Cyclases of the 3'-terminal phosphate in RNA: a new family of RNA processing enzymes conserved in eucarya, bacteria and archaea.

The 2',3'-cyclic phosphate termini are produced, as either intermediates or final products, during RNA cleavage by many different endoribonucleases. Likewise, ribozymes such as hammerheads, hairpins, or the hepatitis delta ribozyme, generate 2',3'-cyclic phosphate ends. Discovery of the RNA 3'-terminal phosphate cyclase has indicated that cyclic phosphate termini in RNA can also be produced by an entirely different mechanism. The RNA 3'-phosphate cyclase converts the 3'-terminal phosphate in RNA into the 2',3'-cyclic phosphodiester in the ATP-dependent reaction which involves formation of the covalent cyclase-AMP and the RNA-N3' pp5' A intermediates. The findings that several eukaryotic and prokaryotic RNA ligases require the 2',3'-cyclic phosphate for the ligation of RNA molecules raised a possibility that the RNA 3'-phosphate cyclase may have an anabolic function in RNA metabolism by generating terminal cyclic groups required for ligation. Recent cloning of a cDNA encoding the human cyclase indicated that genes encoding cyclase-like proteins are conserved among Eucarya, Bacteria, and Archaea. The protein encoded by the Escherichia coli gene was overexpressed and shown to have the RNA 3'-phosphate cyclase activity. This article reviews properties of the human and bacterial cyclases, their mechanism of action and substrate specificity. Possible biological functions of the enzymes are also discussed.     

RtcB is the RNA ligase component of an Escherichia coli RNA repair operon

RNA 2',3'-cyclic phosphate ends play important roles in RNA metabolism as substrates for RNA ligases during tRNA restriction-repair and tRNA splicing. Diverse bacteria from multiple phyla encode a two-component RNA repair cassette, comprising Pnkp (polynucleotide kinase-phosphatase-ligase) and Hen1 (RNA 3'-terminal ribose 2'-O-methyltransferase), that heals and then seals broken tRNAs with 2',3'-cyclic phosphate and 5'-OH ends. The Pnkp-Hen1 repair operon is absent in the majority of bacterial species, thereby raising the prospect that other RNA repair systems might be extant. A candidate component is RNA 3'-phosphate cyclase, a widely distributed enzyme that transforms RNA 3'-monophosphate termini into 2',3'-cyclic phosphates but cannot seal the ends it produces. Escherichia coli RNA cyclase (RtcA) is encoded in a σ(54)-regulated operon with RtcB, a protein of unknown function. Taking a cue from Pnkp-Hen1, we purified E. coli RtcB and tested it for RNA ligase activity. We report that RtcB per se seals broken tRNA-like stem-loop structures with 2',3'-cyclic phosphate and 5'-OH ends to form a splice junction with a 2'-OH, 3',5'-phosphodiester. We speculate that: (i) RtcB might afford bacteria a means to recover from stress-induced RNA damage; and (ii) RtcB homologs might catalyze tRNA repair or splicing reactions in archaea and eukarya.     

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.     

The human RNA 3''-terminal phosphate cyclase is a member of a new family of proteins conserved in Eucarya, Bacteria and Archaea.

RNA 3'-terminal phosphate cyclase catalyses the ATP-dependent conversion of the 3'-phosphate to a 2',3'-cyclic phosphodiester at the end of RNA. The physiological function of the cyclase is not known, but the enzyme could be involved in the maintenance of cyclic ends in tRNA splicing intermediates or in the cyclization of the 3' end of U6 snRNA. In this work, we describe cloning of the human cyclase cDNA. The purified bacterially overexpressed protein underwent adenylylation in the presence of [alpha-32P]ATP and catalysed cyclization of the 3'-terminal phosphate in different RNA substrates, consistent with previous findings. Comparison of oligoribonucleotides and oligodeoxyribonucleotides of identical sequence demonstrated that the latter are approximately 500-fold poorer substrates for the enzyme. In Northern analysis, the cyclase was expressed in all analysed mammalian tissues and cell lines. Indirect immunofluorescence, performed with different transfected mammalian cell lines, showed that this protein is nuclear, with a diffuse nucleoplasmic localization. The sequence of the human cyclase has no apparent motifs in common with any proteins of known function. However, inspection of the databases identified proteins showing strong similarity to the enzyme, originating from as evolutionarily distant organisms as yeast, plants, the bacterium Escherichia coli and the archaeon Methanococcus jannaschii. The overexpressed E. coli protein has cyclase activity similar to that of the human enzyme. The conservation of the RNA 3'-terminal phosphate cyclase among Eucarya, Bacteria and Archaea argues that the enzyme performs an important function in RNA metabolism.     

The sequential 2',3'-cyclic phosphodiesterase and 3'-phosphate/5'-OH ligation steps of the RtcB RNA splicing pathway are GTP-dependent

The RNA ligase RtcB splices broken RNAs with 5'-OH and either 2',3'-cyclic phosphate or 3'-phosphate ends. The 3'-phosphate ligase activity requires GTP and entails the formation of covalent RtcB-(histidinyl)-GMP and polynucleotide-(3')pp(5')G intermediates. There are currently two models for how RtcB executes the strand sealing step. Scheme 1 holds that the RNA 5'-OH end attacks the 3'-phosphorus of the N(3')pp(5')G end to form a 3',5'-phosphodiester and release GMP. Scheme 2 posits that the N(3')pp(5')G end is converted to a 2',3'-cyclic phosphodiester, which is then attacked directly by the 5'-OH RNA end to form a 3',5'-phosphodiester. Here we show that the sealing of a 2',3'-cyclic phosphate end by RtcB requires GTP, is contingent on formation of the RtcB-GMP adduct, and involves a kinetically valid RNA(3')pp(5')G intermediate. Moreover, we find that RtcB catalyzes the hydrolysis of a 2',3'-cyclic phosphate to a 3'-phosphate at a rate that is at least as fast as the rate of ligation. These results weigh in favor of scheme 1. The cyclic phosphodiesterase activity of RtcB depends on GTP and the formation of the RtcB-GMP adduct, signifying that RtcB guanylylation precedes the cyclic phosphodiesterase and 3'-phosphate ligase steps of the RNA splicing pathway.     

Novel mechanism of RNA repair by RtcB via sequential 2',3'-cyclic phosphodiesterase and 3'-Phosphate/5'-hydroxyl ligation reactions

RtcB enzymes are a newly discovered family of RNA ligases, implicated in tRNA splicing and other RNA repair reactions, that seal broken RNAs with 2',3'-cyclic phosphate and 5'-OH ends. Parsimony and energetics would suggest a one-step mechanism for RtcB sealing via attack by the O5' nucleophile on the cyclic phosphate, with expulsion of the ribose O2' and generation of a 3',5'-phosphodiester at the splice junction. Yet we find that RtcB violates Occam's razor, insofar as (i) it is adept at ligating 3'-monophosphate and 5'-OH ends; (ii) it has an intrinsic 2',3'-cyclic phosphodiesterase activity. The 2',3'-cyclic phosphodiesterase and ligase reactions both require manganese and are abolished by mutation of the RtcB active site. Thus, RtcB executes a unique two-step pathway of strand joining whereby the 2',3'-cyclic phosphodiester end is hydrolyzed to a 3'-monophosphate, which is then linked to the 5'-OH end to form the splice junction. The energy for the 3'-phosphate ligase activity is provided by GTP, which reacts with RtcB in the presence of manganese to form a covalent RtcB-guanylate adduct. This adduct is sensitive to acid and hydroxylamine but resistant to alkali, consistent with a phosphoramidate bond.     

Characterization of the adenylation site in the RNA 3'-terminal phosphate cyclase from Escherichia coli

RNA 3'-terminal phosphate cyclases are a family of evolutionarily conserved enzymes that catalyze ATP-dependent conversion of the 3'-phosphate to the 2',3'-cyclic phosphodiester at the end of RNA. The precise function of cyclases is not known, but they may be responsible for generating or regenerating cyclic phosphate RNA ends required by eukaryotic and prokaryotic RNA ligases. Previous work carried out with human and Escherichia coli enzymes demonstrated that the initial step of the cyclization reaction involves adenylation of the protein. The AMP group is then transferred to the 3'-phosphate in RNA, yielding an RNA-N(3')pp(5')A (N is any nucleoside) intermediate, which finally undergoes cyclization. In this work, by using different protease digestions and mass spectrometry, we assign the site of adenylation in the E. coli cyclase to His-309. This histidine is conserved in all members of the class I subfamily of cyclases identified by phylogenetic analysis. Replacement of His-309 with asparagine or alanine abrogates both enzyme-adenylate formation and cyclization of the 3'-terminal phosphate in a model RNA substrate. The cyclase is the only known protein undergoing adenylation on a histidine residue. Sequences flanking the adenylated histidine in cyclases do not resemble those found in other proteins modified by nucleotidylation.     

RNA 3'-phosphate cyclase (RtcA) catalyzes ligase-like adenylylation of DNA and RNA 5'-monophosphate ends

RNA 3'-phosphate cyclase (Rtc) enzymes are a widely distributed family that catalyze the synthesis of RNA 2',3'-cyclic phosphate ends via an ATP-dependent pathway comprising three nucleotidyl transfer steps: reaction of Rtc with ATP to form a covalent Rtc-(histidinyl-N)-AMP intermediate and release PP(i); transfer of AMP from Rtc to an RNA 3'-phosphate to form an RNA(3')pp(5')A intermediate; and attack by the terminal nucleoside O2' on the 3'-phosphate to form an RNA 2',3'-cyclic phosphate product and release AMP. The chemical transformations of the cyclase pathway resemble those of RNA and DNA ligases, with the key distinction being that ligases covalently adenylylate 5'-phosphate ends en route to phosphodiester synthesis. Here we show that the catalytic repertoire of RNA cyclase overlaps that of ligases. We report that Escherichia coli RtcA catalyzes adenylylation of 5'-phosphate ends of DNA or RNA strands to form AppDNA and AppRNA products. The polynucleotide 5' modification reaction requires the His(309) nucleophile, signifying that it proceeds through a covalent RtcA-AMP intermediate. We established this point directly by demonstrating transfer of [(32)P]AMP from RtcA to a pDNA strand. RtcA readily adenylylated the 5'-phosphate at a 5'-PO(4)/3'-OH nick in duplex DNA but was unable to covert the nicked DNA-adenylate to a sealed phosphodiester. Our findings raise the prospect that cyclization of RNA 3'-ends might not be the only biochemical pathway in which Rtc enzymes participate; we discuss scenarios in which the 5'-adenylyltransferase of RtcA might play a role.     

Purification of wheat germ RNA ligase. I. Characterization of a ligase-associated 5'-hydroxyl polynucleotide kinase activity

An RNA ligase that catalyzes the formation of a 2'-phosphomonoester-3',5'-phosphodiester bond in the presence of ATP and Mg2+ was purified approximately 6000-fold from raw wheat germ. A 5'-hydroxyl polynucleotide kinase activity copurified with RNA ligase through all chromatographic steps. Both activities cosedimented upon glycerol gradient centrifugation even in the presence of high salt and urea. RNA ligase and kinase activities sedimented as a single peak on glycerol gradients with a sedimentation coefficient of 6.2 S. The purified polynucleotide kinase activity required dithiothreitol and a divalent cation for activity and was inhibited by pyrophosphate and by ADP. The kinase phosphorylated a variety of 5'-hydroxyl-terminated polynucleotide chains including some that were substrates for the RNA ligase (e.g. 2',3'-cyclic phosphate-terminated poly(A)) and others that were not ligase substrates (e.g. DNA or RNA containing 3'-hydroxyl termini). RNA molecules containing either 5'-hydroxyl or 5'-phosphate and 2',3'-cyclic or 2'-phosphate termini were substrates for the purified RNA ligase activity. The rate of ligation of 5'-hydroxyl-terminated RNA chains was greater than that of 5'-phosphate-terminated molecules, suggesting that an interaction between the wheat germ kinase and ligase activities occurs during the course of ligation.     

Circularization of linear viroid RNA via 2'-phosphomonoester, 3', 5'-phosphodiester bonds by a novel type of RNA ligase from wheat germ and Chlamydomonas.

A novel type of RNA ligase activity in extracts of wheat germ or Chlamydomonas requires 2', 3'-cyclic phosphate and 5'-phosphate ends for ligation to form a 2'-phosphomonoester, 3',5'-phosphodiester bond. Using 5'-3 2P-labeled linear PSTV, we demonstrate that RNase T1-nicked viroid predominantly forms (formula; see text) U-bonds. Natural linear PSTV, however, forms mainly (formula; see text) A-bonds upon enzymatic circularization. We show that natural linear PSTV RNA has nicks between C181 and A182, or between C348 and A349, and that consequently C181 and C348 carry 2',3'-cyclophosphate termini.     

Zn2+-dependent deoxyribozymes that form natural and unnatural RNA linkages

We report Zn(2+)-dependent deoxyribozymes that ligate RNA. The DNA enzymes were identified by in vitro selection and ligate RNA with k(obs) up to 0.5 min(-)(1) at 1 mM Zn(2+) and 23 degrees C, pH 7.9, which is substantially faster than our previously reported Mg(2+)-dependent deoxyribozymes. Each new Zn(2+)-dependent deoxyribozyme mediates the reaction of a specific nucleophile on one RNA substrate with a 2',3'-cyclic phosphate on a second RNA substrate. Some of the Zn(2+)-dependent deoxyribozymes create native 3'-5' RNA linkages (with k(obs) up to 0.02 min(-)(1)), whereas all of our previous Mg(2+)-dependent deoxyribozymes that use a 2',3'-cyclic phosphate create non-native 2'-5' RNA linkages. On this basis, Zn(2+)-dependent deoxyribozymes have promise for synthesis of native 3'-5'-linked RNA using 2',3'-cyclic phosphate RNA substrates, although these particular Zn(2+)-dependent deoxyribozymes are likely not useful for this practical application. Some of the new Zn(2+)-dependent deoxyribozymes instead create non-native 2'-5' linkages, just like their Mg(2+) counterparts. Unexpectedly, other Zn(2+)-dependent deoxyribozymes synthesize one of three unnatural linkages that are formed upon the reaction of an RNA nucleophile other than a 5'-hydroxyl group. Two of these unnatural linkages are the 3'-2' and 2'-2' linear junctions created when the 2'-hydroxyl of the 5'-terminal guanosine of one RNA substrate attacks the 2',3'-cyclic phosphate of the second RNA substrate. The third unnatural linkage is a branched RNA that results from attack of a specific internal 2'-hydroxyl of one RNA substrate at the 2',3'-cyclic phosphate. When compared with the consistent creation of 2'-5' linkages by Mg(2+)-dependent ligation, formation of this variety of RNA ligation products by Zn(2+)-dependent deoxyribozymes highlights the versatility of transition metals such as Zn(2+) for mediating nucleic acid catalysis.     

Sequence requirements for maturation of the 5' terminus of human 18 S rRNA in vitro.

Creation of the mature 5' terminus of human 18 S rRNA in vitro occurs via a two-step processing reaction. In the first step, an endonucleolytic activity found in HeLa cell nucleolar extract cleaves an rRNA precursor spanning the external transcribed spacer-18 S boundary at a position 3 bases upstream from the mature 18 S terminus leaving 2',3'-cyclic phosphate, 5' hydroxyl termini. In the second step, a nucleolytic activity(s) found in HeLa cell cytoplasmic extract removes the 3 extra bases and creates the authentic 5'-phosphorylated terminus of 18 S rRNA. Here we have examined the sequence requirements for the trimming reaction. The trimming activity(s), in addition to requiring a 5' hydroxyl terminus, prefers the naturally occurring adenosine as the 5'-terminal base. By a combination of deletion, site-directed mutagenesis, and chemical modification interference approaches we have also identified a region of 18 S rRNA spanning bases +6 to +25 (with respect to the mature 5' end) which comprises a critical recognition sequence for the trimming activity(s).     

Crystal structure of the 2'-5' RNA ligase from Thermus thermophilus HB8

The 2'-5' RNA ligase family members are bacterial and archaeal RNA ligases that ligate 5' and 3' half-tRNA molecules with 2',3'-cyclic phosphate and 5'-hydroxyl termini, respectively, to the product containing the 2'-5' phosphodiester linkage. Here, the crystal structure of the 2'-5' RNA ligase protein from an extreme thermophile, Thermus thermophilus HB8, was solved at 2.5A resolution. The structure of the 2'-5' RNA ligase superimposes well on that of the Arabidopsis thaliana cyclic phosphodiesterase (CPDase), which hydrolyzes ADP-ribose 1",2"-cyclic phosphate (a product of the tRNA splicing reaction) to the monoester ADP-ribose 1"-phosphate. Although the sequence identity between the two proteins is remarkably low (9.3%), the 2'-5' RNA ligase and CPDase structures have two HX(T/S)X motifs in their corresponding positions. The HX(T/S)X motifs play important roles in the CPDase activity, and are conserved in both the CPDases and 2'-5' RNA ligases. Therefore, the catalytic mechanism of the 2'-5' RNA ligase may be similar to that of the CPDase. On the other hand, the electrostatic potential of the cavity of the 2'-5' RNA ligase is positive, but that of the CPDase is negative. Furthermore, in the CPDase, two loops with low B-factors cover the cavity. In contrast, in the 2'-5' RNA ligase, the corresponding loops form an open conformation and are flexible. These characteristics may be due to the differences in the substrates, tRNA and ADP-ribose 1",2"-cyclic phosphate.     

tRNA ligase catalyzes the GTP-dependent ligation of RNA with 3'-phosphate and 5'-hydroxyl termini

The RNA ligase RtcB is conserved in all domains of life and is essential for tRNA maturation in archaea and metazoa. Here we show that bacterial and archaeal RtcB catalyze the GTP-dependent ligation of RNA with 3'-phosphate and 5'-hydroxyl termini. Reactions with analogues of RNA and GTP suggest a mechanism in which RtcB heals the 3'-phosphate terminus by forming a 2',3'-cyclic phosphate before joining it to the 5'-hydroxyl group of a second RNA strand. Thus, RtcB can ligate RNA cleaved by RNA endonucleases, which generate 2',3'-cyclic phosphate and then 3'-phosphate termini on one strand, and a 5'-hydroxyl terminus on another strand.     

Purification of RNA 3'-terminal phosphate cyclase from HeLa cells. Covalent modification of the enzyme with different nucleotides

RNA 3'-terminal phosphate cyclase has been purified about 6000-fold to near homogeneity from HeLa cells. The purified protein is a single polypeptide with an Mr of 38,000-40,000 and a Stokes radius of 2.66 nm. The cyclase shows a pH optimum of 8.0-9.0. In the presence of Mg2+ and ATP this enzyme catalyzes the conversion of a 3'-phosphate group into the cyclic 2',3'-phosphodiester at the 3' end of RNA, through formation of a covalent cyclase-AMP intermediate. GTP, CTP and UTP (but not dATP or ADP) can also function as cofactors in the cyclization reaction, although less efficiently (apparent Km values for ATP and GTP are 6 microM and 200 microM, respectively). Consistent with this, the enzyme can be covalently labelled with the four [alpha-32P]NTPs.     

Rcl1p, the yeast protein similar to the RNA 3'-phosphate cyclase, associates with U3 snoRNP and is required for 18S rRNA biogenesis

RNA 3'-terminal phosphate cyclases are evolutionarily conserved enzymes catalysing conversion of the 3'-terminal phosphate in RNA to the 2',3'-cyclic phosphodiester. Their biological role remains unknown. The yeast Saccharomyces cerevisiae contains a gene encoding a protein with strong sequence similarity to the characterized cyclases from humans and Escherichia coli. The gene, named RCL1 (for RNA terminal phosphate cyclase like), is essential for growth, and its product, Rcl1p, is localized in the nucleolus. Depletion or inactivation of Rcl1p impairs pre-rRNA processing at sites A(0), A(1) and A(2), and leads to a strong decrease in 18S rRNA and 40S ribosomal subunit levels. Immunoprecipitations indicate that Rcl1p is specifically associated with the U3 snoRNP, although, based on gradient analyses, it is not its structural component. Most of Rcl1p sediments in association with the 70-80S pre-ribosomal particle and a 10S complex of unknown identity. Proteins similar to Rcl1p are encoded in genomes of all eukaryotes investigated and the mouse orthologue complements yeast strains depleted of Rcl1p. Possible functions of Rcl1p in pre-rRNA processing and its relationship to the RNA 3'-phosphate cyclase are discussed.     

Crystal structure of RNA 3'-terminal phosphate cyclase, a ubiquitous enzyme with unusual topology

BACKGROUND: RNA cyclases are a family of RNA-modifying enzymes that are conserved in eucarya, bacteria and archaea. They catalyze the ATP-dependent conversion of the 3'-phosphate to the 2',3'-cyclic phosphodiester at the end of RNA, in a reaction involving formation of the covalent AMP-cyclase intermediate. These enzymes might be responsible for production of the cyclic phosphate RNA ends that are known to be required by many RNA ligases in both prokaryotes and eukaryotes. RESULTS: The high-resolution structure of the Escherichia coli RNA 3'-terminal phosphate cyclase was determined using multiwavelength anomalous diffraction. Two orthorhombic crystal forms of E. coli cyclase (space group P2(1)2(1)2(1) and P2(1)2(1)2) were used to solve and refine the structure to 2.1 A resolution (R factor 20.4%; R(free) 27.6%). Each molecule of RNA cyclase consists of two domains. The larger domain contains three repeats of a folding unit comprising two parallel alpha helices and a four-stranded beta sheet; this fold was previously identified in translation initiation factor 3 (IF3). The large domain is similar to one of the two domains of 5-enolpyruvylshikimate-3-phosphate synthase and UDP-N-acetylglucosamine enolpyruvyl transferase. The smaller domain uses a similar secondary structure element with different topology, observed in many other proteins such as thioredoxin. CONCLUSIONS: The fold of RNA cyclase consists of known elements connected in a new and unique manner. Although the active site of this enzyme could not be unambiguously assigned, it can be mapped to a region surrounding His309, an adenylate acceptor, in which a number of amino acids are highly conserved in the enzyme from different sources. The structure of E. coli cyclase will be useful for interpretation of structural and mechanistic features of this and other related enzymes.     

Purification of a RNA debranching activity from HeLa cells

The splicing of messenger RNA precursors (pre-mRNA) of eukaryotic cells involves the formation of a branched RNA intermediate known as a RNA lariat. This structure is formed in the first step of the reaction when a cleavage at the 5' splice site generates the 5' exon and a RNA species containing the intron and 3' exon in which the phosphate moiety at the 5' end of the intron is forming a 2'-5' phosphodiester bond with the 2'-hydroxyl moiety of a specific adenine residue near the 3' end of the intron forming a RNA branch with the following structure: -pA2'-pX-3'-pZ-. We have purified a debranching activity approximately 700-fold from the cytosolic fraction of HeLa cells. This activity catalyzes the hydrolysis of the 2'-5' phosphodiester bond of branched RNA structures yielding a 5'-phosphate end and a 2'-hydroxyl group at the branch attachment site. The activity possessed a sedimentation coefficient of 3.5 S. The reaction catalyzed by the purified fraction requires a divalent cation and is optimal at pH 7.0. The purified activity can efficiently hydrolyze triester trinucleotide structures (pY2'-pX-3'-pZ-) prepared by digestion of RNA lariats with nuclease P1. In contrast, a 2' phosphate monoester product (-pG2'-p 3'-pC-), formed by the wheat germ RNA ligase, was not attacked.