Intronic sequence elements impede exon ligation and trigger a discard pathway that yields functional telomerase RNA in fission yeast.

The fission yeast telomerase RNA (TER1) precursor harbors an intron immediately downstream from its mature 3' end. Unlike most introns, which are removed from precursor RNAs by the spliceosome in two sequential but tightly coupled transesterification reactions, TER1 only undergoes the first cleavage reaction during telomerase RNA maturation. The mechanism underlying spliceosome-mediated 3' end processing has remained unclear. We now demonstrate that a strong branch site (BS), a long distance to the 3' splice site (3' SS), and a weak polypyrimidine (Py) tract act synergistically to attenuate the transition from the first to the second step of splicing. The observation that a strong BS antagonizes the second step of splicing in the context of TER1 suggests that the BS-U2 snRNA interaction is disrupted after the first step and thus much earlier than previously thought. The slow transition from first to second step triggers the Prp22 DExD/H-box helicase-dependent rejection of the cleaved products and Prp43-dependent "discard" of the splicing intermediates. Our findings explain how the spliceosome can function in 3' end processing and provide new insights into the mechanism of splicing.

Kilo-Scale GMP Synthesis of Renewable Semisynthetic Vaccine-Grade Squalene.

Emulsions of the triterpene squalene ((6E,10E,14E,18E)-2,6,10,15,19,23-hexamethyltetracosa-2,6,10,14,18,22-hexaene, CAS 111-02-4) have been used as adjuvants in influenza vaccines since the 1990s. Traditionally sourced from shark liver oil, the overfishing of sharks and concomitant reduction in the oceanic shark population raises sustainability issues for vaccine adjuvant grade squalene. We report a semisynthetic route to squalene meeting current pharmacopeial specifications for use in vaccines that leverages the ready availability of trans-ß-farnesene ((6E)-7,11-dimethyl-3-methylene-1,6,10-dodecatriene, CAS 18794-84-8), manufactured from sustainable sugarcane via a yeast fermentation process. The scalability of the proposed route was verified by a kilo-scale GMP synthesis. We also report data demonstrating the synthesized semi-synthetic squalene's physical stability and biological activity when used in a vaccine adjuvant formulation.

Functional selection and systematic analysis of intronic splicing elements identify active sequence motifs and associated splicing factors.

Despite the critical role of pre-mRNA splicing in generating proteomic diversity and regulating gene expression, the sequence composition and function of intronic splicing regulatory elements (ISREs) have not been well elucidated. Here, we employed a high-throughput in vivo Screening PLatform for Intronic Control Elements (SPLICE) to identify 125 unique ISRE sequences from a random nucleotide library in human cells. Bioinformatic analyses reveal consensus motifs that resemble splicing regulatory elements and binding sites for characterized splicing factors and that are enriched in the introns of naturally occurring spliced genes, supporting their biological relevance. In vivo characterization, including an RNAi silencing study, demonstrate that ISRE sequences can exhibit combinatorial regulatory activity and that multiple trans-acting factors are involved in the regulatory effect of a single ISRE. Our work provides an initial examination into the sequence characteristics and function of ISREs, providing an important contribution to the splicing code.

MBNL1 binds GC motifs embedded in pyrimidines to regulate alternative splicing.

Muscleblind-like 1 (MBNL1) regulates alternative splicing and is a key player in the disease mechanism of myotonic dystrophy (DM). In DM, MBNL1 becomes sequestered to expanded CUG/CCUG repeat RNAs resulting in splicing defects, which lead to disease symptoms. In order to understand MBNL1's role in both the disease mechanism of DM and alternative splicing regulation, we sought to identify its RNA-binding motif. A doped SELEX was performed on a known MBNL1-binding site. After five rounds of SELEX, MBNL1 selected pyrimidine-rich RNAs containing YGCY motifs. Insertion of multiple YGCY motifs into a normally MBNL1-independent splicing reporter was sufficient to promote regulation by MBNL1. MBNL1 was also shown to regulate the splicing of exon 22 in the ATP2A1 pre-mRNA, an exon mis-spliced in DM, via YGCY motifs. A search for YGCY motifs in 24 pre-mRNA transcripts that are mis-spliced in DM1 patients revealed an interesting pattern relative to the regulated exon. The intronic regions upstream of exons that are excluded in normal tissues relative to DM1, are enriched in YGCY motifs. Meanwhile, the intronic regions downstream of exons that are included in normal tissues relative to DM1, are enriched in YGCY motifs.

RNA binding specificity of Drosophila muscleblind.

Members of the muscleblind family of RNA binding proteins found in Drosophila and mammals are key players in both the human disease myotonic dystrophy and the regulation of alternative splicing. Recently, the mammalian muscleblind-like protein, MBNL1, has been shown to have interesting RNA binding properties with both endogenous and disease-related RNA targets. Here we report the characterization of RNA binding properties of the Drosophila muscleblind protein Mbl. Mutagenesis of double-stranded CUG repeats demonstrated that Mbl requires pyrimidine-pyrimidine mismatches for binding and that the identity and location of the C-G and G-C base pairs within the repeats are essential for Mbl binding. Systematic evolution of ligands by exponential enrichment (SELEX) was used to identify RNA sequences that bind Mbl with much higher affinity than CUG repeats. The RNA sequences identified by SELEX are structured and contain a five-nucleotide consensus sequence of 5'-AGUCU-3'. RNase footprinting of one of the SELEX RNA sequences with Mbl showed that Mbl binds both double-stranded and single-stranded regions of the RNA. Three guanosines show the strongest footprint in the presence of Mbl; mutation of any of these three guanosines eliminates Mbl binding. It was also found that Mbl specifically bound a human MBNL1 RNA target, demonstrating the conservation of the muscleblind proteins in recognizing RNA targets. Our results reveal that Mbl recognizes complex RNA secondary structures.

Computational approaches to mine publicly available databases.

Publicly available sequence annotation data is a vital resource for researchers. Many types of information are available, including structural annotations (i.e., the locations and identities of genomic features) and functional annotations (e.g., gene expression and protein interactions). Annotation data is especially useful for interrogating Next-Gen sequencing data (e.g., identifying genomic features that are associated with mapped reads). Additionally, the vast amount of data that is available offers researchers the opportunity to mine existing data sets and make new discoveries. The ability to efficiently obtain, manipulate, and interrogate this data is a valuable and empowering skill. In this chapter, we introduce several primary data repositories and describe the most commonly encountered file formats. In order to highlight some of the key concepts, operations, and utilities that are involved in working with annotation data we provide a fully worked example of using annotations to answer some basic questions about a particular CHIP-seq data set.

Frequent gain and loss of intronic splicing regulatory elements during the evolution of vertebrates.

Splicing regulatory elements (SREs) are sequences bound by proteins that influence splicing of nearby splice sites. Constitutively spliced introns have evolved to utilize many different splicing factors. The evolutionary processes that influenced which splicing factors are used for splicing of individual introns are generally unclear. We demonstrate that in the lineage that gave rise to mammals, many introns lost U-rich sequences and gained G-rich sequences, both of which resemble known SREs. The apparent conversion of U-rich to G-rich SREs suggests that the associated splicing factors are functionally equivalent. In support of this we demonstrated that U-rich and G-rich SREs are both capable of promoting splicing of an SRE-dependent splicing reporter. Furthermore, we demonstrate, using the heterologous MS2 tethering system (bacterial MS2 coat fusion-protein and its RNA stem-loop binding site), that both the U-rich SRE-binding protein (TIA1) and the G-rich SRE-binding protein (HNRNPF) can promote splicing of the same intron. We also observed that gain of G-rich SREs is significantly associated with G/C-rich genomic isochores, suggesting that gain or loss of SREs was driven by the same processes that ultimately resulted in the formation of mammalian genomic isochores. We propose the following model for the gain and loss of mammalian SREs. Ancestral U-rich SREs located in genomic regions that were experiencing high rates of A/T to G/C conversion would have suffered frequent deleterious mutations. However, this same process resulted in increased formation of functionally equivalent G-rich SREs, and acquisition of new G-rich SREs decreased purifying selection on the U-rich SREs, which were then free to decay.

Alternative modes of binding by U2AF65 at the polypyrimidine tract.

During initial recognition of an intron in pre-mRNA, the 3' end of the intron is bound by essential splicing factors. Notably, the consensus RNA sequences bound by these proteins are highly degenerate in humans. This raises the question of 3' splicing factor function in introns lacking canonical binding sites. Investigating the introns of the model organism Neurospora crassa revealed a different organization at the 3' end of the intron compared to most eukaryotic organisms. The predicted branch point sequences of Neurospora introns are much closer to the 3' splice site compared to those in human introns. In addition, Neurospora introns lack the canonical polypyrimidine tract found at the end of introns in most eukaryotic organisms. The large subunit of the U2 snRNP associated factor (U2AF65), which is essential for splicing of human introns and specifically recognizes the polypyrimidine tract, is also present in Neurospora. We show that Neurospora U2AF65 binds RNA with low affinity and specificity, apparently evolving with its disappearing binding site. The arginine/serine rich domain at the N-terminus of Neurospora U2AF65 regulates its RNA binding. We find that this regulated binding can be recapitulated in human U2AF65 which has been mutated to decrease both affinity and overall charge. Finally, we show that the addition of the small U2AF subunit (U2AF35) to U2AF65 with weakened RNA binding affinity significantly enhances the affinity of the resulting U2AF heterodimer.

Identification of motifs that function in the splicing of non-canonical introns.

BACKGROUND: While the current model of pre-mRNA splicing is based on the recognition of four canonical intronic motifs (5' splice site, branchpoint sequence, polypyrimidine (PY) tract and 3' splice site), it is becoming increasingly clear that splicing is regulated by both canonical and non-canonical splicing signals located in the RNA sequence of introns and exons that act to recruit the spliceosome and associated splicing factors. The diversity of human intronic sequences suggests the existence of novel recognition pathways for non-canonical introns. This study addresses the recognition and splicing of human introns that lack a canonical PY tract. The PY tract is a uridine-rich region at the 3' end of introns that acts as a binding site for U2AF65, a key factor in splicing machinery recruitment. RESULTS: Human introns were classified computationally into low- and high-scoring PY tracts by scoring the likely U2AF65 binding site strength. Biochemical studies confirmed that low-scoring PY tracts are weak U2AF65 binding sites while high-scoring PY tracts are strong U2AF65 binding sites. A large population of human introns contains weak PY tracts. Computational analysis revealed many families of motifs, including C-rich and G-rich motifs, that are enriched upstream of weak PY tracts. In vivo splicing studies show that C-rich and G-rich motifs function as intronic splicing enhancers in a combinatorial manner to compensate for weak PY tracts. CONCLUSION: The enrichment of specific intronic splicing enhancers upstream of weak PY tracts suggests that a novel mechanism for intron recognition exists, which compensates for a weakened canonical pre-mRNA splicing motif.

A comprehensive computational characterization of conserved mammalian intronic sequences reveals conserved motifs associated with constitutive and alternative splicing.

Orthologous mammalian introns contain many highly conserved sequences. Of these sequences, many are likely to represent protein binding sites that are under strong positive selection. In order to identify conserved protein binding sites that are important for splicing, we analyzed the composition of intronic sequences that are conserved between human and six eutherian mammals. We focused on all completely conserved sequences of seven or more nucleotides located in the regions adjacent to splice-junctions. We found that these conserved intronic sequences are enriched in specific motifs, and that many of these motifs are statistically associated with either alternative or constitutive splicing. In validation of our methods, we identified several motifs that are known to play important roles in alternative splicing. In addition, we identified several novel motifs containing GCT that are abundant and are associated with alternative splicing. Furthermore, we demonstrate that, for some of these motifs, conservation is a strong indicator of potential functionality since conserved instances are associated with alternative splicing while nonconserved instances are not. A surprising outcome of this analysis was the identification of a large number of AT-rich motifs that are strongly associated with constitutive splicing. Many of these appear to be novel and may represent conserved intronic splicing enhancers (ISEs). Together these data show that conservation provides important insights into the identification and possible roles of cis-acting intronic sequences important for alternative and constitutive splicing.