Evolution of the Early Spliceosomal Complex—From Constitutive to Regulated Splicing

Pre-mRNA splicing is a major process in the regulated expression of genes in eukaryotes, and alternative splicing is used to generate different proteins from the same coding gene. Splicing is a catalytic process that removes introns and ligates exons to create the RNA sequence that codifies the final protein. While this is achieved in an autocatalytic process in ancestral group II introns in prokaryotes, the spliceosome has evolved during eukaryogenesis to assist in this process and to finally provide the opportunity for intron-specific splicing. In the early stage of splicing, the RNA 5′ and 3′ splice sites must be brought within proximity to correctly assemble the active spliceosome and perform the excision and ligation reactions. The assembly of this first complex, termed E-complex, is currently the least understood process. We focused in this review on the formation of the E-complex and compared its composition and function in three different organisms. We highlight the common ancestral mechanisms in S. cerevisiae, S. pombe, and mammals and conclude with a unifying model for intron definition in constitutive and regulated co-transcriptional splicing.

Transcription and splicing dynamics during early Drosophila development

ABSTRACTWidespread co-transcriptional splicing has been demonstrated from yeast to human. However, measuring the kinetics of splicing relative to transcription has been hampered by technical challenges. Here, we took advantage of native elongating transcript sequencing (NET-seq) to identify the position of RNA polymerase II (Pol II) when exons become ligated in the newly synthesized RNA. We analyzed Drosophila melanogaster embryos because the genes transcribed initially during development have few and short introns (like yeast genes), whereas genes transcribed later contain multiple long introns (more similar to human genes). We detected spliced NET-seq reads connected to Pol II molecules that were positioned just a few nucleotides downstream of the 3’ splice site. Although the majority of splice junctions were covered by spliced reads, many introns remained unspliced, resulting in a complex range of heterogeneity in splicing dynamics. Introns that show splicing completion before Pol II has reached the end of the downstream exon are necessarily intron-defined. As expected, we found a relationship between the proportion of spliced reads and intron size. However, intron definition was observed at all intron sizes. Both canonical and recursive splicing were associated with a higher Pol II density, suggesting a splicing-coupled mechanism that slows down transcription elongation. We further observed that transcription termination was very efficient for isolated genes but that the presence of an overlapping antisense gene was often associated with transcriptional read-through. Taken together, our data unravels novel dynamic features of Pol II transcription and splicing in the developing Drosophila embryo.

In vitro assembly of an early spliceosome defining both splice sites

ABSTRACTFor splicing of a metazoan pre-mRNA, the four major splice signals – 5′ and 3′ splice sites (SS), branch-point site (BS), and a poly-pyrimidine tract (PPT) – are initially bound by splicing factors U1 snRNP, U2AF35, SF1, and U2AF65, respectively, leading up to an early spliceosomal complex, the E-complex. The E-complex consists of additional components and the mechanism of its assembly is unclear. Hence, how splice signals are organized within E-complex defining the exon-intron boundaries remains elusive. Here we present in vitro stepwise reconstitution of an early spliceosome, assembled by cooperative actions of U1 snRNP, SRSF1, SF1, U2AF65, U2AF35, and hnRNP A1, termed here the recognition (R) complex, within which both splice sites are recognized. The R-complex assembly indicates that the SRSF1:pre-mRNA complex initially defines a substrate for U1 snRNP, engaging exons at both ends of an intron. Subsequent 5′SS-dependent U1 snRNP binding enables recognition of the remaining splice signals, defining the intron. This R-complex assembly indicates the minimal constituents for intron definition revealing mechanistic principles behind the splice site recognition.

RES complex is associated with intron definition and required for zebrafish early embryogenesis

Pre-mRNA splicing is a critical step of gene expression in eukaryotes. Transcriptome-wide splicing patterns are complex and primarily regulated by a diverse set of recognition elements and associated RNA-binding proteins. The retention and splicing (RES) complex is formed by three different proteins (Bud13p, Pml1p and Snu17p) and is involved in splicing in yeast. However, the importance of the RES complex for vertebrate splicing, the intronic features associated with its activity, and its role in development are unknown. In this study, we have generated loss-of-function mutants for the three components of the RES complex in zebrafish and showed that they are required during early development. The mutants showed a marked neural phenotype with increased cell death in the brain and a decrease in differentiated neurons. Transcriptomic analysis of bud13, snip1 (pml1) and rbmx2 (snu17) mutants revealed a global defect in intron splicing, with strong mis-splicing of a subset of introns. We found these RES-dependent introns were short, rich in GC and flanked by GC depleted exons, all of which are features associated with intron definition. Using these features we developed a predictive model that classifies RES dependent introns. Altogether, our study uncovers the essential role of the RES complex during vertebrate development and provides new insights into its function during splicing.