Interaction of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) with the group I intron P4-P6 domain. Thermodynamic analysis and the role of metal ions

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) functions in splicing group I introns by promoting the formation of the catalytically active structure of the intron's catalytic core. Previous studies suggested a model in which the protein binds first to the intron's P4-P6 domain, and then makes additional contacts with the P3-P9 domain to stabilize the two domains in the correct relative orientation to form the intron's active site. Here, we analyzed the interaction of CYT-18 with a small RNA (P4-P6 RNA) corresponding to the isolated P4-P6 domain of the N. crassa mitochondrial large subunit ribosomal RNA intron. RNA footprinting and modification-interference experiments showed that CYT-18 binds to this small RNA around the junction of the P4-P6 stacked helices on the side opposite the active-site cleft, as it does to the P4-P6 domain in the intact intron. The binding is inhibited by chemical modifications that disrupt base-pairing in P4, P6, and P6a, indicating that a partially folded structure of the P4-P6 domain is required. The temperature-dependence of binding indicates that the interaction is driven by a favorable enthalpy change, but is accompanied by an unfavorable entropy change. The latter may reflect entropically unfavorable conformational changes or decreased conformational flexibility in the complex. CYT-18 binding is inhibited at > or =125 mM KCl, indicating a strong dependence on phosphodiester-backbone interactions. On the other hand, Mg(2+) is absolutely required for CYT-18 binding, with titration experiments showing approximately 1.5 magnesium ions bound per complex. Metal ion-cleavage experiments identified a divalent cation-binding site near the boundary of P6 and J6/6a, and chemical modification showed that Mg(2+) binding induces RNA conformational changes in this region, as well as elsewhere, particularly in J4/5. Together, these findings suggest a model in which the binding of Mg(2+) near J6/6a and possibly at one additional location in the P4-P6 RNA induces formation of a specific phosphodiester-backbone geometry that is required for CYT-18 binding. The binding of CYT-18 may then establish the correct structure at the junction of the P4/P6 stacked helices for assembly of the P3-P9 domain. The interaction of CYT-18 with the P4-P6 domain appears similar to the TyrRS interaction with the D-/anticodon arm stacked helices of tRNA(Tyr).     

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.     

The Neurospora crassa CYT-18 protein C-terminal RNA-binding domain helps stabilize interdomain tertiary interactions in group I introns

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) promotes the splicing of group I introns by stabilizing the catalytically active RNA structure. To accomplish this, CYT-18 recognizes conserved structural features of group I intron RNAs using regions of the N-terminal nucleotide-binding fold, intermediate alpha-helical, and C-terminal RNA-binding domains that also function in binding tRNA(Tyr). Curiously, whereas the splicing of the N. crassa mitochondrial large subunit rRNA intron is completely dependent on CYT-18's C-terminal RNA-binding domain, all other group I introns tested thus far are spliced efficiently by a truncated protein lacking this domain. To investigate the function of the C-terminal domain, we used an Escherichia coli genetic assay to isolate mutants of the Saccharomyces cerevisiae mitochondrial large subunit rRNA and phage T4 td introns that can be spliced in vivo by the wild-type CYT-18 protein, but not by the C-terminally truncated protein. Mutations that result in dependence on CYT-18's C-terminal domain include those disrupting two long-range GNRA tetraloop/receptor interactions: L2-P8, which helps position the P1 helix containing the 5'-splice site, and L9-P5, which helps establish the correct relative orientation of the P4-P6 and P3-P9 domains of the group I intron catalytic core. Our results indicate that different structural mutations in group I intron RNAs can result in dependence on different regions of CYT-18 for RNA splicing.     

Function of tyrosyl-tRNA synthetase in splicing group I introns: an induced-fit model for binding to the P4-P6 domain based on analysis of mutations at the junction of the P4-P6 stacked helices

We used an Escherichia coli genetic assay based on the phage T4 td intron to test the ability of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) to suppress mutations that cause structural defects around its binding site in the P4-P6 domain of the group I intron catalytic core. We analyzed all possible combinations of nucleotides at either P4 bp-1 or P6 bp-1, which together form the junction of the P4-P6 stacked helices, and looked for synergistic effects in double mutants. Most mutations at either position inhibit self-splicing, but can be suppressed by CYT-18. CYT-18 can compensate efficiently for mutations that disrupt base-pairing at either P4 bp-1 or P6 bp-1, for mutations at P6 bp-1 that disrupt the base-triple interaction with J3/4-3, and for nucleotide substitutions at either position that are predicted to be suboptimal for base stacking, based on the analysis of DNA four-way junctions. However, CYT-18 has difficulty suppressing combinations of mutations at P4 bp-1 and P6 bp-1 that simultaneously disrupt base-pairing and base stacking. Thermal denaturation and Fe(II)-EDTA analysis showed that mutations at the junction of the P4-P6 stacked helices lead to grossly impaired tertiary-structure formation centered in the P4-P6 domain. CYT-18-suppressible mutants bind the protein with K(d) values up to 79-fold higher than that for the wild-type intron, but in all cases tested, the k(off) value for the complex remains within twofold of the wild-type value, suggesting that the binding site can be formed properly and that the increased K(d) value reflects primarily an increased k(on) value for the binding of CYT-18 to the misfolded intron. Our results indicate that the P4/P6 junction is a linchpin region, where even small nucleotide substitutions grossly disrupt the catalytically-active group I intron tertiary structure, and that CYT-18 binding induces the formation of the correct structure in this region, leading to folding of the group I intron catalytic core.     

Protein Roles in Group I Intron RNA Folding: The Tyrosyl-tRNA Synthetase CYT-18 Stabilizes the Native State Relative to a Long-Lived Misfolded Structure without Compromising Folding Kinetics

The Neurospora crassa CYT-18 protein is a mitochondrial tyrosyl-tRNA synthetase that also promotes self-splicing of group I intron RNAs by stabilizing the functional structure in the conserved core. CYT-18 binds the core along the same surface as a common peripheral element, P5abc, suggesting that CYT-18 can replace P5abc functionally. In addition to stabilizing structure generally, P5abc stabilizes the native conformation of the Tetrahymena group I intron relative to a globally similar misfolded conformation that has only local differences within the core and is populated significantly at equilibrium by a ribozyme variant lacking P5abc (E^ΔP5abc). Here, we show that CYT-18 specifically promotes formation of the native group I intron core from this misfolded conformation. Catalytic activity assays demonstrate that CYT-18 shifts the equilibrium of E^ΔP5abc toward the native state by at least 35-fold, and binding assays suggest an even larger effect. Thus, similar to P5abc, CYT-18 preferentially recognizes the native core, despite the global similarity of the misfolded core and despite forming crudely similar complexes, as revealed by dimethyl sulfate footprinting. Interestingly, the effects of CYT-18 and P5abc on folding kinetics differ. Whereas P5abc inhibits refolding of the misfolded conformation by forming peripheral contacts that must break during refolding, CYT-18 does not display analogous inhibition, most likely because it relies to a greater extent on direct interactions with the core. Although CYT-18 does not encounter this RNA in vivo, our results suggest that it stabilizes its cognate group I introns relative to analogous misfolded intermediates. By specifically recognizing native structural features, CYT-18 may also interact with earlier folding intermediates to avoid RNA misfolding or to trap native contacts as they form. More generally, our results highlight the ability of a protein cofactor to stabilize a functional RNA structure specifically without incurring associated costs in RNA folding kinetics.     

Function of the C-terminal domain of the DEAD-box protein Mss116p analyzed in vivo and in vitro

The DEAD-box proteins CYT-19 in Neurospora crassa and Mss116p in Saccharomyces cerevisiae are general RNA chaperones that function in splicing mitochondrial group I and group II introns and in translational activation. Both proteins consist of a conserved ATP-dependent RNA helicase core region linked to N and C-terminal domains, the latter with a basic tail similar to many other DEAD-box proteins. In CYT-19, this basic tail was shown to contribute to non-specific RNA binding that helps tether the core helicase region to structured RNA substrates. Here, multiple sequence alignments and secondary structure predictions indicate that CYT-19 and Mss116p belong to distinct subgroups of DEAD-box proteins, whose C-terminal domains have a defining extended α-helical region preceding the basic tail. We find that mutations or C-terminal truncations in the predicted α-helical region of Mss116p strongly inhibit RNA-dependent ATPase activity, leading to loss of function in both translational activation and RNA splicing. These findings suggest that the α-helical region may stabilize and/or regulate the activity of the RNA helicase core. By contrast, a truncation that removes only the basic tail leaves high RNA-dependent ATPase activity and causes only a modest reduction in translation and RNA splicing efficiency in vivo and in vitro. Biochemical analysis shows that deletion of the basic tail leads to weaker non-specific binding of group I and group II intron RNAs, and surprisingly, also impairs RNA-unwinding at saturating protein concentrations and nucleotide-dependent tight binding of single-stranded RNAs by the RNA helicase core. Together, our results indicate that the two sub-regions of Mss116p's C-terminal domain act in different ways to support and modulate activities of the core helicase region, whose RNA-unwinding activity is critical for both the translation and RNA splicing functions.     

Self-assembly of a group I intron active site from its component tertiary structural domains.

The catalytic core of Group I self-splicing introns has been proposed to consist of two structural domains, P4-P6 and P3-P9. Each contains helical segments and conserved unpaired nucleotides, and the isolated P4-P6 domain has been shown to have substantial native tertiary structure. The proposed tertiary structure domains of the Tetrahymena intron were synthesized separately and shown to self-assemble into a catalytically active complex. Surprisingly, the concentration dependence of these reactions revealed that the domains interact with nanomolar apparent dissociation constants, even though there is no known base pairing between P4-P6 and P3-P9. This suggests that the domains interact through multiple tertiary contacts, the nature of which can now be explored in this system. For example, a circularly permuted version of the P4-P6 domain, which folds similarly to the native P4-P6 molecule, formed a stable but inactive complex. Interestingly, activity was demonstrated with the permuted molecule when nucleotides proposed to form a triple-strand interaction with P4 and P6 were restored as part of the P1-P3 substrate or as part of the P3-P9 RNA. Thus, beyond stabilization of the P4-P6 domain, the triple-strand region may facilitate correct orientation of the RNA domains or participate more directly in catalysis.     

NMR Structure of the C-terminal domain of a tyrosyl-tRNA synthetase that functions in group I intron splicing

The mitochondrial tyrosyl-tRNA synthetases (mt TyrRSs) of Pezizomycotina fungi are bifunctional proteins that aminoacylate mitochondrial tRNA(Tyr) and are structure-stabilizing splicing cofactors for group I introns. Studies with the Neurospora crassa synthetase (CYT-18 protein) showed that splicing activity is dependent upon Pezizomycotina-specific structural adaptations that form a distinct group I intron-binding site in the N-terminal catalytic domain. Although CYT-18's C-terminal domain also binds group I introns, it has been intractable to X-ray crystallography in the full-length protein. Here, we determined an NMR structure of the isolated C-terminal domain of the Aspergillus nidulans mt TyrRS, which is closely related to but smaller than CYT-18's. The structure shows an S4 fold like that of bacterial TyrRSs, but with novel features, including three Pezizomycontia-specific insertions. (15)N-(1)H two-dimensional NMR showed that C-terminal domains of the full-length A. nidulans and Geobacillus stearothermophilus synthetases do not tumble independently in solution, suggesting restricted orientations. Modeling onto a CYT-18/group I intron cocrystal structure indicates that the C-terminal domains of both subunits of the homodimeric protein bind different ends of the intron RNA, with one C-terminal domain having to undergo a large shift on its flexible linker to bind tRNA(Tyr) or the intron RNA on either side of the catalytic domain. The modeling suggests that the C-terminal domain acts together with the N-terminal domain to clamp parts of the intron's catalytic core, that at least one C-terminal domain insertion functions in group I intron binding, and that some C-terminal domain regions bind both tRNA(Tyr) and group I intron RNAs.     

The neurospora CYT-18 protein suppresses defects in the phage T4 td intron by stabilizing the catalytically active structure of the intron core.

The Neurospora CYT-18 protein, a tyrosyl-tRNA synthetase, which functions in splicing group I introns in mitochondria, promotes splicing of mutants of the distantly related bacteriophage T4 td intron. In an in vivo assay, wild-type CYT-18 protein expressed in E. coli suppressed mutations in the td intron's catalytic core. CYT-18-suppressible mutations were also suppressed by high Mg2+ or spermidine in vitro, suggesting they affect intron structure. Both the N- and C-terminal domains of CYT-18 are required for efficient splicing, but CYT-18 with a large C-terminal truncation retains some activity. Our results indicate that CYT-18 interacts with conserved structural features of group I introns, and they provide direct evidence that a protein promotes splicing by stabilizing the catalytically active structure of the intron RNA.     

Minimal catalytic domain of a group I self-splicing intron RNA

The self-splicing intron ribozymes have been regarded as primitive forms of the splicing machinery for eukaryotic pre-mRNAs. The splicing activity of group I self-splicing introns is dependent on an absolutely conserved and exceptionally densely packed core region composed of two helical domains, P3-P7 and P4-P6, that are connected rigidly via base triples. Here we show that a mutant group I intron ribozyme lacking both the P4-P6 domain and the base triples can perform the phosphoester transfer reactions required for splicing at both the 5' and 3' splice sites, demonstrating that the elements required for splicing are concentrated in the stacked helical P3-P7 domain. This finding establishes that the conserved core of the intron consists of two physically and functionally separable components, and we present a model showing the architecture of a prototype of this class of intron and the course of its molecular evolution.     

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.     

Linking the branchpoint helix to a newly found receptor allows lariat formation by a group II intron

Like spliceosomal introns, the ribozyme-containing group II introns are excised as branched, lariat structures: a 2'-5' bond is created between the first nucleotide of the intron and an adenosine in domain VI, a component which is missing from available crystal structures of the ribozyme. Comparative sequence analysis, modelling and nucleotide substitutions point to the existence, and probable location, of a specific RNA receptor for the section of domain VI that lies just distal to the branchpoint adenosine. By designing oligonucleotides that tether domain VI to this novel binding site, we have been able to specifically activate lariat formation in an engineered, defective group II ribozyme. The location of the newly identified receptor implies that prior to exon ligation, the distal part of domain VI undergoes a major translocation, which can now be brought under control by the system of anchoring oligonucleotides we have developed. Interestingly, these oligonucleotides, which link the branchpoint helix and the binding site for intron nucleotides 3-4, may be viewed as counterparts of U2-U6 helix III in the spliceosome.     

Function of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase in RNA splicing. Role of the idiosyncratic N-terminal extension and different modes of interaction with different group I introns

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) promotes the splicing of group I introns by helping the intron RNA fold into the catalytically active structure. The regions required for splicing include an idiosyncratic N-terminal extension, the nucleotide-binding fold domain, and the C-terminal RNA-binding domain. Here, we show that the idiosyncratic N-terminal region is in fact comprised of two functionally distinct parts: an upstream region consisting predominantly of a predicted amphipathic alpha-helix (H0), which is absent from bacterial tyrosyl-tRNA synthetases (TyrRSs), and a downstream region, which contains predicted alpha-helices H1 and H2, corresponding to features in the X-ray crystal structure of the Bacillus stearothermophilus TyrRS. Bacterial genetic assays with libraries of CYT-18 mutants having random mutations in the N-terminal region identified functionally important amino acid residues and supported the predicted structures of the H0 and H1 alpha-helices. The function of N and C-terminal domains of CYT-18 was investigated by detailed biochemical analysis of deletion mutants. The results confirmed that the N-terminal extension is required only for splicing activity, but surprisingly, at least in the case of the N. crassa mitochondrial (mt) large ribosomal subunit (LSU) intron, it appears to act primarily by stabilizing the structure of another region that interacts directly with the intron RNA. The H1/H2 region is required for splicing activity and TyrRS activity with the N. crassa mt tRNA(Tyr), but not for TyrRS activity with Escherichia coli tRNA(Tyr), implying a somewhat different mode of recognition of the two tyrosyl-tRNAs. Finally, a CYT-18 mutant lacking the N-terminal H0 region is totally defective in binding or splicing the N. crassa ND1 intron, but retains substantial residual activity with the mt LSU intron, and conversely, a CYT-18 mutant lacking the C-terminal RNA-binding domain is totally defective in binding or splicing the mt LSU intron, but retains substantial residual activity with the ND1 intron. These findings lead to the surprising conclusion that CYT-18 promotes splicing via different sets of interactions with different group I introns. We suggest that these different modes of promoting splicing evolved from an initial interaction based on the recognition of conserved tRNA-like structural features of the group I intron catalytic core.     

Dynamics in the U6 RNA intramolecular stem-loop: a base flipping conformational change

The U6 RNA intramolecular stem-loop (ISL) structure is an essential component of the spliceosome and binds a metal ion required for pre-messenger RNA splicing. The metal binding internal loop region of the stem contains a partially protonated C67-(+)A79 base pair (pK(a) = 6.5) and an unpaired U80 nucleotide that is stacked within the helix at pH 7.0. Here, we determine that protonation occurs with an exchange lifetime of approximately 20 micros and report the solution structures of the U6 ISL at pH 5.7. The differences between pH 5.7 and 7.0 structures reveal that the pH change significantly alters the RNA conformation. At lower pH, U80 is flipped out into the major groove. Base flipping involves a purine stacking interaction of flanking nucleotides, inversion of the sugar pucker 5' to the flipped base, and phosphodiester backbone rearrangement. Analysis of residual dipolar couplings as a function of pH indicates that base flipping is not restricted to a local conformational change. Rather, base flipping alters the alignment of the upper and lower helices. The alternative conformations of the U6 ISL reveal striking structural similarities with both the NMR and crystal structures of domain 5 of self-splicing group II introns. These structures suggest that base flipping at an essential metal binding site is a conserved feature of the splicing machinery for both the spliceosome and group II self-splicing introns.     

An RNA internal loop acts as a hinge to facilitate ribozyme folding and catalysis.

RNA molecules commonly consist of helical regions separated by internal loops, and in many cases these internal loops have been found to assume stable structures. We have examined the function and dynamics of an internal loop, J5/5a, that joins the two halves of the P4-P6 domain of the Tetrahymena self-splicing group I intron. P4-P6 RNAs with mutations in the J5/5a region showed nondenaturing gel electrophoretic mobilities and levels of Fe(II)-EDTA cleavage protection intermediate between those of wild-type RNA and a mutant incapable of folding into the native P4-P6 tertiary structure. Mutants with the least structured J5/5a loops behaved the most like wild-type P4-P6, and required smaller amounts of Mg2+ to rescue folding. The activity of reconstituted introns containing mutant P4-P6 RNAs correlated similarly with the nature of the J5/5a mutation. Our results suggest that, in solution, the P4-P6 RNA is in a two-state equilibrium between folded and unfolded states. We conclude that this internal loop mainly acts as a flexible hinge, allowing the coaxially stacked helical regions on either side of it to interact via specific tertiary contacts. To a lesser extent, the specific bases within the loop contribute to folding. Furthermore, it is crucial that the junction remain unstructured in the unfolded state. These conclusions cannot be derived from a simple examination of the P4-P6 crystal structure (Cate JH et al., 1996, Science 273:1678-1685), showing once again that structure determination must be supplemented with mutational and thermodynamic analysis to provide a complete picture of a folded macromolecule.     

Toward predicting self-splicing and protein-facilitated splicing of group I introns

In the current era of massive discoveries of noncoding RNAs within genomes, being able to infer a function from a nucleotide sequence is of paramount interest. Although studies of individual group I introns have identified self-splicing and nonself-splicing examples, there is no overall understanding of the prevalence of self-splicing or the factors that determine it among the >2300 group I introns sequenced to date. Here, the self-splicing activities of 12 group I introns from various organisms were assayed under six reaction conditions that had been shown previously to promote RNA catalysis for different RNAs. Besides revealing that assessing self-splicing under only one condition can be misleading, this survey emphasizes that in vitro self-splicing efficiency is correlated with the GC content of the intron (>35% GC was generally conductive to self-splicing), and with the ability of the introns to form particular tertiary interactions. Addition of the Neurospora crassa CYT-18 protein activated splicing of two nonself-splicing introns, but inhibited the second step of self-splicing for two others. Together, correlations between sequence, predicted structure and splicing begin to establish rules that should facilitate our ability to predict the self-splicing activity of any group I intron from its sequence.     

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.     

Unwinding by Local Strand Separation Is Critical for the Function of DEAD-Box Proteins as RNA Chaperones

The DEAD-box proteins CYT-19 in Neurospora crassa and Mss116p in Saccharomyces cerevisiae are broadly acting RNA chaperones that function in mitochondria to stimulate group I and group II intron splicing and to activate mRNA translation. Previous studies showed that the S. cerevisiae cytosolic/nuclear DEAD-box protein Ded1p could stimulate group II intron splicing in vitro. Here, we show that Ded1p complements mitochondrial translation and group I and group II intron splicing defects in mss116Δ strains, stimulates the in vitro splicing of group I and group II introns, and functions indistinguishably from CYT-19 to resolve different nonnative secondary and/or tertiary structures in the Tetrahymena thermophila large subunit rRNA-ΔP5abc group I intron. The Escherichia coli DEAD-box protein SrmB also stimulates group I and group II intron splicing in vitro, while the E. coli DEAD-box protein DbpA and the vaccinia virus DExH-box protein NPH-II gave little, if any, group I or group II intron splicing stimulation in vitro or in vivo. The four DEAD-box proteins that stimulate group I and group II intron splicing unwind RNA duplexes by local strand separation and have little or no specificity, as judged by RNA-binding assays and stimulation of their ATPase activity by diverse RNAs. In contrast, DbpA binds group I and group II intron RNAs nonspecifically, but its ATPase activity is activated specifically by a helical segment of E. coli 23S rRNA, and NPH-II unwinds RNAs by directional translocation. The ability of DEAD-box proteins to stimulate group I and group II intron splicing correlates primarily with their RNA-unwinding activity, which, for the protein preparations used here, was greatest for Mss116p, followed by Ded1p, CYT-19, and SrmB. Furthermore, this correlation holds for all group I and group II intron RNAs tested, implying a fundamentally similar mechanism for both types of introns. Our results support the hypothesis that DEAD-box proteins have an inherent ability to function as RNA chaperones by virtue of their distinctive RNA-unwinding mechanism, which enables refolding of localized RNA regions or structures without globally disrupting RNA structure.     

A DEAD-box protein functions as an ATP-dependent RNA chaperone in group I intron splicing

The Neurospora crassa CYT-18 protein, the mitochondrial tyrosyl-tRNA synthetase, functions in splicing group I introns by inducing formation of the catalytically active RNA structure. Here, we identified a DEAD-box protein (CYT-19) that functions in concert with CYT-18 to promote group I intron splicing in vivo and vitro. CYT-19 does not bind specifically to group I intron RNAs and instead functions as an ATP-dependent RNA chaperone to destabilize nonnative RNA structures that constitute kinetic traps in the CYT-18-assisted RNA-folding pathway. Our results demonstrate that a DExH/D-box protein has a specific, physiologically relevant chaperone function in the folding of a natural RNA substrate.     

Structural basis of the enhanced stability of a mutant ribozyme domain and a detailed view of RNA--solvent interactions

BACKGROUND: The structure of P4-P6, a 160 nucleotide domain of the self-splicing Tetrahymena thermophila intron, was solved previously. Mutants of the P4-P6 RNA that form a more stable tertiary structure in solution were recently isolated by successive rounds of in vitro selection and amplification. RESULTS: We show that a single-site mutant (Delta C209) possessing greater tertiary stability than wild-type P4-P6 also crystallizes much more rapidly and under a wider variety of conditions. The crystal structure provides a satisfying explanation for the increased stability of the mutant; the deletion of C209 allows the adjacent bulged adenine to enter the P4 helix and form an A-G base pair, presumably attenuating the conformational flexibility of the helix. The structure of another mutant (Delta A210) was also solved and supports this interpretation. The crystals of Delta C209 diffract to a higher resolution limit than those of wild-type RNA (2.25 A versus 2.8 A), allowing assignment of innersphere and outersphere coordination contacts for 27 magnesium ions. Structural analysis reveals an intricate solvent scaffold with a preponderance of ordered water molecules on the inside rather than the surface of the folded RNA domain. CONCLUSIONS: In vitro evolution facilitated the identification of a highly stable, structurally homogeneous mutant RNA that was readily crystallizable. Analysis of the structure suggests that improving RNA secondary structure can stabilize tertiary structure and perhaps promote crystallization. In addition, the higher resolution model provides new details of metal ion-RNA interactions and identifies a core of ordered water molecules that may be integral to RNA tertiary structure formation.