Kinetic mechanism of the Mg2+-dependent nucleotidyl transfer catalyzed by T4 DNA and RNA ligases.

The Mg(2+)-dependent adenylylation of the T4 DNA and RNA ligases was studied in the absence of a DNA substrate using transient optical absorbance and fluorescence spectroscopy. The concentrations of Mg(2+), ATP, and pyrophosphate were systematically varied, and the results led to the conclusion that the nucleotidyl transfer proceeds according to a two-metal ion mechanism. According to this mechanism, only the di-magnesium-coordinated form Mg(2)ATP(0) reacts with the enzyme forming the covalent complex E.AMP. The reverse reaction (ATP synthesis) occurs between the mono-magnesium-coordinated pyrophosphate form MgP(2)O(7)(2-) and the enzyme.MgAMP complex. The nucleotide binding rate decreases in the sequence ATP(4-) > MgATP(2-) > Mg(2)ATP(0), indicating that the formation of the non-covalent enzyme.nucleotide complex is driven by electrostatic interactions. T4 DNA ligase shows notably higher rates of ATP binding and of subsequent adenylylation compared with RNA ligase, in part because it decreases the K(d) of Mg(2+) for the enzyme-bound Mg(2)ATP(0) more than 10-fold. To elucidate the role of Mg(2+) in the nucleotidyl transfer catalyzed by T4 DNA and RNA ligases, we propose a transition state configuration, in which the catalytic Mg(2+) ion coordinates to both reacting nucleophiles: the lysyl moiety of the enzyme that forms the phosphoramidate bond and the alpha-beta-bridging oxygen of ATP.     

Molecular architecture and ligand recognition determinants for T4 RNA ligase

RNA ligase type 1 from bacteriophage T4 (Rnl1) is involved in countering a host defense mechanism by repairing 5'-PO4 and 3'-OH groups in tRNA(Lys). Rnl1 is widely used as a reagent in molecular biology. Although many structures for DNA ligases are available, only fragments of RNA ligases such as Rnl2 are known. We report the first crystal structure of a complete RNA ligase, Rnl1, in complex with adenosine 5'-(alpha,beta-methylenetriphosphate) (AMPcPP). The N-terminal domain is related to the equivalent region of DNA ligases and Rnl2 and binds AMPcPP but with further interactions from the additional N-terminal 70 amino acids in Rnl1 (via Tyr37 and Arg54) and the C-terminal domain (Gly269 and Asp272). The active site contains two metal ions, consistent with the two-magnesium ion catalytic mechanism. The C-terminal domain represents a new all alpha-helical fold and has a charge distribution and architecture for helix-nucleic acid groove interaction compatible with tRNA binding.     

Structure-function analysis of T4 RNA ligase 2

Bacteriophage T4 RNA ligase 2 (Rnl2) exemplifies a polynucleotide ligase family that includes the trypanosome RNA-editing ligases and putative RNA ligases encoded by eukaryotic viruses and archaea. Here we analyzed 12 individual amino acids of Rnl2 that were identified by alanine scanning as essential for strand joining. We determined structure-activity relationships via conservative substitutions and examined mutational effects on the isolated steps of ligase adenylylation and phosphodiester bond formation. The essential residues of Rnl2 are located within conserved motifs that define a superfamily of nucleotidyl transferases that act via enzyme-(lysyl-N)-NMP intermediates. Our mutagenesis results underscore a shared active site architecture in Rnl2-like ligases, DNA ligases, and mRNA capping enzymes. They also highlight two essential signature residues, Glu(34) and Asn(40), that flank the active site lysine nucleophile (Lys(35)) and are unique to the Rnl2-like ligase family.     

Structure and mechanism of RNA ligase

T4 RNA ligase 2 (Rnl2) exemplifies an RNA ligase family that includes the RNA editing ligases (RELs) of Trypanosoma and Leishmania. The Rnl2/REL enzymes are defined by essential signature residues and a unique C-terminal domain, which we show is essential for sealing of 3'-OH and 5'-PO4 RNA ends by Rnl2, but not for ligase adenylation or phosphodiester bond formation at a preadenylated AppRNA end. The N-terminal segment Rnl2(1-249) of the 334 aa Rnl2 protein comprises an autonomous adenylyltransferase/AppRNA ligase domain. We report the 1.9 A crystal structure of the ligase domain with AMP bound at the active site, which reveals a shared fold, catalytic mechanism, and evolutionary history for RNA ligases, DNA ligases, and mRNA capping enzymes.     

Making AppDNA using T4 DNA ligase

5('),5(')-Adenylyl pyrophosphoryl DNA (AppDNA) contains a high-energy pyrophosphate linkage and can be exploited as an activated DNA substrate to derive new DNA enzymes for carrying out various DNA modification reactions. For this reason, enzymatic synthesis of AppDNA is highly desirable. AppDNA is a known intermediate in DNA ligase mediated DNA ligation reactions, but rarely accumulates under normal reaction conditions. Here we report that T4 DNA ligase can quantitatively convert 5(')-phosphoryl DNA donor into AppDNA in the absence of acceptor DNA but in the presence of a template DNA that contains at least one unpaired nucleotide opposite the 5(')-phosphoryl DNA donor site. This adenylylation behavior of T4 DNA ligase is not observed with Thermus aquaticus (Taq) and Escherichia coli DNA ligases. We further found that a donor-template duplex of 11-bp in length is required by T4 DNA ligase for the formation of AppDNA.     

Structure-function analysis of Methanobacterium thermoautotrophicum RNA ligase - engineering a thermostable ATP independent enzyme

ABSTRACT: BACKGROUND: RNA ligases are essential reagents for many methods in molecular biology including NextGen RNA sequencing. To prevent ligation of RNA to itself, ATP independent mutant ligases, defective in self-adenylation, are often used in combination with activated pre-adenylated linkers. It is important that these ligases not have de-adenylation activity, which can result in activation of RNA and formation of background ligation products. An additional useful feature is for the ligase to be active at elevated temperatures. This has the advantage or reducing preferences caused by structures of single-stranded substrates and linkers. RESULTS: To create an RNA ligase with these desirable properties we performed mutational analysis of the archaeal thermophilic RNA ligase from Methanobacterium thermoautotrophicum. We identified amino acids essential for ATP binding and reactivity but dispensable for phosphodiester bond formation with 5' pre-adenylated donor substrate. The motif V lysine mutant (K246A) showed reduced activity in the first two steps of ligation reaction. The mutant has full ligation activity with pre-adenylated substrates but retained the undesirable activity of deadenylation, which is the reverse of step 2 adenylation. A second mutant, an alanine substitution for the catalytic lysine in motif I (K97A) abolished activity in the first two steps of the ligation reaction, but preserved wild type ligation activity in step 3. The activity of the K97A mutant is similar with either pre-adenylated RNA or single-stranded DNA (ssDNA) as donor substrates but we observed two-fold preference for RNA as an acceptor substrate compared to ssDNA with an identical sequence. In contrast, truncated T4 RNA ligase 2, the commercial enzyme used in these applications, is significantly more active using pre-adenylated RNA as a donor compared to pre-adenylated ssDNA. However, the T4 RNA ligases are ineffective in ligating ssDNA acceptors. CONCLUSIONS: Mutational analysis of the heat stable RNA ligase from Methanobacterium thermoautotrophicum resulted in the creation of an ATP independent ligase. The K97A mutant is defective in the first two steps of ligation but retains full activity in ligation of either RNA or ssDNA to a pre-adenylated linker. The ability of the ligase to function at 65 deg C should reduce the constraints of RNA secondary structure in RNA ligation experiments.     

Effect of single amino acid changes in the region of the adenylylation site of T4 RNA ligase

Preparation and analysis of a series of mutants of bacteriophage T4 RNA ligase that carry single amino acid changes at or near the site of covalent reaction with ATP (adenylylation) are described. The mutant proteins were constructed by site-directed mutagenesis of the gene for T4 RNA ligase (g63) cloned in M13 vectors, transfer of the mutant genes into a lambda pL-containing expression plasmid, and subsequent expression in Escherichia coli. The results give further evidence that Lys-99 is the adenylylation site and that the residue is also important to step 3 in the RNA ligase mechanism (ligation between acceptor and adenylylated donor). Mutations at Glu-100 or Asp-101 have no effect on adenylylation, but Asp-101 is shown to be crucial to both step 2 (transfer of adenylyl to donor) and step 3.     

Polymer-stimulated ligation: enhanced ligation of oligo- and polynucleotides by T4 RNA ligase in polymer solutions.

The effects of macromolecular crowding were tested on several reactions catalyzed by T4 RNA ligase. The rate of cyclization of oligoriboadenylates was stimulated up to 10-fold by relatively high concentrations of several polymers (polyethylene glycol (PEG) 8000 or 20,000; bovine plasma albumin; Ficoll 70). In addition, higher concentrations of PEG 8000 or PEG 20,000 allowed the novel formation of large linear products from the oligoriboadenylates. Also stimulated by high concentrations of PEG 8000 were the rate at which T4 RNA ligase joined p(dT)10 to oligoriboadenylates and the rate at which the enzyme activated p(dT)n by transfer of an adenylyl moiety from ATP to the oligonucleotides. These results with T4 RNA ligase are compared to earlier studies on the effects of crowding on DNA ligases.     

Efficient RNA 5'-adenylation by T4 DNA ligase to facilitate practical applications

We describe a simple procedure for RNA 5'-adenylation using T4 DNA ligase. The 5'-monophosphorylated terminus of an RNA substrate is annealed to a complementary DNA strand that has a 3'-overhang of 10 nucleotides. Then, T4 DNA ligase and ATP are used to synthesize 5'-adenylated RNA (5'-AppRNA), which should find use in a variety of practical applications. In the absence of an acceptor nucleic acid strand, the two-step T4 DNA ligase mechanism is successfully interrupted after the adenylation step, providing 40%-80% yield of 5'-AppRNA after PAGE purification with few side products (the yield varies with RNA sequence). Optimized reaction conditions are described for 5'-adenylating RNA substrates of essentially any length including long and structured RNAs, without need for sequestration of the RNA 3'-terminus to avoid circularization. The new procedure is applicable on the preparative nanomole scale. This 5'-adenylation strategy using T4 DNA ligase is a substantial improvement over our recently reported adenylation method that uses T4 RNA ligase, which often leads to substantial amounts of side products and requires careful optimization for each RNA substrate. Efficient synthetic access to 5'-adenylated RNA will facilitate a range of applications by providing substrates for in vitro selection; by establishing a new protocol for RNA 5'-capping; and by providing an alternative approach for labeling RNA with (32)P or biophysical probes at the 5'-terminus.     

Identification of essential residues in Thermus thermophilus DNA ligase.

DNA ligases play a pivotal role in DNA replication, repair and recombination. Reactions catalyzed by DNA ligases consist of three steps: adenylation of the ligase in the presence of ATP or NAD+, transferring the adenylate moiety to the 5'-phosphate of the nicked DNA substrate (deadenylation) and sealing the nick through the formation of a phosphodiester bond. Thermus thermophilus HB8 DNA ligase (Tth DNA ligase) differs from mesophilic ATP-dependent DNA ligases in three ways: (i) it is NAD+ dependent; (ii) its optimal temperature is 65 instead of 37 degrees C; (iii) it has higher fidelity than T4 DNA ligase. In order to understand the structural basis underlying the reaction mechanism of Tth DNA ligase, we performed site-directed mutagenesis studies on nine selected amino acid residues that are highly conserved in bacterial DNA ligases. Examination of these site-specific mutants revealed that: residue K118 plays an essential role in the adenylation step; residue D120 may facilitate the deadenylation step; residues G339 and C433 may be involved in formation of the phosphodiester bond. This evidence indicates that a previously identified KXDG motif for adenylation of eukaryotic DNA ligases [Tomkinson, A.E., Totty, N.F., Ginsburg, M. and Lindahl, T. (1991) Proc. Natl. Acad. Sci. USA, 88, 400-404] is also the adenylation site for NAD+-dependent bacterial DNA ligases. In a companion paper, we demonstrate that mutations at a different Lys residue, K294, may modulate the fidelity of Tth DNA ligase.     

Structure of the adenylation domain of an NAD+-dependent DNA ligase.

BACKGROUND: DNA ligases catalyse phosphodiester bond formation between adjacent bases in nicked DNA, thereby sealing the nick. A key step in the catalytic mechanism is the formation of an adenylated DNA intermediate. The adenyl group is derived from either ATP (in eucaryotes and archaea) or NAD+4 (in bacteria). This difference in cofactor specificity suggests that DNA ligase may be a useful antibiotic target. RESULTS: The crystal structure of the adenylation domain of the NAD+-dependent DNA ligase from Bacillus stearothermophilus has been determined at 2.8 A resolution. Despite a complete lack of detectable sequence similarity, the fold of the central core of this domain shares homology with the equivalent region of ATP-dependent DNA ligases, providing strong evidence for the location of the NAD+-binding site. CONCLUSIONS: Comparison of the structure of the NAD+4-dependent DNA ligase with that of ATP-dependent ligases and mRNA-capping enzymes demonstrates the manifold utilisation of a conserved nucleotidyltransferase domain within this family of enzymes. Whilst this conserved core domain retains a common mode of nucleotide binding and activation, it is the additional domains at the N terminus and/or the C terminus that provide the alternative specificities and functionalities in the different members of this enzyme superfamily.     

Functional characterization of the T4 DNA ligase: a new insight into the mechanism of action.

ATP-dependent DNA ligases are essential enzymes in both DNA replication and DNA repair processes. Here we report a functional characterization of the T4 DNA ligase. One N-terminal and two C-terminal deletion mutants were expressed in Escherichia coli as histidine- tagged proteins. An additional mutant bore a substitution of Lys159 in the active site that abolished ATP binding. All the proteins were tested in biochemical assays for ATP-dependent self-adenylation, DNA binding, nick joining, blunt-end ligation and AMP- dependent DNA relaxation. From this analysis we conclude that binding to DNA is mediated by sequences at both protein ends and plays a key role in the reaction. The enzyme establishes two different complexes with DNA: (i) a transient complex (T.complex) involving the adenylated enzyme; (ii) a stable complex (S.complex) requiring the deadenylated T4 DNA ligase. The formation of an S. complex seems to be relevant during both blunt-end ligation and DNA relaxation. Moreover the inactive His-K159L substitution mutant, although unable to self-adenylate, still possesses AMP-dependent DNA nicking activity.     

T4 RNA ligase catalyzes the synthesis of dinucleoside polyphosphates.

T4 RNA ligase has been shown to synthesize nucleoside and dinucleoside 5'-polyphosphates by displacement of the AMP from the E-AMP complex with polyphosphates and nucleoside diphosphates and triphosphates. Displacement of the AMP by tripolyphosphate (P3) was concentration dependent, as measured by SDS/PAGE. When the enzyme was incubated in the presence of 0.02 mm [alpha-32P] ATP, synthesis of labeled Ap4A was observed: ATP was acting as both donor (Km, microm) and acceptor (Km, mm) of AMP from the enzyme. Whereas, as previously known, ATP or dATP (but not other nucleotides) were able to form the E-AMP complex, the specificity of a compound to be acceptor of AMP from the E-AMP complex was very broad, and with Km values between 1 and 2 mm. In the presence of a low concentration (0.02 mm) of [alpha-32P] ATP (enough to form the E-AMP complex, but only marginally enough to form Ap4A) and 4 mm of the indicated nucleotides or P3, the relative rate of synthesis of the following radioactive (di)nucleotides was observed: Ap4X (from XTP, 100); Ap4dG (from dGTP, 74); Ap4G (from GTP, 49); Ap4dC (from dCTP, 23); Ap4C (from CTP, 9); Ap3A (from ADP, 5); Ap4ddA, (from ddATP, 1); p4A (from P3, 200). The enzyme also synthesized efficiently Ap3A in the presence of 1 mm ATP and 2 mm ADP. The following T4 RNA ligase donors were inhibitors of the synthesis of Ap4G: pCp > pAp > pA2'p.     

Novel DNA ligase with broad nucleotide cofactor specificity from the hyperthermophilic crenarchaeon Sulfophobococcus zilligii: influence of ancestral DNA ligase on cofactor utilization

DNA ligases are divided into two groups according to their cofactor requirement to form ligase-adenylate, ATP-dependent DNA ligases and NAD(+)-dependent DNA ligases. The conventional view that archaeal DNA ligases only utilize ATP has recently been disputed with discoveries of dual-specificity DNA ligases (ATP/ADP or ATP/NAD(+)) from the orders Desulfurococcales and Thermococcales. Here, we studied DNA ligase encoded by the hyperthermophilic crenarchaeon Sulfophobococcus zilligii. The ligase exhibited multiple cofactor specificity utilizing ADP and GTP in addition to ATP. The unusual cofactor specificity was confirmed via a DNA ligase nick-closing activity assay using a fluorescein/biotin-labelled oligonucleotide and a radiolabelled oligonucleotide. The exploitation of GTP as a catalytic energy source has not to date been reported in any known DNA ligase. This phenomenon may provide evolutionary evidence of the nucleotide cofactor utilization by DNA ligases. To bolster this hypothesis, we summarize and evaluate previous assertions. We contend that DNA ligase evolution likely started from crenarchaeotal DNA ligases and diverged to eukaryal DNA ligases and euryarchaeotal DNA ligases. Subsequently, the NAD(+)-utilizing property of some euryarchaeotal DNA ligases may have successfully differentiated to bacterial NAD(+)-dependent DNA ligases.     

RNA substrate specificity and structure-guided mutational analysis of bacteriophage T4 RNA ligase 2

Here we report that bacteriophage T4 RNA ligase 2 (Rnl2) is an efficient catalyst of RNA ligation at a 3'-OH/5'-PO(4) nick in a double-stranded RNA or an RNA.DNA hybrid. The critical role of the template strand in approximating the reactive 3'-OH and 5'-PO(4) termini is underscored by the drastic reductions in the RNA-sealing activity of Rnl2 when the duplex substrates contain gaps or flaps instead of nicks. RNA nick joining requires ATP and a divalent cation cofactor (either Mg or Mn). Neither dATP, GTP, CTP, nor UTP can substitute for ATP. We identify by alanine scanning seven functionally important amino acids (Tyr-5, Arg-33, Lys-54, Gln-106, Asp-135, Arg-155, and Ser-170) within the N-terminal nucleotidyl-transferase domain of Rnl2 and impute specific roles for these residues based on the crystal structure of the AMP-bound enzyme. Mutational analysis of 14 conserved residues in the C-terminal domain of Rnl2 identifies 3 amino acids (Arg-266, Asp-292, and Glu-296) as essential for ligase activity. Our findings consolidate the evolutionary connections between bacteriophage Rnl2 and the RNA-editing ligases of kinetoplastid protozoa.     

T4 DNA ligase is more than an effective trap of cyclized dsDNA

T4 DNA ligase is used in standard cyclization assays to trap double-stranded DNA (dsDNA) in low-probability, cyclic or highly bent conformations. The cyclization probability, deduced from the relative yield of cyclized product, can be used in conjunction with statistical mechanical models to extract the bending stiffness of dsDNA. By inserting the base analog 2-aminopurine (2-AP) at designated positions in 89bp and 94bp dsDNA fragments, we find that T4 DNA ligase can have a previously unknown effect. Specifically, we observe that addition of T4 ligase to dsDNA in proportions comparable to what is used in the cyclization assay leads to a significant increase in fluorescence from 2-AP. This effect is believed to originate from stabilization of local base-pair opening by formation of transient DNA-ligase complexes. Non-specific binding of T4 ligase to dsDNA is also confirmed using fluorescence correlation spectroscopy (FCS) experiments, which reveal a systematic reduction of dsDNA diffusivity in the presence of ligase. ATP competes with regular DNA for non-covalent binding to the T4 ligase and is found to significantly reduce DNA-ligase complexation. For short dsDNA fragments, however, the population of DNA-ligase complexes at typical ATP concentrations used in DNA cyclization studies is determined to be large enough to dominate the cyclization reaction.     

Characterization of bacteriophage T3 DNA ligase

DNA ligases of bacteriophage T4 and T7 have been widely used in molecular biology for decades, but little is known about bacteriophage T3 DNA ligase. Here is the first report on the cloning, expression and biochemical characterization of bacteriophage T3 DNA ligase. The polyhistidine-tagged recombinant T3 DNA ligase was shown to be an ATP-dependent enzyme. The enzymatic activity was not affected by high concentration of monovalent cations up to 1 M, whereas 2 mM ATP could inhibit its activity by 50%. Under optimal conditions (pH 8.0, 0.5 mM ATP, 5 mM DTT, 1 mM Mg(2+) and 300 mM Na(+)), 1 fmol of T3 DNA ligase could achieve 90% ligation of 450 fmol of cohesive dsDNA fragments in 30 min. T3 DNA ligase was shown to be over 5-fold more efficient than T4 DNA ligase for ligation of cohesive DNA fragments, but less active for blunt-ended DNA fragments. Phylogenetic analysis showed that T3 DNA ligase is more closely related to T7 DNA ligase than to T4 DNA ligase.     

Standard free energy for the hydrolysis of adenylylated T4 DNA ligase and the apparent pKa of lysine 159

Equilibrium constants for the adenylylation of T4 DNA ligase have been measured at 10 pH values. The values, when plotted against pH, fit a titration curve corresponding to a pKa of 8.4 +/- 0.1. The simplest interpretation is that the apparent pKa is that of the 6-amino group of the AMP-accepting residue Lys159. Based on the pH dependence of the equilibrium constants, the value at pH 7.0 is 0. 0213 at 25 degrees C, corresponding to DeltaG'o = +2.3 kcal mol-1. From this value and the standard free energy change of -10.9 kcal mol-1 for the hydrolysis of ATP to AMP and PPi, we calculate that DeltaG'o for the hydrolysis of the adenylyl-DNA ligase is -13.2 kcal mol-1. The presence of conserved basic amino acid residues in the catalytic domain, which are proximal to the active site in the homologous catalytic domain of T7 DNA ligase, suggests that the pKa of Lys159 is perturbed downward by the electrostatic effects of nearby positively charged amino acid side chains. The lower than normal pKa 8.4 compared with 10.5 for the 6-amino group of lysine and the high energy of the alpha,beta-phosphoanhydride linkage in ATP significantly facilitate adenylylation of the enzyme.     

The polynucleotide ligase and RNA capping enzyme superfamily of covalent nucleotidyltransferases

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.     

Mutational analysis of bacteriophage T4 RNA ligase 1. Different functional groups are required for the nucleotidyl transfer and phosphodiester bond formation steps of the ligation reaction

T4 RNA ligase 1 (Rnl1) exemplifies an ATP-dependent RNA ligase family that includes fungal tRNA ligase (Trl1) and a putative baculovirus RNA ligase. Rnl1 acts via a covalent enzyme-AMP intermediate generated by attack of Lys-99 N zeta on the alpha phosphorus of ATP. Mutation of Lys-99 abolishes ligase activity. Here we tested the effects of alanine mutations at 19 conserved positions in Rnl1 and thereby identified 9 new residues essential for ligase activity: Arg-54, Lys-75, Phe-77, Gly-102, Lys-119, Glu-227, Gly-228, Lys-240, and Lys-242. Seven of the essential residues are located within counterparts of conserved nucleotidyltransferase motifs I (99KEDG102), Ia (118SK119), IV (227EGYVA231), and V (238HFKIK242) that comprise the active sites of DNA ligases, RNA capping enzymes, and T4 RNA ligase 2. Three other essential residues, Arg-54, Lys-75 and Phe-77, are located upstream of the AMP attachment site within a conserved domain unique to the Rnl1-like ligase family. We infer a shared evolutionary history and active site architecture in Rnl1 (a tRNA repair enzyme) and Trl1 (a tRNA splicing enzyme). We determined structure-activity relationships via conservative substitutions and examined mutational effects on the isolated steps of Rnl1 adenylylation (step 1) and phosphodiester bond formation (step 3). Lys-75, Lys-240, and Lys-242 were found to be essential for step 1 and overall ligation of 5'-phosphorylated RNA but not for phosphodiester bond formation. These results suggest that the composition of the Rnl1 active site is different during steps 1 and 3. Mutations at Arg-54 and Lys-119 abolished the overall RNA ligation reaction without affecting steps 1 and 3. Arg-54 and Lys-119 are thereby implicated as specific catalysts of the RNA adenylation reaction (step 2) of the ligation pathway.