Mg2+ mimicry in the promotion of group I ribozyme activities by aminoglycoside antibiotics

Aminoglycoside antibiotics inhibit several types of ribozymes, including group I introns, by displacing critical Mg2+ ions. However, they stimulate activity of the small hairpin ribozyme. We show here that aminoglycosides promote self-splicing of the Cr.psbA2 group I intron at subthreshold Mg2+ concentrations. Neomycin is the most effective of the aminoglycosides tested; it stimulates splicing of Cr.psbA2 at micromolar concentrations, and, in this respect, is >100-fold more effective than spermidine. At optimal Mg2+ for Cr.psbA2 splicing, these drugs, especially kanamycin B and tobramycin, promote GTP attack at the 3' splice-site. Kinetic analysis suggests that this is due to an alternatively folded state of the ribozyme that is induced, or stabilized, by aminoglycosides. A similar effect is observed at high Mg2+ concentrations. Comparing the effects of structurally related aminoglycosides indicates that splicing promotion is more sensitive to drug structure than misfolding and occurs at lower drug concentrations. These data show that aminoglycosides can promote biochemical activities of a large ribozyme by acting as a Mg2+ mimic. The results also underscore the functional diversity of group I introns in nature.     

Ribozyme-catalyzed dipeptide synthesis in monovalent metal ions alone

Previously we have identified a highly active ribozyme (R180, cis ribozyme) that can catalyze dipeptide synthesis using N-biotinylcaproyl-aminoacyl-adenylate anhydride (Bio-aa-5'-AMP) as its substrate. In this work, we re-engineered the cis R180 ribozyme into a 158-nt trans ribozyme (TR158) and designed a new substrate (5'-Phe-linker-20-mer). First, the metal ion requirements were examined and compared between the two ribozymes. Both R180 and TR158 ribozymes were active in Mg2+ and Ca2+ but inert with Zn2+, Cu2+, Mn2+, and Co2+. It is intriguing that both ribozymes were highly active in Li+, Na+, or K+ alone but showed very low activity with NH4+. The two ribozymes showed similar linear concentration dependence on Li+ and K+, while they displayed different dependency behavior on Mg2+. Moreover, by using the trans system, the detailed kinetic studies and pH dependent experiments were performed in either 10 mM Mg2+ or 1.0 M Li+. Analysis of kcat and Km values obtained at different pHs (6.0 to 9.0) indicated that it is the catalytic activity of the ribozyme but not the substrate binding affinity that changes significantly with pH. The slopes of the linear parts of the pH-rate plots were close to 1.0 in both Mg2+- and Li+-mediated reactions, suggesting that one proton transfer is involved in the rate-limiting step of catalysis. Overall, our results suggest that Mg2+ and Li+ function similarly in the ribozyme-catalyzed dipeptide synthesis.     

In vitro self-splicing reactions of the chloroplast group I intron Cr.LSU from Chlamydomonas reinhardtii and in vivo manipulation via gene-replacement.

The group I intron from the chloroplast rRNA large subunit of Chlamydomonas reinhardtii (Cr.LSU) undergoes autocatalytic splicing in vitro. Cr.LSU displays a range of reactions typical of other group I introns. Under optimal conditions, the 5' cleavage step proceeds rapidly, but the exon-ligation step is relatively slow, and no pH dependent hydrolysis of the 3' splice site occurs. A requirement for high temperature and high [Mg2+] suggests involvement of additional splicing factors in vivo. The positions of three cyclization sites of the free intron have been mapped; two of these sites represent reactions analogous to 5'-splice site cleavage, whereas the third is an example of G-exchange. Cr.LSU contains an open reading frame (ORF) potentially encoding an 163 amino acid polypeptide. ORF function has been investigated by using chloroplast gene replacement via particle bombardment. We have shown that the ORF can be deleted from Cr.LSU without affecting splicing in vivo and it thus does not encode an essential splicing factor.     

Relationship between the self-splicing activity and the solidity of the master domain of the Tetrahymena group I ribozyme

The highly conserved P3-P7 domain of the Group I intron ribozymes is known to contain essential elements, such as the binding site for the cofactor guanosine, required for conducting the splicing reaction. We investigated the domain of the Tetrahymena intron ribozyme and its variants in order to clarify the relationship between its stability and function. We found that the destabilization of the P3-P7 domain facilitates the active structure formation at high magnesium ion concentrations where the formation is retarded for the wild type. The destabilized domain also increases K(GTP)(m) although this can be compensated by increasing the concentration of Mg(2+), indicating that the stable domain is required for establishing a tight guanosine binding site. The results suggest that the stability of the domain affects the rate-limiting step in the RNA folding pathway and also regulates the efficiency of the splicing reaction.     

Productive folding to the native state by a group II intron ribozyme.

Group II introns are large catalytic RNA molecules that fold into compact structures essential for the catalysis of splicing and intron mobility reactions. Despite a growing body of information on the folded state of group II introns at equilibrium, there is currently no information on the folding pathway and little information on the ionic requirements for folding. Folding isotherms were determined by hydroxyl radical footprinting for the 32 individual protections that are distributed throughout a group II intron ribozyme derived from intron ai5gamma. The isotherms span a similar range of Mg(2+) concentrations and share a similar index of cooperativity. Time-resolved hydroxyl radical footprinting studies show that all regions of the ribozyme fold slowly and with remarkable synchrony into a single catalytically active structure at a rate comparable to those of other ribozymes studied thus far. The rate constants for the formation of tertiary contacts and recovery of catalytic activity are identical within experimental error. Catalytic activity analyses in the presence of urea provide no evidence that the slow folding of the ai5gamma intron is attributable to the presence of unproductive kinetic traps along the folding pathway. Taken together, the data suggest that the rate-limiting step for folding of group II intron ai5gamma occurs early along the reaction pathway. We propose that this behavior resembles protein folding that is limited in rate by high contact order, or the need to form key tertiary interactions from partners that are located far apart in the primary or secondary structure.     

Folding of the group I intron ribozyme from the 26S rRNA gene of Candida albicans

Preincubation of the group I intron Ca.LSU from Candida albicans at 37°C in the absence of divalent cations results in partial folding of this intron. This is indicated by increased resistance to T1 ribonuclease cleavage of many G residues in most local helices, including P4-P6, as well as the non-local helix P7, where the G binding site is located. These changes correlate with increased gel mobility and activation of catalysis by precursor RNA containing this intron after preincubation. The presence of divalent cations or spermidine during preincubation results in formation of the predicted helices, as indicated by protection of additional G residues. However, addition of these cations during preincubation of the precursor RNA alters its gel mobility and eliminates the preincubation activation of precursor RNA seen in the absence of cations. These results suggest that, in the presence of divalent cations or spermidine, Ca.LSU folds into a more ordered, stable but misfolded conformation that is less able to convert into the catalytically active form than the ribozyme preincubated without cations. These results indicate that, like the group I intron of Tetrahymena, multiple folding pathways exist for Ca.LSU. However, it appears that the role cations play in the multiple folding pathways leading to the catalytically active form may differ between folding of these two group I introns.     

Perturbation of the hierarchical folding of a large RNA by the destabilization of its Scaffold's tertiary structure

The P4-P6 domain serves as a scaffold against which the periphery and catalytic core organize and fold during Mg2+-mediated folding of the Tetrahymena thermophila ribozyme. The most prominent structural motif of the P4-P6 domain is the tetraloop-tetraloop receptor interaction which "clamps" the distal parts of its hairpin-like structure. Destabilization of the tertiary structure of the P4-P6 domain by perturbation of the tetraloop-tetraloop receptor interaction alters the Mg2+-mediated folding pathway. The folding hierarchy of P5c approximately P4-P6 > periphery > catalytic core that is a striking attribute of the folding of the wild-type RNA is abolished. The initial steps in folding of the mutant RNA are > or =50-fold faster than those of the wild-type ribozyme with the earliest observed tertiary contacts forming around regions known to specifically bind Mg2+. The interaction between the mutant tetraloop and the tetraloop receptor appears coincidently with slowly forming catalytic core tertiary contacts. Thus, the stability conferred upon the P4-P6 domain by the tetraloop-tetraloop receptor interaction dictates the preferred folding pathway by stabilizing an early intermediate. A sub-denaturing concentration of urea diminishes the early barrier to folding the wild-type ribozyme along with complex effects on the subsequent steps of folding the wild-type and mutant RNA.     

Metal ion interaction with cosubstrate in self-splicing of group I introns.

The catalytic mechanism for self-splicing of the group I intron in the pre-mRNA from the nrdB gene in bacteriophage T4 has been investigated using 2'-amino- 2'-deoxyguanosine or guanosine as cosubstrates in the presence of Mg2+, Mn2+and Zn2+. The results show that a divalent metal ion interacts with the cosubstrate and thereby influences the efficiency of catalysis in the first step of splicing. This suggests the existence of a metal ion that catalyses the nucleophilic attack of the cosubstrate. Of particular significance is that the transesterification reactions of the first step of splicing with 2'-amino-2'-deoxyguanosine as cosubstrate are more efficient in mixtures containing either Mn2+or Zn2+together with Mg2+than with only magnesium ions present. The experiments in metal ion mixtures show that two (or more) metal ions are crucial for the self-splicing of group I introns and suggest the possibility that more than one of these have a direct catalytic role. A working model for a two-metal-ion mechanism in the transesterification steps is suggested.     

Evolutionary transfer of ORF-containing group I introns between different subcellular compartments (chloroplast and mitochondrion)

We describe here a case of homologous introns containing homologous open reading frames (ORFs) that are inserted at the same site in the large subunit (LSU) rRNA gene of different organelles in distantly related organisms. We show that the chloroplast LSU rRNA gene of the green alga Chlamydomonas pallidostigmatica contains a group I intron (CpLSU.2) encoding a site-specific endonuclease (I-CpaI). This intron is inserted at the identical site (corresponding to position 1931-1932 of the Escherichia coli 23S rRNA sequence) as a group I intron (AcLSU.m1) in the mitochondrial LSU rRNA gene of the amoeboid protozoon Acanthamoeba castellanii. The CpLSU.2 intron displays a remarkable degree of nucleotide similarity in both primary sequence and secondary structure to the AcLSU.m1 intron; moreover, the Acanthamoeba intron contains an ORF in the same location within its secondary structure as the CpLSU.2 ORF and shares with it a strikingly high level of amino acid similarity (65%; 42% identity). A comprehensive survey of intron distribution at site 1931 of the chloroplast LSU rRNA gene reveals a rather restricted occurrence within the polyphyletic genus Chlamydomonas, with no evidence of this intron among a number of non- Chlamydomonad green algae surveyed, nor in land plants. A parallel survey of homologues of a previously described and similar intron/ORF pair (C. reinhardtii chloroplast CrLSU/A. castellanii mitochondrial AcLSU.m3) also shows a restricted occurrence of this intron (site 2593) among chloroplasts, although the intron distribution is somewhat broader than that observed at site 1931, with site-2593 introns appearing in several green algal branches outside of the Chlamydomonas lineage. The available data, while not definitive, are most consistent with a relatively recent horizontal transfer of both site-1931 and site- 2593 introns (and their contained ORFs) between the chloroplast of a Chlamydomonas-type organism and the mitochondrion of an Acanthamoeba- like organism, probably in the direction chloroplast to mitochondrion. The data also suggest that both introns could have been acquired in a single event.      

Mapping divalent metal ion binding sites in a group II intron by Mn(2+)- and Zn(2+)-induced site-specific RNA cleavage.

The function of group II introns depends on positively charged divalent metal ions that stabilize the ribozyme structure and may be directly involved in catalysis. We investigated Mn2+- and Zn2+-induced site-specific RNA cleavage to identify metal ions that fit into binding pockets within the structurally conserved bI1 group II intron domains (DI-DVI), which might fulfill essential roles in intron function. Ten cleavage sites were identified in DI, two sites in DIII and two in DVI. All cleavage sites are located in the center or close to single-stranded and flexible RNA structures. Strand scissions mediated by Mn2+/Zn2+ are competed for by Mg2+, indicating the existence of Mg2+ binding pockets in physical proximity to the observed Mn2+-/Zn2+-induced cleavage positions. To distinguish between metal ions with a role in structure stabilization and those that play a more specific and critical role in the catalytic process of intron splicing, we combined structural and functional assays, comparing wild-type precursor and multiple splicing-deficient mutants. We identified six regions with binding pockets for Mg2+ ions presumably playing an important role in bI1 structure stabilization. Remarkably, assays with DI deletions and branch point mutants revealed the existence of one Mg2+ binding pocket near the branching A, which is involved in first-step catalysis. This pocket formation depends on precise interaction between the branching nucleotide and the 5' splice site, but does not require exon-binding site 1/intron binding site 1 interaction. This Mg2+ ion might support the correct placing of the branching A into the 'first-step active site'.     

Crystal structure of a phage Twort group I ribozyme-product complex

Group I introns are catalytic RNAs capable of orchestrating two sequential phosphotransesterification reactions that result in self-splicing. To understand how the group I intron active site facilitates catalysis, we have solved the structure of an active ribozyme derived from the orf142-I2 intron from phage Twort bound to a four-nucleotide product RNA at a resolution of 3.6 A. In addition to the three conserved domains characteristic of all group I introns, the Twort ribozyme has peripheral insertions characteristic of phage introns. These elements form a ring that completely envelops the active site, where a snug pocket for guanosine is formed by a series of stacked base triples. The structure of the active site reveals three potential binding sites for catalytic metals, and invokes a role for the 2' hydroxyl of the guanosine substrate in organization of the active site for catalysis.     

Cleavage and recognition pattern of a double-strand-specific endonuclease (I-creI) encoded by the chloroplast 23S rRNA intron of Chlamydomonas reinhardtii.

Several group-I introns have been shown to specifically invade intron-minus alleles of the genes that contain them. This type of intron mobility is referred to as 'intron homing', and depends on restriction endonucleases (ENases) encoded by the mobile introns. The ENase cleaves the intron-minus allele near the site of intron insertion, thereby initiating gene conversion. The 23S (LSU) rRNA-encoding gene (LSU) of the chloroplast genome of Chlamydomonas reinhardtii contains a self-splicing group-I intron (CrLSU) that has a free-standing open reading frame (ORF) of 163 codons. Translation of CrLSU intron RNA in cell-free systems produces a polypeptide of approx. 18 kDa, the size expected for correct translation of the ORF. The in vitro-synthesized 18-kDa protein cleaves plasmid DNA that contains a portion of LSU where the intron normally resides, but lacking the intron itself. Cleavage by the intron-encoded enzyme (I-CreI) occurs 5 bp and 1 bp 3' to the intron insertion site (in the 3'-exon) in the top (/) and bottom (,) strands, respectively, resulting in 4-nt single-stranded overhangs with 3'-OH termini. We also show that the recognition sequence of I-CreI spans the cleavage site and is 24 bp in length (5'-CAAAACGTC,GTGA/GACAGTTTGGT).     

Mutations at the guanosine-binding site of the Tetrahymena ribozyme also affect site-specific hydrolysis.

Self-splicing group I introns use guanosine as a nucleophile to cleave the 5' splice site. The guanosine-binding site has been localized to the G264-C311 base pair of the Tetrahymena intron on the basis of analysis of mutations that change the specificity of the nucleophile from G (guanosine) to 2AP (2-aminopurine ribonucleoside) (F. Michel et al. (1989) Nature 342, 391-395). We studied the effect of these mutations (G-U, A-C and A-U replacing G264-C311) in the L-21 ScaI version of the Tetrahymena ribozyme. In this enzymatic system (kcat/Km)G monitors the cleavage step. This kinetic parameter decreased by at least 5 x 10(3) when the G264-C311 base pair was mutated to an A-U pair, while (kcat/Km)2AP increased at least 40-fold. This amounted to an overall switch in specificity of at least 2 x 10(5). The nucleophile specificity (G > 2AP for the G-C and G-U pairs, 2AP > G for the A-U and A-C pairs) was consistent with the proposed hydrogen bond between the nucleotide at position 264 and N1 of the nucleophile. Unexpectedly, the A-U and A-C mutants showed a decrease of an order of magnitude in the rate of ribozyme-catalyzed hydrolysis of RNA, in which H2O or OH- replaces G as the nucleophile, whereas the G-U mutant showed a decrease of only 2-fold. The low hydrolysis rates were not restored by raising the Mg2+ concentration or lowering the temperature. In addition, the mutant ribozymes exhibited a pattern of cleavage by Fe(II)-EDTA indistinguishable from that of the wild type, and the [Mg2+]1/2 for folding of the A-U mutant ribozyme was the same as that of the wild type. Therefore the guanosine-binding site mutations do not appear to have a major effect on RNA folding or stability. Because changing G264 affects the hydrolysis reaction without perturbing the global folding of the RNA, we conclude that the catalytic role of this conserved nucleotide is not limited to guanosine binding.     

Kinetic pathway for folding of the Tetrahymena ribozyme revealed by three UV-inducible crosslinks.

The kinetics of RNA folding were examined in the L-21 ribozyme, an RNA enzyme derived from the self-splicing Tetrahymena intron. Three UV-inducible crosslinks were mapped, characterized, and used as indicators for the folded state of the ribozyme. Together these data suggest that final structures are adopted first by the P4-P6 independently folding domain and only later in a region that positions the P1 helix (including the 5' splice site), a region whose folding is linked to that of a portion of the catalytic core. At intermediate times, a non-native structure forms in the region of the triple helical scaffold, which connects the major folding domains. At 30 degrees C, the unfolded ribozyme passes through these stages with a half-life of 2 min from the time magnesium cations are provided. At higher temperatures, the half-life is shortened but the order of events is unchanged. Thermal melting of the fully folded ribozyme also revealed a multi-stage process in which the steps of folding are reversed: the kinetically slowest structure is the least stable and melts first. These structures of the ribozyme also bind Mg2+ cooperatively and their relative affinity for binding seems to be a major determinant in the order of events during folding. Na+ can also substitute for Mg2+ to give rise to the same crosslinkable structures, but only at much higher concentrations. Specific binding sites for Mg2+ may make this cation particularly efficient at electrostatic stabilization during folding of these ribozyme structures.     

Monitoring intermediate folding states of the td group I intron in vivo

Group I introns consist of two major structural domains, the P4-P6 and P3-P9 domains, which assemble through interactions with peripheral extensions to fold into an active ribozyme. To assess group I intron folding in vivo, we probed the structure of td wild-type and mutant introns using dimethyl sulfate. The results suggest that the majority of the intron population is in the native state in accordance with the current structural model, which was refined to include two novel tertiary contacts. The importance of the loop E motif in the P7.1-P7.2 extension in assisting ribozyme folding was deduced from modeling and mutational analyses. Destabilization of stem P6 results in a deficiency in tertiary structure formation in both major domains, while weakening of stem P7 only interferes with folding of the P3-P9 domain. The different impact of mutations on the tertiary structure suggests that they interfere with folding at different stages. These results provide a first insight into the structure of folding intermediates and suggest a putative order of events in a hierarchical folding pathway in vivo.     

Ribozyme cleavage of a 2,5-phosphodiester linkage: mechanism and a restricted divalent metal-ion requirement.

The natural substrate cleaved by the hepatitis delta virus (HDV) ribozyme contains a 3',5'-phosphodiester linkage at the cleavage site; however, a 2',5'-linked ribose-phosphate backbone can also be cleaved by both trans-acting and self-cleaving forms of the HDV ribozyme. With substrates containing either linkage, the HDV ribozyme generated 2',3'-cyclic phosphate and 5'-hydroxyl groups suggesting that the mechanisms of cleavage in both cases were by a nucleophilic attack on the phosphorus center by the adjacent hydroxyl group. Divalent metal ion was required for cleavage of either linkage. However, although the 3',5'-linkage was cleaved slightly faster in Ca2+ than in Mg2+, the 2',5'-linkage was cleaved in Mg2+ (or Mn2+) but not Ca2+. This dramatic difference in metal-ion specificity is strongly suggestive of a crucial metal-ion interaction at the active site. In contrast to the HDV ribozymes, cleavage at a 2',5'-phosphodiester bond was not efficiently catalyzed by the hammerhead ribozyme. The relaxed linkage specificity of the HDV ribozymes may be due in part to lack of a rigid binding site for sequences 5' to the cleavage site.     

Metal ion binding sites in a group II intron core

Group II introns are catalytic RNA molecules that require divalent metal ions for folding, substrate binding, and chemical catalysis. Metal ion binding sites in the group II core have now been elucidated by monitoring the site-specific RNA hydrolysis patterns of bound ions such as Tb(3+) and Mg(2+). Major sites are localized near active site elements such as domain 5 and its surrounding tertiary interaction partners. Numerous sites are also observed at intron substructures that are involved in binding and potentially activating the splice sites. These results highlight the locations of specific metal ions that are likely to play a role in ribozyme catalysis.     

Fast formation of the P3-P7 pseudoknot: a strategy for efficient folding of the catalytically active ribozyme

Formation of the P3-P7 pseudoknot structure, the core of group I ribozymes, requires long-range base pairing. Study of the Tetrahymena ribozyme appreciates the hierarchical folding of the large, multidomain RNA, in which the P3-P7 core folds significantly slower than do the other domains. Here we explored the formation of the P3-P7 pseudoknot of the Candida ribozyme that has been reported to concertedly fold to the catalytically active structure with a rate constant of 2 min(-1). We demonstrate that pseudoknot formation occurs during the rapid ribozyme compaction, coincident with formation of many tertiary interactions of the ribozyme. A low physiological concentration of magnesium (1.5 mM) is sufficient to fully support the pseudoknot formation. The presence of nonnative intermediates containing an unfolded P3-P7 region is evident. However, catalysis-based analysis shows these nonnative intermediates are stable and fail to convert to the catalytically active structure, suggesting that rapid pseudoknot formation is essential for folding of the active ribozyme. Interestingly, RNAstructure predicts no stable Alt P3 structure for the Candida ribozyme, but two stable Alt P3s for the Tetrahymena ribozyme, explaining the dramatic difference in folding of the P3-P7 core of these two ribozymes. We propose that rapid formation of the P3-P7 pseudoknot represents a folding strategy ensuring efficient production of the catalytically active structure of group I ribozymes, which sheds new light on the mechanism of effective ribozyme folding in vivo.     

RNA folding and catalysis mediated by iron (II)

Mg2? shares a distinctive relationship with RNA, playing important and specific roles in the folding and function of essentially all large RNAs. Here we use theory and experiment to evaluate Fe2? in the absence of free oxygen as a replacement for Mg2? in RNA folding and catalysis. We describe both quantum mechanical calculations and experiments that suggest that the roles of Mg2? in RNA folding and function can indeed be served by Fe2?. The results of quantum mechanical calculations show that the geometry of coordination of Fe2? by RNA phosphates is similar to that of Mg2?. Chemical footprinting experiments suggest that the conformation of the Tetrahymena thermophila Group I intron P4-P6 domain RNA is conserved between complexes with Fe2? or Mg2?. The catalytic activities of both the L1 ribozyme ligase, obtained previously by in vitro selection in the presence of Mg2?, and the hammerhead ribozyme are enhanced in the presence of Fe2? compared to Mg2?. All chemical footprinting and ribozyme assays in the presence of Fe2? were performed under anaerobic conditions. The primary motivation of this work is to understand RNA in plausible early earth conditions. Life originated during the early Archean Eon, characterized by a non-oxidative atmosphere and abundant soluble Fe2?. The combined biochemical and paleogeological data are consistent with a role for Fe2? in an RNA World. RNA and Fe2? could, in principle, support an array of RNA structures and catalytic functions more diverse than RNA with Mg2? alone.