Branch-point attack in group II introns is a highly reversible transesterification, providing a potential proofreading mechanism for 5'-splice site selection.

By examining the first step of group II intron splicing in the absence of the second step, we have found that there is an interplay of three distinct reactions at the 5'-splice site: branching, reverse branching, and hydrolytic cleavage. This approach has yielded the first kinetic parameters describing eukaryotic branching and establishes that group II intron catalysis can proceed on a rapid timescale. The efficient reversibility of the first step is due to increased conformational organization in the branched intermediate and it has several important mechanistic implications. Reversibility in the first step requires that the second step of splicing serve as a kinetic trap, thus driving splicing to completion and coordinating the first and second step of splicing. Facile reverse branching also provides the intron with a proofreading mechanism to control the fidelity of 5'-splice site selection and it provides a kinetic basis for the apparent mobility of group II introns.     

Exon ligation is proofread by the DExD/H-box ATPase Prp22p

To produce messenger RNA, the spliceosome excises introns from precursor (pre)-mRNA and splices the flanking exons. To establish fidelity, the spliceosome discriminates against aberrant introns, but current understanding of such fidelity mechanisms is limited. Here we show that an ATP-dependent activity represses formation of mRNA from aberrant intermediates having mutations in any of the intronic consensus sequences. This proofreading activity is disabled by mutations that impair the ATPase or RNA unwindase activity of Prp22p, a conserved spliceosomal DExD/H-box ATPase. Further, cold-sensitive prp22 mutants permit aberrant mRNA formation from a mutated 3' splice-site intermediate in vivo. We conclude that Prp22p generally represses splicing of aberrant intermediates, in addition to its known ATP-dependent role in promoting release of genuine mRNA. This dual function for Prp22p validates a general model in which fidelity can be enhanced by a DExD/H-box ATPase.     

Staying on message: ensuring fidelity in pre-mRNA splicing

The faithful expression of genes requires that cellular machinery select substrates with high specificity at each step in gene expression. High specificity is particularly important at the stage of nuclear pre-mRNA splicing, during which the spliceosome selects splice sites and excises intervening introns. With low specificity, the usage of alternative sites would yield insertions, deletions and frame shifts in mRNA. Recently, biochemical, genetic and genome-wide approaches have significantly advanced our understanding of splicing fidelity. In particular, we have learned that DExD/H-box ATPases play a general role in rejecting and discarding suboptimal substrates and that these factors serve as a paradigm for proofreading NTPases in other systems. Recent advances have also defined fundamental questions for future investigations.     

Analysis of spliceosome assembly and the structure of a regulated intron in Drosophila in vitro splicing extracts.

We characterize spliceosome assembly in Drosophila embryonic nuclear extracts. Further, we show that these extracts contain high levels of a 5' to 3' exoribonuclease activity allowing rapid, convenient protection mapping of 5' splice site and branchpoint sequences. We use this assay to show, for the first time, that a regulated arthropod intron uses a remote branchpoint strikingly similar in structure to those observed previously in regulated vertebrate introns. These results provide new evidence that both regulated and constitutive splicing are similar in detail in vertebrates and arthropods indicating that the powerful genetic systems for analysis of splicing regulation in Drosophila are likely to be directly informative for regulated splicing throughout metazoa. In addition, we report formation of a novel class of intron-dependent complexes. Behavior of these complexes indicates that they represent a mutually exclusive, kinetically competing pathway with spliceosome assembly. We propose that this competition represents the basis for a kinetic proofreading mechanism enhancing fidelity of intron recognition. We also discuss possible implications of this model for regulated splicing.     

Mechanisms of fidelity in pre-mRNA splicing

The pre-mRNA splicing machinery consists of five small nuclear RNAs (U1, U2, U4, U5 and U6) and more than fifty proteins. Over the past year, important advances have been made in understanding how these factors function to achieve fidelity in splicing. Of particular note were the discoveries that the splicing factor U2AF(35) recognizes the AG dinucleotide at the 3' splice site early in spliceosome assembly, that a DEAD-box ATPase, Prp28, triggers specific rearrangements of the spliceosome, and that the splicing factor hSlu7 functions in the fidelity of AG choice during catalytic step II of splicing.     

The spliceosome catalyzes debranching in competition with reverse of the first chemical reaction

Splicing of nuclear pre-mRNA occurs via two steps of the transesterification reaction, forming a lariat intermediate and product. The reactions are catalyzed by the spliceosome, a large ribonucleoprotein complex composed of five small nuclear RNAs and numerous protein factors. The spliceosome shares a similar catalytic core structure with that of fungal group II introns, which can self-splice using the same chemical mechanism. Like group II introns, both catalytic steps of pre-mRNA splicing can efficiently reverse on the affinity-purified spliceosome. The spliceosome also catalyzes a hydrolytic spliced-exon reopening reaction as observed in group II introns, indicating a strong link in their evolutionary relationship. We show here that, by arresting splicing after the first catalytic step, the purified spliceosome can catalyze debranching of lariat-intron-exon 2. The debranching reaction, although not observed in group II introns, has similar monovalent cation preferences as those for splicing catalysis of group II introns. The debranching reaction is in competition with the reverse Step 1 reaction influenced by the ionic environment and the structure of components binding near the catalytic center, suggesting that the catalytic center of the spliceosome can switch between different conformations to direct different chemical reactions.     

Inhibition of mammalian spliceosome assembly and pre-mRNA splicing by peptide inhibitors of protein kinases.

Four peptides are shown to block mammalian spliceosome assembly and pre-mRNA splicing in vitro. Previously, these peptides have been shown to inhibit Ca2+-dependent calmodulin kinase II (CaMK II) via distinct mechanisms. One is a competitive inhibitor of the kinase, two interfere with autophosphorylation events, and one competes for binding to calmodulin, a CaMK II-activating protein. However, because EGTA does not inhibit splicing, the involvement of CaMK II itself in splicing is unlikely; rather, a protein similar to CaMK II may be involved in spliceosome assembly and splicing. Two of the inhibitory peptides, the calmodulin binding domain (CBD) and glycogen synthase (GS) fragment, block assembly of spliceosomal complex C. These peptides inhibited splicing if they were added to reactions any time within the first 10 min of splicing assays. No inhibition of spliceosome assembly or splicing occurred in the presence of randomized versions of the CBD or GS peptide. Additionally, the GS peptide inhibited splicing when added to assays at later time points, despite the fact that spliceosomal complex C had formed. Cumulatively, these analyses suggest that the peptides inhibit at least two distinct events in the spliceosomal cycle. The first event occurs early during in vitro splicing. For this event, prolonged incubations of splicing reactions do not result in a recovery of splicing activity. The second event occurs later and represents a slowing of an essential step, because splicing activity can be recovered in prolonged incubations. Peptides known to inhibit protein kinase A and protein kinase C had no effect on pre-mRNA splicing, underscoring the specificity of the observed inhibitory effects.     

Competition between the ATPase Prp5 and branch region-U2 snRNA pairing modulates the fidelity of spliceosome assembly

ATPase-facilitated steps during spliceosome function have been postulated to afford opportunities for kinetic proofreading. Spliceosome assembly requires the ATPase Prp5p, whose activity might thus impact fidelity during initial intron recognition. Using alanine mutations in S. cerevisiae Prp5p, we identified a suboptimal intron whose splicing could be improved by altered Prp5p activity and then, using this intron, screened for potent prp5 mutants. These prp5 alleles specifically alter branch region selectivity, with improved splicing in vivo of suboptimal substrates correlating with reduced ATPase activity in vitro for a series of mutants in ATPase motif III (SAT). Because these effects are abrogated by compensatory U2 snRNA mutations or other changes that increase branch region-U2 pairing, these results explicitly link a fidelity event with a defined physical structure, the branch region-U2 snRNA duplex, and provide strong evidence that progression of the splicing pathway requires branch region-U2 snRNA pairing prior to Prp5p-facilitated conformational change.     

Functional roles of DExD/H-box RNA helicases in Pre-mRNA splicing

Splicing of precursor mRNA takes place via two consecutive steps of transesterification catalyzed by a large ribonucleoprotein complex called the spliceosome. The spliceosome is assembled through ordered binding to the pre-mRNA of five small nuclear RNAs and numerous protein factors, and is disassembled after completion of the reaction to recycle all components. Throughout the splicing cycle, the spliceosome changes its structure, rearranging RNA-RNA, RNA-protein and protein-protein interactions, for positioning and repositioning of splice sites. DExD/H-box RNA helicases play important roles in mediating structural changes of the spliceosome by unwinding of RNA duplexes or disrupting RNA-protein interactions. DExD/H-box proteins are also implicated in the fidelity control of the splicing process at various steps. This review summarizes the functional roles of DExD/H-box proteins in pre-mRNA splicing according to studies conducted mostly in yeast and will discuss the concept of the complicated splicing reaction based on recent findings.     

A systematic characterization of Cwc21, the yeast ortholog of the human spliceosomal protein SRm300

Cwc21 (complexed with Cef1 protein 21) is a 135 amino acid yeast protein that shares homology with the N-terminal domain of human SRm300/SRRM2, a large serine/arginine-repeat protein shown previously to associate with the splicing coactivator and 3′-end processing stimulatory factor, SRm160. Proteomic analysis of spliceosomal complexes has suggested a role for Cwc21 and SRm300 at the core of the spliceosome. However, specific functions for these proteins have remained elusive. In this report, we employ quantitative genetic interaction mapping, mass spectrometry of tandem affinity-purified complexes, and microarray profiling to investigate genetic, physical, and functional interactions involving Cwc21. Combined data from these assays support multiple roles for Cwc21 in the formation and function of splicing complexes. Consistent with a role for Cwc21 at the core of the spliceosome, we observe strong genetic, physical, and functional interactions with Isy1, a protein previously implicated in the first catalytic step of splicing and splicing fidelity. Together, the results suggest multiple functions for Cwc21/SRm300 in the splicing process, including an important role in the activation of splicing in association with Isy1.     

The spliceosome: caught in a web of shifting interactions

Splicing is a crucial, ubiquitous and highly complex step in eukaryotic gene expression. The daunting complexity of the splicing reaction, although fascinating, has severely limited our understanding of its mechanistic details. Recent advances have begun to provide exciting new insights into the dynamic interactions that govern the function of the spliceosome, the multi-megadalton complex that performs splicing. An emerging paradigm is the presence of a succession of distinct conformational states, which are stabilized by an intricate network of interactions. Recent data suggest that even subtle changes in the composition of the interaction network can result in interconversion of the different conformational states, providing opportunities for regulation and proofreading of spliceosome function. Significant progress in proteomics has elucidated the protein composition of the spliceosome at different stages of assembly. Also, the increased sophistication and resolution of cryo-electron microscopy techniques, combined with high-resolution structural studies on a smaller scale, promise to create detailed images of the global structure of the spliceosome and its main components, which in turn will provide a plethora of mechanistic insights. Overall, the past two years have seen a convergence of data from different lines of research into what promises to become a holistic picture of spliceosome function.     

Helicases involved in splicing from malaria parasite Plasmodium falciparum

An interesting element of eukaryotic genomes is the large quantity of non-coding intervening sequences commonly known as introns, which regularly interrupt functional genes and therefore must be removed prior to the use of genetic information by the cell. After splicing, the mature RNA is exported from the nucleus to the cytoplasm. Any error in the process of recognition and removal of introns, or splicing, would lead to change in genetic message and thus has potentially catastrophic consequences. Thus splicing is a highly complex essential step in eukaryotic gene expression. It takes place in spliceosome, which is a dynamic RNA-protein complex made of snRNPs and non-snRNP proteins. The splicing process consists of following sequential steps: spliceosome formation, the first transesterification and second transesterification reactions, release of the mature mRNA and recycling of the snRNPs. The spliceosomal components produce a complex network of RNA-RNA, RNA-protein and protein-protein interactions and spliceosome experience remodeling during each splicing cycle. Helicases are essentially required at almost each step for resolution of RNA-RNA and/or RNA-protein interactions. RNA helicases share a highly conserved helicase domain which includes the motif DExD/H in the single letter amino acid code. This article will focus on members of the DExD/H-box proteins involved specially in splicing in the malaria parasite Plasmodium falciparum.     

The splice is right: guarantors of fidelity in pre-mRNA splicing

Two recent papers, one from the Staley laboratory (Koodathingal and colleagues) and the other from the Cheng laboratory (Tseng and colleagues), show that the RNA-dependent ATPase Prp16, which is required for the second step of splicing, acts to reject slowly splicing pre-mRNAs immediately before the first catalytic reaction in pre-mRNA splicing. The results answer long-investigated questions about the actions of Prp16 and provide a wealth of molecular details on the proofreading process in pre-mRNA splicing. The discussion here reviews and integrates the results of the two papers and describes the implications for proofreading in splicing.     

Functional roles of protein splicing factors

RNA splicing is one of the fundamental processes in gene expression in eukaryotes. Splicing of pre-mRNA is catalysed by a large ribonucleoprotein complex called the spliceosome, which consists of five small nuclear RNAs and numerous protein factors. The spliceosome is a highly dynamic structure, assembled by sequential binding and release of the small nuclear RNAs and protein factors. DExD/H-box RNA helicases are required to mediate structural changes in the spliceosome at various steps in the assembly pathway and have also been implicated in the fidelity control of the splicing reaction. Other proteins also play key roles in mediating the progression of the spliceosome pathway. In this review, we discuss the functional roles of the protein factors involved in the spliceosome pathway primarily from studies in the yeast system.     

Functional analysis of the human CDC5L complex and identification of its components by mass spectrometry

Recently, we identified proteins that co-purify with the human spliceosome using mass spectrometry. One of the identified proteins, CDC5L, corresponds to the human homologue of the Schizosaccharomyces pombe CDC5(+) gene product. Here we show that CDC5L is part of a larger multiprotein complex in HeLa nuclear extract that incorporates into the spliceosome in an ATP-dependent step. We also show that this complex is required for the second catalytic step of pre-mRNA splicing. Immunodepletion of the CDC5L complex from HeLa nuclear extract inhibits the formation of pre-mRNA splicing products in vitro but does not prevent spliceosome assembly. The first catalytic step of pre-mRNA splicing is less affected by immunodepleting the complex. The purified CDC5L complex in HeLa nuclear extract restores pre-mRNA splicing activity when added to extracts that have been immunodepleted using anti-CDC5L antibodies. Using mass spectrometry and database searches, the major protein components of the CDC5L complex have been identified. This work reports a first purification and characterization of a functional, human non-snRNA spliceosome subunit containing CDC5L and at least five additional protein factors.     

Metal ion catalysis during the exon-ligation step of nuclear pre-mRNA splicing: extending the parallels between the spliceosome and group II introns

Mechanistic analyses of nuclear pre-mRNA splicing by the spliceosome and group II intron self-splicing provide insight into both the catalytic strategies of splicing and the evolutionary relationships between the different splicing systems. We previously showed that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA has no effect on splicing. We now report that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA causes a switch in metal specificity when the second step of splicing is monitored using a bimolecular exon-ligation assay. This suggests that the spliceosome uses a catalytic metal ion to stabilize the 3'-oxyanion leaving group during the second step of splicing, as shown previously for the first step. The lack of a metal-specificity switch under cis splicing conditions indicates that a rate-limiting conformational change between the two steps of splicing may mask the subsequent chemical step and the metal-specificity switch. As the group II intron, a true ribozyme, uses identical catalytic strategies for splicing, our results strengthen the argument that the spliceosome is an RNA catalyst that shares a common molecular ancestor with group II introns.     

Brr2解旋U4/U6 SnRNAs的调控机制

前体mRNA(precursor messager RNA,pre-mRNA)剪接是去除内含子和将外显子彼此连接形成成熟mRNA的过程。剪接过程在一个呈动态变化的大核糖核蛋白(ribonucleoprotein, RNP)复合体,即剪接体催化作用下完成。DExD/H-box RNA解旋酶在剪接体组装、激活及解聚过程中都发挥着重要作用。Brr2(bad response to refrigeration 2)这种DExD/H-box RNA解旋酶是构成U5稳定的亚单位。Brr2含有两个串联解旋酶盒结构,在剪接体激活中负责U4/U6的解旋,还参与剪接体催化及解聚过程,因此Brr2在剪接过程中必需具备严格的调控机制。在剪接过程中,Prp8的C端包含两个连续的RNase H域和Jab1/MPN域,能够正负调控Brr2活性。Snu114在调节Brr2活性中具有非常重要的作用。此外,Brr2通过C端解旋酶盒(C-terminal cassette, CC)与N末端域(N-terminal region)进行分子内的自我活性调节。本文综述了近年来在Brr2的分子间和分子内活性调节机制的研究进展,这些不同的调节机制协同作用才确保真核生物pre-mRNA可变剪接的保真性。     

Alterations of RNase H sensitivity of the 3'' splice site region during the in vitro splicing reaction.

We have developed a splicing assay system with an immobilized pre-mRNA to study the mechanism of the splicing reaction after spliceosome assembly. Using this system, we have found that the second step of the splicing reaction could be dissected into two stages. After the 5' splice site reaction, at least two factors interact with the pre-formed spliceosome containing intermediate molecules in an ATP-independent manner to convert the spliceosome into a form competent for the 3' splice site reaction. Then, the 3' splice site reaction occurs on this spliceosome, if ATP is supplied to the reaction mixture. We have also investigated the dynamic state of the 3' splice site region in the spliceosomes during the splicing reaction by probing with RNase H sensitivity. Prior to the 5' splice site reaction, the 3' splice site region was protected from RNase H attack. The region became sensitive immediately after the 5' splice site reaction, and subsequently became resistant again as the spliceosome competent for the 3' splice site reaction was formed. These results suggest that the interaction of the 3' splice site region with some spliceosome components changes significantly during the splicing reaction.     

Saccharomyces cerevisiae NineTeen complex (NTC)-associated factor Bud31/Ycr063w assembles on precatalytic spliceosomes and improves first and second step pre-mRNA splicing efficiency

Pre-mRNA splicing occurs in spliceosomes whose assembly and activation are critical for splice site selection and catalysis. The highly conserved NineTeen complex protein complex stabilizes various snRNA and protein interactions early in the spliceosome assembly pathway. Among several NineTeen complex-associated proteins is the nonessential protein Bud31/Ycr063w, which is also a component of the Cef1p subcomplex. A role for Bud31 in pre-mRNA splicing is implicated by virtue of its association with splicing factors, but its specific functions and spliceosome interactions are uncharacterized. Here, using in vitro splicing assays with extracts from a strain lacking Bud31, we illustrate its role in efficient progression to the first catalytic step and its requirement for the second catalytic step in reactions at higher temperatures. Immunoprecipitation of functional epitope-tagged Bud31 from in vitro reactions showed that its earliest association is with precatalytic B complex and that the interaction continues in catalytically active complexes with stably bound U2, U5, and U6 small nuclear ribonucleoproteins. In complementary experiments, wherein precatalytic spliceosomes are selected from splicing reactions, we detect the occurrence of Bud31. Cross-linking of proteins to pre-mRNAs with a site-specific 4-thio uridine residue at the -3 position of exon 1 was tested in reactions with WT and bud31 null extracts. The data suggest an altered interaction between a ～25-kDa protein and this exonic residue of pre-mRNAs in the arrested bud31 null spliceosomes. These results demonstrate the early spliceosomal association of Bud31 and provide plausible functions for this factor in stabilizing protein interactions with the pre-mRNA.