Structural analyses of the pre‐mRNA splicing machinery

Pre‐mRNA splicing is a critical event in the gene expression pathway of all eukaryotes. The splicing reaction is catalyzed by the spliceosome, a huge protein‐RNA complex that contains five snRNAs and hundreds of different protein factors. Understanding the structure of this large molecular machinery is critical for understanding its function. Although the highly dynamic nature of the spliceosome, in both composition and conformation, posed daunting challenges to structural studies, there has been significant recent progress on structural analyses of the splicing machinery, using electron microscopy, crystallography, and nuclear magnetic resonance. This review discusses key recent findings in the structural analyses of the spliceosome and its components and how these findings advance our understanding of the function of the splicing machinery.     

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.     

Neuronal regulation of pre-mRNA splicing by polypyrimidine tract binding proteins,PTBP1 and PTBP2

Alternative splicing patterns are regulated by RNA binding proteins that assemble onto each pre-mRNA to form a complex RNP structure. The polypyrimidine tract binding protein, PTB, has served as an informative model for understanding how RNA binding proteins affect spliceosome assembly and how changes in the expression of these proteins can control complex programs of splicing in tissues. In this review, we describe the mechanisms of splicing regulation by PTB and its function, along with its paralog PTBP2, in neuronal development.     

Neuronal regulation of pre-mRNA splicing by polypyrimidine tract binding proteins, PTBP1 and PTBP2

Alternative splicing patterns are regulated by RNA binding proteins that assemble onto each pre-mRNA to form a complex RNP structure. The polypyrimidine tract binding protein, PTB, has served as an informative model for understanding how RNA binding proteins affect spliceosome assembly and how changes in the expression of these proteins can control complex programs of splicing in tissues. In this review, we describe the mechanisms of splicing regulation by PTB and its function, along with its paralog PTBP2, in neuronal development.     

Use of minigene systems to dissect alternative splicing elements

Pre-mRNA splicing is an essential step for gene expression in higher eukaryotes. The splicing efficiency of individual exons is determined by multiple features involving gene architecture, a variety of cis-acting elements within the exons and flanking introns, and interactions with components of the basal splicing machinery (called the spliceosome) and auxiliary regulatory factors which transiently co-assemble with the spliceosome. Both alternative and constitutive exons are recognized by multiple weak protein:RNA interactions and different exons differ in the interactions which are determinative for exon usage. Alternative exons are often regulated according to cell-specific patterns and regulation is mediated by specific sets of cis-acting elements and trans-acting factors. Transient expression of minigenes is a commonly used in vivo assay to identify the intrinsic features of a gene that control exon usage, identify specific cis-acting elements that control usage of constitutive and alternative exons, identify cis-acting elements that control cell-specific usage of alternative exons, and once regulatory elements have been identified, to identify the trans-acting factors that bind to these elements and modulate splicing. This chapter describes approaches and strategies for using minigenes to define the cis-acting elements that determine splice site usage and to identify and characterize the trans-acting factors that bind to these elements and regulate alternative splicing.     

Dissecting the human spliceosome through bioinformatics and proteomics approaches

The precise excision of introns from mRNAs is executed by the spliceosome, a cellular machinery composed by five small nuclear RNAs and hundreds of proteins. In the last few years, several groups have used proteomics and computational biology tools to characterize the components of the human spliceosome. These reports have identified basically all known splicing factors and several new proteins. The composition of the human spliceosome confirms the link between splicing and other steps in gene expression. Here we comment on these reports and discuss the perspectives for the coming years.     

Small molecule control of pre-mRNA splicing

SR proteins regulate alternative splicing by binding to exonic sequences where, via an arginine/serine-rich splicing activation domain, they enhance the binding of the spliceosome to the adjacent splice sites. Here, a system is described in which a nontoxic derivative of the small molecule rapamycin is used to control pre-mRNA splicing in vitro. This involves the rapamycin-dependent recruitment of a splicing activation domain located on one protein to a second protein bound to the pre-mRNA. These results provide a new approach to explore for regulating gene expression in vivo with small molecules by controlling pre-mRNA splicing.     

Commitment to splice site pairing coincides with A complex formation

Differential recognition of exons by the spliceosome regulates gene expression and exponentially increases the complexity of metazoan proteomes. After definition of the exons, the spliceosome is activated by a series of sequential structural rearrangements. Formation of the first ATP-independent spliceosomal complex commits the pre-mRNA to the general splicing pathway. However, the time at which a commitment to a specific splice site choice and pairing is made is unknown. Here, we demonstrate that alternative splicing patterns are irreversibly chosen at a kinetic step different from the ATP-independent commitment to splicing. Splice sites become committed at the first ATP-dependent spliceosomal complex when rearrangements lock U2 snRNP onto the pre-mRNA. Thus, commitment to the splicing pathway and commitment to splice site pairing are separate steps during spliceosomal assembly, and ATP hydrolysis drives the irreversible juxtaposition of exons within the spliceosome.     

Differential connectivity of splicing activators and repressors to the human spliceosome

BackgroundDuring spliceosome assembly, protein-protein interactions (PPI) are sequentially formed and disrupted to accommodate the spatial requirements of pre-mRNA substrate recognition and catalysis. Splicing activators and repressors, such as SR proteins and hnRNPs, modulate spliceosome assembly and regulate alternative splicing. However, it remains unclear how they differentially interact with the core spliceosome to perform their functions.ResultsHere, we investigate the protein connectivity of SR and hnRNP proteins to the core spliceosome using probabilistic network reconstruction based on the integration of interactome and gene expression data. We validate our model by immunoprecipitation and mass spectrometry of the prototypical splicing factors SRSF1 and hnRNPA1. Network analysis reveals that a factor’s properties as an activator or repressor can be predicted from its overall connectivity to the rest of the spliceosome. In addition, we discover and experimentally validate PPIs between the oncoprotein SRSF1 and members of the anti-tumor drug target SF3 complex. Our findings suggest that activators promote the formation of PPIs between spliceosomal sub-complexes, whereas repressors mostly operate through protein-RNA interactions.ConclusionsThis study demonstrates that combining in-silico modeling with biochemistry can significantly advance the understanding of structure and function relationships in the human spliceosome.

Electronic supplementary material

The online version of this article (doi:10.1186/s13059-015-0682-5) contains supplementary material, which is available to authorized users.     

Proofreading and spellchecking: a two-tier strategy for pre-mRNA splicing quality control

Multi-tier strategies exist in many biochemical processes to ensure a maximal fidelity of the reactions. In this review, we focus on the two-tier quality control strategy that ensures the quality of the products of the pre-mRNA splicing reactions catalyzed by the spliceosome. The first step in the quality control process relies on kinetic proofreading mechanisms that are internal to the spliceosome and that are performed by ATP-dependent RNA helicases. The second quality control step, spellchecking, involves recognition of unspliced pre-mRNAs or aberrantly spliced mRNAs that have escaped the first proofreading mechanisms, and subsequent degradation of these molecules by degradative enzymes in the nucleus or in the cytoplasm. This two-tier quality control strategy highlights a need for high fidelity and a requirement for degradative activities that eliminate defective molecules. The presence of multiple quality control activities during splicing underscores the importance of this process in the expression of genetic information.