Metal binding and base ionization in the U6 RNA intramolecular stem-loop structure

U6 RNA is a key component of the catalytic core of the spliceosome. A metal ion essential for the first catalytic step of pre-mRNA splicing binds to the U80 Sp phosphate oxygen within the yeast U6 intramolecular stem-loop (ISL). Here we present the first structural data for U6 RNA, revealing the three-dimensional structure of the highly conserved U6 ISL. The ISL binds metal ion at the U80 site with the same stereo specificity as the intact spliceosome. The metal-binding site is adjacent to a readily protonated C.A wobble pair. Protonation of the C.A pair and metal binding are mutually antagonistic. These results support a ribozyme model for U6 RNA function and suggest a possible mechanism for the regulation of RNA splicing.     

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.     

Structural basis for a lethal mutation in U6 RNA

U6 RNA is essential for nuclear pre-mRNA splicing and has been implicated directly in catalysis of intron removal. The U80G mutation at the essential magnesium binding site of the U6 3' intramolecular stem-loop region (ISL) is lethal in yeast. To further understand the structure and function of the U6 ISL, we have investigated the structural basis for the lethal U80G mutation by NMR and optical spectroscopy. The NMR structure reveals that the U80G mutation causes a structural rearrangement within the ISL resulting in the formation of a new Watson-Crick base pair (C67 x G80), and disrupts a protonated C67 x A79 wobble pair that forms in the wild-type structure. Despite the structural change, the accessibility of the metal binding site is unperturbed, and cadmium titration produces similar phosphorus chemical shift changes for both the U80G mutant and wild-type RNAs. The thermodynamic stability of the U80G mutant is significantly increased (Delta Delta G(fold) = -3.6 +/- 1.9 kcal/mol), consistent with formation of the Watson-Crick pair. Our structural and thermodynamic data, in combination with previous genetic data, suggest that the lethal basis for the U80G mutation is stem-loop hyperstabilization. This hyperstabilization may prevent the U6 ISL melting and rearrangement necessary for association with U4.     

Use of a novel Förster resonance energy transfer method to identify locations of site-bound metal ions in the U2-U6 snRNA complex

U2 and U6 snRNAs pair to form a phylogenetically conserved complex at the catalytic core of the spliceosome. Interactions with divalent metal ions, particularly Mg(II), at specific sites are essential for its folding and catalytic activity. We used a novel Förster resonance energy transfer (FRET) method between site-bound luminescent lanthanide ions and a covalently attached fluorescent dye, combined with supporting stoichiometric and mutational studies, to determine locations of site-bound Tb(III) within the human U2–U6 complex. At pH 7.2, we detected three metal-ion-binding sites in: (1) the consensus ACACAGA sequence, which forms the internal loop between helices I and III; (2) the four-way junction, which contains the conserved AGC triad; and (3) the internal loop of the U6 intra-molecular stem loop (ISL). Binding at each of these sites is supported by previous phosphorothioate substitution studies and, in the case of the ISL site, by NMR. Binding of Tb(III) at the four-way junction and the ISL sites was found to be pH-dependent, with no ion binding observed below pH 6 and 7, respectively. This pH dependence of metal ion binding suggests that the local environment may play a role in the binding of metal ions, which may impact on splicing activity.     

Structure of the yeast U2/U6 snRNA complex

The U2/U6 snRNA complex is a conserved and essential component of the active spliceosome that interacts with the pre-mRNA substrate and essential protein splicing factors to promote splicing catalysis. Here we have elucidated the solution structure of a 111-nucleotide U2/U6 complex using an approach that integrates SAXS, NMR, and molecular modeling. The U2/U6 structure contains a three-helix junction that forms an extended "Y" shape. The U6 internal stem-loop (ISL) forms a continuous stack with U2/U6 Helices Ib, Ia, and III. The coaxial stacking of Helix Ib on the U6 ISL is a configuration that is similar to the Domain V structure in group II introns. Interestingly, essential features of the complex--including the U80 metal binding site, AGC triad, and pre-mRNA recognition sites--localize to one face of the molecule. This observation suggests that the U2/U6 structure is well-suited for orienting substrate and cofactors during splicing catalysis.     

A dynamic bulge in the U6 RNA internal stem-loop functions in spliceosome assembly and activation

The highly conserved internal stem-loop (ISL) of U6 spliceosomal RNA is unwound for U4/U6 complex formation during spliceosome assembly and reformed upon U4 release during spliceosome activation. The U6 ISL is structurally similar to Domain 5 of group II self-splicing introns, and contains a dynamic bulge that coordinates a Mg++ ion essential for the first catalytic step of splicing. We have analyzed the causes of growth defects resulting from mutations in the Saccharomyces cerevisiae U6 ISL-bulged nucleotide U80 and the adjacent C67-A79 base pair. Intragenic suppressors and enhancers of the cold-sensitive A79G mutation, which replaces the C-A pair with a C-G pair, suggest that it stabilizes the ISL, inhibits U4/U6 assembly, and may also disrupt spliceosome activation. The lethality of mutations C67A and C67G results from disruption of base-pairing potential between U4 and U6, as these mutations are fully suppressed by compensatory mutations in U4 RNA. Strikingly, suppressor analysis shows that the lethality of the U80G mutation is due not only to formation of a stable base pair with C67, as previously proposed, but also another defect. A U6-U80G strain in which mispairing with position 67 is prevented grows poorly and assembles aberrant spliceosomes that retain U1 snRNP and fail to fully unwind the U4/U6 complex at elevated temperatures. Our data suggest that the U6 ISL bulge is important for coupling U1 snRNP release with U4/U6 unwinding during spliceosome activation.     

Dynamics and metal ion binding in the U6 RNA intramolecular stem-loop as analyzed by NMR

The U6 RNA intramolecular stem-loop (ISL) is a conserved component of the spliceosome, and contains an essential metal ion binding site centered between a protonated adenine, A79, and U80. Correlated with protonation of A79, U80 undergoes a base-flipping conformational change accompanied by significant helical movement. We have investigated the dynamics of the U6 ISL by analyzing the power dependence of 13C NMR relaxation rates in the rotating frame. The data provide evidence that the conformational transition is centered around an exchange lifetime of 84 micros. The U80 nucleotide displays low internal mobility on the picosecond time-scale at pH 7.0 but high internal mobility at pH 6.0, in agreement with the global transition resulting in the base of U80 adopting a looped-out conformation with increased dynamic disorder. A kinetic analysis suggests that the conformational change, rather than adenine protonation, is the rate-limiting step in the pathway of the conformational transition. Two nucleotides, U70 and U80, were found from chemical shift perturbation mapping to interact with the magnesium ion, with apparent K(d) values in the micromolar to millimolar range. These nucleotides also displayed metal ion-induced elevation of R1 rates, which can be explained by a model that assumes dynamic metal ion coordination concomitant with an induced higher shielding anisotropy for the base 13C nuclei. Addition of Mg2+ shifts the conformational equilibrium toward the high-pH (base-stacked) structure, accompanied by a significant drop in the apparent pK(a) of A79.     

Specific metal-ion binding sites in a model of the P4-P6 triple-helical domain of a group I intron

Divalent metal ions play a crucial role in RNA structure and catalysis. Phosphorothioate substitution and manganese rescue experiments can reveal phosphate oxygens interacting specifically with magnesium ions essential for structure and/or activity. In this study, phosphorothioate interference experiments in combination with structural sensitive circular dichroism spectroscopy have been used to probe molecular interactions underlying an important RNA structural motif. We have studied a synthetic model of the P4-P6 triple-helical domain in the bacteriophage T4 nrdB group I intron, which has a core sequence analogous to the Tetrahymena ribozyme. Rp and Sp sulfur substitutions were introduced into two adjacent nucleotides positioned at the 3' end of helix P6 (U452) and in the joining region J6/7 (U453). The effects of sulfur substitution on triple helix formation in the presence of different ratios of magnesium and manganese were studied by the use of difference circular dichroism spectroscopy. The results show that the pro-Sp oxygen of U452 acts as a ligand for a structurally important magnesium ion, whereas no such effect is seen for the pro-Rp oxygen of U452. The importance of the pro-Rp and pro-Sp oxygens of U453 is less clear, because addition of manganese could not significantly restore the triple-helical interactions within the isolated substituted model systems. The interpretation is that U453 is so sensitive to structural disturbance that any change at this position hinders the proper formation of the triple helix.     

U2-U6 RNA folding reveals a group II intron-like domain and a four-helix junction

Intron removal in nuclear precursor mRNA is catalyzed through two transesterification reactions by a multi-megaDalton ribonucleoprotein machine called the spliceosome. A complex between U2 and U6 small nuclear RNAs is a core component of the spliceosome. Here we present an NMR structural analysis of a protein-free U2-U6 complex from Saccharomyces cerevisiae. The observed folding of the U2-U6 complex is a four-helix junction, in which the catalytically important AGC triad base-pairs only within U6 and not with U2. The base-pairing of the AGC triad extends the U6 intramolecular stem-loop (U6 ISL), and the NMR structure of this extended U6 ISL reveals structural similarities with domain 5 of group II self-splicing introns. The observed conformation of the four-helix junction could be relevant to the first, but not the second, step of splicing and may help to position the U6 ISL adjacent to the 5' splice site.     

A novel occluded RNA recognition motif in Prp24 unwinds the U6 RNA internal stem loop

The essential splicing factor Prp24 contains four RNA Recognition Motif (RRM) domains, and functions to anneal U6 and U4 RNAs during spliceosome assembly. Here, we report the structure and characterization of the C-terminal RRM4. This domain adopts a novel non-canonical RRM fold with two additional flanking α-helices that occlude its β-sheet face, forming an occluded RRM (oRRM) domain. The flanking helices form a large electropositive surface. oRRM4 binds to and unwinds the U6 internal stem loop (U6 ISL), a stable helix that must be unwound during U4/U6 assembly. NMR data indicate that the process starts with the terminal base pairs of the helix and proceeds toward the loop. We propose a mechanistic and structural model of Prp24's annealing activity in which oRRM4 functions to destabilize the U6 ISL during U4/U6 assembly.     

Metal interactions with a GAAA RNA tetraloop characterized by (31)P NMR and phosphorothioate substitutions

A metal site in a 5'-GAAA-3' tetraloop, a stabilizing and phylogenetically conserved RNA motif, is explored using (31)P NMR spectroscopy and phosphorothioate modifications. Similar to previous reports [Legault, P., and Pardi, A. (1994) J. Magn. Reson., Ser. B 103, 82-86], the (31)P NMR spectrum of a 12-nucleotide stem-loop sequence 5'-GGCCGAAAGGCC-3' exhibits resolved features from each of the phosphodiester linkages. Titration with Mg(2+) results in distinct shifts of a subset of these (31)P features, which are assigned to phosphodiesters 5' to A6, A7, and G5. Titration with Co(NH(3))(6)(3+) causes only a slight upfield shift in the A6 feature, suggesting that changes caused by Mg(2+) are due to inner-sphere metal-phosphate coordination. R(p)-Phosphorothioate substitutions introduced enzymatically 5' to each of the three A residues of the tetraloop provide well-resolved (31)P NMR features that are observed to shift in the presence of Cd(2+) but not Mg(2+), again consistent with a metal-phosphate site. Analysis of (31)P NMR spectra using the sequence 5'-GGGCGAAAGUCC-3' with single phosphorothioate substitutions in the loop region, separated into R(p) and S(p) diastereomers, provides evidence for an inner-sphere interaction with the phosphate 5' to A7 but outer-sphere or structural effects that cause perturbations 5' to A6. Introduction of an R(p)-phosphorothioate 5' to A7 results in a distinct (31)P NMR spectrum, consistent with thermodynamic studies reported in the accompanying paper that indicate a unique structure caused by this substitution. On the basis of these results and existing structural information, a metal site in the 5'-GAAA-3' tetraloop is modeled using restrained molecular dynamics simulations.     

Specific phosphorothioate substitutions probe the active site of Bacillus subtilis ribonuclease P

Ribonuclease P (RNase P) is a ribonucleoprotein that requires magnesium ions to catalyze the 5' maturation of transfer RNA. To identify interactions essential for catalysis, the properties of RNase P containing single sulfur substitutions for nonbridging phosphodiester oxygens in helix P4 of Bacillus subtilis RNase P were analyzed using transient kinetic experiments. Sulfur substitution at the nonbridging oxygens of the phosphodiester bond of nucleotide U51 only modestly affects catalysis. However, phosphorothioate substitutions at A49 and G50 decrease the cleavage rate constant enormously (300-4,000-fold for P RNA and 500-15,000-fold for RNase P holoenzyme) in magnesium without affecting the affinity of pre-tRNA(Asp), highlighting the importance of this region for catalysis. Furthermore, addition of manganese enhances pre-tRNA cleavage catalyzed by B. subtilis RNase P RNA containing an Sp phosphorothioate modification at A49, as observed for Escherichia coli P RNA [Christian et al., RNA, 2000, 6:511-519], suggesting that an essential metal ion may be coordinated at this site. In contrast, no manganese rescue is observed for the A49 Sp phosphorothioate modification in RNase P holoenzyme. These differential manganese rescue effects, along with affinity cleavage, suggest that the protein component may interact with a metal ion bound near A49 in helix P4 of P RNA.     

Phosphorothioate substitution can substantially alter RNA conformation

Phosphorothioate substitution-interference experiments, routinely used to stereospecifically identify phosphoryl oxygen sites that participate in RNA-ligand binding and RNA-directed catalysis, rest in their interpretation on the untested assumption that substitution does not alter the conformation of the modified molecule from its biologically active state. Using NMR spectroscopy, we have tested this assumption by determining the structural effect of stereospecific phosphorothioate substitution at five positions in an RNA hairpin containing the binding site for bacteriophage MS2 capsid protein. At most sites, substitution has little or no effect, causing minor perturbations in the phosphate backbone and increasing the stacking among nucleotides in the hairpin loop. At one site, however, phosphorothioate substitution causes an unpaired adenine necessary for formation of the capsid protein-RNA complex to loop out of the RNA helix into the major groove. These results indicate that phosphorothioate substitution can substantially alter the conformation of RNA at positions of irregular secondary structure, complicating the use of substitution-interference experiments to study RNA structure and function.     

Minimum-Energy Path for a U6 RNA Conformational Change Involving Protonation, Base-Pair Rearrangement and Base Flipping

The U6 RNA internal stem-loop (U6 ISL) is a highly conserved domain of the spliceosome that is important for pre-mRNA splicing. The U6 ISL contains an internal loop that is in equilibrium between two conformations controlled by the protonation state of an adenine (pK_a = 6.5). Lower pH favors formation of a protonated C-A⁺ wobble pair and base flipping of the adjacent uracil. Higher pH favors stacking of the uracil and allows an essential metal ion to bind at this position. Here, we define the minimal-energy path for this conformational transition. To do this, we solved the U6 ISL structure at higher pH (8.0) in order to eliminate interference from the low-pH conformer. This structure reveals disruption of the protonated C-A⁺ pair and formation of a new C-U pair, which explains the preference for a stacked uracil at higher pH. Next, we used nudged elastic band molecular dynamics simulations to calculate the minimum-energy path between the two conformations. Our results indicate that the C-U pair is dynamic, which allows formation of the more stable C-A⁺ pair upon adenine protonation. After formation of the C-A⁺ pair, the unpaired uracil follows a minor-groove base-flipping pathway. Molecular dynamics simulations suggest that the extrahelical uracil is stabilized by contacts with the adjacent helix.     

Remodeling of U2-U6 snRNA helix I during pre-mRNA splicing by Prp16 and the NineTeen Complex protein Cwc2

Removal of intron regions from pre-messenger RNA (pre-mRNA) requires spliceosome assembly with pre-mRNA, then subsequent spliceosome remodeling to allow activation for the two steps of intron removal. Spliceosome remodeling is carried out through the action of DExD/H-box ATPases that modulate RNA–RNA and protein–RNA interactions. The ATPase Prp16 remodels the spliceosome between the first and second steps of splicing by catalyzing release of first step factors Yju2 and Cwc25 as well as destabilizing U2-U6 snRNA helix I. How Prp16 destabilizes U2-U6 helix I is not clear. We show that the NineTeen Complex (NTC) protein Cwc2 displays genetic interactions with the U6 ACAGAGA, the U6 internal stem loop (ISL) and the U2-U6 helix I, all RNA elements that form the spliceosome active site. We find that one function of Cwc2 is to stabilize U2-U6 snRNA helix I during splicing. Cwc2 also functionally cooperates with the NTC protein Isy1/NTC30. Mutation in Cwc2 can suppress the cold sensitive phenotype of the prp16-302 mutation indicating a functional link between Cwc2 and Prp16. Specifically the prp16-302 mutation in Prp16 stabilizes Cwc2 interactions with U6 snRNA and destabilizes Cwc2 interactions with pre-mRNA, indicating antagonistic functions of Cwc2 and Prp16. We propose that Cwc2 is a target for Prp16-mediated spliceosome remodeling during pre-mRNA splicing.     

Identification of an active site ligand for a group I ribozyme catalytic metal ion

The transition state of the group I intron self-splicing reaction is stabilized by three metal ions. The functional groups within the intron substrates (guanosine and an oligoribonucleotide mimic of the 5'-exon) that coordinate these metal ions have been systematically defined through a series of metal ion specificity switch experiments. In contrast, the catalytic metal ligands within the ribozyme active site are unknown. In an effort to identify them, stereospecific (R(P) or S(P)) single-site phosphorothioate substitutions were introduced at five phosphates predicted to be in the vicinity of the catalytic center (A207, C208, A304, U305, and A306) within the Tetrahymena intron. Of the 10 ribozymes that were studied, four phosphorothioate substitutions (A207 S(P), C208 S(P), A306 R(P), and A306 S(P)) exhibited a significant reduction in the cleavage rate. Only the effect of the C208 S(P) phosphorothioate substitution could be significantly rescued by the addition of a thiophilic metal ion, either Mn(2+) or Zn(2+), when tested with an all-oxy substrate. The effect was not rescued with Cd(2+). To determine if one of the catalytic metal ions is coordinated to the C208 pro-S(P) oxygen, the phosphorothioate-substituted ribozymes were also assayed using oligonucleotide substrates with a 3'-phosphorothiolate or an S(P) phosphorothioate substitution at the scissile phosphate. This resulted in a second metal specificity switch, in that Mn(2+) or Zn(2+) no longer rescued the C208 S(P) ribozyme, but Cd(2+) provided efficient rescue in the context of either sulfur-containing substrate. The 3'-oxygen and the pro-S(P) oxygen of the scissile phosphate are both known to coordinate the same metal ion, M(A), which stabilizes the negative charge on the leaving group 3'-oxygen in the transition state. Taken together, these data suggest that metal M(A) is coordinated to the C208 pro-S(P) phosphate oxygen, which constitutes the first functional link between a specific catalytic metal ion and a particular functional group within the group I ribozyme active site.     

Cwc2 and its human homologue RBM22 promote an active conformation of the spliceosome catalytic centre

RNA-structural elements play key roles in pre-mRNA splicing catalysis; yet, the formation of catalytically competent RNA structures requires the assistance of spliceosomal proteins. We show that the S. cerevisiae Cwc2 protein functions prior to step 1 of splicing, and it is not required for the Prp2-mediated spliceosome remodelling that generates the catalytically active B complex, suggesting that Cwc2 plays a more sophisticated role in the generation of a functional catalytic centre. In active spliceosomes, Cwc2 contacts catalytically important RNA elements, including the U6 internal stem-loop (ISL), and regions of U6 and the pre-mRNA intron near the 5' splice site, placing Cwc2 at/near the spliceosome's catalytic centre. These interactions are evolutionarily conserved, as shown by studies with Cwc2's human counterpart RBM22, indicating that Cwc2/RBM22-RNA contacts are functionally important. We propose that Cwc2 induces an active conformation of the spliceosome's catalytic RNA elements. Thus, the function of RNA-RNA tertiary interactions within group II introns, namely to induce an active conformation of domain V, may be fulfilled by proteins that contact the functionally analogous U6-ISL, within the spliceosome.     

Modulation of individual steps in group I intron catalysis by a peripheral metal ion

Enzymes are complex macromolecules that catalyze chemical reactions at their active sites. Important information about catalytic interactions is commonly gathered by perturbation or mutation of active site residues that directly contact substrates. However, active sites are engaged in intricate networks of interactions within the overall structure of the macromolecule, and there is a growing body of evidence about the importance of peripheral interactions in the precise structural organization of the active site. Here, we use functional studies, in conjunction with published structural information, to determine the effect of perturbation of a peripheral metal ion binding site on catalysis in a well-characterized catalytic RNA, the Tetrahymena thermophila group I ribozyme. We perturbed the metal ion binding site by site-specifically introducing a phosphorothioate substitution in the ribozyme's backbone, replacing the native ligands (the pro-R (P) oxygen atoms at positions 307 and 308) with sulfur atoms. Our data reveal that these perturbations affect several reaction steps, including the chemical step, despite the absence of direct contacts of this metal ion with the atoms involved in the chemical transformation. As structural probing with hydroxyl radicals did not reveal significant change in the three-dimensional structure upon phosphorothioate substitution, the effects are likely transmitted through local, rather subtle conformational rearrangements. Addition of Cd(2+), a thiophilic metal ion, rescues some reaction steps but has deleterious effects on other steps. These results suggest that native interactions in the active site may have been aligned by the naturally occurring peripheral residues and interactions to optimize the overall catalytic cycle.     

Metal-phosphate interactions in the hammerhead ribozyme observed by 31P NMR and phosphorothioate substitutions

The hammerhead ribozyme is a catalytic RNA that requires divalent metal cations for activity under moderate ionic strength. Two important sites that are proposed to bind metal ions in the hammerhead ribozyme are the A9/G10.1 site, located at the junction between stem II and the conserved core, and the scissile phosphate (P1.1). (31)P NMR spectroscopy in conjunction with phosphorothioate substitutions is used in this study to investigate these putative metal sites. The (31)P NMR feature of a phosphorothioate appears in a unique spectral window and can be monitored for changes upon addition of metals. Addition of 1-2 equiv of Cd(2+) to the hammerhead with an A9-S(Rp) or A9-S(S)(Rp) substitution results in a 2-3 ppm upfield shift of the (31)P NMR resonance. In contrast, the P1.1-S(Rp) and P1.1-S(Sp) (31)P NMR features shift slightly and in opposite directions, with a total change in delta of 相似文献   

Reconstitution of functional mammalian U4 small nuclear ribonucleoprotein: Sm protein binding is not essential for splicing in vitro.

We have developed an in vitro splicing complementation assay to investigate the domain structure of the mammalian U4 small nuclear RNA (snRNA) through mutational analysis. The addition of affinity-purified U4 snRNP or U4 RNA to U4-depleted nuclear extract efficiently restores splicing activity. In the U4-U6 interaction domain of U4 RNA, only stem II was found to be essential for splicing activity; the 5' loop is important for spliceosome stability. In the central domain, we have identified a U4 RNA sequence element that is important for splicing and spliceosome assembly. Surprisingly, an intact Sm domain is not essential for splicing in vitro. Our data provide evidence that several distinct regions of U4 RNA contribute to snRNP assembly, spliceosome assembly and stability, and splicing activity.