzyme composed of HD phosphoesterase and P-loop kinase modules. HD-Pnk homologs are found in 129 bacterial genera from 11 phyla. In 123/129 instances, HD-Pnk is encoded in an operon-like gene cluster with a putative ATP-dependent polynucleotide ligase (LIG), suggesting that HD-Pnk and LIG are agents of a conserved bacterial nucleic acid repair pathway.

NAD+-dependent RNA terminal 2' and 3' phosphomonoesterase activity of a subset of Tpt1 enzymes.

The enzyme Tpt1 removes the 2'-PO4 at the splice junction generated by fungal tRNA ligase; it does so via a two-step reaction in which (i) the internal RNA 2'-PO4 attacks NAD+ to form an RNA-2'-phospho-ADP-ribosyl intermediate; and (ii) transesterification of the ribose O2″ to the 2'-phosphodiester yields 2'-OH RNA and ADP-ribose-1″,2″-cyclic phosphate products. The role that Tpt1 enzymes play in taxa that have no fungal-type RNA ligase remains obscure. An attractive prospect is that Tpt1 enzymes might catalyze reactions other than internal RNA 2'-PO4 removal, via their unique NAD+-dependent transferase mechanism. This study extends the repertoire of the Tpt1 enzyme family to include the NAD+-dependent conversion of RNA terminal 2' and 3' monophosphate ends to 2'-OH and 3'-OH ends, respectively. The salient finding is that different Tpt1 enzymes vary in their capacity and positional specificity for terminal phosphate removal. Clostridium thermocellum and Aeropyrum pernix Tpt1 proteins are active on 2'-PO4 and 3'-PO4 ends, with a 2.4- to 2.6-fold kinetic preference for the 2'-PO4 The accumulation of a terminal 3'-phospho-ADP-ribosylated RNA intermediate during the 3'-phosphotransferase reaction suggests that the geometry of the 3'-p-ADPR adduct is not optimal for the ensuing transesterification step. Chaetomium thermophilum Tpt1 acts specifically on a terminal 2'-PO4 end and not with a 3'-PO4 In contrast, Runella slithyformis Tpt1 and human Tpt1 are ineffective in removing either a 2'-PO4 or 3'-PO4 end.

Structure of tRNA splicing enzyme Tpt1 illuminates the mechanism of RNA 2'-PO4 recognition and ADP-ribosylation.

Tpt1 is an essential agent of fungal tRNA splicing that removes the 2'-PO4 at the splice junction generated by fungal tRNA ligase. Tpt1 catalyzes a unique two-step reaction whereby the 2'-PO4 attacks NAD+ to form an RNA-2'-phospho-ADP-ribosyl intermediate that undergoes transesterification to yield 2'-OH RNA and ADP-ribose-1″,2″-cyclic phosphate products. Because Tpt1 is inessential in exemplary bacterial and mammalian taxa, Tpt1 is seen as an attractive antifungal target. Here we report a 1.4 Šcrystal structure of Tpt1 in a product-mimetic complex with ADP-ribose-1″-phosphate in the NAD+ site and pAp in the RNA site. The structure reveals how Tpt1 recognizes a 2'-PO4 RNA splice junction and the mechanism of RNA phospho-ADP-ribosylation. This study also provides evidence that a bacterium has an endogenous phosphorylated substrate with which Tpt1 reacts.

NAD+-dependent synthesis of a 5'-phospho-ADP-ribosylated RNA/DNA cap by RNA 2'-phosphotransferase Tpt1.

RNA 2'-phosphotransferase Tpt1 converts an internal RNA 2'-monophosphate to a 2'-OH via a two-step NAD+-dependent mechanism in which: (i) the 2'-phosphate attacks the C1″ of NAD+ to expel nicotinamide and form a 2'-phospho-ADP-ribosylated RNA intermediate; and (ii) the ADP-ribose O2″ attacks the phosphate of the RNA 2'-phospho-ADPR intermediate to expel the RNA 2'-OH and generate ADP-ribose 1″-2″ cyclic phosphate. Tpt1 is an essential component of the fungal tRNA splicing pathway that generates a unique 2'-PO4, 3'-5' phosphodiester splice junction during tRNA ligation. The wide distribution of Tpt1 enzymes in taxa that have no fungal-type RNA ligase raises the prospect that Tpt1 might catalyze reactions other than RNA 2'-phosphate removal. A survey of Tpt1 enzymes from diverse sources reveals that whereas all of the Tpt1 enzymes are capable of NAD+-dependent conversion of an internal RNA 2'-PO4 to a 2'-OH (the canonical Tpt1 reaction), a subset of Tpt1 enzymes also catalyzed NAD+-dependent ADP-ribosylation of an RNA or DNA 5'-monophosphate terminus. Aeropyrum pernix Tpt1 (ApeTpt1) is particularly adept in this respect. One-step synthesis of a 5'-phospho-ADP-ribosylated cap structure by ApeTpt1 (with no subsequent 5'-phosphotransferase step) extends the repertoire of the Tpt1 enzyme family and the catalogue of ADP-ribosylation reactions involving nucleic acid acceptors.

Two-step mechanism and step-arrest mutants of Runella slithyformis NAD+-dependent tRNA 2'-phosphotransferase Tpt1.

Tpt1 catalyzes the transfer of an internal 2'-monophosphate moiety (2'-PO4) from a "branched" 2'-PO4 RNA splice junction to NAD+ to form a "clean" 2'-OH, 3'-5' phosphodiester junction, ADP-ribose 1″-2″ cyclic phosphate, and nicotinamide. First discovered as an essential component of the Saccharomyces cerevisiae tRNA splicing machinery, Tpt1 is widely distributed in nature, including in taxa that have no yeast-like RNA splicing system. Here we characterize the RslTpt1 protein from the bacterium Runella slithyformis, in which Tpt1 is encoded within a putative RNA repair gene cluster. We find that (i) expression of RslTpt1 in yeast complements a lethal tpt1Δ knockout, and (ii) purified recombinant RslTpt1 is a bona fide NAD+-dependent 2'-phosphotransferase capable of completely removing an internal 2'-phosphate from synthetic RNAs. The in vivo activity of RslTpt1 is abolished by alanine substitutions for conserved amino acids Arg16, His17, Arg64, and Arg119. The R64A, R119A, and H17A mutants accumulate high levels of a 2'-phospho-ADP-ribosylated RNA reaction intermediate (2'-P-ADPR, evanescent in the wild-type RslTpt1 reaction), which is converted slowly to a 2'-OH RNA product. The R16A mutant is 300-fold slower than wild-type RslTpt1 in forming the 2'-P-ADPR intermediate. Whereas wild-type RsTpt1 rapidly converts the isolated 2'-P-ADPR intermediate to 2'-OH product in the absence of NAD+, the H17A, R119A, R64A, and R16A mutant are slower by factors of 3, 33, 210, and 710, respectively. Our results identify active site constituents involved in the catalysis of step 1 and step 2 of the Tpt1 reaction pathway.

Characterization of Runella slithyformis HD-Pnk, a Bifunctional DNA/RNA End-Healing Enzyme Composed of an N-Terminal 2',3'-Phosphoesterase HD Domain and a C-Terminal 5'-OH Polynucleotide Kinase Domain.

5'- and 3'-end-healing reactions are key steps in nucleic acid break repair in which 5'-OH ends are phosphorylated by a polynucleotide kinase (Pnk) and 3'-PO4 or 2',3'-cyclic-PO4 ends are hydrolyzed by a phosphoesterase to generate the 5'-PO4 and 3'-OH termini required for sealing by classic polynucleotide ligases. End-healing and sealing enzymes are present in diverse bacterial taxa, often organized as modular units within a single multifunctional polypeptide or as subunits of a repair complex. Here we identify and characterize Runella slithyformis HD-Pnk as a novel bifunctional end-healing enzyme composed of an N-terminal 2',3'-phosphoesterase HD domain and a C-terminal 5'-OH polynucleotide kinase P-loop domain. HD-Pnk phosphorylates 5'-OH polynucleotides (9-mers or longer) in the presence of magnesium and any nucleoside triphosphate donor. HD-Pnk dephosphorylates RNA 2',3'-cyclic phosphate, RNA 3'-phosphate, RNA 2'-phosphate, and DNA 3'-phosphate ends in the presence of a transition metal cofactor, which can be nickel, copper, or cobalt. HD-Pnk homologs are present in genera from 11 bacterial phyla and are often encoded in an operon with a putative ATP-dependent polynucleotide ligase. IMPORTANCE The present study provides insights regarding the diversity of nucleic acid repair strategies via the characterization of Runella slithyformis HD-Pnk as the exemplar of a novel clade of dual 5'- and 3'-end-healing enzymes that phosphorylate 5'-OH termini and dephosphorylate 2',3'-cyclic-PO4, 3'-PO4, and 2'-PO4 ends. The distinctive feature of HD-Pnk is its domain composition, i.e., a fusion of an N-terminal HD phosphohydrolase module and a C-terminal P-loop polynucleotide kinase module. Homologs of Runella HD-Pnk with the same domain composition, same domain order, and similar polypeptide sizes are distributed widely among genera from 11 bacterial phyla.

Structures of bacterial polynucleotide kinase in a michaelis complex with nucleoside triphosphate (NTP)-Mg2+ and 5'-OH RNA and a mixed substrate-product complex with NTP-Mg2+ and a 5'-phosphorylated oligonucleotide.

Clostridium thermocellum polynucleotide kinase (CthPnk), the 5'-end-healing module of a bacterial RNA repair system, catalyzes reversible phosphoryl transfer from a nucleoside triphosphate (NTP) donor to a 5'-OH polynucleotide acceptor, either DNA or RNA. Here we report the 1.5-Šcrystal structure of CthPnk-D38N in a Michaelis complex with GTP-Mg(2+) and a 5'-OH RNA oligonucleotide. The RNA-binding mode of CthPnk is different from that of the metazoan RNA kinase Clp1. CthPnk makes hydrogen bonds to the ribose 2'-hydroxyls of the 5' terminal nucleoside, via Gln51, and the penultimate nucleoside, via Gln83. The 5'-terminal nucleobase is sandwiched by Gln51 and Val129. Mutating Gln51 or Val129 to alanine reduced kinase specific activity 3-fold. Ser37 and Thr80 donate functionally redundant hydrogen bonds to the terminal phosphodiester; a S37A-T80A double mutation reduced kinase activity 50-fold. Crystallization of catalytically active CthPnk with GTP-Mg(2+) and a 5'-OH DNA yielded a mixed substrate-product complex with GTP-Mg(2+) and 5'-PO4 DNA, wherein the product 5' phosphate group is displaced by the NTP γ phosphate and the local architecture of the acceptor site is perturbed.