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.     

Perturbed folding kinetics of circularly permuted RNAs with altered topology

The folding pathway of the Tetrahymena ribozyme correlates inversely with the sequence distance between native interactions, or contact order. The rapidly folding P4-P6 domain has a low contact order, while the slowly folding P3-P7 region has a high contact order. To examine the role of topology and contact order in RNA folding, we screened for circular permutants of the ribozyme that retain catalytic activity. Permutants beginning in the P4-P6 domain fold 5 to 20 times more slowly than the wild-type ribozyme. By contrast, 50% of a permuted RNA that disjoins a non-native interaction in P3 folds tenfold faster than the wild-type ribozyme. Hence, the probability of rapidly folding to the native state depends on the topology of tertiary domains.     

Role of a conserved J8/7 X P4 base-triple in the Tetrahymena ribozyme

The Tetrahymena group I intron ribozyme folds into a complex three dimensional structure for performing the self-splicing reaction. Catalysis depends on its core structure comprising two helical domains, P4-P6 and P3-P7. The two domains are joined by three sets of conserved base-triple(s) and other tertiary interactions. We found that the disruption of J8/7 X P4, one such conserved base-triple, causes the catalytic ability to deteriorate without altering the folding rate. This suggests that the base-triple stabilizes the active structure of the ribozyme but plays no significant role in RNA folding. By combining the present and previous results, it can be concluded that three sets of conserved base-triples play distinct roles in the Tetrahymena ribozyme.     

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.     

Designed structural-rearrangement of an active group I ribozyme

The catalytic core of the Tetrahyemena group I ribozyme consists of two functionally different domains, P4-P6 and P3-P7, that are conjugated via multiple tertiary interactions. The sequence encoding the P3-P7 domain is divided into two fragments in its primary sequence although the two domains are physically separable in the three dimensional (3D-) structure of the ribozyme: The sequence encoding the P4-P6 domain is inserted into that of the P3-P7 domain. An artificial rearrangement was designed and attempted for the primary sequence of the P3-P7 domain on the basis of a 3D-structural model and the biochemical data on the ribozyme. The domain in the primary structure was relocated to form a contiguous region while retaining the 3D-structure of the ribozyme required for self-splicing. The topologically rearranged ribozyme exhibited self-splicing activity.     

A deteriorated triple-helical scaffold accelerates formation of the Tetrahymena ribozyme active structure

The Tetrahymena group I ribozyme requires a hierarchical folding process to form its correct three-dimensional structure. Ribozyme activity depends on the catalytic core consisting of two domains, P4-P6 and P3-P7, connected by a triple-helical scaffold. The folding proceeds in the following order: (i) fast folding of the P4-P6 domain, (ii) slow folding of the P3-P7 domain, and (iii) structure rearrangement to form the active ribozyme structure. The third step is believed to directly determine the conformation of the active catalytic domain, but as yet the precise mechanisms remain to be elucidated. To investigate the folding kinetics of this step, we analyzed mutant ribozymes having base substitution(s) in the triple-helical scaffold and found that disruption of the scaffold at A105G results in modest slowing of the P3-P7 folding (1.9-fold) and acceleration of step (iii) by 5.9-fold. These results suggest that disruption or destabilization of the scaffold is a normal component in the formation process of the active structure of the wild type ribozyme.     

In vitro selection of RNAs with increased tertiary structure stability.

An in vitro selection system was devised to select RNAs based on their tertiary structural stability, independent of RNA activity. Selection studies were conducted on the P4-P6 domain from the Tetrahymena thermophila group I intron, an autonomous self-folding unit that contains several important tertiary folding motifs including the tetraloop receptor and the A-rich bulge. Partially randomized P4-P6 molecules were selected based on their ability to fold into compact structures using native gel electrophoresis in the presence of decreasing concentrations of MgCl2. After 10 rounds of the selection process, a number of sequence alterations were identified that stabilized the P4-P6 RNA. One of these, a single base deletion of C209 within the P4 helix, significantly stabilized the P4-P6 molecule and would not have been identified by an activity-based selection because of its essential role for ribozyme function. Additionally, the sequence analysis provided evidence that stabilization of secondary structure may contribute to overall tertiary stability for RNAs. This system for probing RNA structure irrespective of RNA activity allows analysis of RNA structure/function relationships by identifying nucleotides or motifs important for folding and then comparing them with RNA sequences required for function.     

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.     

The P9.1-P9.2 peripheral extension helps guide folding of the Tetrahymena ribozyme.

We have previously proposed a hierarchical model for the folding mechanism of the Tetrahymena ribozyme that may illustrate general features of the folding pathways of large RNAs. While the role of elements in the conserved catalytic core of this ribozyme during the folding process is beginning to emerge, the participation of non-conserved peripheral extensions in the kinetic folding mechanism has not yet been addressed. We now show that the 3'-terminal P9.1-P9.2 extension of the Tetrahymena ribozyme plays an important role during the folding process and appears to guide formation of the catalytic core.     

Multiple monovalent ion-dependent pathways for the folding of the L-21 Tetrahymena thermophila ribozyme

Synchrotron hydroxyl radical (*OH) footprinting is a technique that monitors the local changes in solvent accessibility of the RNA backbone on milliseconds to minutes time-scales. The Mg(2+)-dependent folding of the L-21 Sca 1 Tetrahymena thermophila ribozyme has been followed using this technique at an elevated concentration of monovalent ion (200 mM NaCl) and as a function of the initial annealing conditions and substrate. Previous studies conducted at low concentrations of monovalent ion displayed sequential folding of the P4-P6 domain, the peripheral helices and the catalytic core, with each protection displaying monophasic kinetics. For ribozyme annealed in buffer containing 200 mM NaCl and folded by the addition of 10 mM MgCl(2), multiple kinetic phases are observed for *OH protections throughout the ribozyme. The independently folding P4-P6 domain is the first to fold with its protections displaying 50-90% burst phase amplitudes. That the folding of P4-P6 within the ribozyme does not display the 100% burst phase of isolated P4-P6 at 200 mM NaCl shows that interactions with the remainder of the ribozyme impede this domain's folding. In addition, *OH protections constituting each side of a tertiary contact are not coincident in some cases, consistent with the formation of transient non-native interactions. While the peripheral contacts and triple helical scaffold exhibit substantial burst phases, the slowest protection to appear is J8/7 in the catalytic core, which displays a minimal burst amplitude and whose formation is coincident with the recovery of catalytic activity. The number of kinetic phases as well as their amplitudes and rates are different when the ribozyme is annealed in low-salt buffer and folded by the concomitant addition of monovalent and divalent cations. Annealed substrate changes the partitioning of the ribozyme among the multiple folding populations. These results provide a map of the early steps in the ribozyme's folding landscape and the degree to which the preferred pathways are dependent upon the initial reaction conditions.     

Artificial modules for enhancing rate constants of a Group I intron ribozyme without a P4-P6 core element

In this paper we report newly selected artificial modules that enhance the kcat values comparable with or higher than those of the wild-type ribozyme with broad substrate specificity. The elements required for the catalysis of Group I intron ribozymes are concentrated in the P3-P7 domain of their core region, which consists of two conserved helical domains, P4-P6 and P3-P7. Previously, we reported the in vitro selection of artificial modules residing at the peripheral region of a mutant Group I ribozyme lacking P4-P6. We found that derivatives of the ribozyme containing the modules performed the reversal of the first step of the self-splicing reaction efficiently by using their affinity to the substrate RNA, although their kcat values and substrate specificity were uninfluenced and limited, respectively. The results show that it is possible to add a variety of new domains at the peripheral region that play a role comparable with that of the conserved P4-P6 domain.     

Monovalent ion-mediated folding of the Tetrahymena thermophila ribozyme

The time-course of monovalent cation-induced folding of the L-21 Sca1 Tetrahymena thermophila ribozyme and a selected mutant was quantitatively followed using synchrotron X-ray (.OH) footprinting. Initiating folding by increasing the concentration of either Na+ or K+ to 1.5M from an initial condition of approximately 0.008 M Na+ at 42 degrees C resulted in the complete formation of tertiary contacts within the P5abc subdomain and between the peripheral helices within the dead time of our measurements (k>50 s(-1)). These results contrast with folding rates of 2-0.2 s(-1) previously observed for formation of these contacts in 10mM Mg2+ from the same initial condition. Thus, the initial formation of native tertiary contacts is inhibited by divalent but not monovalent cations. The native contacts within the catalytic core form without a detectable burst phase at rates of 0.4-1.0 s(-1) in a manner reminiscent of the Mg2+-dependent folding behavior, although tenfold faster. The tertiary interactions stabilizing the catalytic core interaction with P4-P6 and P2.1, as well as one of the protections internal for the P4-P6 domain, display progress curves with appreciable burst amplitudes and a phase comparable in rate to that of the catalytic core. That the slow folding of the ribozyme's core is a consequence of the alt-P3 secondary structure is shown by the 100% burst phase amplitudes that are observed for folding of the U273A mutant ribozyme within which the native secondary structure (P3) is strengthened. Thus, formation of a misfolded intermediate(s) resulting from the alt-P3 secondary structure is independent of ion valency while the rate at which the respective intermediates are resolved is sensitive to ion valency. The overall portrait painted by these results is that ion valency differentially affects steps in the folding process and that folding in monovalent ion alone for the U273A mutant Tetrahymena ribozyme is fast and direct.     

Assembly of an exceptionally stable RNA tertiary interface in a group I ribozyme

Group I intron RNAs contain a core of highly conserved helices flanked by peripheral domains that stabilize the core structure. In the Tetrahymena group I ribozyme, the P4, P5, and P6 helices of the core pack tightly against a three-helix subdomain called P5abc. Chemical footprinting and the crystal structure of the Tetrahymena intron P4-P6 domain revealed that tertiary interactions between these two parts of the domain create an extensive solvent-inaccessible interface. We have examined the formation and stability of this tertiary interface by providing the P5abc segment in trans to a Tetrahymena ribozyme construct that lacks P5abc (EDeltaP5abc). Equilibrium gel shift experiments show that the affinity of the P5abc and EDeltaP5abc RNAs is exceptionally strong, with a Kd of approximately 100 pM at 10 mM MgCl2 (at 37 degrees C). Chemical and enzymatic footprinting shows that the RNAs are substantially folded prior to assembly of the complex. Solvent accessibility mapping reveals that, in the absence of P5abc, the intron RNA maintains a nativelike fold but its active-site helices are not tightly packed. Upon binding of P5abc, the catalytic core becomes more tightly packed through indirect effects of the tertiary interface formation. This two-component system facilitates quantitative examination of individual tertiary contacts that stabilize the folded intron.     

Folding mechanism of the Tetrahymena ribozyme P4-P6 domain

Synchrotron X-ray-dependent hydroxyl radical footprinting was used to probe the folding kinetics of the P4-P6 domain of the Tetrahymena group I ribozyme, which forms a stable, closely packed tertiary structure. The 160-nt domain folds independently at a similar rate (approximately 2 s(-1)) as it does in the ribozyme, when folding is measured in 10 mM sodium cacodylate and 10 mM MgCl(2). Surprisingly, tertiary interactions around a three-helix junction (P5abc) within the P4-P6 domain fold at least 25 times more rapidly (k >/= 50 s(-1)) in isolation, than when part of the wild-type P4-P6 RNA. This difference implies that long-range interactions in the P4-P6 domain can interfere with folding of P5abc. P4-P6 was observed to fold much faster at higher ionic strength than in 10 mM sodium cacodylate. Analytical centrifugation was used to measure the sedimentation and diffusion coefficients of the unfolded RNA. The hydrodynamic radius of the RNA decreased from 58 to 46 A over the range of 0-100 mM NaCl. We propose that at low ionic strength, the addition of Mg(2+) causes the domain to collapse to a compact intermediate where P5abc is trapped in a non-native structure. At high ionic strength, the RNA rapidly collapses to the native structure. Faster folding most likely results from a different average initial conformation of the RNA in higher salt conditions.     

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.     

Fast folding of a ribozyme by stabilizing core interactions: evidence for multiple folding pathways in RNA

Folding of the Tetrahymena ribozyme under physiological conditions in vitro is limited by slow conversion of long-lived intermediates to the active structure. These intermediates arise because the most stable domain of the ribozyme folds 10-50 times more rapidly than the core region containing helix P3. Native gel electrophoresis and time-resolved X-ray-dependent hydroxyl radical cleavage revealed that mutations that weaken peripheral interactions between domains accelerated folding fivefold, while a point mutation that stabilizes P3 enabled 80 % of the mutant RNA to reach the native conformation within 30 seconds at 22 degrees C. The P3 mutation increased the folding rate of the catalytic core as much as 50-fold, so that both domains of the ribozyme were formed at approximately the same rate. The results show that the ribozyme folds rapidly without significantly populating metastable intermediates when native interactions in the ribozyme core are stabilized relative to peripheral structural elements.     

A Tyrosyl-tRNA Synthetase Suppresses Structural Defects in the Two Major Helical Domains of the Group I Intron Catalytic Core

TheNeurospora crassamitochondrial tyrosyl-tRNA synthetase, the CYT-18 protein, functions in splicing group I introns by promoting the formation of the catalytically active structure of the intron RNA. The group I intron catalytic core is thought to consist of two extended helical domains, one formed by coaxial stacking of P5, P4, P6, and P6a (P4-P6 domain) and the other consisting of P8, P3, P7, and P9 (P3-P9 domain). To investigate how CYT-18 stabilizes the active RNA structure, we used anEscherichia coligenetic assay based on the phage T4tdintron to systematically test the ability of CYT-18 to compensate for structural defects in three key regions of the catalytic core: J3/4 and J6/7, connecting regions that form parts of the triple-helical-scaffold structure with the P4-P6 domain, and P7, a long- range base-pairing interaction that forms the guanosine-binding site and is part of the P3-P9 domain. Our results show that CYT-18 can suppress numerous mutations that disrupt the J3/4 and J6/7 nucleotide-triple interactions, as well as mutations that disrupt base-pairing in P7. CYT-18 suppressed mutations of phylogenetically conserved nucleotide residues at all positions tested, except for the universally conserved G-residue at the guanosine-binding site. Structure mapping experiments with selected mutant introns showed that the CYT-18-suppressible J3/4 mutations primarily impaired folding of the P4-P6 domain, while the J6/7 mutations impaired folding of both the P4-P6 and P3-P9 domains to various degrees. The P7 mutations impaired the formation of both P7 and P3, thereby grossly disrupting the P3-P9 domain. The finding that the P7 mutations also impaired formation of P3 provides evidence that the formation of these two long-range pairings is interdependent in thetdintron. Considered together with previous work, the nature of mutations suppressed by CYT-18 supports a model in which CYT-18 helps assemble the P4-P6 domain and then stabilizes the two major helical domains of the catalytic core in the correct relative orientation to form the intron's active site.     

Unusual metal specificity and structure of the group I ribozyme from Chlamydomonas reinhardtii 23S rRNA

Group I intron ribozymes require cations for folding and catalysis, and the current literature indicates that a number of cations can promote folding, but only Mg2+ and Mn2+ support both processes. However, some group I introns are active only with Mg2+, e.g. three of the five group I introns in Chlamydomonas reinhardtii. We have investigated one of these ribozymes, an intron from the 23S LSU rRNA gene of Chlamydomonas reinhardtii (Cr.LSU), by determining if the inhibition by Mn2+ involves catalysis, folding, or both. Kinetic analysis of guanosine-dependent cleavage by a Cr.LSU ribozyme, 23S.5 Delta Gb, that lacks the 3' exon and intron-terminal G shows that Mn2+ does not affect guanosine binding or catalysis, but instead promotes misfolding of the ribozyme. Surprisingly, ribozyme misfolding induced by Mn2+ is highly cooperative, with a Hill coefficient larger than that of native folding induced by Mg2+. At lower Mn2+ concentrations, metal inhibition is largely alleviated by the guanosine cosubstrate (GMP). The concentration dependence of guanosine cosubstrate-induced folding suggests that it functions by interacting with the G binding site, perhaps by displacing an inhibitory Mn2+. Because of these and other properties of Cr.LSU, the tertiary structure of the intron from 23S.5 Delta Gb was examined using Fe2+-EDTA cleavage. The ground-state structure shows evidence of an unusually open ribozyme core: the catalytic P3-P7 domain and the nucleotides that connect it to the P4-P5-P6 domain are exposed to solvent. The implications of this structure for the in vitro and in vivo properties of this intron ribozyme are discussed.     

Concordant exploration of the kinetics of RNA folding from global and local perspectives

Time-resolved small-angle X-ray scattering (SAXS) with millisecond time-resolution reveals two discrete phases of global compaction upon Mg2+-mediated folding of the Tetrahymena thermophila ribozyme. Electrostatic relaxation of the RNA occurs rapidly and dominates the first phase of compaction during which the observed radius of gyration (R(g)) decreases from 75 angstroms to 55 angstroms. A further decrease in R(g) to 45 angstroms occurs in a well-defined second phase. An analysis of mutant ribozymes shows that the latter phase depends upon the formation of long-range tertiary contacts within the P4-P6 domain of the ribozyme; disruption of the three remaining long-range contacts linking the peripheral helices has no effect on the 55-45 angstroms compaction transition. A better understanding of the role of specific tertiary contacts in compaction was obtained by concordant time-resolved hydroxyl radical (OH) analyses that report local changes in the solvent accessibility of the RNA backbone. Comparison of the global and local measures of folding shows that formation of a subset of native tertiary contacts (i.e. those defining the ribozyme core) can occur within a highly compact ensemble whose R(g) is close to that of the fully folded ribozyme. Analyses of additional ribozyme mutants and reaction conditions establish the generality of the rapid formation of a partially collapsed state with little to no detectable tertiary structure. These studies directly link global RNA compaction with formation of tertiary structure as the molecule acquires its biologically active structure, and underscore the strong dependence on salt of both local and global measures of folding kinetics.     

RNA tertiary folding monitored by fluorescence of covalently attached pyrene

The pathways by which large RNAs adopt tertiary structure are just beginning to be explored, and new methods that reveal RNA folding are highly desirable. Here we report an assay for RNA tertiary folding in which the fluorescence of a covalently incorporated chromophore is monitored. Folding of the 160-nucleotide Tetrahymena group I intron P4-P6 domain was used as a test system. Guided by the P4-P6 X-ray crystal structure, we chose a nucleotide (U107) for which derivatization at the 2'-position should not perturb the folded conformation. A 15-mer RNA oligonucleotide with a 2'-amino substitution at U107 was derivatized with a pyrene chromophore on a variable-length tether, and then ligated to the remainder of P4-P6, providing a site-specifically pyrene-labeled P4-P6 derivative. Upon titration of the pyrene-derivatized P4-P6 with Mg(2+), the equilibrium fluorescence intensity reversibly increased several-fold, as expected if the probe's chemical microenvironment changes as the RNA to which it is attached folds. The concentration and specificity of divalent ions required to induce the fluorescence change (Mg(2+) approximately Ca(2+) > Sr(2+)) correlated well with biochemical folding assays that involve nondenaturing gel electrophoresis. Furthermore, mutations in P4-P6 remote from the chromophore that shifted the Mg(2+) folding requirement on nondenaturing gels also affected in a predictable way the Mg(2+) requirement for the fluorescence increase. Initial stopped-flow studies with millisecond time resolution suggest that this fluorescence method will be useful for following the kinetics of P4-P6 tertiary folding. We conclude that a single site-specifically tethered chromophore can report the formation of global structure of a large RNA molecule, allowing one to monitor both the equilibrium progress and the real-time kinetics of RNA tertiary folding.