Template-dependent nucleotide addition in the reverse (3'-5') direction by Thg1-like protein

The diverse structural modes of tRNA binding and recognition

tRNAs are short noncoding RNAs responsible for decoding mRNA codon triplets, delivering correct amino acids to the ribosome, and mediating polypeptide chain formation. Due to their key roles during translation, tRNAs have a highly conserved shape and large sets of tRNAs are present in all living organisms. Regardless of sequence variability, all tRNAs fold into a relatively rigid three-dimensional L-shaped structure. The conserved tertiary organization of canonical tRNA arises through the formation of two orthogonal helices, consisting of the acceptor and anticodon domains. Both elements fold independently to stabilize the overall structure of tRNAs through intramolecular interactions between the D- and T-arm. During tRNA maturation, different modifying enzymes posttranscriptionally attach chemical groups to specific nucleotides, which not only affect translation elongation rates but also restrict local folding processes and confer local flexibility when required. The characteristic structural features of tRNAs are also employed by various maturation factors and modification enzymes to assure the selection, recognition, and positioning of specific sites within the substrate tRNAs. The cellular functional repertoire of tRNAs continues to extend well beyond their role in translation, partly, due to the expanding pool of tRNA-derived fragments. Here, we aim to summarize the most recent developments in the field to understand how three-dimensional structure affects the canonical and noncanonical functions of tRNA.

Analysis of GTP addition in the reverse (3'-5') direction by human tRNAHis guanylyltransferase

Human tRNA^His guanylyltransferase (HsThg1) catalyzes the 3'-5' addition of guanosine triphosphate (GTP) to the 5'-end (-1 position) of tRNA^His, producing mature tRNA^His In human cells, cytoplasmic and mitochondrial tRNA^His have adenine (A) or cytidine (C), respectively, opposite to G_-1 Little attention has been paid to the structural requirements of incoming GTP in 3'-5' nucleotidyl addition by HsThg1. In this study, we evaluated the incorporation efficiencies of various GTP analogs by HsThg1 and compared the reaction mechanism with that of Candida albicans Thg1 (CaThg1). HsThg1 incorporated GTP opposite A or C in the template most efficiently. In contrast to CaThg1, HsThg1 could incorporate UTP opposite A, and guanosine diphosphate (GDP) opposite C. These results suggest that HsThg1 could transfer not only GTP, but also other NTPs, by forming Watson-Crick (WC) hydrogen bonds between the incoming NTP and the template base. On the basis of the molecular mechanism, HsThg1 succeeded in labeling the 5'-end of tRNA^His with biotinylated GTP. Structural analysis of HsThg1 was also performed in the presence of the mitochondrial tRNA^His Structural comparison of HsThg1 with other Thg1 family enzymes suggested that the structural diversity of the carboxy-terminal domain of the Thg1 enzymes might be involved in the formation of WC base-pairing between the incoming GTP and template base. These findings provide new insights into an unidentified biological function of HsThg1 and also into the applicability of HsThg1 to the 5'-terminal modification of RNAs.

Fidelity of base-pair recognition by a 3'-5' polymerase: mechanism of the Saccharomyces cerevisiae tRNAHis guanylyltransferase

The tRNA^His guanylyltransferase (Thg1) was originally discovered in Saccharomyces cerevisiae where it catalyzes 3'-5' addition of a single nontemplated guanosine (G_-1) to the 5' end of tRNA^His In addition to this activity, S. cerevisiae Thg1 (SceThg1) also catalyzes 3'-5' polymerization of Watson-Crick (WC) base pairs, utilizing nucleotides in the 3'-end of a tRNA as the template for addition. Subsequent investigation revealed an entire class of enzymes related to Thg1, called Thg1-like proteins (TLPs). TLPs are found in all three domains of life and preferentially catalyze 3'-5' polymerase activity, utilizing this unusual activity to repair tRNA, among other functions. Although both Thg1 and TLPs utilize the same chemical mechanism, the molecular basis for differences between WC-dependent (catalyzed by Thg1 and TLPs) and non-WC-dependent (catalyzed exclusively by Thg1) reactions has not been fully elucidated. Here we investigate the mechanism of base-pair recognition by 3'-5' polymerases using transient kinetic assays, and identify Thg1-specific residues that play a role in base-pair discrimination. We reveal that, regardless of the identity of the opposing nucleotide in the RNA "template," addition of a non-WC G_-1 residue is driven by a unique kinetic preference for GTP. However, a secondary preference for forming WC base pairs is evident for all possible templating residues. Similar to canonical 5'-3' polymerases, nucleotide addition by SceThg1 is driven by the maximal rate rather than by NTP substrate affinity. Together, these data provide new insights into the mechanism of base-pair recognition by 3'-5' polymerases.

Chemical footprinting and kinetic assays reveal dual functions for highly conserved eukaryotic tRNAHis guanylyltransferase residues

tRNA^His guanylyltransferase (Thg1) adds a single guanine to the -1 position of tRNA^His as part of its maturation. This seemingly modest addition of one nucleotide to tRNA^His ensures translational fidelity by providing a critical identity element for the histidyl aminoacyl tRNA synthetase (HisRS). Like HisRS, Thg1 utilizes the GUG anticodon for selective tRNA^His recognition, and Thg1-tRNA complex structures have revealed conserved residues that interact with anticodon nucleotides. Separately, kinetic analysis of alanine variants has demonstrated that many of these same residues are required for catalytic activity. A model in which loss of activity with the variants was attributed directly to loss of the critical anticodon interaction has been proposed to explain the combined biochemical and structural results. Here we used RNA chemical footprinting and binding assays to test this model and further probe the molecular basis for the requirement for two critical tRNA-interacting residues, His-152 and Lys-187, in the context of human Thg1 (hThg1). Surprisingly, we found that His-152 and Lys-187 alanine-substituted variants maintain a similar overall interaction with the anticodon region, arguing against the sufficiency of this interaction for driving catalysis. Instead, conservative mutagenesis revealed a new direct function for these residues in recognition of a non-Watson-Crick G_-1:A₇₃ bp, which had not been described previously. These results have important implications for the evolution of eukaryotic Thg1 from a family of ancestral promiscuous RNA repair enzymes to the highly selective enzymes needed for their essential function in tRNA^His maturation.

5'-End sequencing in Saccharomyces cerevisiae offers new insights into 5'-ends of tRNAH is and snoRNAs

tRNA^{H is} guanylyltransferase (Thg1) specifies eukaryotic tRNA^{H is} identity by catalysing a 3'-5' non-Watson-Crick (WC) addition of guanosine to the 5'-end of tRNA^{H is} . Thg1 family enzymes in Archaea and Bacteria, called Thg1-like proteins (TLPs), catalyse a similar but distinct 3'-5' addition in an exclusively WC-dependent manner. Here, a genetic system in Saccharomyces cerevisiae was employed to further assess the biochemical differences between Thg1 and TLPs. Utilizing a novel 5'-end sequencing pipeline, we find that a Bacillus thuringiensis TLP sustains the growth of a thg1Δ strain by maintaining a WC-dependent addition of U_-1 across from A₇₃ . Additionally, we observe 5'-end heterogeneity in S. cerevisiae small nucleolar RNAs (snoRNAs), an observation that may inform methods of annotation and mechanisms of snoRNA processing.

The Role of 3' to 5' Reverse RNA Polymerization in tRNA Fidelity and Repair

The tRNA^His guanylyltransferase (Thg1) superfamily includes enzymes that are found in all three domains of life that all share the common ability to catalyze the 3′ to 5′ synthesis of nucleic acids. This catalytic activity, which is the reverse of all other known DNA and RNA polymerases, makes this enzyme family a subject of biological and mechanistic interest. Previous biochemical, structural, and genetic investigations of multiple members of this family have revealed that Thg1 enzymes use the 3′ to 5′ chemistry for multiple reactions in biology. Here, we describe the current state of knowledge regarding the catalytic features and biological functions that have been so far associated with Thg1 and its homologs. Progress toward the exciting possibility of utilizing this unusual protein activity for applications in biotechnology is also discussed.

Molecular mechanism of substrate recognition and specificity of tRNAHis guanylyltransferase during nucleotide addition in the 3'-5' direction

The tRNA^His guanylyltransferase (Thg1) transfers a guanosine triphosphate (GTP) in the 3'-5' direction onto the 5'-terminal of tRNA^His, opposite adenosine at position 73 (A₇₃). The guanosine at the -1 position (G_-1) serves as an identity element for histidyl-tRNA synthetase. To investigate the mechanism of recognition for the insertion of GTP opposite A₇₃, first we constructed a two-stranded tRNA^His molecule composed of a primer and a template strand through division at the D-loop. Next, we evaluated the structural requirements of the incoming GTP from the incorporation efficiencies of GTP analogs into the two-piece tRNA^His Nitrogen at position 7 and the 6-keto oxygen of the guanine base were important for G_-1 addition; however, interestingly, the 2-amino group was found not to be essential from the highest incorporation efficiency of inosine triphosphate. Furthermore, substitution of the conserved A₇₃ in tRNA^His revealed that the G_-1 addition reaction was more efficient onto the template containing the opposite A₇₃ than onto the template with cytidine (C₇₃) or other bases forming canonical Watson-Crick base-pairing. Some interaction might occur between incoming GTP and A₇₃, which plays a role in the prevention of continuous templated 3'-5' polymerization. This study provides important insights into the mechanism of accurate tRNA^His maturation.

Minimal requirements for reverse polymerization and tRNA repair by tRNAHis guanylyltransferase

tRNA^His guanylyltransferase (Thg1) has unique reverse (3'-5') polymerase activity occurring in all three domains of life. Most eukaryotic Thg1 homologs are essential genes involved in tRNA^His maturation. These enzymes normally catalyze a single 5' guanylation of tRNA^His lacking the essential G^-1 identity element required for aminoacylation. Recent studies suggest that archaeal type Thg1, which includes most archaeal and bacterial Thg1 enzymes is phylogenetically distant from eukaryotic Thg1. Thg1 is evolutionarily related to canonical 5'-3' forward polymerases but catalyzes reverse 3'-5'polymerization. Similar to its forward polymerase counterparts, Thg1 encodes the conserved catalytic palm domain and fingers domain. Here we investigate the minimal requirements for reverse polymerization. We show that the naturally occurring minimal Thg1 enzyme from Ignicoccus hospitalis (IhThg1), which lacks parts of the conserved fingers domain, is catalytically active. And adds all four natural nucleotides to RNA substrates, we further show that the entire fingers domain of Methanosarcina acetivorans Thg1 and Pyrobaculum aerophilum Thg1 (PaThg1) is dispensable for enzymatic activity. In addition, we identified residues in yeast Thg1 that play a part in preventing extended polymerization. Mutation of these residues with alanine resulted in extended reverse polymerization. PaThg1 was found to catalyze extended, template dependent tRNA repair, adding up to 13 nucleotides to a truncated tRNA^His substrate. Sequencing results suggest that PaThg1 fully restored the near correct sequence of the D- and acceptor stem, but also produced incompletely and incorrectly repaired tRNA products. This research forms the basis for future engineering efforts towards a high fidelity, template dependent reverse polymerase.

Crystal structure of tRNAHis guanylyltransferase from Saccharomyces cerevisiae

tRNA maturation involves several steps, including processing, splicing, CCA addition, and posttranscriptional modifications. tRNA^His guanylyltransferase (Thg1) is the only enzyme known to catalyze templated nucleotide addition in the 3'-5' direction, unlike other DNA and RNA polymerases. For a better understanding of its unique catalytic mechanism at the molecular level, we determined the crystal structure of GTP-bound Thg1 from Saccharomyces cerevisiae at the maximum resolution of 3.0 Å. The structure revealed the enzyme to have a tetrameric conformation that is well conserved among different species, and the GTP molecule was clearly bound at the active site, coordinating with two magnesium ions. In addition, two flexible protomers at the potential binding site (PBS) for tRNA^His were observed. We suggest that the PBS of the tetramer could also be one of the sites for interaction with partner proteins.