U2 small nuclear RNA 3' end formation is directed by a critical internal structure distinct from the processing site

The SMN complex drives structural changes in human snRNAs to enable snRNP assembly

Spliceosomal snRNPs are multicomponent particles that undergo a complex maturation pathway. Human Sm-class snRNAs are generated as 3'-end extended precursors, which are exported to the cytoplasm and assembled together with Sm proteins into core RNPs by the SMN complex. Here, we provide evidence that these pre-snRNA substrates contain compact, evolutionarily conserved secondary structures that overlap with the Sm binding site. These structural motifs in pre-snRNAs are predicted to interfere with Sm core assembly. We model structural rearrangements that lead to an open pre-snRNA conformation compatible with Sm protein interaction. The predicted rearrangement pathway is conserved in Metazoa and requires an external factor that initiates snRNA remodeling. We show that the essential helicase Gemin3, which is a component of the SMN complex, is crucial for snRNA structural rearrangements during snRNP maturation. The SMN complex thus facilitates ATP-driven structural changes in snRNAs that expose the Sm site and enable Sm protein binding.

Gemin5 delivers snRNA precursors to the SMN complex for snRNP biogenesis

The SMN complex assembles Sm cores on snRNAs, a key step in the biogenesis of snRNPs, the spliceosome's major components. Here, using SMN complex inhibitors identified by high-throughput screening and a ribo-proteomic strategy on formaldehyde crosslinked RNPs, we dissected this pathway in cells. We show that protein synthesis inhibition impairs the SMN complex, revealing discrete SMN and Gemin subunits and accumulating an snRNA precursor (pre-snRNA)-Gemin5 intermediate. By high-throughput sequencing of this transient intermediate's RNAs, we discovered the previously undetectable precursors of all the snRNAs and identified their Gemin5-binding sites. We demonstrate that pre-snRNA 3' sequences function to enhance snRNP biogenesis. The SMN complex is also inhibited by oxidation, and we show that it stalls an inventory-complete SMN complex containing pre-snRNAs. We propose a stepwise pathway of SMN complex formation and snRNP biogenesis, highlighting Gemin5's function in delivering pre-snRNAs as substrates for Sm core assembly and processing.

Modified nucleotides at the 5' end of human U2 snRNA are required for spliceosomal E-complex formation

U2 snRNA, a key player in nuclear pre-mRNA splicing, contains a 5'-terminal m3G cap and many internal modifications. The latter were shown in vertebrates to be generally required for U2 function in splicing, but precisely which residues are essential and their role in snRNP and/or spliceosome assembly is presently not clear. Here, we investigated the roles of individual modified nucleotides of HeLa U2 snRNA in pre-mRNA splicing, using a two-step in vitro reconstitution/complementation assay. We show that the three pseudouridines and five 2'O-methyl groups within the first 20 nucleotides of U2 snRNA, but not the m3G cap, are required for efficient pre-mRNA splicing. Individual pseudouridines were not essential, but had cumulative effects on U2 function. In contrast, four of five 2'O-methylations (at positions 1, 2, 12, and 19) were individually required for splicing. The in vitro assembly of 17S U2 snRNPs was not dependent on the presence of modified U2 residues. However, individual internal modifications were required for the formation of the ATP-independent early spliceosomal E complex. Our data strongly suggest that modifications within the first 20 nucleotides of U2 play an important role in facilitating the interaction of U2 with U1 snRNP and/or other factors within the E complex.

A 3'-terminal minihelix in the precursor of human spliceosomal U2 small nuclear RNA

U2 RNA is one of five small nuclear RNAs that participate in the majority of mRNA splicing. In addition to its role in mRNA splicing, the biosynthesis of U2 RNA and three of the other spliceosomal RNAs is itself an intriguing process involving nuclear export followed by 5'-cap hypermethylation, assembly with specific proteins, 3' end processing, and then nuclear import. Previous work has identified sequences near the 3' end of pre-U2 RNA that are required for accurate and efficient processing. In this study, we have investigated the structural basis of U2 RNA 3' end processing by chemical and enzymatic probing methods. Our results demonstrate that the 3' end of pre-U2 RNA is a minihelix with an estimated stabilization free energy of -6.9 kcal/mol. Parallel RNA structure mapping experiments with mutant pre-U2 RNAs revealed that the presence of this 3' minihelix is itself not required for in vitro 3'-processing of pre-U2 RNA, in support of earlier studies implicating internal regions of pre-U2 RNA. Other considerations raise the possibility that this distinctive structural motif at the 3' end of pre-U2 RNA plays a role in the cleavage of the precursor from its longer primary transcript or in its nucleocytoplasmic traffic.

Inhibition of collagen alpha 1(I) expression by the 5' stem-loop as a molecular decoy

Collagen alpha1(I) mRNA is posttranscriptionally regulated in hepatic stellate cells (HSCs). Binding of protein factors to the evolutionary conserved stem-loop in the 5'-untranslated region (5' stem-loop) is required for a high level of expression in activated HSCs. The 5' stem-loop is also found in alpha2(I) and alpha1(III) mRNAs. Titration of the 5' stem-loop binding factors by a stably expressed RNA containing the 5' stem-loop (molecular decoy) may decrease the expression of these collagen mRNAs. We designed a 108-nt RNA that is transcribed from the optimized mouse U7 small nuclear RNA gene and contains the 5' stem-loop (p74WT decoy). This decoy accumulates in the nucleus and in the cytoplasm. When expressed in NIH 3T3 fibroblasts, the p74WT decoy decreased collagen alpha1(I) mRNA level by 60% and decreased collagen type I secreted into the cellular medium by 50%. We also expressed this decoy in quiescent rat HSCs by adenoviral gene transfer. Quiescent HSCs undergo activation in culture, resulting in a 60-70-fold increase in collagen alpha1(I) mRNA. The decoy decreases collagen alpha1(I) mRNA expression by 50-60% during activation of HSCs. It also decreases collagen alpha2(I) mRNA expression and collagen alpha1(III) mRNA expression. The cellular levels of collagen alpha1(I) propeptide and of disulfide-bonded collagen type I trimer are reduced by 70%. However, the p74WT decoy did not decrease alpha smooth muscle actin protein or the mRNA levels of glyceraldehyde-3-phosphate dehydrogenase and interleukin-6. The p74WT decoy was also introduced into activated human HSCs. In these cells, the decoy decreased collagen alpha1(I) propeptide and disulfide-bonded collagen trimer by 50-60%. These results indicate that the 5' stem-loop specifically regulates fibrillar collagen synthesis and represents a novel target for antifibrotic therapy. The molecular decoys provide a generalized method of assessing the functional significance of blocking the interactions of mRNA and proteins.

Interactions of U2 gene loci and their nuclear transcripts with Cajal (coiled) bodies: evidence for PreU2 within Cajal bodies

The Cajal (coiled) body (CB) is a structure enriched in proteins involved in mRNA, rRNA, and snRNA metabolism. CBs have been shown to interact with specific histone and snRNA gene loci. To examine the potential role of CBs in U2 snRNA metabolism, we used a variety of genomic and oligonucleotide probes to visualize in situ newly synthesized U2 snRNA relative to U2 loci and CBs. Results demonstrate that long spacer sequences between U2 coding repeats are transcribed, supporting other recent evidence that U2 transcription proceeds past the 3' box. The presence of bright foci of this U2 locus RNA differed between alleles within the same nucleus; however, this did not correlate with the loci's association with a CB. Experiments with specific oligonucleotide probes revealed signal for preU2 RNA within CBs. PreU2 was also detected in the locus-associated RNA foci, whereas sequences 3' of preU2 were found only in these foci, not in CBs. This suggests that a longer primary transcript is processed before entry into CBs. Although this work shows that direct contact of a U2 locus with a CB is not simply correlated with RNA at that locus, it provides the first evidence of new preU2 transcripts within CBs. We also show that, in contrast to CBs, SMN gems do not associate with U2 gene loci and do not contain preU2. Because other evidence indicates that preU2 is processed in the cytoplasm before assembly into snRNPs, results point to an involvement of CBs in modification or transport of preU2 RNA.

Genome-wide protein interaction screens reveal functional networks involving Sm-like proteins

A set of seven structurally related Sm proteins forms the core of the snRNP particles containing the spliceosomal U1, U2, U4 and U5 snRNAs. A search of the genomic sequence of Saccharomyces cerevisiae has identified a number of open reading frames that potentially encode structurally similar proteins termed Lsm (Like Sm) proteins. With the aim of analysing all possible interactions between the Lsm proteins and any protein encoded in the yeast genome, we performed exhaustive and iterative genomic two-hybrid screens, starting with the Lsm proteins as baits. Indeed, extensive interactions amongst eight Lsm proteins were found that suggest the existence of a Lsm complex or complexes. These Lsm interactions apparently involve the conserved Sm domain that also mediates interactions between the Sm proteins. The screens also reveal functionally significant interactions with splicing factors, in particular with Prp4 and Prp24, compatible with genetic studies and with the reported association of Lsm proteins with spliceosomal U6 and U4/U6 particles. In addition, interactions with proteins involved in mRNA turnover, such as Mrt1, Dcp1, Dcp2 and Xrn1, point to roles for Lsm complexes in distinct RNA metabolic processes, that are confirmed in independent functional studies. These results provide compelling evidence that two-hybrid screens yield functionally meaningful information about protein-protein interactions and can suggest functions for uncharacterized proteins, especially when they are performed on a genome-wide scale.

Genome-wide protein interaction screens reveal functional networks involving Sm-like proteins

A set of seven structurally related Sm proteins forms the core of the snRNP particles containing the spliceosomal U1, U2, U4 and U5 snRNAs. A search of the genomic sequence of Saccharomyces cerevisiae has identified a number of open reading frames that potentially encode structurally similar proteins termed Lsm (Like Sm) proteins. With the aim of analysing all possible interactions between the Lsm proteins and any protein encoded in the yeast genome, we performed exhaustive and iterative genomic two-hybrid screens, starting with the Lsm proteins as baits. Indeed, extensive interactions amongst eight Lsm proteins were found that suggest the existence of a Lsm complex or complexes. These Lsm interactions apparently involve the conserved Sm domain that also mediates interactions between the Sm proteins. The screens also reveal functionally significant interactions with splicing factors, in particular with Prp4 and Prp24, compatible with genetic studies and with the reported association of Lsm proteins with spliceosomal U6 and U4/U6 particles. In addition, interactions with proteins involved in mRNA turnover, such as Mrt1, Dcp1, Dcp2 and Xrn1, point to roles for Lsm complexes in distinct RNA metabolic processes, that are confirmed in independent functional studies. These results provide compelling evidence that two-hybrid screens yield functionally meaningful information about protein-protein interactions and can suggest functions for uncharacterized proteins, especially when they are performed on a genome-wide scale.

The C-group heterogeneous nuclear ribonucleoprotein proteins bind to the 5' stem-loop of the U2 small nuclear ribonucleoprotein particle

The C-group heterogeneous nuclear ribonucleoprotein (hnRNP) proteins bind to nascent pre-messenger RNA. In vitro studies have indicated that the C hnRNP proteins bind particularly strongly to the intron polypyrimidine tract of pre-mRNA and may be important for pre-mRNA splicing. In addition, there is evidence that the interaction of the C hnRNP proteins with pre-mRNA is facilitated by the U1 and U2 small nuclear RNPs (snRNPs). In the present study, we have uncovered another feature of the C hnRNP proteins that may provide a unifying framework for these previous observations; the C hnRNP proteins bind to the 5' stem-loop of the U2 snRNP. This was detected by incubating human 32P-labeled U2 snRNP in micrococcal nuclease-treated HeLa nuclear extracts, followed by UV-mediated protein-RNA cross-linking, which revealed that C hnRNP proteins were cross-linked to 32P-nucleotides in the U2 snRNP. In similar experiments, no cross-linking of C hnRNP proteins to 32P-labeled U1 or U4 snRNPs was observed. The observed cross-linking of C hnRNP proteins to U2 snRNP was efficiently competed by excess U2 RNA and by poly(U) but not by poly(A). No competition was observed with an RNA molecule comprising U2 nucleotides 105-189, indicating that the C hnRNP protein interactive regions of U2 RNA reside solely in the 5' half of the molecule. Oligodeoxynucleotide-mediated RNase H cleavage experiments revealed that a 5' region of U2 RNA including nucleotides 15-28 is essential for the observed C hnRNP protein cross-linking. C hnRNP protein cross-linking to U2 snRNP was efficiently competed by a mini-RNA corresponding to the first 29 nucleotides of U2 RNA, whereas no competition was observed with a variant of this mini-RNA in which the UUUU loop of stem-loop I was mutationally configured into a single-stranded RNA by replacing the stem with non-pairing nucleotides. Competition experiments with another mutant mini-U2 RNA in which the UUUU loop was replaced by AAAA indicated that both the UUUU loop and the stem are important for C hnRNP protein cross-linking, a finding consistent with other recent data on the RNA sequence specificity of C hnRNP protein binding.

Ribonucleoprotein particle assembly and modification of U2 small nuclear RNA containing 5-fluorouridine

An in vitro assembly/modification system was used to study the effect of 5-fluorouridine (5-FU) incorporation on the biosynthesis of the U2 small nuclear ribonucleoprotein particle (U2 snRNP). Labeled U2 RNAs were transcribed in vitro with 5-fluoro-UTP either partially supplementing or completely replacing UTP during synthesis. The resulting U2 RNAs have levels of 5-fluorouridine that range from 0 to 100% of the uridine content. When incubated in reactions containing extracts from HeLa cells, these 5-FU U2 RNAs are assembled into RNPs that are recognized by anti-Sm monoclonal antibody even when there is a complete replacement of uridine with 5-FU. However, when the in vitro assembled U2 snRNPs are subjected to buoyant density gradient centrifugation, the particles that contain 100% 5-FU are not resistant to salt dissociation. When the in vitro assembled U2 snRNPs were analyzed by velocity sedimentation gradient centrifugation, 5-FU incorporation correlated with a shift in the sedimentation rate of the particles. With 100% 5-FU incorporation, the peak of radioactivity shifted to approximately 15 S (control U2 RNA was at approximately 12 S). This peak from 5-FU U2 snRNPs was not resistant to dissociation on cesium sulfate gradients. The amount of pseudouridine (psi) found in the RNA from snRNP assembled in vitro on control and 5-FU-containing U2 RNAs was determined, and even at very low levels of 5-FU incorporation (5% replacement), the formation of psi was severely inhibited (36% of control). At higher levels of 5-FU incorporation, there was essentially no psi formed.