Project description:Exon skipping technologies enable exclusion of targeted exons from mature mRNA transcripts, which has broad applications in molecular and cellular biology, medicine and biotechnology. Existing exon skipping techniques include antisense oligonucleotides, targetable nucleases and base editors, which, while effective for specific applications at some target exons, remain hindered by shortcomings preventing their broader implementation including transient effects in the case of oligonucleotides or limiting PAM motifs, sequence context preferences for deaminases, and undesirable cryptic splicing in the case of gene editing tools. To overcome these limitations, we created SPLICER, a toolbox of next-generation base editors consisting of near-PAMless Cas9 nickase variants fused with different deaminases for simultaneous editing of splice acceptor (SA) and splice donor (SD) sequences. Synchronized SA and SD editing not only improves exon skipping rates but also reduces aberrant outcomes such as cryptic splicing and intron retention. SPLICER enables editing of exon splice sites with high efficiency, including many exons refractory to splicing reprogramming by the native SpCas9 BEs. To demonstrate the therapeutic potential of SPLICER, we targeted APP exon 17, which contains the amino acid residues responsible for the formation of Aβ plaques in Alzheimer’s disease. SPLICER enabled precise and highly efficient exon skipping, which reduced the formation of Aβ42 peptides in vitro while inducing DNA editing and exon skipping in vivo within a humanized mouse model of Alzheimer’s disease. Overall, SPLICER is a widely applicable and highly efficient toolbox for exon skipping with broad therapeutic applications.

Project description:Exon skipping technologies enable exclusion of targeted exons from mature mRNA transcripts, which has broad applications in molecular and cellular biology, medicine and biotechnology. Existing exon skipping techniques include antisense oligonucleotides, targetable nucleases and base editors, which, while effective for specific applications at some target exons, remain hindered by shortcomings preventing their broader implementation including transient effects in the case of oligonucleotides or limiting PAM motifs, sequence context preferences for deaminases, and undesirable cryptic splicing in the case of gene editing tools. To overcome these limitations, we created SPLICER, a toolbox of next-generation base editors consisting of near-PAMless Cas9 nickase variants fused with different deaminases for simultaneous editing of splice acceptor (SA) and splice donor (SD) sequences. Synchronized SA and SD editing not only improves exon skipping rates but also reduces aberrant outcomes such as cryptic splicing and intron retention. SPLICER enables editing of exon splice sites with high efficiency, including many exons refractory to splicing reprogramming by the native SpCas9 BEs. To demonstrate the therapeutic potential of SPLICER, we targeted APP exon 17, which contains the amino acid residues responsible for the formation of Aβ plaques in Alzheimer’s disease. SPLICER enabled precise and highly efficient exon skipping, which reduced the formation of Aβ42 peptides in vitro while inducing DNA editing and exon skipping in vivo within a humanized mouse model of Alzheimer’s disease. Overall, SPLICER is a widely applicable and highly efficient toolbox for exon skipping with broad therapeutic applications.

Project description:Eukaryotic cells express a large number of transcripts from a single gene due to alternative splicing. Despite hundreds of thousands of splice isoforms being annotated in databases, it has been reported that the current exon catalogs remain incomplete. At the same time, introns of human protein-coding genes contain a large number of evolutionarily conserved elements with unknown function. Here, we explore the possibility that some of them represent cryptic exons that are expressed in rare conditions. We identified a group of cryptic exons that are similar to the annotated exons in terms of evolutionary conservation and RNA-seq read coverage in the GTEx dataset. Most of them were poison, i.e. generated an NMD isoform upon inclusion, and many showed signs of tissue-specific and cancer-specific expression and regulation. We performed RNA-seq in A549 cell line treated with cycloheximide to inactivate NMD, and confirmed using qPCR that seven of eight exons tested are, indeed, expressed. This study shows that introns of human protein-coding genes contain cryptic poison exons, which reside in conserved intronic regions and remain not fully annotated due to insufficient representation in RNA-seq libraries.

Project description:RNA splicing and protein degradation systems allow functional adaptation of the proteome in response to changing cellular contexts. However, the regulatory mechanisms connecting these processes remain poorly understood. Here, we show that impaired spliceosome assembly caused by USP39 deficiency leads to a pathogenic splicing profile characterized by the use of cryptic 5′ splice sites. Importantly, disruptive cryptic variants evade mRNA surveillance pathways and are translated into misfolded proteins. These spurious isoforms disrupt proteostasis causing proteotoxic aggregates, ER stress and CHOP-mediated cell death. In response to impaired splicing, eukaryotic cells enhance ubiquitination and ER-phagy to alleviate the pathogenic translation of proteotoxic exons. Our findings show how cryptic splicing-inducedproteotoxicity can be mitigated, and provide insight into the molecular pathogenesis of spliceosome-associated diseases, such as retinitis pigmentosa.

Project description:Alternative splicing generates functional diversity in higher organisms through alternative first and last exons, skipped and included exons, intron retentions and alternative donor and acceptor sites. In large-scale microarray studies in human and mouse, emphasis so far has been placed on exon-skip events, leaving the prevalence and importance of other splice types largely unexplored. Using a new human splice variant database and a genome-wide microarray to probes thousands of splice events of each type, we measured differential expression of splice types across 6 pairs of diverse cell lines and validated the database annotation process. Results suggest that splicing in human is more complex than simple exon skip events, which account for a minority of splicing differences. The relative frequency of differential expression of the splice types correlates with what is found by our annotation efforts. In conclusion, alternative splicing in human cells is considerably more complex than the canonical example of the exon-skip. The complementary approaches of genome-wide annotation of alternative splicing in human and design of genome-wide splicing microarrays to measure differential splicing in biological samples provide a powerful high-throughput tool to study the role of alternative splicing in human biology. Keywords: alternative splicing

Project description:Splicing misregulation, such as the inclusion of previously unknown cryptic exons, is implicated in numerous diseases. Recent methods have increased accurate and efficient detection of such splicing alterations occurring in disease phenotypes. However, the quantification and differential analyses of non-canonical splicing alterations remains focused at a splice event level, thus preventing a complete view of the effects on the downstream transcriptomic landscape. Here, we present a novel and integrated pipeline, SpliCeAT, that (1) detects and quantifies differential non-canonical splicing events from short-read bulk RNA-seq data, (2) augments the canonical transcriptome with novel transcripts containing these non-canonical splicing events, and (3) performs transcript-level differential analysis to identify and quantify aberrant cryptic exon-containing transcripts based on this augmented transcriptome. Using TDP-43, an ALS/FTD-associated RNA-binding protein as an example, we identified and catalogued aberrant splicing events in embryonic mouse brains. The accuracy of our integrated pipeline was further confirmed and validated with long-read isoform sequencing. Furthermore, by comparing neuronal TDP-43 knockouts in mice with a publicly available human dataset with TDP-43 pathology, we identified and validated 4 common genes, namely, Kalrn/KALRN, Poldip3/POLDIP3, Rnf144a/RNF144A, and Unc13a/UNC13A, with cryptic exons. In summary, our integrated pipeline, novel splice events are identified, incorporated and quantified at the transcript level, thereby enabling more complete transcriptome profiling of well-annotated genomes in in the case of pathological splicing misregulation.

Project description:Alternative pre-mRNA splicing increases proteomic diversity and provides a potential mechanism underlying both phenotypic diversity and susceptibility to genetic disorders in human populations. To investigate the variation in splicing among humans on a genomewide scale, we use a comprehensive exon-targeted microarray to examine alternative splicing in lymphoblasts derived from the CEPH HapMap population. We show the identification of transcripts containing annotated and novel sequence verified exon skipping, intron retention, and cryptic splice site usage that are specific between individuals. Using family-based linkage analysis, we demonstrate Mendelian inheritance and segregation of specific splice isoforms with regulatory haplotypes for three genes. Allelic association was further used to identify individual SNPs or regulatory haplotype blocks linked to the alternative splicing event, taking advantage of the high-resolution genotype information from the CEPH HapMap population. Keywords: Comparative genomic hybridiation within a 3 generation pedigree We used 14 individuals from the 3 generation CEPH/UTAH 1444 pedigree for our analysis of looking at heritability of differentially spliced exons within the family. 3 biological growths of individuals NA12739, NA12740, NA12750, and NA12751 were used and a single biological growth for the remaining 10 individuals.

Project description:Recent studies have shown that expression of many genes with exceptionally long introns in the mammalian brain can be perturbed by regulatory factors linked to neurodevelopmental or neurodegenerative disorders1-3, suggesting unique regulatory mechanisms. Here we identify functional recursive splice sites (RSS) in long introns of genes expressed in the brain. These RSS are highly conserved in genes with extreme length across diverse vertebrate species and permit step-wise removal of long introns via recursive splicing. Recursive splicing requires initial definition of a “recursive exon” that is located downstream of RSS, and most often contains premature stop codons. Moreover, we show that RSS create a splicing switch driven by splice site competition in order to distinguish primary mRNA isoforms from alternative isoforms that are prevalent in long genes. The recursive exon is not detectable in the dominant mRNA isoform due to recursive splicing, but is completely included when cryptic promoters or other cryptic exons are used. Thus, by coupling inclusion of recursive exons with the use of cryptic elements, RSS act to distinguish new mRNA isoforms emerging from long genes.

Project description:Altered splicing is a frequent mechanism by which genetic variants cause disease. However, the regulatory architecture of human exons remains poorly understood, making the therapeutic modulation of splicing in disease challenging. Here we show that deep indel mutagenesis (DIM) provides an efficient strategy to chart the regulatory landscape of human exons and to rapidly identify effective splice-modulating oligonucleotides. DIM defines a minimal exon length, uncovers a mechanism for the evolutionary birth of unusually short microexons and the repression of transmembrane domain-encoding exons, and reveals a checkerboard architecture of sequential enhancers and silencers in a model alternatively spliced exon. Accurate prediction of the effects of deletions using deep learning provides a resource, DANGO, that maps the splicing regulatory landscape of all human exons and predicts effective splice-altering antisense oligonucleotides genome-wide.

Project description:Long introns with short exons in vertebrate genes are thought to require spliceosome assembly across exons (exon definition), rather than introns, thereby requiring transcription of an exon to splice an upstream intron. Here, we developed CoLa-seq (co-transcriptional lariat sequencing) to investigate the timing and determinants of co-transcriptional splicing genome wide. Unexpectedly, 90% of all introns, including long introns, can splice before transcription of a downstream exon, indicating that exon definition is not obligatory for most human introns. Still, splicing timing varies dramatically across introns, and various genetic elements determine this variation. Strong U2AF2 binding to the polypyrimidine tract predicts early splicing, explaining exon definition-independent splicing. Together, our findings question the essentiality of exon definition and reveal features beyond intron and exon length that are determinative for splicing timing.