The Experts below are selected from a list of 282 Experts worldwide ranked by ideXlab platform
Stewart Shuman - One of the best experts on this subject based on the ideXlab platform.
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Crystal structure of vaccinia virus mRNA capping enzyme provides insights into the mechanism and evolution of the capping apparatus
Structure, 2014Co-Authors: O.j.p. Kyrieleis, Stewart Shuman, Jonathan Chang, Marcos De La Peña, Stephen CusackAbstract:Summary Vaccinia virus capping enzyme is a heterodimer of D1 (844 aa) and D12 (287 aa) polypeptides that executes all three steps in m 7 GpppRNA synthesis. The D1 subunit comprises an N-terminal RNA triphosphatase (TPase)-guanylyltransferase (GTase) module and a C-terminal guanine-N7-methyltransferase (MTase) module. The D12 subunit binds and allosterically stimulates the MTase module. Crystal structures of the complete D1⋅D12 heterodimer disclose the TPase and GTase as members of the triphosphate tunnel metalloenzyme and covalent nucleotidyltransferase superfamilies, respectively, albeit with distinctive active site features. An extensive TPase-GTase interface clamps the GTase nucleotidyltransferase and OB-fold domains in a closed conformation around GTP. Mutagenesis confirms the importance of the TPase-GTase interface for GTase activity. The D1⋅D12 structure complements and rationalizes four decades of biochemical studies of this enzyme, which was the first capping enzyme to be purified and characterized, and provides new insights into the origins of the capping systems of other large DNA viruses.
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the adenylyltransferase domain of bacterial pnkp defines a unique rna ligase family
Proceedings of the National Academy of Sciences of the United States of America, 2012Co-Authors: Paul Smith, Pravin A Nair, Li Kai Wang, Stewart ShumanAbstract:Pnkp is the end-healing and end-sealing component of an RNA repair system present in diverse bacteria from ten different phyla. To gain insight to the mechanism and evolution of this repair system, we determined the crystal structures of the ligase domain of Clostridium thermocellum Pnkp in three functional states along the reaction pathway: apoenzyme, ligase•ATP substrate complex, and covalent ligase-AMP intermediate. The tertiary structure is composed of a classical ligase nucleotidyltransferase module that is embellished by a unique α-helical insert module and a unique C-terminal α-helical module. Structure-guided mutational analysis identified active site residues essential for ligase adenylylation. Pnkp defines a new RNA ligase family with signature structural and functional properties.
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Structural Insights to How Mammalian Capping Enzyme Reads the CTD Code
Molecular Cell, 2011Co-Authors: Agnidipta Ghosh, Stewart Shuman, Christopher D. LimaAbstract:Summary Physical interaction between the phosphorylated RNA polymerase II carboxyl-terminal domain (CTD) and cellular capping enzymes is required for efficient formation of the 5′ mRNA cap, the first modification of nascent mRNA. Here, we report the crystal structure of the RNA guanylyltransferase component of mammalian capping enzyme (Mce) bound to a CTD phosphopeptide. The CTD adopts an extended β-like conformation that docks Tyr1 and Ser5-PO 4 onto the Mce nucleotidyltransferase domain. Structure-guided mutational analysis verified that the Mce-CTD interface is a tunable determinant of CTD binding and stimulation of guanylyltransferase activity, and of Mce function in vivo. The location and composition of the CTD binding site on mammalian capping enzyme is distinct from that of a yeast capping enzyme that recognizes the same CTD primary structure. Thus, capping enzymes from different taxa have evolved different strategies to read the CTD code.
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sequence specific 1hn 13c and 15n backbone resonance assignments of the 34 kda paramecium bursaria chlorella virus 1 pbcv1 dna ligase
Biomolecular Nmr Assignments, 2009Co-Authors: Andrea Piserchio, Stewart Shuman, Pravin A Nair, Ranajeet GhoseAbstract:Chlorella virus DNA ligase (ChVLig) is a minimal (298-amino acid) pluripotent ATP-dependent ligase composed of three structural modules—a nucleotidyltransferase domain, an OB domain, and a β-hairpin latch—that forms a circumferential clamp around nicked DNA. ChVLig provides an instructive model to understand the chemical and conformational steps of nick repair. Here we report the assignment of backbone 13C, 15N, 1HN resonances of this 34.2 kDa protein, the first for a DNA ligase in full-length form.
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The polynucleotide ligase and RNA capping enzyme superfamily of covalent Nucleotidyltransferases.
Current Opinion in Structural Biology, 2004Co-Authors: Stewart Shuman, Christopher D. LimaAbstract:ATP- and NAD+-dependent DNA ligases, ATP-dependent RNA ligases and GTP-dependent mRNA capping enzymes comprise a superfamily of proteins that catalyze nucleotidyl transfer to polynucleotide 5′ ends via covalent enzyme-(lysyl-N)–NMP intermediates. The superfamily is defined by five peptide motifs that line the nucleotide-binding pocket and contribute amino acid sidechains essential for catalysis. Early crystal structures revealed a shared core tertiary structure for DNA ligases and capping enzymes, which are composed minimally of a nucleotidyltransferase domain fused to a distal OB-fold domain. Recent structures of viral and bacterial DNA ligases, and a fungal mRNA capping enzyme underscore how the substrate-binding and chemical steps of the ligation and capping pathways are coordinated with large rearrangements of the component protein domains and with remodeling of the atomic contacts between the enzyme and the nucleotide at the active site. The first crystal structure of an RNA ligase suggests that contemporary DNA ligases, RNA ligases and RNA capping enzymes evolved by fusion of ancillary effector domains to an ancestral catalytic module involved in RNA repair.
Christopher D. Lima - One of the best experts on this subject based on the ideXlab platform.
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Structural Insights to How Mammalian Capping Enzyme Reads the CTD Code
Molecular Cell, 2011Co-Authors: Agnidipta Ghosh, Stewart Shuman, Christopher D. LimaAbstract:Summary Physical interaction between the phosphorylated RNA polymerase II carboxyl-terminal domain (CTD) and cellular capping enzymes is required for efficient formation of the 5′ mRNA cap, the first modification of nascent mRNA. Here, we report the crystal structure of the RNA guanylyltransferase component of mammalian capping enzyme (Mce) bound to a CTD phosphopeptide. The CTD adopts an extended β-like conformation that docks Tyr1 and Ser5-PO 4 onto the Mce nucleotidyltransferase domain. Structure-guided mutational analysis verified that the Mce-CTD interface is a tunable determinant of CTD binding and stimulation of guanylyltransferase activity, and of Mce function in vivo. The location and composition of the CTD binding site on mammalian capping enzyme is distinct from that of a yeast capping enzyme that recognizes the same CTD primary structure. Thus, capping enzymes from different taxa have evolved different strategies to read the CTD code.
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A Dual Interface Determines the Recognition of RNA Polymerase II by RNA Capping Enzyme
Journal of Biological Chemistry, 2010Co-Authors: Man-hee Suh, Peter Meyer, Mincheng Zhang, Craig D. Kaplan, Christopher D. LimaAbstract:RNA capping enzyme (CE) is recruited specifically to RNA polymerase II (Pol II) transcription sites to facilitate cotranscriptional 5′-capping of pre-mRNA and other Pol II transcripts. The current model to explain this specific recruitment of CE to Pol II as opposed to Pol I and Pol III rests on the interaction between CE and the phosphorylated C-terminal domain (CTD) of Pol II largest subunit Rpb1 and more specifically between the CE nucleotidyltransferase domain and the phosphorylated CTD. Through biochemical and diffraction analyses, we demonstrate the existence of a distinctive stoichiometric complex between CE and the phosphorylated Pol II (Pol IIO). Analysis of the complex revealed an additional and unexpected polymerase-CE interface (PCI) located on the multihelical Foot domain of Rpb1. We name this interface PCI1 and the previously known nucleotidyltransferase/phosphorylated CTD interface PCI2. Although PCI1 and PCI2 individually contribute to only weak interactions with CE, a dramatically stabilized and stoichiometric complex is formed when PCI1 and PCI2 are combined in cis as they occur in an intact phosphorylated Pol II molecule. Disrupting either PCI1 or PCI2 by alanine substitution or deletion diminishes CE association with Pol II and causes severe growth defects in vivo. Evidence from manipulating PCI1 indicates that the Foot domain contributes to the specificity in CE interaction with Pol II as opposed to Pol I and Pol III. Our results indicate that the dual interface based on combining PCI1 and PCI2 is required for directing CE to Pol II elongation complexes.
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The polynucleotide ligase and RNA capping enzyme superfamily of covalent Nucleotidyltransferases.
Current Opinion in Structural Biology, 2004Co-Authors: Stewart Shuman, Christopher D. LimaAbstract:ATP- and NAD+-dependent DNA ligases, ATP-dependent RNA ligases and GTP-dependent mRNA capping enzymes comprise a superfamily of proteins that catalyze nucleotidyl transfer to polynucleotide 5′ ends via covalent enzyme-(lysyl-N)–NMP intermediates. The superfamily is defined by five peptide motifs that line the nucleotide-binding pocket and contribute amino acid sidechains essential for catalysis. Early crystal structures revealed a shared core tertiary structure for DNA ligases and capping enzymes, which are composed minimally of a nucleotidyltransferase domain fused to a distal OB-fold domain. Recent structures of viral and bacterial DNA ligases, and a fungal mRNA capping enzyme underscore how the substrate-binding and chemical steps of the ligation and capping pathways are coordinated with large rearrangements of the component protein domains and with remodeling of the atomic contacts between the enzyme and the nucleotide at the active site. The first crystal structure of an RNA ligase suggests that contemporary DNA ligases, RNA ligases and RNA capping enzymes evolved by fusion of ancillary effector domains to an ancestral catalytic module involved in RNA repair.
Aidan J Doherty - One of the best experts on this subject based on the ideXlab platform.
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primase polymerases are a functionally diverse superfamily of replication and repair enzymes
Nucleic Acids Research, 2015Co-Authors: Thomas A Guilliam, Benjamin A Keen, Nigel C Brissett, Aidan J DohertyAbstract:Until relatively recently, DNA primases were viewed simply as a class of proteins that synthesize short RNA primers requisite for the initiation of DNA replication. However, recent studies have shown that this perception of the limited activities associated with these diverse enzymes can no longer be justified. Numerous examples can now be cited demonstrating how the term 'DNA primase' only describes a very narrow subset of these Nucleotidyltransferases, with the vast majority fulfilling multifunctional roles from DNA replication to damage tolerance and repair. This article focuses on the archaeo-eukaryotic primase (AEP) superfamily, drawing on recently characterized examples from all domains of life to highlight the functionally diverse pathways in which these enzymes are employed. The broad origins, functionalities and enzymatic capabilities of AEPs emphasizes their previous functional misannotation and supports the necessity for a reclassification of these enzymes under a category called primase-polymerases within the wider functional grouping of polymerases. Importantly, the repositioning of AEPs in this way better recognizes their broader roles in DNA metabolism and encourages the discovery of additional functions for these enzymes, aside from those highlighted here.
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Conversion of a DNA ligase into an RNA capping enzyme
Nucleic Acids Research, 1999Co-Authors: Aidan J DohertyAbstract:In eukaryotes, newly synthesised mRNA is 'capped' by the addition of GMP to the 5" end by RNA capping enzymes. Recent structural studies have shown that RNA capping enzymes and DNA ligases have similar protein folds, suggesting a conserved catalytic mechanism. To explore these similarities we have produced a chimeric enzyme comprising the N-terminal domain 1 of a DNA ligase fused to the C-terminal domain 2 of a mRNA capping enzyme. This report shows that this hybrid enzyme retains adenylation activity, characteristic of DNA ligases but, remarkably, the chimera has ATP-dependent mRNA capping activity. This is the first observation of ATP-dependent RNA capping. These results suggest that Nucleotidyltransferases may have evolved from a common ancestral gene.
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crystal structure of an atp dependent dna ligase from bacteriophage t7
Cell, 1996Co-Authors: H S Subramanya, Aidan J Doherty, Stephen R Ashford, Dale B WigleyAbstract:Abstract The crystal structure of the ATP-dependent DNA ligase from bacteriophage T7 has been solved at 2.6 A resolution. The protein comprises two domains with a deep cleft running between them. The structure of a complex with ATP reveals that the nucleotide binding pocket is situated on the larger N-terminal domain, at the base of the cleft between the two domains of the enzyme. Comparison of the overall domain structure with that of DNA methyltransferases, coupled with other evidence, suggests that DNA also binds in this cleft. Since this structure is the first of the nucleotidyltransferase superfamily, which includes the eukaryotic mRNA capping enzymes, the relationship between the structure of DNA ligase and that of other Nucleotidyltransferases is also discussed.
Mario Morl - One of the best experts on this subject based on the ideXlab platform.
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cca addition gone wild unusual occurrence and phylogeny of four different trna Nucleotidyltransferases in acanthamoeba castellanii
Molecular Biology and Evolution, 2021Co-Authors: Lieselotte Erber, Heike Betat, Mario MorlAbstract:tRNAs are important players in the protein synthesis machinery, where they act as adapter molecules for translating the mRNA codons into the corresponding amino acid sequence. In a series of highly conserved maturation steps, the primary transcripts are converted into mature tRNAs. In the amoebozoan Acanthamoeba castellanii, a highly unusual evolution of some of these processing steps was identified that are based on unconventional RNA polymerase activities. In this context, we investigated the synthesis of the 3'-terminal CCA-end that is added posttranscriptionally by a specialized polymerase, the tRNA nucleotidyltransferase (CCA-adding enzyme). The majority of eukaryotic organisms carry only a single gene for a CCA-adding enzyme that acts on both the cytosolic and the mitochondrial tRNA pool. In a bioinformatic analysis of the genome of this organism, we identified a surprising multitude of genes for enzymes that contain the active site signature of eukaryotic/eubacterial tRNA Nucleotidyltransferases. In vitro activity analyses of these enzymes revealed that two proteins represent bona fide CCA-adding enzymes, one of them carrying an N-terminal sequence corresponding to a putative mitochondrial target signal. The other enzymes have restricted activities and represent CC- and A-adding enzymes, respectively. The A-adding enzyme is of particular interest, as its sequence is closely related to corresponding enzymes from Proteobacteria, indicating a horizontal gene transfer. Interestingly, this unusual diversity of nucleotidyltransferase genes is not restricted to Acanthamoeba castellanii but is also present in other members of the Acanthamoeba genus, indicating an ancient evolutionary trait.
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cold adaptation of trna Nucleotidyltransferases a tradeoff in activity stability and fidelity
RNA Biology, 2018Co-Authors: Felix G M Ernst, Heike Betat, Lieselotte Erber, Joana Sammler, Frank Juhling, Mario MorlAbstract:Cold adaptation is an evolutionary process that has dramatic impact on enzymatic activity. Increased flexibility of the protein structure represents the main evolutionary strategy for efficient cat...
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the ancestor of modern holozoa acquired the cca adding enzyme from alphaproteobacteria by horizontal gene transfer
Nucleic Acids Research, 2015Co-Authors: Heike Betat, Tobias Mede, Sandy Tretbar, Lydia Steiner, Peter F Stadler, Mario Morl, Sonja J ProhaskaAbstract:Transfer RNAs (tRNAs) require the absolutely conserved sequence motif CCA at their 3′-ends, representing the site of aminoacylation. In the majority of organisms, this trinucleotide sequence is not encoded in the genome and thus has to be added post-transcriptionally by the CCA-adding enzyme, a specialized nucleotidyltransferase. In eukaryotic genomes this ubiquitous and highly conserved enzyme family is usually represented by a single gene copy. Analysis of published sequence data allows us to pin down the unusual evolution of eukaryotic CCA-adding enzymes. We show that the CCA-adding enzymes of animals originated from a horizontal gene transfer event in the stem lineage of Holozoa, i.e. Metazoa (animals) and their unicellular relatives, the Choanozoa. The tRNA nucleotidyltransferase, acquired from an α-proteobacterium, replaced the ancestral enzyme in Metazoa. However, in Choanoflagellata, the group of Choanozoa that is closest to Metazoa, both the ancestral and the horizontally transferred CCA-adding enzymes have survived. Furthermore, our data refute a mitochondrial origin of the animal tRNA Nucleotidyltransferases.
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tRNA Nucleotidyltransferases: ancient catalysts with an unusual mechanism of polymerization
Cellular and Molecular Life Sciences, 2010Co-Authors: Heike Betat, Christiane Rammelt, Mario MorlAbstract:RNA polymerases are important enzymes involved in the realization of the genetic information encoded in the genome. Thereby, DNA sequences are used as templates to synthesize all types of RNA. Besides these classical polymerases, there exists another group of RNA polymerizing enzymes that do not depend on nucleic acid templates. Among those, tRNA Nucleotidyltransferases show remarkable and unique features. These enzymes add the nucleotide triplet C–C–A to the 3′-end of tRNAs at an astonishing fidelity and are described as “CCA-adding enzymes”. During this incorporation of exactly three nucleotides, the enzymes have to switch from CTP to ATP specificity. How these tasks are fulfilled by rather simple and small enzymes without the help of a nucleic acid template is a fascinating research area. Surprising results of biochemical and structural studies allow scientists to understand at least some of the mechanistic principles of the unique polymerization mode of these highly unusual enzymes.
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trna Nucleotidyltransferases highly unusual rna polymerases with vital functions
FEBS Letters, 2010Co-Authors: Stefan Vortler, Mario MorlAbstract:tRNA-Nucleotidyltransferases are fascinating and unusual RNA polymerases responsible for the synthesis of the nucleotide triplet CCA at the 3'-terminus of tRNAs. As this CCA end represents an essential functional element for aminoacylation and translation, these polymerases (CCA-adding enzymes) are of vital importance in all organisms. With a possible origin of ancient telomerase-like activity, the CCA-adding enzymes obviously emerged twice during evolution, leading to structurally different, but functionally identical enzymes. The evolution as well as the unique polymerization features of these interesting proteins will be discussed in this review.
Alan M Weiner - One of the best experts on this subject based on the ideXlab platform.
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a single catalytically active subunit in the multimeric sulfolobus shibatae cca adding enzyme can carry out all three steps of cca addition
Journal of Biological Chemistry, 2004Co-Authors: Alan M WeinerAbstract:Abstract The CCA-adding enzyme ATP(CTP):tRNA nucleotidyltransferase builds and repairs the 3′-terminal CCA sequence of tRNA. Although this unusual RNA polymerase has no nucleic acid template, it can construct the CCA sequence one nucleotide at a time using CTP and ATP as substrates. We found previously that tRNA does not translocate along the enzyme during CCA addition (Yue, D., Weiner, A. M., and Maizels, N. (1998) J. Biol. Chem. 273, 29693-29700) and that a single nucleotidyltransferase motif adds all three nucleotides (Shi, P.-Y., Maizels, N., and Weiner, A. M. (1998) EMBO J. 17, 3197-3206). Intriguingly, the CCA-adding enzyme from the archaeon Sulfolobus shibatae is a homodimer that forms a tetramer upon binding two tRNAs. We therefore asked whether the active form of the S. shibatae enzyme might have two quasi-equivalent active sites, one adding CTP and the other ATP. Using an intersubunit complementation approach, we demonstrate that the dimer is active and that a single catalytically active subunit can carry out all three steps of CCA addition. We also locate one UV light-induced tRNA cross-link on the enzyme structure and provide evidence suggesting the location of another. Our data rule out shuttling models in which the 3′-end of the tRNA shuttles from one quasi-equivalent active site to another, demonstrate that tRNA-induced tetramerization is not required for CCA addition, and support a role for the tail domain of the enzyme in tRNA binding.
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u2 small nuclear rna is a substrate for the cca adding enzyme trna nucleotidyltransferase
Journal of Biological Chemistry, 2002Co-Authors: Hyundae D Cho, Kozo Tomita, Tsutomu Suzuki, Alan M WeinerAbstract:The CCA-adding enzyme builds and repairs the 3' terminus of tRNA. Approximately 65% of mature human U2 small nuclear RNA (snRNA) ends in 3'-terminal CCA, as do all mature tRNAs; the other 35% ends in 3' CC or possibly 3' C. The 3'-terminal A of U2 snRNA cannot be encoded because the 3' end of the U2 snRNA coding region is CC/CC, where the slash indicates the last encoded nucleotide. The first detectable U2 snRNA precursor contains 10-16 extra 3' nucleotides that are removed by one or more 3' exonucleases. Thus, if 3' exonuclease activity removes the encoded 3' CC during U2 snRNA maturation, as appears to be the case in vitro, the cell may need to build or rebuild the 3'-terminal A, CA, or CCA of U2 snRNA. We asked whether homologous and heterologous class I and class II CCA-adding enzymes could add 3'-terminal A, CA, or CCA to human U2 snRNA lacking 3'-terminal A, CA, or CCA. The naked U2 snRNAs were good substrates for the human CCA-adding enzyme but were inactive with the Escherichia coli enzyme; activity was also observed on native U2 snRNPs. We suggest that the 3' stem/loop of U2 snRNA resembles a tRNA minihelix, the smallest efficient substrate for class I and II CCA-adding enzymes, and that CCA addition to U2 snRNA may take place in vivo after snRNP assembly has begun.
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Collaboration Between CC- and A-Adding Enzymes to Build and Repair the 3'-Terminal CCA of tRNA in Aquifex aeolicus
Science (New York N.Y.), 2001Co-Authors: Kozo Tomita, Alan M WeinerAbstract:The universal 3'-terminal CCA sequence of all transfer RNAs (tRNAs) is repaired, and sometimes constructed de novo, by the CCA-adding enzyme [ATP(CTP):tRNA nucleotidyltransferase]. This RNA polymerase has no nucleic acid template, yet faithfully builds the CCA sequence one nucleotide at a time using cytidine triphosphate (CTP) and adenosine triphosphate (ATP) as substrates. All previously characterized CCA-adding enzymes from all three kingdoms are single polypeptides with CCA-adding activity. Here, we demonstrate through biochemical and genetic approaches that CCA addition in Aquifex aeolicus requires collaboration between two related polypeptides, one that adds CC and another that adds A.
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the cca adding enzyme has a single active site
Journal of Biological Chemistry, 1998Co-Authors: Alan M Weiner, Nancy MaizelsAbstract:Abstract The CCA-adding enzyme (tRNA nucleotidyltransferase) synthesizes and repairs the 3′-terminal CCA sequence of tRNA. The eubacterial, eukaryotic, and archaeal CCA-adding enzymes all share a single active-site signature motif, which identifies these enzymes as belonging to the nucleotidyltransferase superfamily. Here we show that mutations at Asp-53 or Asp-55 of theSulfolobus shibatae signature sequence abolish addition of both C and A, demonstrating that a single active site is responsible for addition of both nucleotides. Mutations at Asp-106 (and to a lesser extent, at Glu-173 and Asp-215) selectively impaired addition of A, but not C. We have previously demonstrated that the tRNA acceptor stem remains fixed on the surface of the CCA-adding enzyme during C and A addition (Shi, P.-Y., Maizels, N., and Weiner, A. M. (1998)EMBO J. 17, 3197–3206). Taken together with this new evidence that there is a single active site for catalysis, our data suggest that specificity of nucleotide addition is determined by a process of collaborative templating: as the single active site catalyzes addition of each nucleotide, the growing 3′-end of the tRNA would progressively refold to create a binding pocket for addition of the next nucleotide.
