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.     

Donor activation in the T4 RNA ligase reaction

T4 RNA ligase catalyzes the adenylation of donor oligonucleotide substrates. These activated intermediates react with an acceptor oligonucleotide which results in phosphodiester bond formation and the concomitant release of AMP. Adenylation of the four common nucleoside 3',5'-bisphosphates as catalyzed by T4 RNA ligase in the absence of an acceptor oligonucleotide has been examined. The extents of product formation indicate that pCp is the best substrate in the reaction and pGp is the poorest. Kinetic parameters for the joining reaction between the preadenylated nucleoside 3',5'-bisphosphates, A(5')pp(5')Cp or A(5')pp(5')Gp, and a good acceptor substrate (ApApA) or a poor acceptor substrate (UpUpU) have been determined. The apparent Km values for both preadenylated donors in the joining reaction are similar, and the reaction velocity is much faster than observed in the overall joining reaction. The nonnucleotide adenylated substrate P1-(5'-adenosyl) P2-(o-nitrobenzyl) diphosphate also exhibits a similar apparent Km but reacts with a velocity 80-fold slower than the adenylated nucleoside 3',5'-bisphosphates. By use of preadenylated donors, oligonucleotide substrates can be elongated more efficiently than occurs with the nucleoside 3',5'-bisphosphates.     

Purification and properties of bacteriophage T4-induced RNA ligase

RNA ligase has been extensively purified by a new procedure in high yield from T4-infected Escherichia coli. The enzyme consists of a single polypeptide chain of molecular weight 47,000. It catalyzes the formation of a phosphodiester bond between a 5′-PO₄-terminated oligonucleotide and a 3′-OH terminated oligonucleotide. The purified enzyme catalyzes both the intramolecular formation of single-stranded circles with longer oligonucleotides of the type pAp(Ap)_nA_?OH, where n is about 15 or greater and the intermolecular joining of pAp(Ap)₃A_OH (where the 5′-PO₄-terminated oligonucleotide is short enough to prevent apposition of its 3′ and 5′ ends) to UpUpU_OH when high concentrations of the 3′-OH-terminated acceptor oligonucleotide are present. Preparations of RNA ligase at all stages of purification show an unusual dependence of specific activity of the enzyme on the concentration of enzyme present in the assay. However, when care is taken to determine meaningful specific activities at each step, the ligase is found to be very stable during chromatography on various ion-exchange columns and may be purified by conventional techniques.     

Equimolar addition of oligoribonucleotides with T4 RNA ligase.

T4 induced RNA ligase will join equimolar concentrations of two oligoribonucleotides, (Ap)3C and p(Up) 5, to form a single product, (Ap)3Cp(Up) 5, in high yield. The presence of the 3' phosphate on p(Up)5 prevents the oligomer from adding to itself. The pH optimum of the reaction is about 7.5, but less of the undesirable adenylated intermediate, App(Up) 5, forms at pH 8.2. The reaction rate is a linear function of oligomer concentration from 3 micronM to 0.6 mM. The data suggest that T4 RNA ligase will be a useful enzyme for the synthesis of oligomers of defined sequence.     

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.     

A new method for 3''-labelling of polyribonucleotides by phosphorylation with RNA ligase and its application to the 3''-modification for joining reactions.

P1-Adenosine 5'-P2-o-nitrobenzyl pyrophosphate (nbzlppA) has been synthesized as a substrate for T4 RNA ligase catalyzed 3'-phosphorylation. Incubation of oligoribonucleotides and nbzlppA with RNA ligase yielded oligoribonucleotides having a 3'-o-(o-nitrobenzyl) phosphate. Photochemical removal of the o-nitrobenzyl group provided the free 3'-phosphate. Using [P2-32P] nbzlppA, 3'-termini of oligoribonucleotides could be labelled with 32P. This reaction was applied to modify the 3'-end of donor molecules in joining reaction with RNA ligase. A trinucleotide U-A-G was converted to U-A-Gpnbzl and phosphorylated with polynucleotide kinase. pU-A-Gpnbzl was then joined to an acceptor trinucleotide A-U-G to yield A-U-G-U-A-Gp.     

Synthesis of bisphosphonate derivatives of ATP by T4 RNA ligase

T4 RNA ligase catalyzes the synthesis of ATP beta,gamma-bisphosphonate analogues, using the following substrates with the relative velocity rates indicated between brackets: methylenebisphosphonate (pCH(2)p) (100), clodronate (pCCl(2)p) (52), and etidronate (pC(OH)(CH(3))p) (4). The presence of pyrophosphatase about doubled the rate of these syntheses. Pamidronate (pC(OH)(CH(2)-CH(2)-NH(2))p), and alendronate (pC(OH)(CH(2)-CH(2)-CH(2)-NH(2))p) were not substrates of the reaction. Clodronate displaced the AMP moiety of the complex E-AMP in a concentration dependent manner. The K(m) values and the rate of synthesis (k(cat)) determined for the bisphosphonates as substrates of the reaction were, respectively: methylenebisphosphonate, 0.26+/-0.05 mM (0.28+/-0.05 s(-1)); clodronate, 0.54+/-0.14 mM (0.29+/-0.05 s(-1)); and etidronate, 4.3+/-0.5 mM (0.028+/-0.013 s(-1)). In the presence of GTP, and ATP or AppCCl(2)p the relative rate of synthesis of adenosine 5',5'-P(1),P(4)-tetraphosphoguanosine (Ap(4)G) was around 100% and 33%, respectively; the methylenebisphosphonate derivative of ATP (AppCH(2)p) was a very poor substrate for the synthesis of Ap(4)G. To our knowledge this report describes, for the first time, the synthesis of ATP beta,gamma-bisphosphonate analogues by an enzyme different to the classically considered aminoacyl-tRNA synthetases.     

RNA ligase from bacteriophage T4. VIII. Solid phase enzymatic synthesis of oligoribonucleotides]

A method of the solid-phase enzymic synthesis of oligoribonucleotides has been suggested. The donor is fixed through its 3'-end on a water-insoluble matrix followed by the stepwise RNA ligase- and T4 polynucleotide kinase-assisted coupling of trinucleoside diphosphates in the 5'-direction. As an example, (pA)6pAox was immobilised on Biogel P-300 hydrazine and the RNA ligase-catalyzed addition of acceptor ApApA to the donor gave (Ap)9 with the 50% yield.     

Synthesis of RNA having cap structure.

RNA consisting 43 nucleotides bearing cap structure was synthesized (Figure). In the first place, 9 mer of a leader sequence with the cap structure (F-1) was synthesized by the phosphotriester method and followed by the capping reaction. Next, 32 mer of a cistron was divided into two fragments and each was synthesized by the phosphoramidite method. The 3'-end nucleotide of the RNA, a modified guanosine 5'-phosphate, was introduced to F-3 by use of P1-2',3'-O-methoxymethylene guanosine-5'-yl P2-adenosine-5'-yl diphosphate (A5' ppGmM) with T4 RNA ligase. The chemically synthesized RNA fragments were ligated with T4 RNA ligase to afford the desired RNA.     

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.     

Several dinucleoside polyphosphates are acceptor substrates in the T4 RNA ligase catalyzed reaction.

Several dinucleoside polyphosphates accept cytidine-3', 5'-bisphosphate from the adenylylated donor 5'-adenylylated cytidine 5',3'-bisphosphate in the T4 RNA ligase catalyzed reaction. The 5'-adenylylated cytidine 5',3'-bisphosphate synthesized in a first step, from ATP and cytidine-3',5'-bisphosphate, is used as a substrate to transfer the cytidine-3',5'-bisphosphate residue to the 3'-OH group(s) of diguanosine tetraphosphate (Gp4G) giving rise to Gp4GpCp and pCpGp4GpCp in a ratio of approximately 10 : 1, respectively. The synthesized Gp4GpCp was characterized by treatment with snake venom phosphodiesterase and alkaline phosphatase and analysis (chromatographic position and UV spectra) of the reaction products by HPLC. The apparent Km values measured for Gp4G and 5'-adenylylated cytidine 5',3'-bisphosphate in this reaction were approximately 4 mM and 0.4 mM, respectively. In the presence of 0.5 mM ATP and 0.5 mM cytidine-3',5'-bisphosphate, the relative efficiencies of the following nucleoside(5')oligophospho(5')nucleosides as acceptors of cytidine-3',5'-bisphosphate from 5'-adenylylated cytidine 5', 3'-bisphosphate are indicated in parentheses: Gp4G (100); Gp5G (101); Ap4G (47); Ap4A (39). Gp2G, Gp3G and Xp4X were not substrates of the reaction. Dinucleotides containing two guanines and at least four inner phosphates were the preferred acceptors of cytidine-3', 5'-bisphosphate at their 3'-OH group(s).     

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.     

Thermostable Pyrococcus furiosus DNA ligase catalyzes the synthesis of (di)nucleoside polyphosphates

DNA ligase from the hyperthermophilic marine archaeon Pyrococcus furiosus (Pfu DNA ligase) synthesizes adenosine 5'-tetraphosphate (p4A) and dinucleoside polyphosphates by displacement of the adenosine 5'-monophosphate (AMP) from the Pfu DNA ligase-AMP (E-AMP) complex with tripolyphosphate (P3), nucleoside triphosphates (NTP), or nucleoside diphosphates (NDP). The experiments were performed in the presence of 1-2 microM [alpha-32P]ATP and millimolar concentrations of NTP or NDP. Relative rates of synthesis (%) of the following adenosine(5')tetraphospho(5')nucleosides (Ap4N) were observed: Ap4guanosine (Ap4G) (from GTP, 100); Ap4deoxythymidine (Ap4dT) (from dTTP, 95); Ap4xanthosine (Ap4X) (from XTP, 94); Ap4deoxycytidine (Ap4dC) (from dCTP, 64); Ap4cytidine (Ap4C) (from CTP, 60); Ap4deoxyguanosine (Ap4dG) (from dGTP, 58); Ap4uridine (Ap4U) (from UTP, <3). The relative rate of synthesis (%) of adenosine(5')triphospho(5')nucleosides (Ap3N) were: Ap3guanosine (Ap3G) (from GDP, 100); Ap3xanthosine (Ap3X) (from XDP, 110); Ap3cytidine (Ap3C) (from CDP, 42); Ap3adenosine (Ap3A) (from ADP, <1). In general, the rate of synthesis of Ap4N was double that of the corresponding Ap3N. The enzyme presented optimum activity at a pH value of 7.2-7.5, in the presence of 4 mM Mg2+, and at 70 degrees C. The apparent Km values for ATP and GTP in the synthesis of Ap4G were about 0.001 and 0.4mM, respectively, lower values than those described for other DNA or RNA ligases. Pfu DNA ligase is used in the ligase chain reaction (LCR) and some of the reactions here reported [in particular the synthesis of Ap4adenosine (Ap4A)] could take place during the course of that reaction.     

Bacteriophage T4 RNA ligase. Reaction intermediates and interaction of substrates.

Bacteriophage T4 RNA ligase catalyzes the ATP-dependent ligation of a 5'-phosphoryl-terminated nucleic acid donor to a 3'-hydroxyl-terminated nucleic acid acceptor. We have identified adenylylated DNA and RNA reaction intermediates in which the AMP moiety is attached by a pyrophosphate bond to the 5'-phosphoryl group of the donor. A large amount of DNA-adenylate accumulates during the reaction and the dependence of joining and adenylylation on chain length are similar. The adenylylated donor is joined by ligase to an acceptor in the absence of ATP, and AMP is released stoichiometrically in this reaction. The acceptor is not only a substrate in the reaction but also a cofactor for adenylylation of the donor; in the absence of a 3'-hydroxyl group the activated intermediate does not form. The activated DNA need not join to the acceptor that initially stimulated activation but can also join to another acceptor. This process of acceptor exchanges has proven useful for promoting the cyclization of small DNA substrates and the synthesis of DNA co-polymers.     

The mitochondrial RNA ligase from Leishmania tarentolae can join RNA molecules bridged by a complementary RNA.

A biochemical characterization was performed with a partially purified RNA ligase from isolated mitochondria of Leishmania tarentolae. This ligase has a K(m) of 25 +/- 0.75 nM and a V(max) of 1.0 x 10(-4) +/- 2.4 x 10(-4) nmol/min when ligating a nicked double-stranded RNA substrate. Ligation was negatively affected by a gap between the donor and acceptor nucleotides. The catalytic efficiency of the circularization of a single-stranded substrate was 5-fold less than that of the ligation of a nicked substrate. These properties of the mitochondrial RNA ligase are consistent with an expected in vivo role in the process of uridine insertion/deletion RNA editing, in which the mRNA cleavage fragments are bridged by a cognate guide RNA.     

Synthesis and reactivity of intermediates formed in the T4 RNA ligase reaction.

The intermediate adenylated donor derivatives A(5')pp(5')dTp and A(5')pp(5')GpGpGp have been prepared from suitable phosphorylating reagents activated by 1-hydroxybenzotriazole. Phosphodiester bond formation between donor and acceptor oligonucleotides as catalyzed by T4 RNA ligase is shown to be more efficient when the adenylated form of the donor molecule is used.     

Characterization of a baculovirus enzyme with RNA ligase, polynucleotide 5'-kinase, and polynucleotide 3'-phosphatase activities

The end-healing and end-sealing steps of the phage T4-induced RNA restriction-repair pathway are performed by two separate enzymes, a bifunctional polynucleotide 5'-kinase/3'-phosphatase and an ATP-dependent RNA ligase. Here we show that a single trifunctional baculovirus enzyme, RNA ligase 1 (Rnl1), catalyzes the identical set of RNA repair reactions. Three enzymatic activities of baculovirus Rnl1 are organized in a modular fashion within a 694-amino acid polypeptide consisting of an autonomous N-terminal RNA-specific ligase domain, Rnl1-(1-385), and a C-terminal kinase-phosphatase domain, Rnl1-(394-694). The ligase domain is itself composed of two functional units. The N-terminal module Rnl1-(1-270) contains essential nucleotidyltransferase motifs I, IV, and V and suffices for both enzyme adenylylation (step 1 of the ligation pathway) and phosphodiester bond formation at a preactivated RNA-adenylate end (step 3). The downstream module extending to residue 385 is required for ligation of a phosphorylated RNA substrate, suggesting that it is involved specifically in the second step of the end-joining pathway, the transfer of AMP from the ligase to the 5'-PO(4) end to form RNA-adenylate. The end-healing domain Rnl1-(394-694) consists of a proximal 5'-kinase module with an essential P-loop motif ((404)GSGKS(408)) and a distal 3'-phosphatase module with an essential acylphosphatase motif ((560)DLDGT(564)). Our findings have implications for the evolution of RNA repair systems and their potential roles in virus-host dynamics.     

3'-end labeling of RNA with recombinant yeast poly(A) polymerase.

Two commonly used methods to end-label RNA-molecules are 5'-end labeling by polynucleotide kinase and 3'-end labeling with pCp and T4 RNA ligase. We show here that RNA 3'-ends can also be labeled with the chain-terminating analogue cordycepin 5'-triphosphate (3'-deoxy-ATP) which is added by poly(A) polymerase. For a synthetic RNA it is shown that 40% of cordycepin becomes incorporated when the nucleotide is used at limiting concentrations and that with an excess of cordycepin 5'-triphosphate essentially all the RNA becomes modified at its 3'-end. The reaction is complete within minutes and the RNA product is uniform and suitable for sequence analysis. The efficiency of labeling varies with different RNA-molecules and is different from RNA ligase. Poly(A) polymerase preferentially labels longer RNA-molecules whereas short RNA-molecules are labeled more efficiently by T4 RNA ligase.     

Molecular design of a eukaryotic messenger RNA and its chemical synthesis.

A designed mRNA consisting of 42 ribonucleotides having the cap structure was synthesized. The capped leader sequence of the brome mosaic virus (BMV) mRNA 4, m7G5'pppGUAUUAAUA (F-1), was synthesized by the phosphotriester method and followed by the capping reaction. A 32-mer consisting of an initiation codon (AUG), the coding region corresponding to a bacterial pheromone cAD1 and two stop codons, was constructed by the 18-mer (F-2) and 14-mer (F-3), which were synthesized by the phosphoramidite method. 2'-,3'-O-Methoxymethylene-guanosine 5'-phosphate was condensed with F-3 using P1-2',3'-O-methoxymethyleneguanosine-5'-yl P2-adenosine-5'-yl pyrophosphate (9) with T4 RNA ligase. The chemically synthesized RNA fragments were ligated successively with T4 RNa ligase to afford the whole RNA molecule.     

Reactions at the termini of tRNA with T4 RNA ligase.

T4 RNA ligase will catalyze the addition of nucleoside 3', 5'-bisphosphates onto the 3' terminus of tRNA resulting in tRNA molecule one nucleotide longer with a 3' terminal phosphate. Under appropriate conditions the reaction is quantitative and, if high specific radioactivity bisphosphates are used, it provides an efficient means for in vitro labeling of tRNA. Although the 3' terminal hydroxyl is a good acceptor, the 5' terminal phosphate in most tRNA's is not an effective donor in the RNA ligase reaction. This poor reactivity is due to the secondary structure of the 5' terminal nucleotide. If E. Coli tRNAf Met is used, the 5' phosphate is reactive and the major product with RNA ligase is the cyclic tRNA.