Mutational analysis of the length of the J3/4 domain of Escherichia coli ribonuclease P ribozyme

We prepared a series of length variants of the J3/4 domain of Escherichia coli ribonuclease P (RNase P) ribozyme: the four-base long J3/4 domain (A(62)G(63)G(64)A(65)) was replaced with GGA (denoted DeltaA), GA (DeltaAG), A (DeltaAGG), AAGGA (SigmaA), AAAGGA (SigmaAA), and AAAAGGA (SigmaAAA). The results indicated that truncating and inserting operations of the J3/4 domain drastically reduced ribozyme activity (WT>SigmaAA>SigmaA>SigmaAAA>DeltaAG>DeltaA, DeltaAGG), but did not affect the cleavage site selection of a substrate by the ribozyme. The reduced ribozyme activity of each mutant was rescued to some extent by the addition of a high concentration of magnesium ions. Our data indicate that the conserved AGGA sequence was important for efficient ribozyme reactions, and suggested that the length mutations affected ribozyme activity through metal ion binding steps.     

Substrate Shape Preference of Escherichia coli Ribonuclease P Ribozyme and Holo Enzyme Using Bottom-Half Part-Shifting Variants of Pre-tRNA

We showed previously that the bacterial ribonuclease P (RNase P) ribozyme has substrate shape preference depending on the concentrations of catalytically important magnesium ions. The ribozyme discriminates a canonical cloverleaf precursor tRNA from a hairpin RNA with a CCA-tag sequence at low concentrations of magnesium ions. By detailed analysis of the shape preference using the bottom-half part-shifting variants of a tRNA precursor, we showed that the RNAs in a T-shape structure can be substrates for the ribozyme reactions even at low concentrations of magnesium ions, and that the RNA in a natural L-shape is the best substrate for both the ribozyme and the holo enzyme. The results also showed that the position of the bottom-half part did not affect the cleavage site selection of a substrate by the enzyme. Our results are the first kinetic evidence to show the importance of the bottom-half part of tRNA molecule, and our result also showed that the holo enzyme can discriminate substrate shape as well as the ribozyme at low concentrations of metal ions.     

Substrate shape preference of Escherichia coli ribonuclease P ribozyme and holo enzyme using bottom-half part-shifting variants of pre-tRNA

We showed previously that the bacterial ribonuclease P (RNase P) ribozyme has substrate shape preference depending on the concentrations of catalytically important magnesium ions. The ribozyme discriminates a canonical cloverleaf precursor tRNA from a hairpin RNA with a CCA-tag sequence at low concentrations of magnesium ions. By detailed analysis of the shape preference using the bottom-half part-shifting variants of a tRNA precursor, we showed that the RNAs in a T-shape structure can be substrates for the ribozyme reactions even at low concentrations of magnesium ions, and that the RNA in a natural L-shape is the best substrate for both the ribozyme and the holo enzyme. The results also showed that the position of the bottom-half part did not affect the cleavage site selection of a substrate by the enzyme. Our results are the first kinetic evidence to show the importance of the bottom-half part of tRNA molecule, and our result also showed that the holo enzyme can discriminate substrate shape as well as the ribozyme at low concentrations of metal ions.     

Cross-ligation and exchange reactions catalyzed by hairpin ribozymes.

The negative strand of the satellite RNA of tobacco ringspot virus (sTobRV(-)) contains a hairpin catalytic domain that shows self-cleavage and self-ligation activities in the presence of magnesium ions. We describe here that the minimal catalytic domain can catalyze a cross-ligation reaction between two kinds of substrates in trans. The cross-ligated product increased when the reaction temperature was decreased during the reaction from 37 degrees C to 4 degrees C. A two-stranded hairpin ribozyme, divided into two fragments between G45 and U46 in a hairpin loop, showed higher ligation activity than the nondivided ribozyme. The two stranded ribozyme also catalyzed an exchange reaction of the 3'-portion of the cleavage site.     

Communication between RNA folding domains revealed by folding of circularly permuted ribozymes

To study the role of sequence and topology in RNA folding, we determined the kinetic folding pathways of two circularly permuted variants of the Tetrahymena group I ribozyme, using time-resolved hydroxyl radical footprinting. Circular permutation changes the distance between interacting residues in the primary sequence, without changing the native structure of the RNA. In the natural ribozyme, tertiary interactions in the P4-P6 domain form in 1 s, while interactions in the P3-P9 form in 1-3 min at 42 degrees C. Permutation of the 5' end to G111 in the P4 helix allowed the stable P4-P6 domain to fold in 200 ms at 30 degrees C, five times faster than in the wild-type RNA, while the other domains folded five times more slowly (5-8 min). By contrast, circular permutation of the 5' end to G303 in J8/7 decreased the folding rate of the P4-P6 domain. In this permuted RNA, regions joining P2, P3 and P4 were protected in 500 ms, while the P3-P9 domain was 60-80% folded within 30 s. RNase T(1) digestion and FMN photocleavage showed that circular permutation of the RNA sequence alters the initial ensemble of secondary structures, thereby changing the tertiary folding pathways. Our results show that the natural 5'-to-3' order of the structural domains in group I ribozymes optimizes structural communication between tertiary domains and promotes self-assembly of the catalytic center.     

Conformational heterogeneity at position U37 of an all-RNA hairpin ribozyme with implications for metal binding and the catalytic structure of the S-turn

The hairpin ribozyme is an RNA enzyme that performs site-specific phosphodiester bond cleavage between nucleotides A-1 and G+1 within its cognate substrate. Previous functional studies revealed that the minimal hairpin ribozyme exhibited "gain-of-function" cleavage properties resulting from U39C or U39 to propyl linker (C3) modifications. Furthermore, each "mutant" displayed different magnesium-dependence in its activity. To investigate the molecular basis for these gain-of-function variants, crystal structures of minimal, junctionless hairpin ribozymes were solved in native (U39), and mutant U39C and U39(C3) forms. The results revealed an overall molecular architecture comprising two docked internal loop domains folded into a wishbone shape, whose tertiary interface forms a sequestered active site. All three minimal hairpin ribozymes bound Co(NH(3))(6)(3+) at G21/A40, the E-loop/S-turn boundary. The native structure also showed that U37 of the S-turn adopts both sequestered and exposed conformations that differ by a maximum displacement of 13 A. In the sequestered form, the U37 base packs against G36, and its 2'-hydroxyl group forms a water mediated hydrogen bond to O4' of G+1. These interactions were not observed in previous four-way-junction hairpin ribozyme structures due to crystal contacts with the U1A splicing protein. Interestingly, the U39C and U39(C3) mutations shifted the equilibrium conformation of U37 into the sequestered form through formation of new hydrogen bonds in the S-turn, proximal to the essential nucleotide A38. A comparison of all three new structures has implications for the catalytically relevant conformation of the S-turn and suggests a rationale for the distinctive metal dependence of each mutant.     

Essential nucleotide sequences and secondary structure elements of the hairpin ribozyme.

In vitro selection experiments have been used to isolate active variants of the 50 nt hairpin catalytic RNA motif following randomization of individual ribozyme domains and intensive mutagenesis of the ribozyme-substrate complex. Active and inactive variants were characterized by sequencing, analysis of RNA cleavage activity in cis and in trans, and by substrate binding studies. Results precisely define base-pairing requirements for ribozyme helices 3 and 4, and identify eight essential nucleotides (G8, A9, A10, G21, A22, A23, A24 and C25) within the catalytic core of the ribozyme. Activity and substrate binding assays show that point mutations at these eight sites eliminate cleavage activity but do not significantly decrease substrate binding, demonstrating that these bases contribute to catalytic function. The mutation U39C has been isolated from different selection experiments as a second-site suppressor of the down mutants G21U and A43G. Assays of the U39C mutation in the wild-type ribozyme and in a variety of mutant backgrounds show that this variant is a general up mutation. Results from selection experiments involving populations totaling more than 10(10) variants are summarized, and consensus sequences including 16 essential nucleotides and a secondary structure model of four short helices, encompassing 18 bp for the ribozyme-substrate complex are derived.     

Structural basis for the guanosine requirement of the hairpin ribozyme

To form a catalytically active complex, the essential nucleotides of the hairpin ribozyme, embedded within the internal loops of the two domains, must interact with one another. Little is known about the nature of these essential interdomain interactions. In the work presented here, we have used recent topographical constraints and other biochemical data in conjunction with molecular modeling (constraint-satisfaction program MC-SYM) to generate testable models of interdomain interactions. Visual analysis of the generated models has revealed a potential interdomain base pair between the conserved guanosine immediately downstream of the reactive phosphodiester (G(+1)) and C(25) within the large domain. We have tested this former model through activity assays, using all 16 combinations of bases at positions +1 and 25. When the standard ribozyme was used, catalytic activity was severely suppressed with substrates containing U(+1), C(+1), or A(+1). Similarly, mutations of the putative pairing partner (C(25) to A(25) or G(25)) reduce activity by several orders of magnitude. The U(25) substitution retains a significant level of activity, consistent with the possible formation of a G.U wobble pair. Strikingly, when combinations of Watson-Crick (or wobble) base pairs were introduced in these positions, catalytic activity was restored, strongly suggesting the existence of the proposed interaction. These results provide a structural basis for the guanosine requirement of this ribozyme and indicate that the hairpin ribozyme can now be engineered to cleave a wider range of RNA sequences.     

Structural variability of rabbit secretory components. Allotype-associated differences in the third, fourth, and fifth domains

We have previously shown (Frutiger, S., Hughes, G. J., Hanly, W. C., Kingzette, M., and Jaton, J.-C. (1986) J. Biol. Chem. 261, 16673-16681) that limited tryptic digestion of the high Mr form of rabbit secretory component of allotypes t61, t62, and t63 generates two major fragments, the NH2-terminal domain and a 40-kDa fragment encompassing domains 3, 4, and 5. Similarly, from the low Mr form of secretory component, (SC) the NH2-terminal domain, together with a 30-kDa fragment containing domains 4 and 5, were released. These fragments were used as inhibitors in a sensitive competitive binding radioimmunoassay with noncross-reactive rabbit alloantisera to study the distribution and localization of the major allotype-specific allotopes within the SC polypeptide. The 40-kDa fragments were shown to inhibit the 125I-labeled intact SC/anti-SC allotype reaction to the extent of 90%, i.e. nearly as well as the intact homologous high Mr SC form. In contrast, the NH2-terminal fragments (domain 1) were not inhibitory. The low Mr SC of each allotype was less inhibitory on a molar basis than the homologous high Mr SC polypeptide, an observation compatible with the deletion of domains 2 and 3 in the smaller polypeptide (Deitcher, D. L., and Mostov, K. E. (1986) Mol. Cell. Biol. 6, 2712-2715; Frutiger, S., Hughes, G. J., Fonck, Ch., and Jaton, J.-C. (1987) J. Biol. Chem. 262, 1712-1715). The structural correlates of the allotypic specificities were evaluated by comparative peptide mapping of the 40-kDa fragments (allotypes t61, t62, and t63). The data suggest that the t61 allotype structure differs significantly from the t62 and t63 structures, the latter two being much more related to each other than to t61. These findings are in full agreement with the serological data. The inhibition results suggest that the major allotype-specific, noncross-reactive allotopes of SC are distributed throughout domains 3, 4, and 5, even though domain 4 appears to be more conserved than domains 3 and 5 between the allotypes t61 and t63. Seven amino acid substitutions between t61 and t63 have been detected within domains 3, 4, and 5.     

Structure and thermodynamics of metal binding in the P5 helix of a group I intron ribozyme.

The solution structure of an RNA hairpin modelling the P5 helix of a group I intron, complexed with Co(NH3)63+, has been determined by nuclear magnetic resonance. Co(NH3)63+, which possesses a geometry very close to Mg(H2O)62+, was used to identify and characterize a Mg2+binding site in the RNA. Strong and positive intermolecular nuclear Overhauser effect (NOE) cross-peaks define a specific complex in which the Co(NH3)63+molecule is in the major groove of tandem G.U base-pairs. The structure of the RNA is characterized by a very low twist angle between the two G.U base-pairs, providing a flat and narrowed major groove. The Co(NH3)63+, although highly localized, is free to rotate to hydrogen bond in several ways to the O4 atoms of the uracil bases and to N7 and O6 of the guanine bases. Negative and small NOE cross-peaks to other protons in the sequence reveal a non-specific or delocalized interaction, characterized by a high mobility of the cobalt ion. Mn2+titrations of P5 show specific broadening of protons of the G.U base-pairs that form the metal ion binding site, in agreement with the NOE data from Co(NH3)63+. Binding constants for the interaction of Co(NH3)63+and of Mg2+to P5 were determined by monitoring imino proton chemical shifts during titration of the RNA with the metal ions. Dissociation constants are on the order of 0.1 mM for Co(NH3)63+and 1 mM for Mg2+. Binding studies were done on mutants with sequences corresponding to the three orientations of tandem G.U base-pairs. The affinities of Co(NH3)63+and Mg2+for the tandem G.U base-pairs depend strongly on their sequences; the differences can be understood in terms of the different structures of the corresponding metal ion-RNA complexes. Substitution of G.C or A.U for G.U pairs also affected the binding, as expected. These structural and thermodynamic results provide systematic new information about major groove metal ion binding in RNA.     

Nuclear magnetic resonance studies of the hammerhead ribozyme domain. Secondary structure formation and magnesium ion dependence

Proton nuclear magnetic resonance (n.m.r.) experiments were used to probe base-pair formation in several hammerhead RNA enzyme (ribozyme) domains. The hammerhead domains consist of a 34 nucleotide ribozyme bound to a complementary 13 nucleotide non-cleavable DNA substrate. Three hammerhead domains were studied that differ in the sequence and stability of one of the helices involved in recognition of the substrate by the ribozyme. The n.m.r. data show a 1:1 stoichiometry for the ribozyme-substrate complexes. The imino proton resonances in the hammerhead complexes were assigned by two-dimensional nuclear Overhauser effect experiments. These data confirm the presence of two of the three helical regions in the hammerhead domain, predicted from phylogenetic data; and are also consistent with the formation of the third helix. Since a divalent cation is required for efficient catalytic activity of the hammerhead domain, the magnesium ion dependence of the n.m.r. spectra was studied for two of the hammerhead complexes. One of the complexes showed very large spectral changes upon addition of magnesium ions. However, the complex that has the most C.G base-pairs in one of the recognition helices shows essentially no spectral (and therefore presumably structural) changes upon addition of magnesium. These data are consistent with a model where the magnesium binding site already exists in the magnesium-free complex, suggesting that the magnesium ion serves primarily a catalytic, and not a structural, role under the conditions used here.     

A conformational change in the "loop E-like" motif of the hairpin ribozyme is coincidental with domain docking and is essential for catalysis

The catalysis of site-specific RNA cleavage and ligation by the hairpin ribozyme requires the formation of a tertiary interaction between two independently folded internal loop domains, A and B. Within the B domain, a tertiary structure has been identified, known as the loop E motif, that has been observed in many naturally occurring RNAs. One characteristic of this motif is a partial cross-strand stack of a G residue on a U residue. In a few cases, including loop B of the hairpin ribozyme, this unusual arrangement gives rise to photoreactivity. In the hairpin, G21 and U42 can be UV cross-linked. Here we show that docking of the two domains correlates very strongly with a loss of UV reactivity of these bases. The rate of the loss of photoreactivity during folding is in close agreement with the kinetics of interdomain docking as determined by hydroxyl-radical footprinting and fluorescence resonance energy transfer (FRET). Fixing the structure of the complex in the cross-linked form results in an inability of the two domains to dock and catalyze the cleavage reaction, suggesting that the conformational change is essential for catalysis.     

Importance of specific nucleotides in the folding of the natural form of the hairpin ribozyme

The hairpin ribozyme in its natural context consists of two loops in RNA duplexes that are connected as arms of a four-way helical junction. Magnesium ions induce folding into the active conformation in which the two loops are in proximity. In this study, we have investigated nucleotides that are important to this folding process. We have analyzed the folding in terms of the cooperativity and apparent affinity for magnesium ions as a function of changes in base sequence and functional groups, using fluorescence resonance energy transfer. Our results suggest that the interaction between the loops is the sum of a number of component interactions. Some sequence variants such as A10U, G+1A, and C25U exhibit loss of cooperativity and reduced affinity of apparent magnesium ion binding. These variants are also very impaired in ribozyme cleavage activity. Nucleotides A10, G+1, and C25 thus appear to be essential in creating the conformational environment necessary for ion binding. The double variant G+1A/C25U exhibits a marked recovery of both folding and catalytic activity compared to either individual variant, consistent with the proposal of a triple-base interaction among A9, G+1, and C25 [Pinard, R., Lambert, D., Walter, N. G., Heckman, J. E., Major, F., and Burke, J. M. (1999) Biochemistry 38, 16035-16039]. However, substitution of A9 leads to relatively small changes in folding properties and cleavage activity, and the double variant G+1DAP/C25U (DAP is 2,6-diaminopurine), which could form an isosteric triple-base interaction, exhibits folding and cleavage activities that are both very impaired compared to those of the natural sequence. Our results indicate an important role for a Watson--Crick base pair between G+1 and C25; this may be buttressed by an interaction with A9, but the loss of this has less significant consequences for folding. 2'-Deoxyribose substitution leads to folding with reduced magnesium ion affinity in the following order: unmodified RNA > dA9 > dA10 > dC25 approximately dA10 plus dC25. The results are interpreted in terms of an interaction between the ribose ring of C25 and the ribose and base of A10, in agreement with the proposal of Ryder and Strobel [Ryder, S. P., and Strobel, S. A. (1999) J. Mol. Biol. 291, 295-311]. In general, there is a correlation between the ability to undergo ion-induced folding and the rate of ribozyme cleavage. An exception to this is provided by G8, for which substitution with uridine leads to severe impairment of cleavage but folding characteristics that are virtually unaltered from those of the natural species. This is consistent with a direct role for the nucleobase of G8 in the chemistry of cleavage.     

Specificity of the hairpin ribozyme. Sequence requirements surrounding the cleavage site.

Substrate sequence requirements of the hairpin ribozyme have been partially defined by both mutational and in vitro selection experiments. It was considered that the best targets were those that included the N downward arrowGUC sequence surrounding the cleavage site. In contrast to previous studies that failed to evaluate all possible combinations of these nucleotides, we have performed an exhaustive analysis of the cleavage of 64 substrate variants. They represent all possible sequence combinations of the J2/1 nucleotides except the well established G(+1). No cleavage was observed with 24 sequences. C(+2) variants showed little or no cleavage, whereas U(+2) substrates were all cleavable. The maximal cleavage rate was obtained with the AGUC substrate. Cleavage rates of sequences HGUC (H = A, C, or U), GGUN, GGGR (R = A or G), AGUU, and UGUA were up to 5 times lower than the AGUC one. This shows that other sequences besides NGUC could also be considered as good targets. A second group of sequences WGGG (W = A or U), UGUK (K = G or U), MGAG (M = A or C), AGUA, and UGGA were cleaved between 6 and 10 times less efficiently. Furthermore, the UGCU sequence of a noncleavable viral target was mutated to AGUC resulting in a proficiently cleavable substrate by its cognate hairpin ribozyme. This indicates that our conclusions may be extrapolated to other hairpin ribozymes with different specificity.     

Evidence for processivity and two-step binding of the RNA substrate from studies of J1/2 mutants of the Tetrahymena ribozyme.

J1/2 of the Tetrahymena ribozyme, a sequence of three A residues, connects the RNA-binding site to the catalytic core. Addition or deletion of bases from J1/2 improves turnover and substrate specificity in the site-specific endonuclease reaction catalyzed by this ribozyme: G2CCCUCUA5 (S) + G in-equilibrium G2CCCUCU (P) + GA5. These paradoxical enhancements are caused by decreased affinity of the ribozyme for S and P [Young, B., Herschlag, D., & Cech, T.R. (1991) Cell 67, 1007]. An additional property of these mutant ribozymes, decreased fidelity of RNA cleavage, is now analyzed. (Fidelity is the ability to cleave at the correct phosphodiester bond within a particular RNA substrate.) Introduction of deoxy residues to give "chimeric" ribo/deoxyribooligonucleotides changes the positions of incorrect cleavage. Previous work indicated that S is bound to the ribozyme by both base pairing and teritary interactions involving 2'-hydroxyl groups of S. The data herein strongly suggest that the P1 duplex, which consists of S base-paired with the 5' exon binding site of the ribozyme, can dock into tertiary interactions in different registers; different 2'-hydroxyl groups of S plug into tertiary contacts with the ribozyme in the different registers. It is concluded that the mutations decrease fidelity by increasing the probability of docking out of register relative to docking in the normal register, thereby giving cleavage at different positions along S. These data also show that the contribution of J1/2 to the teritiary interactions is indirect, not direct. Thus, a structural role of the nonconserved J1/2 is indicated: this sequence positions S to optimize tertiary binding interactions and to ensure cleavage at the phosphodiester bond corresponding to the 5' splice site. Substitution of sulfur for the nonbridging pro-RP oxygen atom at the normal cleavage site has no effect on (kcat/Km)S but decreases the fraction of cleavage at the normal site in reactions catalyzed by the -3A mutant ribozyme, which has all three A residues of J1/2 removed. Thus, the ribozyme chooses where to cleave S after rate-limiting binding of S, indicating that docking can change after binding and suggesting that the ribozyme could act processively. Indeed, it is shown that the +2A ribozyme cleaves at one position along an RNA substrate and then, before releasing that RNA product, cleaves it again.(ABSTRACT TRUNCATED AT 400 WORDS)     

NAIM and site-specific functional group modification analysis of RNase P RNA: magnesium dependent structure within the conserved P1-P4 multihelix junction contributes to catalysis

The tRNA processing endonuclease ribonuclease P contains an essential and highly conserved RNA molecule (RNase P RNA) that is the catalytic subunit of the enzyme. To identify and characterize functional groups involved in RNase P RNA catalysis, we applied self-cleaving ribozyme-substrate conjugates, on the basis of the RNase P RNA from Escherichia coli, in nucleotide analogue interference mapping (NAIM) and site-specific modification experiments. At high monovalent ion concentrations (3 M) that facilitate protein-independent substrate binding, we find that the ribozyme is largely insensitive to analogue substitution and that concentrations of Mg2+ (1.25 mM) well below that necessary for optimal catalytic rate (>100 mM) are required to produce interference effects because of modification of nucleotide bases. An examination of the pH dependence of the reaction rate at 1.25 mM Mg2+ indicates that the increased sensitivity to analogue interference is not due to a change in the rate-limiting step. The nucleotide positions detected by NAIM under these conditions are located exclusively in the catalytic domain, consistent with the proposed global structure of the ribozyme, and predominantly occur within the highly conserved P1-P4 multihelix junction. Several sensitive positions in J3/4 and J2/4 are proximal to a previously identified site of divalent metal ion binding in the P1-P4 element. Kinetic analysis of ribozymes with site-specific N7-deazaadenosine and deazaguanosine modifications in J3/4 was, in general, consistent with the interference results and also permitted the analysis of sites not accessible by NAIM. These results show that, in this region only, modification of the N7 positions of A62, A65, and A66 resulted in measurable effects on reaction rate and modification at each position displayed distinct sensitivities to Mg2+ concentration. These results reveal a restricted subset of individual functional groups within the catalytic domain that are particularly important for substrate cleavage and demonstrate a close association between catalytic function and metal ion-dependent structure in the highly conserved P1-P4 multihelix junction.     

A covariant change of the two highly conserved bases in the GTPase-associated center of 28 S rRNA in silkworms and other moths

The GTPase-associated center in 23/28 S rRNA is one of the most conserved functional domains throughout all organisms. We detected a unique sequence of this domain in Bombyx mori species in which the bases at positions 1094 and 1098 (numbering from Escherichia coli 23 S rRNA) are C and G instead of the otherwise universally conserved bases U and A, respectively. These changes were also observed in four other species of moths, but not in organisms other than the moths. Characteristics of the B. mori rRNA domain were investigated by native polyacrylamide gel electrophoresis using RNA fragments containing residues 1030-1128. Although two bands of protein-free RNA appeared on gel, they shifted to a single band when bound to Bombyx ribosomal proteins Bm-L12 and Bm-P complex, equivalent to E. coli L11 and L8, respectively. Bombyx RNA showed lower binding capacity than rat RNA for the ribosomal proteins and anti-28 S autoantibody, specific for a folded structure of the eukaryotic GTPase-associated domain. When the C(1094)/G(1098) bases in Bombyx RNA were replaced by the conserved U/A bases, the protein-free RNA migrated as a single band, and the complex formation with Bm-L12, Bm-P complex, and anti-28 S autoantibody was comparable to that of rat RNA. The results suggest that the GTPase-associated domain of moth-type insects has a labile structural feature that is caused by an unusual covariant change of the U(1094)/A(1098) bases to C/G.     

Essential roles of innersphere metal ions for the formation of the glutamine binding site in a bifunctional ribozyme.

Numerous studies on naturally occurring ribozymes have shown that the functional roles of metal ions in promoting RNA catalysis are diverse. Earlier studies performed on the in vitro selected aminoacyl-transferase ribozyme (ATRib) have revealed that a fully hydrated Mg2+ ion plays an essential role in catalysis [Suga, H., Cowan, J. A., and Szostak, J. W. (1998) Biochemistry 28, 10118-10125]. More recently, we have evolved this ATRib into a bifunctional ribozyme, called AD02 [Lee, N., et al. (2000) Nat. Struct. Biol. 7, 28-33]. This new ribozyme consists of two catalytic domains, the original ATRib domain and a new glutamine-recognition (QR) domain, and exhibits a function of charging glutamine to tRNA. Here we elucidate crucial roles of metal ions involved in the QR domain, that are distinct from those in the ATRib domain. The metal ions in the QR domain require innersphere coordinations, and both Mg2+ and Ca2+ can support catalysis. Extensive Tb3+-Mg2+ and Tb3+-Co(NH3)6(3+) competition cleavage experiments have shown that the QR domain has high and low affinity metal binding sites, which are involved in the Mg2+-dependent structural alteration to form the glutamine binding site [Lee, N., and Suga, H. (2001) RNA 7, 1043-1051]. Kinetic studies in the presence of divalent and monovalent ions have suggested that the essential role of the metal ions in the QR domain is most likely structural.     

Concurrent molecular recognition of the amino acid and tRNA by a ribozyme.

We have recently reported an in vitro-evolved precursor tRNA (pre-tRNA) that is able to catalyze aminoacylation on its own 3'-hydroxyl group. This catalytic pre-tRNA is susceptible to RNase P RNA, generating the 5'-leader ribozyme and mature tRNA. The 5'-leader ribozyme is also capable of aminoacylating the tRNA in trans, thus acting as an aminoacyl-tRNA synthetase-like ribozyme (ARS-like ribozyme). Here we report its structural characterization that reveals the essential catalytic core. The ribozyme consists of three stem-loops connected by two junction regions. The chemical probing analyses show that a U-rich region (U59-U62 in J2a/3 and U67-U68 in L3) of the ribozyme is responsible for the recognition of the phenylalanine substrate. Moreover, a GGU-motif (G70-U72) of the ribozyme, adjacent to the U-rich region, forms base pairs with the tRNA 3' terminus. Our demonstration shows that simple RNA motifs can recognize both the amino acid and tRNA simultaneously, thus aminoacylating the 3' terminus of tRNA in trans.