`Single addition' and `transnucleotidation' reactions catalyzed by polynucleotide phosphorylase. Effect of enzymatic removal of inorganic phosphate during reaction

The reaction of the tetranucleotide, pA-A(2)-A, with 2'(3')-0-(alpha-methoxyethyl)uridine 5'-diphosphate, Mg(2+) ions, and M. luteus polynucleotide phosphorylase followed by mild acid treatment to remove the blocking groups results in a 49% yield of the desired single addition product, pA-A(3)-U, together with smaller amounts of pA-A-U, pA-A-A, pA-A(2)-U, pA-A(2)-A, pA-A(3)-A, pA-A(4)-U, and pA-A(4)-A. The side products are thought to arise from the phosphorolysis of the acceptor molecule by the inorganic phosphate formed in the reaction mixture and from subsequent additions to the various oligonucleotide species by the resulting adenosine 5'-diphosphate. A system developed for the removal of inorganic phosphate as it is formed in the synthesis involves the addition to the reaction mixture of calf spleen nucleoside phosphorylase and nicotinamide riboside and, under these conditions, pA-A(3)-U can be prepared in 90% yield with essentially no side products. Under similar conditions, pA-A(3)-A, pA-A(3)-G, and pA-A(3)-C may be prepared from pA-A(2)-A and the appropriate blocked nucleoside diphosphate in yields of 85-94%. The incubation of pA-A(2)-A alone with polynucleotide phosphorylase exhibits the phenomenon of "transnucleotidation" in that the molecule is partially converted to oligonucleotides of smaller and larger chain lengths. In the presence of the phosphate removal system, however, the tetranucleotide is not attacked by the enzyme, and thus, "transnucleotidation" appears to be simply a combination of phosphorolytic and addition reactions catalyzed by trace amounts of inorganic phosphate contaminating the enzyme and/or the substrate.     

Chemical reactions in double-stranded nucleic acids. The nature of the bond formed during chemical ligation using a cis-diol group

Chemical and enzymatic ligation between the 5'-terminal phosphate of one oligonucleotide and the 3'-terminal 2',3'-cis-diol group of the other oligonucleotide on a complementary template was studied. Carbodiimide, imidazolide and N-hydroxybenzotriazole ester methods were used for chemical activation of the phosphate group, and T4 DNA ligase for enzymatic ligation. All the chemical activation methods produced 3',5'- and 2',5'-phosphodiester bonds (40-45 and 55-60%, resp.), whereas enzymatic ligation gave the product only with 3',5'-phosphodiester bond.     

Novel missense mutations in red/green opsin genes in congenital color-vision deficiencies

Lipocortin I-S100 (calcyclin) heterotetramer exhibited ATPase activity in the presence of dsDNA but not ssDNA. To demonstrate its helicase activity, an 80-mer polynucleotide complementary to the replication origin of M13mp18 was synthesized, and the oligonucleotide, (dC)(20), was ligated to either its 5'- or 3'- end for binding to lipocortin. Lipocortin I heterotetramer displaced chains of the partially Y-shaped duplexes with a dC-tail at either the 5'- or 3'- end. The chain displacement required ATP and Mg(2+). Nonhydrolyzable ATP analogues were not effective. Lipocortin I heterotetramer also catalyzed annealing of the polynucleotides to M13mp18. Ca(2+) and phospholipids but not ATP and Mg(2+) were essential for this reaction. Since the chain displacing and annealing reactions were inhibited by monospecific anti-lipocortin I or anti-S100 antibodies, the present observations suggest that the lipocortin I heterotetramer regulates unwinding and annealing of DNA by Mg(2+) (plus ATP) and Ca(2+) (and phospholipids), respectively.     

Replacement and insertion of nucleotides at the anticodon loop of E. coli tRNAMetf by ligation of chemically synthesized ribooligonucleotides.

Insertion of the four major nucleotides at the 5'-side of the anticodon triplet of E. coli tRNAMetf was performed by joining of the half molecules obtained by limited digestion with RNase A and the chemically synthesized tetranucleotide pN-C-A-U using RNA ligase. Insertion of U-U at the 5'-side or A and A-A at the 3'-side of the anticodon were also performed using U-U-C-A-U, C-A-U-A and C-A-U-A-A. The constant U next to the 5'-side of the anticodon was replaced with A and C by ligation of A-C-A-U and C-C-A-U to the 5'-half molecule which had been treated with periodate plus lysine, followed by joining to the 3'-half. These modified tRNAs were tested for their ability to accept methionine with the methionyl-tRNA synthetase of E. coli. The affinity of these analogs for the synthetase decreased more extensively when the insertion was at the 3'-side of the anticodon triplet. Insertion of mononucleotides at the 5'-side or replacement of the constant U next to the 5'-side of the anticodon did not affect aminoacylation drastically. This may mean that the 3'-side of the anticodon loop of tRNA is one of the major recognition sites for the methionyl-tRNA synthetase.     

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.     

A probe for the mutagenic activity of the carcinogen 4-aminobiphenyl: synthesis and characterization of an M13mp10 genome containing the major carcinogen-DNA adduct at a unique site

The duplex genome of Escherichia coli virus M13mp10 was modified at a unique site to contain N-(deoxyguanosin-8-yl)-4-aminobiphenyl (dG8-ABP), the major carcinogen-DNA adduct of the human bladder carcinogen 4-aminobiphenyl. A tetradeoxynucleotide containing a single dG8-ABP residue was synthesized by reacting 5'-d(TpGpCpA)-3' with N-acetoxy-N-(trifluoracetyl)-4-aminobiphenyl, followed by high-performance liquid chromatography purification of the principal reaction product 5'-d(TpG8-ABPpCpA)-3' (yield 15-30%). Characterization by fast atom bombardment mass spectrometry confirmed the structure as an intact 4-aminobiphenyl-modified tetranucleotide, while 1H nuclear magnetic resonance spectroscopy established the site of substitution and the existence of ring stacking between the carcinogen residue and DNA bases. Both 5'-d(TpG8-ABPpCpA)-3' and 5'-d(TpGpCpA)-3' were 5'-phosphorylated by use of bacteriophage T4 polynucleotide kinase and were incorporated into a four-base gap uniquely positioned in the center of the recognition site for the restriction endonuclease PstI, in an otherwise duplex genome of M13mp10. In the case of the adducted tetranucleotide, dG8-ABP was located in the minus strand at genome position 6270. Experiments in which the tetranucleotides were 5' end labeled with [32P]phosphate revealed the following: the adducted oligomer, when incubated in a 1000-fold molar excess in the presence of T4 DNA ligase and ATP, was found to be incorporated into the gapped DNA molecules with an efficiency of approximately 30%, as compared to the unadducted d(pTpGpCpA), which was incorporated with 60% ligation efficiency; radioactivity from the 5' end of each tetranucleotide was physically mapped to a restriction fragment that contained the PstI site and represented 0.2% of the genome; the presence of the lesion within the PstI recognition site inhibited the ability of PstI to cleave the genome at this site; in genomes in which ligation occurred, T4 DNA ligase was capable of covalently joining both modified and unmodified tetranucleotides to the gapped structures on both the 5' and the 3' ends with at least 90% efficiency. Evidence also is presented showing that the dG8-ABP-modified tetranucleotide was stable to the conditions of the recombinant DNA techniques used to insert it into the viral genome.(ABSTRACT TRUNCATED AT 400 WORDS)     

DNA ligase I from Saccharomyces cerevisiae: physical and biochemical characterization of the CDC9 gene product.

Genetic studies have previously demonstrated that the Saccharomyces cerevisiae CDC9 gene product, which is functionally homologous to mammalian DNA ligase I, is required for DNA replication and is also involved in DNA repair and genetic recombination. In the present study we have purified the yeast enzyme. When measured under denaturing conditions, Cdc9 protein has a polypeptide molecular mass of 87 kDa. The native form of the enzyme is an 80-kDa asymmetric monomer. Both estimates are in good agreement with the M(r) = 84,406 predicted from the translated sequence of the CDC9 gene. Cdc9 DNA ligase acts via the same basic reaction mechanism employed by all known ATP-dependent DNA ligases. The catalytic functions reside in a 70-kDa C-terminal domain that is conserved in mammalian DNA ligase I and in Cdc17 DNA ligase from Schizosaccharomyces pombe. The ATP analog ATP alpha S inhibits the ligation reaction, although Cdc9 protein does form an enzyme-thioadenylate intermediate. Since Cdc9 DNA ligase exhibited the same substrate specificity as mammalian DNA ligase I, this enzyme can be considered to be the DNA ligase I of S. cerevisiae. There is genetic evidence suggesting that DNA ligase may be directly involved in error-prone DNA repair. We examined the ability of Cdc9 DNA ligase to join nicks with mismatches at the termini. Mismatches at the 5' termini of nicks had very little effect on ligation, whereas mismatches opposite a purine at 3' termini inhibited DNA ligation. The joining of DNA molecules with mismatched termini by DNA ligase may be responsible for the generation of mutations.     

Adenylyl-(5′, 2′)-adenosine 5′-Phosphate ((2′-5′) pA-A) in Crude Crystals of 5′-Adenylic Acid Isolated from Nuclease P1 (Penicillium Nuclease) Digest of Technical Grade Yeast RNA

Adenylyl (5′,2′)-adenosine 5′-phosphate ((2′-5′)pA-A) was detected in crude crystals of 5′-AMP prepared from Penicillium nuclease (nuclease P₁) digest of a technical grade yeast RNA. While (3′–5′)A-A was split by nuclease P₁, spleen phosphodiesterase, snake venom phosphodiesterase or alkali, (2′–5′)A-A was not split by a usual level of nuclease P₁ or spleen phosphodiesterase. Nuclease P₁ digests of 12 preparations of technical grade yeast RNA tested were confirmed to contain (2′–5′)pA-A. Its content was about 1 to 2% of the AMP component of each RNA preparation. As poly(A) was degraded completely by the Penicillium enzyme into 5′-AMP without formation of any appreciable amount of (2′–5′)pA-A, the technical grade RNA is supposed to contain 2–5′ phosphodiester linkages in addition to 3′–5′ major linkages.     

"Single Addition" substrates for the synthesis of specific oligoribonucleotides with polynucleotide phosphorylase. Synthesis of 2'-(alpha-methoxyethy) nucleoside 5'-diphosphates.

A number of synthetic methods for the preparation of the 2-O-(alpha-methoxyethyl) derivatives of the 5-diphosphates of adenosine, cytidine, guanosine, and uridine have been studied in order to provide nucleotide substrates that can be applied to the synthesis of specific oligoribonucleotides using polynucleotide phosphorylase. The reaction of nucleoside 5-diphosphates with methyl vinyl ether for a limited time produces low yields of the corresponding 2-O-(alpha-methoxyethyl) derivatives because the rate of methoxyethylation of the 3-hydroxyl groups. A study of the rates of acidic hydrolysis of alpha-methoxyethyl groups in the 2 and 3 positions of nucleosides and nucleotides has been made, and the results obtained form the basis of a more efficient method for the synthesis of the blocked nucleoside diphosphates. The method involves the reaction of nucleoside 5-diphosphates with methyl vinyl ether to give the corresponding 2,3-di-O-(alpha-methoxyethyl)nucleoside 5-diphosphates, and exploits the fact that, in the acidic hydrolysis of these derivatives, the rate of removal of the 3-methoxyethyl group is about twice that of the group in the 2 position. Alternative syntheses were based on the phosphorylation of methoxyethylated nucleosides and nucleotides. The derivatives, 2-O- and 2,3-di-O-(alpha-methoxyethyl)uridine, were prepared by the methoxyethylation of 3,5-di-O-acetyluridine and 5-O-acetyluridine followed by removal of the acetyl groups. The corresponding guanosine derivatives were made by the synthetic routes: (i) guanosine leads to O-2,O-3,O-5,N-2-tetrabenzoylguanosine leads to 2-N-benzoylguanosine leads to O3-acetyl-N-2,O5-dibenzoylguanosine leads to 2-O-(alpha-methoxyethyl)guanosine, and (ii) 2,3-O-isopropylideneguanosine leads to N-2,O5-diacetyl-2,3-O-isopropylideneguanosine leads to N-2,O-5-diacetylguanosine leads to 2,3-di-O-(alpha-methoxyethyl)guanosine. These methoxyethylated nucleosides were converted to the corresponding 5-phosphates by reaction with cyanoethyl phosphate and dicyclohexylcarbodiimide, and then to the corresponding 5-diphosphates by subsequent reaction with 1,1-carbonyldiimidazole and inorganic phosphate.     

Guanosine tetraphyosphate and its analogues. Chemical synthesis of guanosine 3',5'-dipyrophosphate, deoxyguanosine 3',5'-dipyrophosphate, guanosine 2',5'-bis(methylenediphosphonate), and guanosine 3',5'-bis(methylenediphosphonate).

A new procedure for the synthesis of the pyrophosphate bond has been employed in the preparation of nucleoside dipyrophosphates from nucleoside 3',5'-diphosphates. The method makes use of a powerful phosphorylating agent generated in a mixture of cyanoethyl phosphate, dicyclohexylcarbodiimide, and mesitylenesulfonyl chloride in order to avoid possible intramolecular reactions between the two phosphate groups on the sugar ring. That such reactions can readily occur was shown by the facile cyclization of deoxyguanosine 3',5'-diphosphate to P1,P2-deoxyguanosine 3',5'-cyclic pyrophosphate in the presence of dicyclohexylcarbodiimide alone. The phosphorylation reagent was initially tested in the conversion of deoxyguanosine 3',5'-diphosphate to the corresponding 3',5'-dipyrophosphate and was then used to phosphorylate 2'-O-(alpha-methoxyethyl)guanosine 3',5'-diphosphate, which had been prepared from 2'-O-(alpha-methoxyethyl)guanosine. In the latter case, the addition of the two beta phosphate groups was accomplished in 40% yield. Removal of the methoxyethyl group from the phosphorylated product gave guanosine 3',5'-dipyrophosphate, which was shown to be identical with guanosine tetraphosphate prepared enzymatically from a mixture of GDP and ATP. A modification of published procedures was also necessary to effect the synthesis of guanosine bis(methylenediphosphonate). Guanosine was treated with methylenediphosphonic acid and dicyclohexylcarbodiimide in the absence of added base. The product consisted of a mixture of guanosine 2',5' - and 3',5'-bis(methylenediphosphonate), which was resolved by anion-exchange chromatography. The 2',5' and 3',5' isomers are interconvertible at low pH, with the ultimate formation of an equilibrium mixture having a composition ratio of 2:3. The predominant constituent of this mixture has been unequivocally identified as the 3',5' isomer by synthesis from 2'-O-tetrahydropyranylguanosine.     

Intrinsic intermolecular DNA ligation activity of eukaryotic topoisomerase II. Potential roles in recombination.

Drosophila melanogaster topoisomerase II is capable of joining phi X174 (+) strand DNA that it has cleaved to duplex oligonucleotide acceptor molecules by an intermolecular ligation reaction (Gale, K. C. and Osheroff, N. (1990) Biochemistry 29, 9538-9545). In order to investigate potential mechanisms for topoisomerase II-mediated DNA recombination, this intrinsic enzyme activity was further characterized. Intermolecular DNA ligation proceeded in a time-dependent fashion and was concentration-dependent with respect to oligonucleotide. The covalent linkage between phi X174 (+) strand DNA and acceptor molecules was confirmed by Southern analysis and alkaline gel electrophoresis. Topoisomerase II-mediated intermolecular DNA ligation required the oligonucleotide to contain a 3'-OH terminus. Moreover, the reaction was dependent on the presence of a divalent cation, was inhibited by salt, and was not affected by the presence of ATP. The enzyme was capable of ligating phi X174 (+) strand DNA to double-stranded oligonucleotides that contained 5'-overhang, 3'-overhand, or blunt ends. Single-stranded, nicked, or gapped oligonucleotides also could be used as acceptor molecules. These results demonstrate that the type II enzyme has an intrinsic ability to mediate illegitimate DNA recombination in vitro and suggests possible roles for topoisomerase II in nucleic acid recombination in vivo.     

Elongation of oligonucleotides in the 3'-direction with activated mononucleotides and their analogs using RNA ligase.

P1-Adenosine 5'-P2-2',3'-ethoxymethylidene nucleosides [A(5')ppN(Em)] from four common nucleosides have been prepared and used for single addition of nucleotides to elongate oligonucleotide chains in the 3'-direction in RNA ligase reaction. U-U-C, T-U-C and A-C-C were used as acceptors. Structural dependence in these acceptors was found to be smaller compared to joining reactions between oligonucleotides. Adenosine analogs including 8-bromo-, 2'-fluoro-, 2'-azido-, 8,2'-O-cyclo-, 8,2'-S-cyclo-adenosine, arabinosyladenine and 2'-deoxyadenosine were added to the 3'-end of A-C-C by adenylation chemically followed by joining with RNA ligase. Symmetrical 5'-pyrophosphates of 8-bromo-, 2'-fluoro- and 2'-azido-adenosine were not recognized as donor substrates.     

Preparation of 2-azidoadenosine 3',5'-[5'-32P]bisphosphate for incorporation into transfer RNA. Photoaffinity labeling of Escherichia coli ribosomes

2-Azidoadenosine was synthesized from 2-chloroadenosine by sequential reaction with hydrazine and nitrous acid and then bisphosphorylated with pyrophosphoryl chloride to form 2-azidoadenosine 3',5'-bisphosphate. The bisphosphate was labeled in the 5'-position using the exchange reaction catalyzed by T4 polynucleotide kinase in the presence of [gamma-32P]ATP. Polynucleotide kinase from a T4 mutant which lacks 3'-phosphatase activity (ATP:5'-dephosphopolynucleotide 5'-phosphotransferase, EC 2.7.1.78) was required to facilitate this reaction. 2-Azidoadenosine 3',5'-[5'-32P]bisphosphate can serve as an efficient donor in the T4 RNA ligase reaction and can replace the 3'-terminal adenosine of yeast tRNAPhe with little effect on the amino acid acceptor activity of the tRNA. In addition, we show that the modified tRNAPhe derivative can be photochemically cross-linked to the Escherichia coli ribosome.     

The enzymatic conversion of 3'-phosphate terminated RNA chains to 2',3'-cyclic phosphate derivatives

The enzyme, RNA cyclase, has been purified from cell-free extracts of HeLa cells approximately 6000-fold. The enzyme catalyzes the conversion of 3'-phosphate ends of RNA chains to the 2',3'-cyclic phosphate derivative in the presence of ATP or adenosine 5'-(gamma-thio)triphosphate (ATP gamma S) and Mg2+. The formation of 1 mol of 2',3'-cyclic phosphate ends is associated with the disappearance of 1 mol of 3'-phosphate termini and the hydrolysis of 1 mol of ATP gamma S to AMP and thiopyrophosphate. No other nucleotides could substitute for ATP or ATP gamma S in the reaction. The reaction catalyzed by RNA cyclase was not reversible and exchange reactions between [32P]pyrophosphate and ATP were not detected. However, an enzyme-AMP intermediate could be identified that was hydrolyzed by the addition of inorganic pyrophosphate or 3'-phosphate terminated RNA chains but not by 3'-OH terminated chains or inorganic phosphate. 3'-[32P](Up)10Gp* could be converted to a form that yielded, (Formula: see text) after degradation with nuclease P1, by the addition of wheat germ RNA ligase, 5'-hydroxylpolynucleotide kinase, RNA cyclase, and ATP. This indicates that the RNA cyclase had catalyzed the formation of the 2',3'-cyclic phosphate derivative, the kinase had phosphorylated the 5'-hydroxyl end of the RNA, and the wheat germ RNA ligase had catalyzed the formation of a 3',5'-phosphodiester linkage concomitant with the conversion of the 2',3'-cyclic end to a 2'-phosphate terminated residue.     

Bacteriophage T4 and human type I DNA ligases relax DNA under joining conditions.

Both bacteriophage T4 and human type I DNA ligases in the presence of a mixture of ATP, AMP and PPi altered the topological properties of a supercoiled substrate by a step-wise reaction eventually leading to a population of fully relaxed, covalently closed products. In the presence of only AMP and PPi DNA products containing nicks with 3'OH/5'P termini accumulated in the presence of bacteriophage T4 DNA ligase, suggesting reversal of the entire joining reaction, but not in the presence of human DNA ligase I. Both DNA ligases became deoxyadenylylated in the presence of dATP, but the joining reaction did not proceed to completion. However, with both enzymes the full relaxing reaction took place in the presence of dAMP alone and in the presence of a mixture of dATP, dAMP and PPi. In no case could the joining reaction be reversed by dAMP and PPi. Related experiments with modified derivatives of deoxyribonucleoside 5'-triphosphates and PPi gave results in accord with these observations. The AMP dependent DNA relaxation catalysed by DNA ligases was insensitive to the presence of exonuclease III. These results indicate that controlled relaxation of the substrate by both DNA ligases occurs as a separate reaction rather than by simple reversal of the joining reaction. These findings support the hypothesis that in vivo the DNA topoisomerising ligases relax their substrate at the replication fork both during and separately from ligation of a pre-existing nick.     

XLF-Cernunnos promotes DNA ligase IV–XRCC4 re-adenylation following ligation

XLF-Cernunnos (XLF) is a component of the DNA ligase IV–XRCC4 (LX) complex, which functions during DNA non-homologous end joining (NHEJ). Here, we use biochemical and cellular approaches to probe the impact of XLF on LX activities. We show that XLF stimulates adenylation of LX complexes de-adenylated by pyrophosphate or following LX decharging during ligation. XLF enhances LX ligation activity in an ATP-independent and dependent manner. ATP-independent stimulation can be attributed to enhanced end-bridging. Whilst ATP alone fails to stimulate LX ligation activity, addition of XLF and ATP promotes ligation in a manner consistent with XLF-stimulated readenylation linked to ligation. We show that XLF is a weakly bound partner of the tightly associated LX complex and, unlike XRCC4, is dispensable for LX stability. 2BN cells, which have little, if any, residual XLF activity, show a 3-fold decreased ability to repair DNA double strand breaks covering a range of complexity. These findings strongly suggest that XLF is not essential for NHEJ but promotes LX adenylation and hence ligation. We propose a model in which XLF, by in situ recharging DNA ligase IV after the first ligation event, promotes double stranded ligation by a single LX complex.     

Transcriptional activation of microRNA-34a by NF-kappa B in human esophageal cancer cells

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°C should reduce the constraints of RNA secondary structure in RNA ligation experiments.     

Purification of wheat germ RNA ligase. II. Mechanism of action of wheat germ RNA ligase

The mechanism of action of purified wheat germ RNA ligase has been examined. ATP was absolutely required for the ligation of substrates containing 5'-OH or 5'-P and 2',3'-cyclic P or 2'-P termini. Ligation of 1 mol of 5'-P-2',3'-cyclic P-terminated poly(A) was accompanied by the hydrolysis of 1 mol of ATP to 1 mol each of AMP and PPi. Purified RNA ligase catalyzed an ATP-PPi exchange reaction, specific for ATP and dATP, and formed a covalent enzyme-adenylate complex that was detected by autoradiography following incubation with [alpha-32P]ATP and separation of the products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A protein doublet with a molecular weight of approximately 110 kDa, the major product detected by silver staining, was labeled in these reactions. Isolated E-AMP complex was dissociated by the addition of ligatable poly(A), containing 5'-P-2',3'-cyclic P termini, to yield AMP and by the addition of PPi to yield ATP. The unique feature of the reactions leading to an exchange reaction between ATP and PPi and to the formation of an E-AMP complex was their marked stimulation (up to 400-fold) by the addition of RNA. This property distinguishes the wheat germ RNA ligase from other known RNA and DNA ligases which catalyze ATP-PPi exchange reactions and form E-AMP complexes in the absence of substrate. Thus, RNA appears to function in two capacities in the wheat germ system: as a cofactor, to stimulate the reaction of the enzyme with ATP, and as an authentic substrate for ligation.     

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.     

Structural requirements of polynucleotides for the activation of (2'' - 5'')An polymerase and protein kinase.

Two enzymatic pathways are involved in the inhibitory effects of double-stranded (ds)RNA on protein synthesis in cell extracts derived from interferon-treated human fibroblasts or HeLa cells, an oligonucleotide polymerase that synthesizes (2'-5')An from ATP and a protein kinase that phosphorylates the alpha subunit of initiation factor eIF-2 as well as a polypeptide of Mr = 72,000. We have now evaluated the activation of both the (2'-5')An polymerase and protein kinase by a large variety of polynucleotides, triple-stranded and synthetic dsRNAs, homopolymers, alternating copolymers, triple-stranded polymers, purine-purine duplexes and purine-pyrimidine duplexes with modifications at either the pyrimidine or ribose moieties. All these polynucleotides have been the subject of previous interferon induction studies. Some polynucleotides, i.e. (I)n.(C)n and mycophage dsRNA, which have been recognized as excellent interferon inducers, were also potent activators of both (2'-5')An polymerase and protein kinase, whereas non-inducers such as (A)n. (X)n and (A)n. (br5U)n did not activate either the kinase or the polymerase. However, some polymers like (I)n.(br5C)n, (difl)n(C)n and (dIcl)n (C)n, while potent interferon inducers and kinase activators, behaved poorly as activators of the (2'-5')An polymerase. Other polymers, i.e. (dAfl)n (U)n and (A)n.(U)nl (I)n, that do not induce interferon, activated the kinase but not the polymerase. Finally, (I)n (s2c)n, a relatively potent interferon inducer, did not activate either kinase or polymerase. These findings indicate that there is no simple relationship between the interferon-inducing ability of dsRNAs and their stimulating effects on (2'-5')An polymerase and protein kinase activity.