Mutation in the U2 snRNA influences exon interactions of U5 snRNA loop 1 during pre-mRNA splicing

The U2 and U6 snRNAs contribute to the catalysis of intron removal while U5 snRNA loop 1 holds the exons for ligation during pre-mRNA splicing. It is unclear how different exons are positioned precisely with U5 loop 1. Here, we investigate the role of U2 and U6 in positioning the exons with U5 loop 1. Reconstitution in vitro of spliceosomes with mutations in U2 allows U5-pre-mRNA interactions before the first step of splicing. However, insertion in U2 helix Ia disrupts U5-exon interactions with the intron lariat-3' exon splicing intermediate. Conversely, U6 helix Ia insertions prevent U5-pre-mRNA interactions before the first step of splicing. In vivo, synthetic lethal interactions have been identified between U2 insertion and U5 loop 1 insertion mutants. Additionally, analysis of U2 insertion mutants in vivo reveals that they influence the efficiency, but not the accuracy of splicing. Our data suggest that U2 aligns the exons with U5 loop 1 for ligation during the second step of pre-mRNA splicing.     

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.     

Spliced leader-associated RNA from Crithidia fasciculata contains a structure resembling stem/loop II of U1 snRNA.

In contrast to earlier proposals, recent evidence suggests that trans-spliceosomes in trypanosomatid protozoa may contain a homolog of U1 small nuclear (sn) RNA (Schnare, M.N. and Gray, M.W. (1999) J. Biol. Chem. 274, 23,691-23,694). However, the candidate trypanosomatid U1 snRNA is unconventional because it lacks the highly conserved stem/loop II present in all other U1 snRNAs. Trypanosomatids also possess a unique spliced leader-associated (SLA) RNA of unknown function. We present the complete sequence of the SLA RNA from Crithidia fasciculata and propose that it may contribute a U1 snRNA-like stem/loop II to the trans-spliceosome.     

Conformational dynamics of stem II of the U2 snRNA

The spliceosome undergoes dramatic changes in both small nuclear RNA (snRNA) composition and structure during assembly and pre-mRNA splicing. It has been previously proposed that the U2 snRNA adopts two conformations within the stem II region: stem IIa or stem IIc. Dynamic rearrangement of stem IIa into IIc and vice versa is necessary for proper progression of the spliceosome through assembly and catalysis. How this conformational transition is regulated is unclear; although, proteins such as Cus2p and the helicase Prp5p have been implicated in this process. We have used single-molecule Förster resonance energy transfer (smFRET) to study U2 stem II toggling between stem IIa and IIc. Structural interconversion of the RNA was spontaneous and did not require the presence of a helicase; however, both Mg²⁺ and Cus2p promote formation of stem IIa. Destabilization of stem IIa by a G53A mutation in the RNA promotes stem IIc formation and inhibits conformational switching of the RNA by both Mg²⁺ and Cus2p. Transitioning to stem IIa can be restored using Cus2p mutations that suppress G53A phenotypes in vivo. We propose that during spliceosome assembly, Cus2p and Mg²⁺ may work together to promote stem IIa formation. During catalysis the spliceosome could then toggle stem II with the aid of Mg²⁺ or with the use of functionally equivalent protein interactions. As noted in previous studies, the Mg²⁺ toggling we observe parallels previous observations of U2/U6 and Prp8p RNase H domain Mg²⁺-dependent conformational changes. Together these data suggest that multiple components of the spliceosome may have evolved to switch between conformations corresponding to open or closed active sites with the aid of metal and protein cofactors.     

Sequence-specific interaction of U1 snRNA with the SMN complex

The survival of motor neurons (SMN) protein complex functions in the biogenesis of spliceosomal small nuclear ribonucleoprotein particles (snRNPs) and prob ably other RNPs. All spliceosomal snRNPs have a common core of seven Sm proteins. To mediate the assembly of snRNPs, the SMN complex must be able to bring together Sm proteins with U snRNAs. We showed previously that SMN and other components of the SMN complex interact directly with several Sm proteins. Here, we show that the SMN complex also interacts specifically with U1 snRNA. The stem--loop 1 domain of U1 (SL1) is necessary and sufficient for SMN complex binding in vivo and in vitro. Substitution of three nucleotides in the SL1 loop (SL1A3) abolishes SMN interaction, and the corresponding U1 snRNA (U1A3) is impaired in U1 snRNP biogenesis. Microinjection of excess SL1 but not SL1A3 into Xenopus oocytes inhibits SMN complex binding to U1 snRNA and U1 snRNP assembly. These findings indicate that SMN complex interaction with SL1 is sequence-specific and critical for U1 snRNP biogenesis, further supporting the direct role of the SMN complex in RNP biogenesis.     

Mutations in U5 snRNA loop 1 influence the splicing of different genes in vivo

The U5 snRNA loop 1 is characterized by the conserved sequence G₁C₂C₃U₄U₅U₆Y₇A₈Y₉ and is essential for the alignment of exons during the second step of pre-mRNA splicing in Saccharo myces cerevisiae. Despite this sequence conservation the size, rather than sequence, of loop 1 is critical for exon alignment in vitro. To determine the in vivo requirements for U5 loop 1 a library of loop 1 sequences was transformed into a yeast strain where the endogenous U5 gene was deleted. Comparison of viable mutations in loop 1 revealed that position 6 was invariant and positions 5 and 7 displayed some sequence conservation. These data indicate positions 5, 6 and 7 in loop 1 are important for U5 function in vivo. A screen for mutations that suppress the temperature-sensitive phenotype of three loop 1 mutants produced eight intragenic suppressors all containing alterations in loop 1. Further analysis of these temperature-sensitive mutants revealed that each displayed distinct cell cycle arrest phenotypes and pre-mRNA splicing inhibition patterns. The cell cycle arrest is likely attributed to inefficient splicing of α-tubulin pre-mRNA in one mutant and actin pre-mRNA in another. These results suggest that various mutations in loop 1 may affect the splicing of different pre-mRNAs in vivo.     

Altering the RNA-binding mode of the U1A RBD1 protein

The N-terminal RNA-binding domain (RBD1) of the human U1A protein is evolutionarily designed to bind its RNA targets with great affinity and specificity. The physical mechanisms that modulate the coupling (local cooperativity) among amino acid residues on the extensive binding surface of RBD1 are investigated here, using mutants that replace a highly conserved glycine residue. This glycine residue, at the strand/loop junction of beta3/loop3, is found in U1A RBD1, and in most RBD domains, suggesting it has a specific role in modulation of RNA binding. Here, two RBD1 proteins are constructed in which that residue (Gly53) is replaced by either alanine or valine. These new proteins are shown by NMR methods and molecular dynamics simulations to be very similar to the wild-type RBD1, both in structure and in their backbone dynamics. However, RNA-binding assays show that affinity for the U1 snRNA stem-loop II RNA target is reduced by nearly 200-fold for the RBD1-G53A protein, and by 1.6 x 10(4)-fold for RBD1-G53V. The mode of RNA binding by RBD1-G53A is similar to that of RBD1-WT, displaying its characteristic non-additive free energies of base recognition and its salt-dependence. The binding mode of RBD1-G53V is altered, having lost its salt-dependence and displaying site-independence of base recognition. The molecular basis for this alteration in RNA-binding properties is proposed to result from the inability of the RNA to induce a change in the structure of the free protein to produce a high-affinity complex.     

Assembly of the U1 snRNP involves interactions with the backbone of the terminal stem of U1 snRNA

Nucleotide analog interference mapping (NAIM) is a powerful method for identifying RNA functional groups involved in protein-RNA interactions. We examined particles assembled on modified U1 small nuclear RNAs (snRNAs) in vitro and detected two categories of interferences. The first class affects the stability of two higher-order complexes and comprises changes in two adenosines, A65 and A70, in the loop region previously identified as the binding site for the U1 small nuclear ribonucleoprotein (snRNP)-specific U1A protein. Addition of an exocyclic amine to position 2 of A65 interferes strongly with protein binding, whereas removal or modification of the exocyclic amine at position 6 makes little difference. Modifications of A70 exhibit the opposite effects: Additions at position 2 are permitted, but modification of the exocyclic amine at position 6 significantly inhibits protein binding. These interactions, critical for U1A-U1 snRNA recognition in the context of in vitro snRNP assembly, are consistent with previous structural studies of the isolated protein with the RNA hairpin containing the U1A binding site. The second category of interferences affects all partially assembled U1-protein complexes by decreasing the stability of Sm core protein associations. Interestingly, most strong interferences occur at phosphates in the terminal stem-loop region of U1, rather than in the Sm binding site. These data argue that interactions with the phosphate backbone of the terminal stem loop are essential for the stable association of Sm core proteins with the U1 snRNA. We suggest that the stem loop of all Sm snRNAs may act as a clamp to hold the ring of Sm proteins in place.     

Conformational heterogeneity of the protein-free human spliceosomal U2-U6 snRNA complex

The complex formed between the U2 and U6 small nuclear (sn)RNA molecules of the eukaryotic spliceosome plays a critical role in the catalysis of precursor mRNA splicing. Here, we have used enzymatic structure probing, ¹⁹F NMR, and analytical ultracentrifugation techniques to characterize the fold of a protein-free biophysically tractable paired construct representing the human U2-U6 snRNA complex. Results from enzymatic probing and ¹⁹F NMR for the complex in the absence of Mg²⁺ are consistent with formation of a four-helix junction structure as a predominant conformation. However, ¹⁹F NMR data also identify a lesser fraction (up to 14% at 25°C) of a three-helix conformation. Based upon this distribution, the calculated ΔG for inter-conversion to the four-helix structure from the three-helix structure is approximately −4.6 kJ/mol. In the presence of 5 mM Mg²⁺, the fraction of the three-helix conformation increased to ∼17% and the Stokes radius, measured by analytical ultracentrifugation, decreased by 2%, suggesting a slight shift to an alternative conformation. NMR measurements demonstrated that addition of an intron fragment to the U2-U6 snRNA complex results in displacement of U6 snRNA from the region of Helix III immediately 5′ of the ACAGAGA sequence of U6 snRNA, which may facilitate binding of the segment of the intron adjacent to the 5′ splice site to the ACAGAGA sequence. Taken together, these observations indicate conformational heterogeneity in the protein-free human U2-U6 snRNA complex consistent with a model in which the RNA has sufficient conformational flexibility to facilitate inter-conversion between steps of splicing in situ.     

U2 and U1 snRNA gene loci associate with coiled bodies

The coiled bodies are nuclear structures rich in a variety of nuclear and nucleolar components including snRNAs. We have investigated the possibility that coiled bodies may associate with snRNA genes and report here that there is a high degree of association between U2 and U1 genes with a subset of coiled bodies. As investigated in human HeLa cells grown in monolayer culture, about 75% of the nuclei had at least one U2 gene associated with a coiled body, and 45% had at least one U1 locus associated. In another suspension-grown HeLa cell strain, 92% of cells showed association of one or more U2 genes with coiled bodies. In contrast to the U2 and U1 gene associations, a locus closely linked to the U2 gene cluster appeared associated with a coiled body only in 10% of cells. Associated snRNA gene signals were repeatedly positioned at the edge of the coiled body. Thus, this association was highly nonrandom and spatically precise. Our analysis revealed a much higher frequency of association for closely spaced “doublet” U2 gene signals, with over 80% of paired signals associated as opposed to 35% for single U2 signals. This finding, coupled with the fact that not all genes were associated in all cells, suggested the possibility of a cell-cycle-dependent, possibly S-phase, association. However, an analysis of S- and non-S-phase cells using BrdU incorporation or cell synchronization did not indicate an increased level of association in S-phase. These and other results suggested that a substantial fraction of paired U2 signals represented association of U2 genes on homologous chromosomes rather than only replicated DNA. Furthermore, triple lable analysis showed that in a significant fraction of cells U1 and U2 genes were both associated with the same coiled body. U1 and U2 genes were closely paired in approximately 20% of cells, over 60% of which were associated with a readily identifiable coiled body. This finding raises the possibility that multiple genes of a particular class may be in association with each coiled body. Thus, the coiled body may be a dynamic structure which transiently interacts with or is formed by one or more specific genetic loci, possibly carrying out some function related to their expression. © 1995 Wiley-Liss, Inc.     

A weak interaction between the U2A'' protein and U2 snRNA helps to stabilize their complex with the U2B" protein.

The U2 snRNP complex contains two specific proteins, U2B" and U2A'. We have analysed the interaction of U2A' with U2B" and with U2 RNA. U2A' can form an weak but detectable RNA-protein complex with U2 RNA and a stable protein complex with U2B". This protein-protein complex binds efficiently and specifically to U2 RNA. Binding experiments with mutant forms of U2A' shows that the region of U2A' essential for binding to U2B" is extensive, being located between amino acid position 1-164. The behaviour of the wild type U2A' protein, and in particular of a mutant version of the protein in which amino acids 3, 4 and 5 are mutated, suggests that U2A' forms a weak interaction with U2 RNA which helps to stabilize the U2A'-U2B"-U2 RNA complex. Mutants of U2 RNA were used to localize the region of U2 RNA important for interaction with U2A'. The results show that U2A' interacts with the stem of hairpin IV.     

ATP-dependent interaction of yeast U5 snRNA loop 1 with the 5' splice site.

Pre-messenger RNA splicing is a two-step process by which introns are removed and exons joined together. In yeast, the U5 snRNA loop 1 interacts with the 5' exon before the first step of splicing and with the 5' and 3' exons before the second step. In vitro studies revealed that yeast U5 loop 1 is not required for the first step of splicing but is essential for holding the 5' and 3' exons for ligation during the second step. It is critical, therefore, that loop 1 contacts the 5' exon before the first step of splicing to hold this exon following cleavage from the pre-mRNA. At present it is not known how U5 loop 1 is positioned on the 5' exon prior to the first step of splicing. To address this question, we have used site-specific photoactivated crosslinking in yeast spliceosomes to investigate the interaction of U5 loop 1 with the pre-mRNA prior to the first step of splicing. We have found that the highly conserved uridines in loop 1 make ATP-dependent contacts with an approximately 8-nt region at the 5' splice site that includes the invariant GU. These interactions are dependent on functional U2 and U6 snRNAs. Our results support a model where U5 snRNA loop 1 interacts with the 5' exon in two steps during its targeting to the 5' splice site.     

Interaction of N-terminal domain of U1A protein with an RNA stem/loop.

The U1A protein is a sequence-specific RNA binding protein found in the U1 snRNP particle where it binds to stem/loop II of U1 snRNA. U1A contains two 'RNP' or 'RRM' (RNA Recognition Motif) domains, which are common to many RNA-binding proteins. The N-terminal RRM has been shown to bind specifically to the U1 RNA stem/loop, while the RNA target of the C-terminal domain is unknown. Here, we describe experiments using a 102 amino acid N-terminal RRM of U1A (102A) and a 25-nucleotide RNA stem/loop to measure the binding constants and thermodynamic parameters of this RNA:protein complex. Using nitrocellulose filter binding, we measure a dissociation constant KD = 2 x 10(-11) M in 250 mM NaCl, 2 mM MgC2, and 10 mM sodium cacodylate, pH 6 at room temperature, and a half-life for the complex of 5 minutes. The free energy of association (delta G degrees) of this complex is about -14 kcal/mol in these conditions. Determination of the salt dependence of the binding suggests that at least 8 ion-pairs are formed upon complex formation. A mutation in the RNA loop sequence reduces the affinity 10 x, or about 10% of the total free energy.     

Functional analysis of the U5 snRNA loop 1 in the second catalytic step of yeast pre-mRNA splicing.

The U5 snRNA loop 1 interacts with the 5' exon before the first step of pre-mRNA splicing and with the 5' and 3' exons following the first step. These U5-exon interactions are proposed to hold the exons in the correct orientation for the second step of splicing. Reconstitution of U5 snRNPs in vitro indicated that U5 loop 1-5' exon interactions are not necessary for the first catalytic step of splicing but are critical for the second step in yeast spliceosomes. We systematically made deletion and insertion mutations in loop 1 then monitored splicing activity and loop-exon interactions by cross-linking. Single nucleotide deletions or insertions in loop 1 permitted both steps of splicing. Larger insertions or deletions allowed the first step but progressively inhibited the second step. Analysis of selected loop 1 insertions and deletions by cross-linking revealed that inhibition of the second catalytic step resulted from misalignment of the 5' and 3' exons. These data indicate that the size of loop 1 is critical for proper alignment of the exons for the second catalytic step of splicing and that the 3' exon is positioned on loop 1 independently of the 5' exon.     

Molecular dynamics simulation of the human U2B" protein complex with U2 snRNA hairpin IV in aqueous solution.

A 2200-ps molecular dynamics (MD) simulation of the U2 snRNA hairpin IV/U2B" complex was performed in aqueous solution using the particle mesh Ewald method to consider long-range electrostatic interactions. To investigate the interaction and recognition process between the RNA and protein, the free energy contributions resulting from individual amino acids of the protein component of the RNA/protein complex were calculated using the recently developed glycine-scanning method. The results revealed that the loop region of the U2 snRNA hairpin IV interacted mainly with three regions of the U2B" protein: 1) beta 1-helix A, 2) beta 2-beta 3, and 3) beta 4-helix C. U2 snRNA hairpin IV bound U2B" in a similar orientation as that previously described for U1 snRNA with the U1A' protein; however, the details of the interaction differed in several aspects. In particular, beta 1-helix A and beta 4-helix C in U2B" were not observed to interact with RNA in the U1A' protein complex. Most of the polar and charged residues in the interacting regions had larger mutant free energies than the nonpolar residues, indicating that electrostatic interactions were important for stabilizing the RNA/protein complex. The interaction was further stabilized by a network of hydrogen bonds and salt bridges formed between RNA and protein that was maintained throughout the MD trajectory. In addition to the direct interactions between RNA and the protein, solvent-mediated interactions also contributed significantly to complex stability. A detailed analysis of the ordered water molecules in the hydration of the RNA/protein complex revealed that bridged water molecules reside at the interface of RNA and protein as long as 2100 ps in the 2200-ps trajectory. At least 20 bridged water molecules, on average, contributed to the instantaneous stability of the RNA/protein complex. The stabilizing interaction energy due to bridging water molecules was obtained from ab initio Hartree-Fock and density functional theory calculations.     

Both U2 snRNA and U12 snRNA are required for accurate splicing of exon 5 of the rat calcitonin/CGRP gene

Two classes of spliceosome are present in eukaryotic cells. Most introns in nuclear pre-mRNAs are removed by a spliceosome that requires U1, U2, U4, U5, and U6 small nuclear ribonucleoprotein particles (snRNPs). A minor class of introns are removed by a spliceosome containing U11, U12, U5, U4atac, and U6 atac snRNPs. We describe experiments that demonstrate that splicing of exon 5 of the rat calcitonin/CGRP gene requires both U2 snRNA and U12 snRNA. In vitro, splicing to calcitonin/ CGRP exon 5 RNA was dependent on U2 snRNA, as preincubation of nuclear extract with an oligonucleotide complementary to U2 snRNA abolished exon 5 splicing. Addition of an oligonucleotide complementary to U12 snRNA increased splicing at a cryptic splice site in exon 5 from <5% to 50% of total spliced RNA. Point mutations in a candidate U12 branch sequence in calcitonin/CGRP intron 4, predicted to decrease U12-pre-mRNA base-pairing, also significantly increased cryptic splicing in vitro. Calcitonin/CGRP genes containing base changes disrupting the U12 branch sequence expressed significantly decreased CGRP mRNA levels when expressed in cultured cells. Coexpression of U12 snRNAs containing base changes predicted to restore U12-pre-mRNA base pairing increased CGRP mRNA synthesis to the level of the wild-type gene. These observations indicate that accurate, efficient splicing of calcitonin/CGRP exon 5 is dependent upon both U2 and U12 snRNAs.