Functional interaction of a novel 15.5kD [U4/U6.U5] tri-snRNP protein with the 5' stem-loop of U4 snRNA.

Activation of the spliceosome for splicing catalysis requires the dissociation of U4 snRNA from the U4/U6 snRNA duplex prior to the first step of splicing. We characterize an evolutionarily conserved 15.5 kDa protein of the HeLa [U4/U6.U5] tri-snRNP that binds directly to the 5' stem-loop of U4 snRNA. This protein shares a novel RNA recognition motif with several RNP-associated proteins, which is essential, but not sufficient for RNA binding. The 15.5kD protein binding site on the U4 snRNA consists of an internal purine-rich loop flanked by the stem of the 5' stem-loop and a stem comprising two base pairs. Addition of an RNA oligonucleotide comprising the 5' stem-loop of U4 snRNA (U4SL) to an in vitro splicing reaction blocked the first step of pre-mRNA splicing. Interestingly, spliceosomal C complex formation was inhibited while B complexes accumulated. This indicates that the 15.5kD protein, and/or additional U4 snRNP proteins associated with it, play an important role in the late stage of spliceosome assembly, prior to step I of splicing catalysis. Our finding that the 15.5kD protein also efficiently binds to the 5' stem-loop of U4atac snRNA indicates that it may be shared by the [U4atac/U6atac.U5] tri-snRNP of the minor U12-type spliceosome.     

The network of protein-protein interactions within the human U4/U6.U5 tri-snRNP

The human 25S U4/U6.U5 tri-snRNP is a major building block of the U2-type spliceosome and contains, in addition to the U4, U6, and U5 snRNAs, at least 30 distinct proteins. To learn more about the molecular architecture of the tri-snRNP, we have investigated interactions between tri-snRNP proteins using the yeast two-hybrid assay and in vitro binding assays, and, in addition, have identified distinct protein domains that are critical for the connectivity of this protein network in the human tri-snRNP. These studies revealed multiple interactions between distinct domains of the U5 proteins hPrp8, hBrr2 (a DExH/D-box helicase), and hSnu114 (a putative GTPase), which are key players in the catalytic activation of the spliceosome, during which the U4/U6 base-pairing interaction is disrupted and U4 is released from the spliceosome. Both the U5-specific, TPR/HAT-repeat-containing hPrp6 protein and the tri-snRNP-specific hSnu66 protein interact with several U5- and U4/U6-associated proteins, including hBrr2 and hPrp3, which contacts the U6 snRNA. Thus, both proteins are located at the interface between U5 and U4/U6 in the tri-snRNP complex, and likely play an important role in transmitting the activity of hBrr2 and hSnu114 in the U5 snRNP to the U4/U6 duplex during spliceosome activation. A more detailed analysis of these protein interactions revealed that different HAT repeats mediate interactions with specific hPrp6 partners. Taken together, data presented here provide a detailed picture of the network of protein interactions within the human tri-snRNP.     

Human U4/U6.U5 and U4atac/U6atac.U5 tri-snRNPs exhibit similar protein compositions

In the U12-dependent spliceosome, the U4atac/U6atac snRNP represents the functional analogue of the major U4/U6 snRNP. Little information is available presently regarding the protein composition of the former snRNP and its association with other snRNPs. In this report we show that human U4atac/U6atac di-snRNPs associate with U5 snRNPs to form a 25S U4atac/U6atac.U5 trimeric particle. Comparative analysis of minor and major tri-snRNPs by using immunoprecipitation experiments revealed that their protein compositions are very similar, if not identical. Not only U5-specific proteins but, surprisingly, all tested U4/U6- and major tri-snRNP-specific proteins were detected in the minor tri-snRNP complex. Significantly, the major tri-snRNP-specific proteins 65K and 110K, which are required for integration of the major tri-snRNP into the U2-dependent spliceosome, were among those proteins detected in the minor tri-snRNP, raising an interesting question as to how the specificity of addition of tri-snRNP to the corresponding spliceosome is maintained. Moreover, immunodepletion studies demonstrated that the U4/U6-specific 61K protein, which is involved in the formation of major tri-snRNPs, is essential for the association of the U4atac/U6atac di-snRNP with U5 to form the U4atac/U6atac.U5 tri-snRNP. Subsequent immunoprecipitation studies demonstrated that those proteins detected in the minor tri-snRNP complex are also incorporated into U12-dependent spliceosomes. This remarkable conservation of polypeptides between minor and major spliceosomes, coupled with the absence of significant sequence similarity between the functionally analogous snRNAs, supports an evolutionary model in which most major and minor spliceosomal proteins, but not snRNAs, are derived from a common ancestor.     

SPF30 is an essential human splicing factor required for assembly of the U4/U5/U6 tri-small nuclear ribonucleoprotein into the spliceosome

Spliceosome assembly involves the sequential recruitment of small nuclear ribonucleoproteins (snRNPs) onto a pre-mRNA substrate. Although several non-snRNP proteins function during the binding of U1 and U2 snRNPs, little is known about the subsequent binding of the U4/U5/U6 tri-snRNP. A recent proteomic analysis of the human spliceosome identified SPF30 (Neubauer, G., King, A., Rappsilber, J., Calvio, C., Watson, M., Ajuh, P., Sleeman, J., Lamond, A., and Mann, M. (1998) Nat. Genet. 20, 46-50), a homolog of the survival of motor neurons (SMN) protein, as a spliceosome factor. We show here that SPF30 is a nuclear protein that associates with both U4/U5/U6 and U2 snRNP components. In the absence of SPF30, the preformed tri-snRNP fails to assemble into the spliceosome. Mass spectrometric analysis shows that a recombinant glutathione S-transferase-SPF30 fusion protein associates with complexes containing core Sm and U4/U5/U6 tri-snRNP proteins when added to HeLa nuclear extract, most strongly to U4/U6-90. The data indicate that SPF30 is an essential human splicing factor that may act to dock the U4/U5/U6 tri-snRNP to the A complex during spliceosome assembly or, alternatively, may act as a late assembly factor in both the tri-snRNP and the A-complex.     

Biochemical and genetic analyses of the U5, U6, and U4/U6 x U5 small nuclear ribonucleoproteins from Saccharomyces cerevisiae.

We have purified the yeast U5 and U6 pre-mRNA splicing small nuclear ribonucleoproteins (snRNPs) by affinity chromatography and analyzed the associated polypeptides by mass spectrometry. The yeast U5 snRNP is composed of the two variants of U5 snRNA, six U5-specific proteins and the 7 proteins of the canonical Sm core. The U6 snRNP is composed of the U6 snRNA, Prp24, and the 7 Sm-Like (LSM) proteins. Surprisingly, the yeast DEAD-box helicase-like protein Prp28 is stably associated with the U5 snRNP, yet is absent from the purified U4/U6 x U5 snRNP. A novel yeast U5 and four novel yeast U4/U6 x U5 snRNP polypeptides were characterized by genetic and biochemical means to demonstrate their involvement in the pre-mRNA splicing reaction. We also show that, unlike the human tri-snRNP, the yeast tri-snRNP dissociated upon addition of ATP or dATP.     

The yeast Prp3 protein is a U4/U6 snRNP protein necessary for integrity of the U4/U6 snRNP and the U4/U6.U5 tri-snRNP.

Previously, yeast prp3 mutants were found to be blocked prior to the first catalytic step of pre-mRNA splicing. No splicing intermediates or products are formed from pre-mRNA in heat-inactivated prp3 mutants or prp3 mutant extracts. Here we show that Prp3p is a component of the U4/U6 snRNP and is also present in the U4/U6.U5 tri-snRNP. Heat inactivation of prp3 extracts results in depletion of free U6 snRNPs and U4/U6.U5 tri-snRNPs, but not U4/U6 snRNPs or U5 snRNPs. Free U4 snRNP, normally not present in wild-type extracts, accumulates under these conditions. Assays of in vivo levels of snRNAs in a prp3 mutant revealed that amounts of free U6 snRNA decreased, free U4 snRNA increased, and U4/U6 hybrids decreased slightly. These results suggest that Prp3p is required for formation of stable U4/U6 snRNPs and for assembly of the U4/U6.U5 tri-snRNP from its component snRNPs. Upon inactivation of Prp3p, spliceosomes cannot assemble from prespliceosomes due to the absence of intact U4/U6.U5 tri-snRNPs. Prp3p is homologous to a human protein that is a component of U4/U6 snRNPs, exemplifying the conservation of splicing factors between yeast and metazoans.     

Proximity of the U12 snRNA with both the 5' splice site and the branch point during early stages of spliceosome assembly

U12 snRNA is required for branch point recognition in the U12-dependent spliceosome. Using site-specific cross-linking, we have captured an unexpected interaction between the 5' end of the U12 snRNA and the -2 position upstream of the 5' splice site of P120 and SCN4a splicing substrates. The U12 snRNA nucleotides that contact the 5' exon are the same ones that form the catalytically important helix Ib with U6atac snRNA in the spliceosome catalytic core. However, the U12/5' exon interaction is transient, occurring prior to the entry of the U4atac/U6atac.U5 tri-snRNP to the spliceosome. This suggests that the helix Ib region of U12 snRNA is positioned near the 5' splice site early during spliceosome assembly and only later interacts with U6atac to form helix Ib. We also provide evidence that U12 snRNA can simultaneously interact with 5' exon sequences near 5' splice site and the branch point sequence, suggesting that the 5' splice site and branch point sequences are separated by <40 to 50 A in the complex A of the U12-dependent spliceosome. Thus, no major rearrangements are subsequently needed to position these sites for the first step of catalysis.     

Hierarchical,clustered protein interactions with U4/U6 snRNA: a biochemical role for U4/U6 proteins

During activation of the spliceosome, the U4/U6 snRNA duplex is dissociated, releasing U6 for subsequent base pairing with U2 snRNA. Proteins that directly bind the U4/U6 interaction domain potentially could mediate these structural changes. We thus investigated binding of the human U4/U6-specific proteins, 15.5K, 61K and the 20/60/90K protein complex, to U4/U6 snRNA in vitro. We demonstrate that protein 15.5K is a nucleation factor for U4/U6 snRNP assembly, mediating the interaction of 61K and 20/60/90K with U4/U6 snRNA. A similar hierarchical assembly pathway is observed for the U4atac/U6atac snRNP. In addition, we show that protein 61K directly contacts the 5' portion of U4 snRNA via a novel RNA-binding domain. Furthermore, the 20/60/90K heteromer requires stem II but not stem I of the U4/U6 duplex for binding, and this interaction involves a direct contact between protein 90K and U6. This uneven clustering of the U4/U6 snRNP-specific proteins on U4/U6 snRNA is consistent with a sequential dissociation of the U4/U6 duplex prior to spliceosome catalysis.     

Sad1 Counteracts Brr2-Mediated Dissociation of U4/U6.U5 in Tri-snRNP Homeostasis

The yeast Sad1 protein was previously identified in a screen for factors involved in the assembly of the U4/U6 di-snRNP particle. Sad1 is required for pre-mRNA splicing both in vivo and in vitro, and its human orthologue has been shown to associate with U4/U6.U5 tri-snRNP. We show here that Sad1 plays a role in maintaining a functional form of the tri-snRNP by promoting the association of U5 snRNP with U4/U6 di-snRNP. In the absence of Sad1, the U4/U6.U5 tri-snRNP dissociates into U5 and U4/U6 upon ATP hydrolysis and cannot bind to the spliceosome. The separated U4/U6 and U5 can reassociate upon incubation more favorably in the absence of ATP and in the presence of Sad1. Brr2 is responsible for mediating ATP-dependent dissociation of the tri-snRNP. Our results demonstrate a role of Sad1 in maintaining the integrity of the tri-snRNP by counteracting Brr2-mediated dissociation of tri-snRNP and provide insights into homeostasis of the tri-snRNP.     

Base pairing with U6atac snRNA is required for 5' splice site activation of U12-dependent introns in vivo.

The minor U12-dependent class of eukaryotic nuclear pre-mRNA introns is spliced by a distinct spliceosomal mechanism that requires the function of U11, U12, U5, U4atac, and U6atac snRNAs. Previous work has shown that U11 snRNA plays a role similar to U1 snRNA in the major class spliceosome by base pairing to the conserved 5'' splice site sequence. Here we show that U6atac snRNA also base pairs to the 5'' splice site in a manner analogous to that of U6 snRNA in the major class spliceosome. We show that splicing defective mutants of the 5'' splice site can be activated for splicing in vivo by the coexpression of compensatory U6atac snRNA mutants. In some cases, maximal restoration of splicing required the coexpression of compensatory U11 snRNA mutants. The allelic specificity of mutant phenotype suppression is consistent with Watson-Crick base pairing between the pre-mRNA and the snRNAs. These results provide support for a model of the RNA-RNA interactions at the core of the U12-dependent spliceosome that is strikingly similar to that of the major class U2-dependent spliceosome.     

3'-cyclic phosphorylation of U6 snRNA leads to recruitment of recycling factor p110 through LSm proteins

Pre-mRNA splicing proceeds through assembly of the spliceosome complex, catalysis, and recycling. During each cycle the U4/U6.U5 tri-snRNP is disrupted and U4/U6 snRNA base-pairing unwound, releasing separate post-spliceosomal U4, U5, and U6 snRNPs, which have to be recycled to the splicing-competent tri-snRNP. Previous work implicated p110--the human ortholog of the yeast Prp24 protein--and the LSm2-8 proteins of the U6 snRNP in U4/U6 recycling. Here we show in vitro that these proteins bind synergistically to U6 snRNA: Both purified and recombinant LSm2-8 proteins are able to recruit p110 protein to U6 snRNA via interaction with the highly conserved C-terminal region of p110. Furthermore, the presence of a 2',3'-cyclic phosphate enhances the affinity of U6 snRNA for the LSm2-8 proteins and inversely reduces La protein binding, suggesting a direct role of the 3'-terminal phosphorylation in RNP remodeling during U6 biogenesis.     

Direct probing of RNA structure and RNA-protein interactions in purified HeLa cell's and yeast spliceosomal U4/U6.U5 tri-snRNP particles

The U4/U6.U5 tri-snRNP is a key component of spliceosomes. By using chemical reagents and RNases, we performed the first extensive experimental analysis of the structure and accessibility of U4 and U6 snRNAs in tri-snRNPs. These were purified from HeLa cell nuclear extract and Saccharomyces cerevisiae cellular extract. U5 accessibility was also investigated. For both species, data demonstrate the formation of the U4/U6 Y-shaped structure. In the human tri-snRNP and U4/U6 snRNP, U6 forms the long range interaction, that was previously proposed to be responsible for dissociation of the deproteinized U4/U6 duplex. In both yeast and human tri-snRNPs, U5 is more protected than U4 and U6, suggesting that the U5 snRNP-specific protein complex and other components of the tri-snRNP wrapped the 5' stem-loop of U5. Loop I of U5 is partially accessible, and chemical modifications of loop I were identical in yeast and human tri-snRNPs. This reflects a strong conservation of the interactions of proteins with the functional loop I. Only some parts of the U4/U6 Y-shaped motif (the 5' stem-loop of U4 and helix II) are protected. Due to difference of protein composition of yeast and human tri-snRNP, the U6 segment linking the 5' stem-loop to the Y-shaped structure and the U4 central single-stranded segment are more accessible in the yeast than in the human tri-snRNP, especially, the phylogenetically conserved ACAGAG sequence of U6. Data are discussed taking into account knowledge on RNA and protein components of yeast and human snRNPs and their involvement in splicesome assembly.     

Electron microscopy of U4/U6 snRNP reveals a Y-shaped U4 and U6 RNA containing domain protruding from the U4 core RNP

We describe the electron microscopic investigation of purified U4/U6 snRNPs from human and murine cells. The U4/U6 snRNP exhibits two morphological features, a main body approximately 8 nm in diameter and a peripheral filamentous domain, 7-10 nm long. Two lines of evidence suggest that the peripheral domain may consist of RNA and to contain U6 RNA as well as the 5' portion of U4 RNA. (a) Separation of the U4/U6 snRNA interaction regions from the core domains by site-directed cleavage of the U4 snRNA with RNase H gave filament-free, globular core snRNP structures. (b) By immuno and DNA-hybridization EM, both the 5' end of U4 and the 3' end of U6 snRNA were located at the distal region of the filamentous domain, furthest from the core. These results, together with our observation that the filamentous U4/U6 domain is often Y shaped, correlate strikingly with the consensus secondary structure proposed by Brow and Guthrie (1988. Nature (Lond.), 334:213-218), where U4 and U6 snRNA are base paired in such a way that two U4/U6 helices together with a stem/loop of U4 snRNA make up a Y-shaped U4/U6 interaction domain.     

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.     

All small nuclear RNAs (snRNAs) of the [U4/U6.U5] Tri-snRNP localize to nucleoli; Identification of the nucleolar localization element of U6 snRNA

Previously, we showed that spliceosomal U6 small nuclear RNA (snRNA) transiently passes through the nucleolus. Herein, we report that all individual snRNAs of the [U4/U6.U5] tri-snRNP localize to nucleoli, demonstrated by fluorescence microscopy of nucleolar preparations after injection of fluorescein-labeled snRNA into Xenopus oocyte nuclei. Nucleolar localization of U6 is independent from [U4/U6] snRNP formation since sites of direct interaction of U6 snRNA with U4 snRNA are not nucleolar localization elements. Among all regions in U6, the only one required for nucleolar localization is its 3' end, which associates with the La protein and subsequently during maturation of U6 is bound by Lsm proteins. This 3'-nucleolar localization element of U6 is both essential and sufficient for nucleolar localization and also required for localization to Cajal bodies. Conversion of the 3' hydroxyl of U6 snRNA to a 3' phosphate prevents association with the La protein but does not affect U6 localization to nucleoli or Cajal bodies.     

Mammalian U6 small nuclear RNA undergoes 3'' end modifications within the spliceosome.

Mammalian U6 small nuclear RNA (snRNA) is heterogeneous with respect to the number of 3' terminal U residues. The major form terminates with five U residues and a 2',3' cyclic phosphate. Because of the presence in HeLa cell nuclear extracts of a terminal uridylyl transferase, a minor form of U6 snRNA is elongated, producing multiple species containing up to 12 U residues. In this study we have used glycerol gradients to demonstrate that these U6 snRNA forms are assembled into U6 ribonucleoprotein (RNP), U4/U6 snRNPs, and U4/U5/U6 tri-snRNP complexes. Furthermore, glycerol gradients combined with affinity selection of biotinylated pre-mRNAs led us to show that elongated forms of U6 snRNAs enter the spliceosome and that some of these become shortened with time to a single species having the same characteristics as the major form of U6 snRNA present in mammalian nuclear extracts. We propose that this elongation-shortening process is related to the function of U6 snRNA in mammalian pre-mRNA splicing.     

The intramolecular stem-loop structure of U6 snRNA can functionally replace the U6atac snRNA stem-loop

The U6 spliceosomal snRNA forms an intramolecular stem-loop structure during spliceosome assembly that is required for splicing and is proposed to be at or near the catalytic center of the spliceosome. U6atac snRNA, the analog of U6 snRNA used in the U12-dependent splicing of the minor class of spliceosomal introns, contains a similar stem-loop whose structure but not sequence is conserved between humans and plants. To determine if the U6 and U6atac stem-loops are functionally analogous, the stem-loops from human and budding yeast U6 snRNAs were substituted for the U6atac snRNA structure and tested in an in vivo genetic suppression assay. Both chimeric U6/U6atac snRNA constructs were active for splicing in vivo. In contrast, several mutations of the native U6atac stem-loop that either delete putatively unpaired residues or disrupt the putative stem regions were inactive for splicing. Compensatory mutations that are expected to restore base pairing within the stem regions restored splicing activity. However, other mutants that retained base pairing potential were inactive, suggesting that functional groups within the stem regions may contribute to function. These results show that the U6atac snRNA stem-loop structure is required for in vivo splicing within the U12-dependent spliceosome and that its role is likely to be similar to that of the U6 snRNA intramolecular stem-loop.     

Identification of a PRPF4 Loss-of-Function Variant That Abrogates U4/U6.U5 Tri-snRNP Integration and Is Associated with Retinitis Pigmentosa

Pre-mRNA splicing by the spliceosome is an essential step in the maturation of nearly all human mRNAs. Mutations in six spliceosomal proteins, PRPF3, PRPF4, PRPF6, PRPF8, PRPF31 and SNRNP200, cause retinitis pigmentosa (RP), a disease characterized by progressive photoreceptor degeneration. All splicing factors linked to RP are constituents of the U4/U6.U5 tri-snRNP subunit of the spliceosome, suggesting that the compromised function of this particle may lead to RP. Here, we report the identification of the p.R192H variant of the tri-snRNP factor PRPF4 in a patient with RP. The mutation affects a highly conserved arginine residue that is crucial for PRPF4 function. Introduction of a corresponding mutation into the zebrafish homolog of PRPF4 resulted in a complete loss of function in vivo. A series of biochemical experiments suggested that p.R192H disrupts the binding interface between PRPF4 and its interactor PRPF3. This interferes with the ability of PRPF4 to integrate into the tri-snRNP, as shown in a human cell line and in zebrafish embryos. These data suggest that the p.R192H variant of PRPF4 represents a functional null allele. The resulting haploinsufficiency of PRPF4 compromises the function of the tri-snRNP, reinforcing the notion that this spliceosomal particle is of crucial importance in the physiology of the retina.     

SR proteins escort the U4/U6.U5 tri-snRNP to the spliceosome.

Pre-spliceosomes, formed in HeLa nuclear extracts and isolated by sedimentation on glycerol gradients, were chased into spliceosomes, the macromolecular enzyme that catalyzes intron removal. We demonstrate that the pre-spliceosome to spliceosome transition was dependent on ATP hydrolysis and required both a U-rich small nuclear ribonucleoprotein (U snRNP)-containing fraction and a fraction of non-snRNP factors. The active components in the non-snRNP fraction were identified as SR proteins and were purified to apparent homogeneity. Recombinant SR proteins (ASF, SC35, SRp55), as well as gel-purified SR proteins, with the exception of SRp20, were able to restore efficient spliceosome formation. We also demonstrate that the pre-spliceosome to spliceosome transition requires phosphorylated SR proteins. This is the first evidence that SR proteins are required for the pre-spliceosome to spliceosome transition, the step at which the U4/U6.U5 tri-snRNP assembles on the pre-mRNA. The results shown here, together with previous data, suggest U snRNPs require SR proteins as escorts to enter the assembling spliceosome.