A novel yeast U2 snRNP protein, Snu17p, is required for the first catalytic step of splicing and for progression of spliceosome assembly

We have isolated and microsequenced Snu17p, a novel yeast protein with a predicted molecular mass of 17 kDa that contains an RNA recognition motif. We demonstrate that Snu17p binds specifically to the U2 small nuclear ribonucleoprotein (snRNP) and that it is part of the spliceosome, since the pre-mRNA and the lariat-exon 2 are specifically coprecipitated with Snu17p. Although the SNU17 gene is not essential, its knockout leads to a slow-growth phenotype and to a pre-mRNA splicing defect in vivo. In addition, the first step of splicing is dramatically decreased in extracts prepared from the snu17 deletion (snu17Delta) mutant. This defect is efficiently reversed by the addition of recombinant Snu17p. To investigate the step of spliceosome assembly at which Snu17p acts, we have used nondenaturing gel electrophoresis. In Snu17p-deficient extracts, the spliceosome runs as a single slowly migrating complex. In wild-type extracts, usually at least two distinct complexes are observed: the prespliceosome, or B complex, containing the U2 but not the U1 snRNP, and the catalytically active spliceosome, or A complex, containing the U2, U6, and U5 snRNPs. Northern blot analysis and affinity purification of the snu17Delta spliceosome showed that it contains the U1, U2, U6, U5, and U4 snRNPs. The unexpected stabilization of the U1 snRNP and the lack of dissociation of the U4 snRNP suggest that loss of Snu17p inhibits the progression of spliceosome assembly prior to U1 snRNP release and after [U4/U6.U5] tri-snRNP addition.     

The differential interaction of snRNPs with pre-mRNA reveals splicing kinetics in living cells

Precursor messenger RNA (pre-mRNA) splicing is catalyzed by the spliceosome, a large ribonucleoprotein (RNP) complex composed of five small nuclear RNP particles (snRNPs) and additional proteins. Using live cell imaging of GFP-tagged snRNP components expressed at endogenous levels, we examined how the spliceosome assembles in vivo. A comprehensive analysis of snRNP dynamics in the cell nucleus enabled us to determine snRNP diffusion throughout the nucleoplasm as well as the interaction rates of individual snRNPs with pre-mRNA. Core components of the spliceosome, U2 and U5 snRNPs, associated with pre-mRNA for 15-30 s, indicating that splicing is accomplished within this time period. Additionally, binding of U1 and U4/U6 snRNPs with pre-mRNA occurred within seconds, indicating that the interaction of individual snRNPs with pre-mRNA is distinct. These results are consistent with the predictions of the step-wise model of spliceosome assembly and provide an estimate on the rate of splicing in human cells.     

The spliceosome assembly pathway in mammalian extracts.

A mammalian splicing commitment complex was functionally defined by using a template commitment assay. This complex was partially purified and shown to be a required intermediate for complex A formation. The productive formation of this commitment complex required both splice sites and the polypyrimidine tract. U1 small nuclear ribonucleoprotein (snRNP) was the only spliceosomal U snRNP required for this formation. A protein factor, very likely U2AF, is probably involved in the formation of the splicing commitment complex. From the kinetics of appearance of complex A and complex B, it was previously postulated that complex A represents a functional intermediate in spliceosome assembly. Complex A was partially purified and shown to be a required intermediate for complex B (spliceosome) formation. Thus, a spliceosome pathway is for the first time supported by direct biochemical evidence: RNA+U1 snRNP+?U2 auxiliary factor+?Y----CC+U2 snRNP+Z----A+U4/6,5 snRNPs+ beta----B.     

Spliceosomal small nuclear ribonucleoprotein particles repeatedly cycle through Cajal bodies

The Cajal body (CB) is a nuclear structure closely associated with import and biogenesis of small nuclear ribonucleoprotein particles (snRNPs). Here, we tested whether CBs also contain mature snRNPs and whether CB integrity depends on the ongoing snRNP splicing cycle. Sm proteins tagged with photoactivatable and color-maturing variants of fluorescent proteins were used to monitor snRNP behavior in living cells over time; mature snRNPs accumulated in CBs, traveled from one CB to another, and they were not preferentially replaced by newly imported snRNPs. To test whether CB integrity depends on the snRNP splicing cycle, two human orthologues of yeast proteins involved in distinct steps in spliceosome disassembly after splicing, hPrp22 and hNtr1, were depleted by small interfering RNA treatment. Surprisingly, depletion of either protein led to the accumulation of U4/U6 snRNPs in CBs, suggesting that reassembly of the U4/U6.U5 tri-snRNP was delayed. Accordingly, a relative decrease in U5 snRNPs compared with U4/U6 snRNPs was observed in CBs, as well as in nuclear extracts of treated cells. Together, the data show that particular phases of the spliceosome cycle are compartmentalized in living cells, with reassembly of the tri-snRNP occurring in CBs.     

A split luciferase-based reporter for detection of a cellular macromolecular complex

The spliceosome is a highly dynamic macromolecular ribonucleoprotein (RNP) machine that catalyzes pre-mRNA splicing by assembling U1, U2, U4, U5, and U6 small nuclear RNPs (snRNPs). To process large numbers of introns with a limited number of snRNPs, synthesis and recycling of snRNPs must be maintained within an appropriate range to avoid their shortage. However, the mechanism that maintains cellular snRNP levels is unknown. Molecules that modulate cellular snRNP levels may help to define this mechanism but are not available. Therefore, the goal of the current study was to develop a reporter for snRNP levels using split luciferase based on proteomic analysis of snRNPs. We constructed an expression library of a luciferase fragment fused to core components of U5 snRNP and used it to isolate pre-mRNA processing factor 6 (PRPF6) and small nuclear ribonucleoprotein 40 kDa (U5-40K) that specifically reconstitute luciferase activity in the U5 snRNP complex. Here we show that this reporter detects the effects of small molecules on the levels of the U5 snRNP reporter protein complex. Our approach provides an alternative assay to discover small molecules targeting a macromolecular complex when the structure of the complex is not precisely identified.     

Requirements for U2 snRNP addition to yeast pre-mRNA.

The in vitro spliceosome assembly pathway is conserved between yeast and mammals as U1 and U2 snRNPs associate with the pre-mRNA prior to U5 and U4/U6 snRNPs. In yeast, U1 snRNP-pre-mRNA complexes are the first splicing complexes visualized on native gels, and association with U1 snRNP apparently commits pre-mRNA to the spliceosome assembly pathway. The current study addresses U2 snRNP addition to commitment complexes. We show that commitment complex formation is relatively slow and does not require ATP, whereas U2 snRNP adds to the U1 snRNP complexes in a reaction that is relatively fast and requires ATP or hydrolyzable ATP analogs. In vitro spliceosome assembly was assayed in extracts derived from strains containing several U1 sRNA mutations. The results were consistent with a critical role for U1 snRNP in early complex formation. A mutation that disrupts the base-pairing between the 5' end of U1 snRNA and the 5' splice site allows some U2 snRNP addition to bypass the ATP requirement, suggesting that ATP may be used to destabilize certain U1 snRNP:pre-mRNA interactions to allow subsequent U2 snRNP addition.     

U5 small nuclear ribonucleoprotein: RNA structure analysis and ATP-dependent interaction with U4/U6.

To understand how the U5 small nuclear ribonucleoprotein (snRNP) interacts with other spliceosome components, its structure and binding to the U4/U6 snRNP were analyzed. The interaction of the U5 snRNP with the U4/U6 snRNP was studied by separating the snRNPs in HeLa cell nuclear extracts on glycerol gradients. A complex running at 25S and containing U4, U5, and U6 but not U1 or U2 snRNAs was identified. In contrast to results with native gel electrophoresis to separate snRNPs, this U4/U5/U6 snRNP complex requires ATP to assemble from the individual snRNPs. The structure of the U5 RNA within the U5 snRNP and the U4/5/6 snRNP complexes was then compared. Oligonucleotide-targeted RNase H digestion identified one RNA sequence in the U5 snRNP capable of base pairing to other nucleic acid sequences. Chemical modification experiments identified this sequence as well as two other U5 RNA sequences as accessible to modification within the U5 RNP. One of these regions is a large loop in the U5 RNA secondary structure whose sequence is conserved from Saccharomyces cerevisiae to humans. Interestingly, no differences in modification of free U5 snRNP as compared to U5 in the U4/U5/U6 snRNP complex were observed, suggesting that recognition of specific RNA sequences in the U5 snRNP is not required for U4/U5/U6 snRNP assembly.     

Polypeptide components of Drosophila small nuclear ribonucleoprotein particles.

In eukaryotes splicing of pre-mRNAs is mediated by the spliceosome, a dynamic complex of small nuclear ribonucleoprotein particles (snRNPs) that associate transiently during spliceosome assembly and the splicing reaction. We have purified snRNPs from nuclear extracts of Drosophila cells by affinity chromatography with an antibody specific for the trimethylguanosine (m3G) cap structure of snRNAs U1-U5. The polypeptide components of Drosophila snRNPs have been characterized and shown to consist of a number of proteins shared by all the snRNPs, and some proteins which appear to be specific to individual snRNP particles. On the basis of their apparent molecular weight and antigenicity many of these common and particle specific Drosophila snRNP proteins are remarkably conserved between Drosophila and human spliceosomes. By probing western blots of the Drosophila snRNP polypeptides with a number of antisera raised against human snRNP proteins, Drosophila polypeptides equivalent to many of the HeLa snRNP-common proteins have been identified, as well as candidates for a number of U1, U2 and U5-specific proteins.     

U1, U2, and U4/U6 small nuclear ribonucleoproteins are required for in vitro splicing but not polyadenylation

The requirement for individual U RNAs in splicing and polyadenylation was investigated using oligonucleotide-directed cleavage of snRNAs in in vitro processing extracts. Cleavage of U1, U2, or U4 RNA inhibited splicing but not polyadenylation of short precursor RNAs. Thus each snRNA and the snRNP in which it is assembled participates in the splicing reaction. Splicing activity was recovered when extracts containing cleaved U RNAs were mixed in pairwise combinations, indicating that U1, U2, and U4/U6 snRNPs independently interact with the assembling spliceosome. The involvement of multiple snRNPs in the splicing of simple precursor RNAs suggests that the spliceosome is a large complex assembly consisting of multiple snRNPs whose activity is dependent on the structural integrity of the individual U RNAs.     

Recycling of the U12-type spliceosome requires p110, a component of the U6atac snRNP

U12-dependent introns are spliced by the so-called minor spliceosome, requiring the U11, U12, and U4atac/U6atac snRNPs in addition to the U5 snRNP. We have recently identified U6-p110 (SART3) as a novel human recycling factor that is related to the yeast splicing factor Prp24. U6-p110 transiently associates with the U6 and U4/U6 snRNPs during the spliceosome cycle, regenerating functional U4/U6 snRNPs from singular U4 and U6 snRNPs. Here we investigated the involvement of U6-p110 in recycling of the U4atac/U6atac snRNP. In contrast to the major U6 and U4/U6 snRNPs, p110 is primarily associated with the U6atac snRNP but is almost undetectable in the U4atac/U6atac snRNP. Since p110 does not occur in U5 snRNA-containing complexes, it appears to be transiently associated with U6atac during the cycle of the minor spliceosome. The p110 binding site was mapped to U6 nucleotides 38 to 57 and U6atac nucleotides 10 to 30, which are highly conserved between these two functionally related snRNAs. With a U12-dependent in vitro splicing system, we demonstrate that p110 is required for recycling of the U4atac/U6atac snRNP.     

The ribonucleotidyl transferase USIP-1 acts with SART3 to promote U6 snRNA recycling

The spliceosome is a large molecular machine that serves to remove the intervening sequences that are present in most eukaryotic pre-mRNAs. At its core are five small nuclear ribonucleoprotein complexes, the U1, U2, U4, U5 and U6 snRNPs, which undergo dynamic rearrangements during splicing. Their reutilization for subsequent rounds of splicing requires reversion to their original configurations, but little is known about this process. Here, we show that ZK863.4/USIP-1 (U Six snRNA-Interacting Protein-1) is a ribonucleotidyl transferase that promotes accumulation of the Caenorhabditis elegans U6 snRNA. Endogenous USIP-1–U6 snRNA complexes lack the Lsm proteins that constitute the protein core of the U6 snRNP, but contain the U6 snRNP recycling factor SART3/B0035.12. Furthermore, co-immunoprecipitation experiments suggest that SART3 but not USIP-1 occurs also in a separate complex containing both the U4 and U6 snRNPs. Based on this evidence, genetic interaction between usip-1 and sart-3, and the apparent dissociation of Lsm proteins from the U6 snRNA during spliceosome activation, we propose that USIP-1 functions upstream of SART3 to promote U6 snRNA recycling.     

Targeted snRNP depletion reveals an additional role for mammalian U1 snRNP in spliceosome assembly

HeLa cell nuclear splicing extracts have been prepared that are specifically and efficiently depleted of U1, U2, or U4/U6 snRNPs by antisense affinity chromatography using biotinylated 2'-OMe RNA oligonucleotides. Removal of each snRNP particle prevents pre-mRNA splicing but arrests spliceosome formation at different stages of assembly. Mixing extracts depleted for different snRNP particles restores formation of functional splicing complexes. Specific binding of factors to the 3' splice site region is still detected in snRNP-depleted extracts. Depletion of U1 snRNP impairs stable binding of U2 snRNP to the pre-mRNA branch site. This role of U1 snRNP in promoting stable preslicing complex formation is independent of the U1 snRNA-5' splice site interaction.     

Reassembly and protection of small nuclear ribonucleoprotein particles by heat shock proteins in yeast cells

The process of mRNA splicing is sensitive to in vivo thermal inactivation, but can be protected by pretreatment of cells under conditions that induce heat-shock proteins (Hsps). This latter phenomenon is known as "splicing thermotolerance". In this article we demonstrate that the small nuclear ribonucleoprotein particles (snRNPs) are in vivo targets of thermal damage within the splicing apparatus in heat-shocked yeast cells. Following a heat shock, levels of the tri-snRNP (U4/U6.U5), free U6 snRNP, and a pre-U6 snRNP complex are dramatically reduced. In addition, we observe multiple alterations in U1, U2, U5, and U4/U6 snRNP profiles and the accumulation of precursor forms of U4- and U6-containing snRNPs. Reassembly of snRNPs following a heat shock is correlated with the recovery of mRNA splicing and requires both Hsp104 and the Ssa Hsp70 family of proteins. Furthermore, we correlate splicing thermotolerance with the protection of a subset of snRNPs by Ssa proteins but not Hsp104, and show that Hsp70 directly associates with U4- and U6-containing snRNPs in splicing thermotolerant cells. In addition, our results show that Hsp70 plays a role in snRNP assembly under normal physiological conditions.     

Pre-mRNA splicing in vitro requires intact U4/U6 small nuclear ribonucleoprotein

Selective cleavage of U4 or U6 RNA in a HeLa cell nuclear extract inhibits splicing of pre-mRNAs containing an adenovirus or a simian virus 40 intron. RNAs in the U4/U6 small nuclear ribonucleoprotein (snRNP) were specifically degraded with RNAase H and deoxyoligonucleotides. Two oligomers complementary to U4 RNA and two complementary to U6 RNA cleave their target RNAs and inhibit the appearance of both spliced products and reaction intermediates. Splicing is reconstituted by mixing an extract containing cleaved U4 or U6 RNA with one in which splicing has been inhibited by degrading U2 RNA. All four abundant snRNPs, containing U1, U2, U5, or U4 and U6 RNAs, are now implicated in pre-mRNA splicing. Possible interactions of the U4/U6 snRNP with other components of the splicing complex are discussed.     

An ordered pathway of snRNP binding during mammalian pre-mRNA splicing complex assembly.

We have studied the assembly, composition and structure of splicing complexes using biotin-avidin affinity chromatography and RNase protection assays. We find that U1, U2, U4, U5 and U6 snRNPs associate with the pre-mRNA and are in the mature, functional complex. Association of U1 snRNP with the pre-mRNA is rapid and ATP independent; binding of all other snRNPs occurs subsequently and is ATP dependent. Efficient binding of U1 and U2 snRNPs requires a 5' splice site or a 3' splice site/branch point region, respectively. Both sequence elements are required for efficient U4, U5 and U6 snRNP binding. Mutant RNA substrates containing only a 5' splice site or a 3' splice site/branch point region are assembled into 'partial' splicing complexes, which contain a subset of these five snRNPs. RNase protection experiments indicate that in contrast to U1 and U2 snRNPs, U4, U5 and U6 snRNPs do not contact the pre-mRNA. Based upon the time course of snRNP binding and the composition of sucrose gradient fractionated splicing complexes we suggest an assembly pathway proceeding from a 20S (U1 snRNP only) through a 40S (U1 and U2 snRNPs) to the functional 60S splicing complex (U1, U2, U4, U5 and U6 snRNPs).     

PRP4: a protein of the yeast U4/U6 small nuclear ribonucleoprotein particle.

The Saccharomyces cerevisiae prp mutants (prp2 through prp11) are known to be defective in pre-mRNA splicing at nonpermissive temperatures. We have sequenced the PRP4 gene and shown that it encodes a 52-kilodalton protein. We obtained PRP4 protein-specific antibodies and found that they inhibited in vitro pre-mRNA splicing, which confirms the essential role of PRP4 in splicing. Moreover, we found that PRP4 is required early in the spliceosome assembly pathway. Immunoprecipitation experiments with anti-PRP4 antibodies were used to demonstrate that PRP4 is a protein of the U4/U6 small nuclear ribonucleoprotein particle (snRNP). Furthermore, the U5 snRNP could be immunoprecipitated through snRNP-snRNP interactions in the large U4/U5/U6 complex.     

Antisense probes containing 2-aminoadenosine allow efficient depletion of U5 snRNP from HeLa splicing extracts.

RNA duplexes containing the modified base 2-amino-adenine in place of adenine are stabilized through the formation of three hydrogen bonds in 2-amino A.U base pairs. Antisense 2'-O-alkyloligoribonucleotide probes incorporating 2-aminoadenosine are thus able to efficiently affinity select RNP particles which are otherwise inaccessible. This has allowed the efficient and specific depletion of U5 snRNP from HeLa cell nuclear splicing extracts. U5 snRNP is shown to be essential for spliceosome assembly and for both steps of pre-mRNA splicing. The absence of U5 snRNP prevents the stable association of U4/U6 but not U1 and U2 snRNPs with pre-mRNA.     

Arrested yeast splicing complexes indicate stepwise snRNP recruitment during in vivo spliceosome assembly

Pre-mRNA splicing is catalyzed by the spliceosome, a macromolecular machine dedicated to intron removal and exon ligation. Despite an abundance of in vitro information and a small number of in vivo studies, the pathway of yeast (Saccharomyces cerevisiae) in vivo spliceosome assembly remains uncertain. To address this situation, we combined in vivo depletions of U1, U2, or U5 snRNAs with chromatin immunoprecipitation (ChIP) analysis of other splicing snRNPs along an intron-containing gene. The data indicate that snRNP recruitment to nascent pre-mRNA predominantly proceeds via the canonical three-step assembly pathway: first U1, then U2, and finally the U4/U6*U5 tri-snRNP. Tandem affinity purification (TAP) using a U2 snRNP-tagged protein allowed the characterization of in vivo assembled higher-order splicing complexes. Consistent with an independent snRNP assembly pathway, we observed high levels of U1-U2 prespliceosomes under U5-depletion conditions, and we observed significant levels of a U2/U5/U6/Prp19-complex mature splicing complex under wild-type conditions. These complexes have implications for the steady-state distribution of snRNPs within nuclei and also reinforce the stepwise recruitment of U1, U2, and the tri-snRNP during in vivo spliceosome assembly.     

Conserved loop I of U5 small nuclear RNA is dispensable for both catalytic steps of pre-mRNA splicing in HeLa nuclear extracts

The function of conserved regions of the metazoan U5 snRNA was investigated by reconstituting U5 small nuclear ribonucleoprotein particles (snRNPs) from purified snRNP proteins and HeLa or Xenopus U5 snRNA mutants and testing their ability to restore splicing to U5-depleted nuclear extracts. Substitution of conserved nucleotides comprising internal loop 2 or deletion of internal loop 1 had no significant effect on the ability of reconstituted U5 snRNPs to complement splicing. However, deletion of internal loop 2 abolished U5 activity in splicing and spliceosome formation. Surprisingly, substitution of the invariant loop 1 nucleotides with a GAGA tetraloop had no effect on U5 activity. Furthermore, U5 snRNPs reconstituted from an RNA formed by annealing the 5' and 3' halves of the U5 snRNA, which lacked all loop 1 nucleotides, complemented both steps of splicing. Thus, in contrast to yeast, loop 1 of the human U5 snRNA is dispensable for both steps of splicing in HeLa nuclear extracts. This suggests that its function can be compensated for in vitro by other spliceosomal components: for example, by proteins associated with the U5 snRNP. Consistent with this idea, immunoprecipitation studies indicated that several functionally important U5 proteins associate stably with U5 snRNPs containing a GAGA loop 1 substitution.