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Alternative splicing

Alternative splicing is a key post-transcriptional regulatory mechanism in eukaryotic cells that allows a single precursor (pre-mRNA) to be processed into multiple distinct mature mRNA isoforms through the selective inclusion or exclusion of exons, or the use of alternative splice sites. This process dramatically expands the proteome's diversity from a limited , with over 95% of multi-exon estimated to undergo alternative splicing, enabling the of hundreds or even thousands of protein variants from one , such as in the Drosophila Dscam that generates up to 38,000 isoforms. By facilitating tissue-specific expression, , and adaptive responses, alternative splicing underpins the complexity of multicellular organisms despite their relatively modest number of approximately 20,000 protein-coding . The discovery of alternative splicing emerged from groundbreaking studies on RNA processing in the 1970s, building on the initial identification of introns in adenoviruses. In 1977, researchers including Susan Berget, Phillip Sharp, and Louise Chow reported the first evidence of alternative splicing in the adenovirus genome, demonstrating that a single pre-mRNA could be spliced in multiple ways to yield distinct mRNA products. This finding was soon extended to cellular genes, such as the immunoglobulin M (IgM) gene in 1980, highlighting its role in immune diversity. In 1978, Walter Gilbert formalized the "introns-early" hypothesis, proposing that genes are composed of exons and introns to allow combinatorial splicing and increase informational capacity beyond the linear DNA sequence. At its core, alternative splicing is executed by the , a dynamic ribonucleoprotein complex assembled from five small nuclear ribonucleoproteins (snRNPs: U1, , U4, U5, and U6) and numerous protein factors, which identifies conserved splice site sequences (typically at the 5' end and at the 3' end of introns) and removes introns through two sequential reactions that form a lariat intermediate. The main types of alternative splicing events include cassette exon inclusion/exclusion (the most common, accounting for about 30% of events), alternative 5' or 3' splice sites, mutually exclusive exons, and intron retention, each contributing to isoform variability. While the majority of splicing follows the U2-type pathway, a minor U12-type pathway handles AT-AC introns, adding further nuance to the process. Regulation of alternative splicing is tightly controlled to ensure specificity and efficiency, involving cis-acting elements—such as exonic splicing enhancers (ESEs) and silencers (ESSs), and their intronic counterparts (ISEs and ISSs)—that modulate splice site recognition. These elements interact with trans-acting factors, including serine/arginine-rich ( that promote splicing and heterogeneous nuclear ribonucleoproteins (hnRNPs) that repress it, whose activities are influenced by cellular signaling, transcription elongation rates, modifications, and secondary structure. For instance, co-transcriptional splicing couples the process to nascent production, allowing real-time adjustments based on promoter usage or marks. Dysfunctions in these regulators, such as mutations in spliceosomal components like SF3B1 or SRSF2, can lead to aberrant splicing patterns. Biologically, alternative splicing is indispensable for , , and , exemplified by its role in diversity, such as alternative splicing of immunoglobulin genes to produce both membrane-bound receptors and secreted antibodies. It also drives neuronal complexity, muscle function, and differentiation, with tissue-specific isoforms enabling functional specialization. However, aberrant alternative splicing is a hallmark of many diseases; for example, it contributes to oncogenesis in over 30 cancer types via upregulated splicing events observed in large cohorts like (TCGA), and to neurodegenerative conditions like (ALS) through mutations in RNA-binding proteins. Recent advances, including high-throughput sequencing and CRISPR-based editing, have illuminated these pathways, paving the way for spliceosome-targeted therapies, such as small-molecule modulators in clinical trials for myelodysplastic syndromes and leukemias.

History and Discovery

Early Observations

In the and early , studies on eukaryotic cells revealed the existence of heterogeneous nuclear RNA (hnRNA), a class of rapidly labeled, short-lived transcripts that were significantly larger and more heterogeneous in size than the mature messenger RNAs (mRNAs) found in the . These observations, made through techniques like pulse-labeling and sedimentation analysis, suggested that hnRNA served as precursors to mRNA but required extensive to remove non-coding sequences, challenging the prevailing view of direct, continuous transcription from to mRNA. Researchers such as James Darnell and Sheldon Penman noted that hnRNA molecules could be up to 10 times larger than their cytoplasmic counterparts, hinting at an unknown mechanism for trimming or rearranging RNA segments. This puzzle intensified with investigations into viral transcripts, particularly from adenoviruses, where discrepancies between genomic DNA and mRNA sequences became evident. In 1977, independent experiments by Phillip A. Sharp's group at the Massachusetts Institute of Technology and Richard J. Roberts's team at Cold Spring Harbor Laboratory used electron microscopy to visualize RNA:DNA hybrids, revealing "loops" of unpaired DNA corresponding to intervening sequences (later termed introns) that were absent from the mature mRNA. Sharp's team, including Susan M. Berget and Claire Moore, mapped spliced segments at the 5' terminus of adenovirus 2 late mRNA, showing that a single mRNA molecule aligned with multiple discontinuous DNA regions. Similarly, Roberts's collaborators, including Louise T. Chow, Thomas R. Broker, and Robert E. Gelinas, produced detailed maps of cytoplasmic adenovirus type 2 transcripts, confirming the split gene structure through R-loop formations observed under the electron microscope. These findings shattered the pre-1977 dogma of colinearity, which posited that genes were continuous DNA segments directly transcribed into uninterrupted mRNA, as established by earlier bacterial studies and the one-gene-one-polypeptide hypothesis. The discovery of split genes in adenovirus demonstrated that eukaryotic genes contained non-coding introns that were excised during RNA processing, ushering in a paradigm shift toward understanding RNA splicing as a fundamental step in gene expression. For their pioneering work, Sharp and Roberts shared the 1993 Nobel Prize in Physiology or Medicine, recognizing the profound implications for eukaryotic genome organization.

Key Milestones and Pioneers

The discovery of introns and RNA splicing in 1977 by Susan Berget, Claire Moore, and Phillip A. Sharp marked a foundational milestone in understanding eukaryotic gene expression, as their work on adenovirus transcripts revealed non-contiguous gene segments joined during mRNA maturation. This breakthrough, shared with Richard Roberts' independent findings, earned Sharp and Roberts the 1993 Nobel Prize in Physiology or Medicine for demonstrating split genes. Concurrently, Joan A. Steitz's identification of small nuclear ribonucleoproteins (snRNPs) in the late 1970s and her 1980 proposal of their role in pre-mRNA splicing laid the groundwork for elucidating the splicing machinery. In the 1980s, the first alternative splicing events were identified in cellular genes, including the immunoglobulin μ heavy chain locus, where alternative polyadenylation and splicing generate membrane-bound and secreted IgM isoforms from a single pre-mRNA. Similarly, alternative splicing in the gene was documented, producing cell-type-specific isoforms through inclusion or exclusion of extra type III domains (EDA and EDB) and the IIICS region, highlighting splicing's role in protein diversity. Parallel efforts characterized components; Walter Keller's group developed the first in vitro splicing system using cell extracts in 1983, enabling mechanistic studies of splice site recognition and catalysis. The 1990s and 2000s saw technological advances that unveiled alternative splicing's prevalence across the genome. (RT-PCR), developed in the late 1980s, facilitated isoform-specific detection and quantification, revealing widespread splicing variation in development and disease. technologies in the mid-2000s enabled genome-wide profiling, estimating that over 90% of human multi-exon genes undergo alternative splicing. Tom Maniatis pioneered studies of regulatory networks, demonstrating in 1992 how splicing enhancers and silencers, bound by and hnRNP factors, control exon inclusion in a combinatorial manner. Post-2010 milestones include long-read sequencing technologies like (PacBio) SMRT and Oxford Nanopore, which capture full-length transcripts to resolve complex isoforms unresolved by short-read methods. For instance, PacBio sequencing in 2015 identified thousands of novel isoforms in cell lines by spanning entire genes without assembly artifacts. In the 2020s, integration with single-cell sequencing has produced splicing atlases, such as long-read single-nucleus analyses of tissues, mapping cell-type-specific isoform usage and dynamic splicing changes across states like development and stress; for example, the 2025 development of SCSES for deciphering splicing heterogeneity at single-cell resolution.

Fundamentals of RNA Splicing

Core Splicing Machinery

The core splicing machinery consists of the spliceosome, a large ribonucleoprotein complex that catalyzes the removal of introns from pre-mRNA in eukaryotic cells through two transesterification reactions. This machinery is composed primarily of five small nuclear ribonucleoproteins (snRNPs)—U1, U2, U4, U5, and U6—each containing a uridine-rich small nuclear RNA (snRNA) associated with Sm core proteins (B/B', D1, D2, D3, E, F, G) and additional specific proteins, along with numerous non-snRNP factors such as U2AF, SF1/mBBP, and DEAH-box helicases like Prp2, Prp16, and Prp22. These components enable the precise recognition of splice sites and the execution of splicing chemistry, which is essential for constitutive intron excision and serves as the foundation for alternative splicing variations. Spliceosome assembly occurs in a stepwise, ATP-dependent manner on the pre-mRNA, forming distinct intermediates: the commitment (E) complex, prespliceosome (A) complex, pre-catalytic (B) complex, activated (B*) complex, and postspliceosomal (C) complex. In the E complex, U1 snRNP binds the 5' splice site via base-pairing between U1 snRNA and the consensus sequence MAG|GURAGU (where M = A/C, R = A/G, and | denotes the exon-intron boundary), while SF1/mBBP and U2AF65/35 associate with the branch point sequence (BPS) YNYURAC and the polypyrimidine tract upstream of the 3' splice site, respectively. The transition to the A complex involves ATP-dependent activity of Prp28, which displaces U1 and allows U2 snRNP to bind the BPS through base-pairing with U2 snRNA, positioning the bulged branch point adenosine for nucleophilic attack. Recruitment of the U4/U6·U5 tri-snRNP, facilitated by Prp5 and Prp28 , forms the B complex, which contains over 100 proteins and prepares the for activation. The splicing reaction proceeds in two catalytic steps within the activated spliceosome. First, the 2'-OH of the branch point adenosine attacks the 5' splice site, cleaving the 5' exon and forming a lariat intron-3' exon intermediate; this adheres to the near-invariant GU-AG rule, where introns typically begin with GU (GT in DNA) at the 5' end and end with AG at the 3' end. The second step involves the 3'-OH of the freed 5' exon attacking the 3' splice site (consensus YAG|G), ligating the exons and releasing the lariat intron. These transesterifications are powered by conformational rearrangements driven by ATP-dependent DEAH-box helicases, such as Prp2 for B to B* activation, Prp16 for the first step completion, and Prp22 for the second step and disassembly. Catalysis occurs in a magnesium-dependent active site coordinated by U6 snRNA and Prp8 protein, where two Mg²⁺ ions stabilize the transition states by neutralizing negative charges on the RNA backbone during phosphoryl transfer. Alternative splice site usage represents a deviation from this core process by competing recognition elements.

Recognition of Splice Sites

The recognition of splice sites in pre-mRNA is a critical initial step in , relying on specific sequence motifs at the 5' and 3' boundaries of introns, as well as auxiliary elements that modulate accuracy. The 5' splice site (5' SS) is typically defined by a that spans the exon-intron junction, often represented as MAG|GURAGU in mammals, where the intronic dinucleotide is nearly and essential for recognition. This is preceded by an exonic (commonly A or G) and followed by additional intronic residues that contribute to specificity. The 3' splice site (3' SS), located at the intron-exon boundary, features a conserved AG dinucleotide immediately upstream of the , preceded by a polypyrimidine tract (Py tract) consisting of multiple U and C residues, which enhances binding affinity. These motifs are degenerate, allowing variability while maintaining core functionality, and their identification initiates recruitment of splicing factors. Central to 3' SS recognition is the branch point sequence (BPS), a conserved located 18-40 upstream of the 3' SS in mammalian introns, with the consensus YNYURAC (Y = , R = , N = any ), where the bulged serves as the in the first step. The BPS is bound specifically by splicing factor 1 (SF1, also known as mammalian branch point binding protein or mBBP), which recognizes the single-stranded RNA via its domain and protects approximately seven centered on the . SF1/mBBP binding is cooperative with U2AF65, a subunit of the U2 auxiliary factor that interacts with the adjacent Py tract, increasing affinity up to 20-fold and stabilizing the E complex during early assembly. Additionally, exonic and intronic splicing enhancers (ESEs/ISEs) and silencers (ESSs/ISSs) provide contextual modulation, promoting or inhibiting splice site usage through interactions with regulatory proteins, though their effects are secondary to core recognition. At the 5' SS, initial molecular recognition occurs via base-pairing between the pre-mRNA and the 5' end of U1 (snRNA) within the U1 , forming an duplex that spans up to 11 across the junction, with the GU pairing to positions 3-5 of U1 snRNA for stability. This interaction is dynamic and can accommodate atypical sites through shifted registers, ensuring broad yet specific targeting. The 3' SS elements, including the BPS and Py tract, are similarly scanned by U2 snRNP components post-U1 binding, bridging the two sites. These recognition events precede full spliceosome assembly. Splice site consensus sequences exhibit evolutionary across eukaryotes, though with varying degeneracy; the GU-AG rule is nearly for U2-type introns, while BPS motifs show greater divergence in non-vertebrates, such as CURAY in versus YNYURAC in metazoans. Comparative analyses across 30 eukaryotic species reveal shared two-site statistical patterns in 5' SS, indicating ancient origins, but with clade-specific adaptations that influence splicing fidelity. This underscores the fundamental role of these motifs in eukaryotic .

Types of Alternative Splicing

Exon Skipping

Exon skipping, also known as cassette exon exclusion, is a fundamental mode of alternative splicing wherein one or more internal s are omitted from the (mRNA), resulting in the direct ligation of the upstream and downstream exons by the . This process generates protein isoforms that lack the encoded sequences, often leading to truncated or structurally altered proteins without the intervening exon content. In contrast to constitutive splicing, where all exons are included, exon skipping allows for the production of diverse mRNA variants from a single pre-mRNA transcript, enhancing proteomic complexity in eukaryotic cells. The mechanistic basis of exon skipping involves the spliceosome's failure to assemble across the boundaries of the target , typically due to suboptimal recognition of its 5' or 3' splice sites, which are weaker than consensus sequences and thus less efficiently bound by core splicing factors like U1 and small nuclear ribonucleoproteins (snRNPs). This inefficiency promotes the spliceosome to bridge the splice sites of the adjacent exons, effectively bypassing the intervening sequence. Additionally, cis-acting regulatory elements, such as exonic or intronic splicing silencers ( or ISS), can recruit repressive trans-acting factors like heterogeneous ribonucleoproteins (hnRNPs) to further inhibit exon inclusion by blocking enhancer-mediated activation or directly interfering with splice site accessibility.01384-6) Exon skipping represents the predominant form of alternative splicing in humans, comprising approximately 40% of all documented alternative splicing events across multi-exon genes, far outpacing other modes like alternative splice site usage or intron retention. This prevalence underscores its role as a primary for generating isoform diversity, with high-throughput sequencing studies revealing tens of thousands of such events in the human transcriptome, many of which are tissue-specific or developmentally regulated. The abundance of exon skipping is particularly pronounced in vertebrates, where it facilitates adaptive responses to physiological demands without requiring genomic duplication. Functionally, often results in the deletion of specific protein or motifs, yielding shorter isoforms that exhibit modified localization, stability, interactions, or enzymatic activities compared to their full-length counterparts. For instance, the exclusion of an encoding a regulatory can shift a protein's conformational state or abolish binding to partners, thereby altering downstream signaling or structural roles within cellular complexes. Such outcomes enable fine-tuned protein functions tailored to distinct contexts, though they may also introduce frameshifts leading to premature termination codons and potential if not balanced by inclusion variants. Overall, these isoform variations contribute to cellular plasticity and functional specialization across tissues.00643-9.pdf)

Alternative Splice Site Usage

Alternative splice site usage refers to the process where multiple potential 5' donor or 3' acceptor sites within or near an are recognized during pre-mRNA splicing, leading to the production of transcript isoforms with varying exon boundary definitions. This type of alternative splicing includes alternative 5' splice sites, where different donor sites upstream of an are selected, and alternative 3' splice sites, where varying acceptor sites downstream are chosen; cassette exons can emerge as a variant when site selection effectively includes or excludes partial segments. These events allow for fine-tuned regulation of isoform diversity without altering entire s. The mechanism underlying alternative splice site usage primarily involves competition among proximal splice sites for recognition by the , with selection influenced by the intrinsic strength of each site. Site strength is determined by the degree of base-pairing complementarity between the splice site sequence and the U1 snRNA for 5' donors or U2 snRNA for 3' acceptors, where stronger matches promote higher and preferential usage. For instance, a 5' splice site with extended complementarity to U1 snRNA's 5' end enhances early assembly, outcompeting weaker nearby sites and directing isoform production. Regulatory factors can further modulate this competition by altering site accessibility or snRNP efficiency. In humans, alternative 5' and 3' splice site usage each accounts for approximately 25% of all alternative splicing events, making this a prevalent mode that contributes significantly to complexity across multi-exon . These events often result in isoforms with altered coding sequences, such as insertions or deletions of a few , or variable untranslated regions (UTRs) that impact mRNA stability, localization, or efficiency. For example, alternative 3' in the calcitonin generates isoforms with distinct C-terminal extensions affecting protein . Many isoforms arising from alternative splice site usage introduce premature termination codons (PTCs), particularly when out-of-frame shifts occur, rendering them substrates for (NMD) to prevent accumulation of truncated proteins. Up to one-third of human alternative splicing events, including those from site usage, couple to NMD, thereby regulating steady-state mRNA levels and providing a quality-control . This AS-NMD linkage is widespread, with evidence from genomic analyses showing that a substantial portion of alternative site-selected transcripts are degraded post-transcriptionally.

Intron Retention and Mutually Exclusive Exons

Intron retention is a form of alternative splicing in which one or more are not removed from the pre-mRNA and remain in the mature mRNA transcript. This retention often introduces premature stop codons that trigger (NMD), thereby reducing the levels of the corresponding protein, or it can result in the production of novel protein isoforms if the retained intron does not disrupt the or evade NMD. Intron retention is particularly prevalent in , where it constitutes the most common alternative splicing event, accounting for 28% to 64% of such events depending on growth conditions and species. In mammals, it is less dominant but widespread, affecting transcripts from over 80% of coding genes across tissues and representing approximately 15% of alternative splicing events in certain contexts like neurodevelopment or . It frequently emerges as a regulatory response to environmental stresses in both and mammals, modulating by delaying or fine-tuning protein production. Mutually exclusive exons represent another specialized mode of alternative splicing, where only one exon from a pair (or cluster) of adjacent, cassette-like exons is included in the mature mRNA, while the other is excluded, effectively swapping structurally similar protein domains. This pattern arises from evolutionary exon duplication events and ensures strict reciprocity in exon choice through mechanisms such as steric hindrance due to minimal spacing between splice sites (often around 50 ), which prevents the from simultaneously accommodating both exons. Additional enforcement occurs via incompatible splice site pairings or regulatory factors that block one pathway, as exemplified in the human alpha-tropomyosin gene, where exons 2 and 3 are mutually exclusive due to an unusually positioned lariat only 42 nucleotides from the donor site of exon 2, inhibiting direct splicing between the two exons and favoring exon 3 inclusion in most types. This mechanism implies a role in constitutive splicing constraints, where proximity to the , rather than the acceptor site, dictates exclusion. Together, intron retention and mutually exclusive exons contribute to roughly 15-20% of alternative splicing events in mammals, with intron retention being more abundant (around 10-15%) and mutually exclusive exons rarer (less than 5%, often in pairs comprising 80% of cases). In functional terms, retention notably enhances diversity in immune-related genes, such as during , where it orchestrates the coordinated downregulation of 86 genes—including those involved in nuclear morphology like Lmnb1—through NMD-sensitive transcripts, thereby promoting cell-type-specific adjustments and functional specialization. This process is conserved across humans and mice, highlighting its regulatory precision in immune development.

Regulatory Mechanisms

Cis-Acting Regulatory Elements

Cis-acting regulatory elements are sequence motifs within pre-mRNA that modulate splice site selection during alternative splicing, functioning as intrinsic signals independent of diffusible factors. These elements include enhancers that promote exon inclusion and silencers that repress it, often located in exons or introns near splice sites. Their activity influences the balance between competing splice sites, contributing to isoform diversity. Exonic splicing enhancers (ESEs) are purine-rich motifs, typically 6–8 long, embedded within exons that facilitate recognition of adjacent weak splice sites. These sequences, such as those responsive to , stabilize interactions at the exon-intron boundaries. Intronic splicing enhancers (ISEs), found within introns, similarly boost splicing efficiency by aiding recruitment to nearby sites. For instance, ISEs in the calcitonin/CGRP pre-mRNA promote inclusion through cooperative effects with exonic elements. In contrast, exonic splicing silencers (ESSs) and intronic splicing silencers (ISSs) inhibit splicing by masking splice sites or competing with enhancers. , often bound by heterogeneous nuclear ribonucleoproteins (hnRNPs), suppress exon definition, as seen in the where an ESS promotes skipping of exon 6, producing a soluble isoform that inhibits by acting as a receptor. ISSs within introns can loop out exons, reducing their inclusion, such as in the of the variable exons. Mechanistically, enhancers like ESEs promote splicing by facilitating the recruitment of U2AF to the 3' splice site, enhancing polypyrimidine tract recognition. Silencers, conversely, may inhibit U1 binding to the 5' splice site, blocking early assembly. These effects can be modulated by RNA secondary structures, where stable stem-loops as short as 7 base pairs sequester enhancers, abolishing their activity, or expose silencers, as observed in the EDA exon. Identification of these elements relies on computational tools that scan sequences for conserved motifs. ESEfinder, for example, uses position weight matrices derived from selection experiments to predict ESEs responsive to specific , scoring potential sites above thresholds (e.g., 1.956 for SF2/ASF) and highlighting mutation impacts. Similar algorithms extend to ISEs, ISSs, and ESSs, aiding in the annotation of splicing regulatory landscapes.

Trans-Acting Splicing Factors

Trans-acting splicing factors are soluble proteins and protein complexes that bind to cis-acting RNA elements on pre-mRNA to modulate splice site selection and promote or repress specific alternative splicing events. These factors include activator families like and repressor families like heterogeneous nuclear ribonucleoproteins (hnRNPs), as well as spliceosome-associated components such as U2 auxiliary factor (U2AF) and the SF3b complex. By interacting with regulatory sequences, they influence the recruitment and assembly of the , thereby determining exon inclusion, skipping, or other splicing patterns. SR proteins function as key activators of splicing, binding primarily to exonic splicing enhancers (ESEs) through their RNA recognition motifs (RRMs) and recruiting spliceosomal components via their serine/arginine-rich (RS) domains. They promote exon inclusion by bridging U1 snRNP to the 5' splice site and U2AF to the 3' splice site, thereby enhancing spliceosome assembly on weak or regulated splice sites. Representative members include SRSF1, SRSF2, and SRSF6, whose combinatorial actions fine-tune alternative splicing outcomes. Heterogeneous nuclear ribonucleoproteins (hnRNPs) typically act as repressors, binding to intronic splicing silencers (ISSs) or exonic splicing silencers (ESSs) to inhibit splice site recognition and inclusion. For example, PTB (a member of the hnRNP family) forms multimers that loop out exons or block U2AF binding, competing directly with for access to overlapping motifs. Other hnRNPs, such as hnRNPA1, can also promote splicing when bound to intronic enhancers, highlighting their context-dependent roles in alternative splicing . Spliceosome-associated trans-acting factors like U2AF and SF3b play essential roles in early splice site recognition. The U2AF heterodimer, comprising U2AF65 and U2AF35, facilitates 3' splice site selection: U2AF65 binds the polypyrimidine tract upstream of the AG dinucleotide, while U2AF35 interacts with the AG itself, cooperatively recruiting U2 snRNP to commit the site for splicing. The SF3b complex, integrated into the U2 snRNP, recognizes and stabilizes the sequence through interactions involving SF3b1, SF3b6, and SF3b7 subunits, enabling proper spliceosome activation and influencing alternative 3' splice site choices. The activities of trans-acting splicing factors are tightly regulated by cellular dynamics, including their concentration, post-translational modifications, and expression profiles. Variations in factor concentration, such as higher levels of favoring inclusion, can shift splicing equilibria towards specific isoforms. , particularly of SRSF1 by kinases like SRPK1 and CLK1, modulates its RNA-binding affinity, subcellular localization, and interactions during progression, thereby linking splicing to temporal cellular states. Tissue-specific expression of factors like hnRNPs and further contributes to the generation of diverse splicing programs across cell types.

Illustrative Examples

Invertebrate Development: Drosophila dsx and tra

In Drosophila melanogaster, sex determination is governed by a cascade of genes where alternative splicing plays a central role in producing sex-specific proteins that direct somatic sexual differentiation. The master regulator, Sex-lethal (Sxl), is expressed in both sexes but undergoes female-specific alternative splicing to produce a functional protein only in females, where the X chromosome-to-autosome ratio is 1.0. This female Sxl protein maintains its own expression through positive autoregulation by blocking the use of a male-specific exon in its pre-mRNA, ensuring persistent female-specific splicing and preventing reversion to the male state. Downstream of Sxl, the (tra) gene exemplifies alternative 3' splice site selection regulated by Sxl. In s, Sxl protein binds to uridine-rich sequences near the non-sex-specific (male) 3' splice site in the tra pre-mRNA, repressing its use and promoting the distal female-specific 3' splice site. This results in an mRNA that lacks a premature , producing a functional Tra protein essential for development. In males, lacking functional Sxl, the default proximal splice site is used, incorporating a stop codon that yields a non-functional, truncated Tra protein. The (dsx) gene, further downstream, illustrates female-specific inclusion orchestrated by Tra in conjunction with Transformer-2 (Tra2). In females, Tra and Tra2 form a complex that enhances recognition of a weak female-specific 3' splice site upstream of 4, leading to its inclusion after 1-3 and subsequent splicing to 6, producing a functional Dsx^F protein that represses male traits and promotes female in tissues. In males, without functional Tra, the splicing skips 4 and includes the male-specific 5, followed by the common 6, yielding the male-specific Dsx^M protein, which represses female traits and activates male-specific . These opposing Dsx isoforms thus coordinate in structures like the genitalia and behaviors. This splicing-based sex determination cascade in exhibits evolutionary conservation in its downstream effectors, particularly the DM domain-containing transcription factors like Dsx, which have orthologs such as MAB-3 in that similarly implement sex-specific gene regulation despite differences in upstream signals.

Vertebrate Apoptosis: Fas Receptor

The , encoded by the gene, undergoes alternative splicing that plays a critical role in regulating in vertebrates, particularly within the . In the Fas pre-mRNA, the or exclusion of 6 determines the functional isoform produced. During T-cell , the polypyrimidine tract-binding protein (PTB) represses the of 6 by to an upstream regulatory (URE6), an exonic splicing silencer, thereby promoting . This PTB-mediated repression is prominent in activated T-s, where it shifts splicing toward the exclusion of 6 to modulate apoptotic responses. Two primary isoforms arise from this splicing event: the membrane-bound , which includes 6 and encodes a that triggers upon ligand binding, and the soluble Fas isoform, generated by skipping 6, which lacks this and circulates extracellularly. The soluble form exerts an anti-apoptotic effect by acting as a decoy receptor, sequestering and inhibiting the pro-apoptotic signaling of the membrane-bound isoform. This isoform switch allows immune cells to fine-tune , preventing excessive cell death during immune responses. The mechanism underlying exon 6 regulation follows the exon definition model, where the weak 3' splice site of 6 necessitates coordinated recognition across the for efficient inclusion. PTB to URE6 disrupts U2AF recruitment to this weak 3' site, impairing snRNP association and favoring skipping, while antagonistic factors like TIA-1 can promote inclusion by enhancing snRNP at the 5' splice site. Dysregulation of this splicing event has implications for autoimmune diseases, such as systemic lupus erythematosus (SLE), where splicing is skewed toward the soluble isoform, leading to elevated soluble levels that impair of autoreactive lymphocytes. In SLE patients, the soluble-to-membrane mRNA ratio is significantly higher than in healthy individuals, correlating with disease activity and contributing to immune dysregulation.

Viral Gene Regulation: HIV-1 tat

In human immunodeficiency virus type 1 (HIV-1), alternative splicing is essential for due to the virus's compact 9.2 kb , which encodes approximately 15 proteins through the production of over 30 distinct mRNA isoforms from a single primary transcript driven by one promoter. This strategy maximizes coding capacity by utilizing four 5' splice donors and eight 3' splice acceptors, enabling the virus to generate regulatory proteins like Tat and from overlapping genomic regions. The of splicing at the tat locus exemplifies how the virus exploits host splicing machinery to balance protein production across its lifecycle. The Tat protein, critical for viral transcription elongation, exists in two main isoforms differing by the inclusion of a second . The multi-exon (two-exon) isoform incorporates a 86-nucleotide 2 (from splice donor D4 to acceptor A7), encoding the full 101-amino-acid protein with the C-terminal domain necessary for optimal activity via TAR RNA and of cellular factors like CDK9. In contrast, the single-exon isoform (using D1 to A3) produces a truncated Tat72 lacking this domain, resulting in reduced efficiency and limited support. This alternative splicing pattern overlaps with Rev production, where Rev mRNA utilizes D4 to A6 for its second , sharing sequence elements but diverging at the acceptor site choice, thus competitively allocating transcripts between full-length Tat and Rev. Splicing of tat exon 2 is tightly regulated by competitive interactions between cis-acting elements and factors within the host splicing machinery. An exonic splicing silencer () in tat exon 2 binds heterogeneous nuclear ribonucleoprotein (hnRNP A1), which represses splice site recognition by blocking U2 snRNP association and inhibiting upstream donor usage, thereby reducing exon 2 inclusion. Counteracting this, an exonic splicing enhancer (ESE) in the same exon recruits serine/arginine-rich () proteins such as ASF/SF2 (also known as SRSF1), which promote exon definition by stabilizing U2AF65 binding to the 3' splice site and facilitating U2 snRNP recruitment. This repressor-activator competition fine-tunes splicing efficiency, with hnRNP A1 dominance favoring Rev transcripts over multi-exon Tat, while ASF/SF2 shifts the balance toward Tat production. Additionally, an intron splicing silencer (ISS) upstream of A7 further enhances hnRNP A1-mediated inhibition by overlapping the , additively suppressing splicing when combined with the ESS. This regulatory balance integrates with nuclear export pathways and the viral lifecycle. Early in infection, when Rev levels are low, multi-exon Tat and Rev mRNAs—being fully spliced—are exported via the cellular NXF1/ pathway to produce initial regulatory proteins. As Rev accumulates, it binds the Rev-responsive element (RRE) on unspliced and partially spliced transcripts, redirecting export through CRM1 to enable structural protein production (, , ). Splicing efficiency at tat 2 thus modulates the Tat/Rev ratio, ensuring early for genome expression while transitioning to late-phase replication; disruptions in this equilibrium, such as ESS mutations, impair viral propagation. Such dependence on host factors highlights HIV-1's adaptation of alternative splicing for temporal control in a constrained .

Evolutionary and Functional Roles

Adaptive Benefits

Alternative splicing significantly expands the functional diversity of the from a limited number of genes, allowing organisms to generate multiple protein isoforms without requiring . The encodes approximately 20,000 protein-coding genes, yet alternative splicing produces over distinct transcripts, with up to 95% of multi-exon genes undergoing this process to yield diverse isoforms that perform specialized roles. This mechanism enhances proteomic complexity, enabling fine-tuned cellular responses that contribute to organismal adaptability. Tissue-specific alternative splicing further exemplifies these adaptive advantages by producing isoforms tailored to the physiological demands of distinct types, thereby optimizing without altering the underlying . For instance, in neurons and muscle cells, voltage-gated calcium channels exhibit variants that differ in their biophysical properties, such as activation thresholds and inactivation kinetics, which are crucial for precise in excitable tissues. These variants, including those in the CACNA1C gene encoding Cav1.2 channels, promote efficient calcium handling in for contraction while supporting synaptic transmission in neurons. Alternative splicing also facilitates rapid adaptation to environmental stresses, shifting isoform ratios to enhance survival under adverse conditions like or heat shock. In hypoxic environments, such as those encountered in tumors or high-altitude settings, splicing changes in genes like those involved in and produce pro-survival isoforms that mitigate oxygen deprivation effects. Similarly, during heat shock, alternative splicing adjusts transcripts of stress-response factors, such as heat shock proteins, to stabilize cellular and prevent , thereby improving thermal tolerance and viability. These dynamic shifts allow cells to rewire their proteome swiftly in response to transient stressors. Quantitative models of splicing treat isoform ratios as tunable parameters that directly influence landscapes, where optimal splicing efficiencies balance functional against the costs of erroneous splicing. In evolutionary terms, these ratios are shaped by selection pressures to maximize adaptive outcomes, with deviations from optimal proportions incurring penalties through reduced protein functionality or wasteful . Such models underscore how alternative splicing acts as a regulatory dial, expression to environmental cues while maintaining evolutionary of core splicing machinery across species.

Evolutionary Conservation and Diversity

Alternative splicing is absent in prokaryotes, which lack and the spliceosomal machinery necessary for intron removal, but it emerged as an ancient feature in the last eukaryotic common ancestor (LECA), where spliceosomal first appeared and enabled basic splicing processes. This origin is tied to the evolution of the , a complex of snRNPs and proteins that recognizes conserved splice sites, with early splicing errors likely contributing to the initial diversification of transcripts in unicellular eukaryotes. In metazoans, alternative splicing expanded dramatically, coinciding with increased intron density and multicellularity, allowing for greater regulatory complexity and diversity beyond what alone could provide. Core splice site sequences, such as the GU-AG dinucleotides at exon-intron boundaries and motifs, are universally conserved across eukaryotes, reflecting their essential role in accurate splicing and the deep evolutionary roots of the . Alternative splicing events themselves show substantial , particularly among vertebrates; for instance, studies comparing and transcriptomes indicate that a majority—approximately 60%—of cassette events and other alternative isoforms are preserved between these species, underscoring the functional importance of many AS patterns. This is higher for tissue-specific events in complex organs like the , where selective pressures maintain isoform diversity for specialized functions. The diversity of alternative splicing varies markedly across eukaryotic lineages, with unicellular organisms like yeast (Saccharomyces cerevisiae) exhibiting low complexity, where only about 5% of genes produce alternatively spliced transcripts, primarily through rare retention or site usage. In contrast, mammals display high AS prevalence, with over 90% of multi-exon genes undergoing alternative splicing, generating multiple isoforms per gene and contributing to phenotypic complexity in tissues such as the and . This gradient reflects evolutionary expansions in intron number and spliceosomal components, with metazoans like arthropods and showing intermediate levels. Evolutionary drivers of alternative splicing include intronic mutations that create novel splice sites, such as point changes introducing cryptic GU or AG sequences, which can activate new exons or shift inclusion levels without disrupting core coding frames. These cis-regulatory mutations often arise neutrally and become fixed if they confer adaptive isoform variants, as seen in the emergence of tissue-specific splicing patterns. Exon shuffling, facilitated by recombination events at intron borders or insertions, further promotes diversity by rearranging modular exons, enabling the assembly of novel protein domains in multidomain genes during metazoan evolution. Such mechanisms have been pivotal in expanding functional repertoires, particularly in and signaling proteins.

Implications in Disease

Oncogenic Splicing Aberrations

Alternative splicing aberrations play a pivotal role in oncogenesis by generating isoforms that promote tumor , , , and to . These dysregulation events often arise from genetic mutations, altered expression of splicing factors, or disruptions in cis-regulatory elements, leading to the production of oncogenic protein variants. In a large proportion of cancers, such aberrations contribute to key hallmarks of , including evasion of and enhanced metastatic potential. Mutations in core components of the , particularly the U2-type SF3B1, are among the most frequent splicing-related alterations in cancer, occurring in up to 20% of myelodysplastic syndromes (MDS) and (AML) cases. These hotspot mutations, often at lysine 700 (K700E), impair recognition during spliceosome assembly, resulting in widespread aberrant splicing of target genes involved in DNA damage response, epigenetic regulation, and . For instance, SF3B1 mutations lead to inclusion of cryptic exons in genes like MAP3K7, promoting leukemic transformation through altered signaling pathways. Overexpression of trans-acting splicing factors, such as (also known as ASF/SF2), is a common mechanism in solid tumors, exemplified by its upregulation in breast cancers, where it drives oncogenic splicing programs. SRSF1 overexpression shifts splicing toward pro-tumorigenic isoforms, including those enhancing cell migration and survival, by binding to exonic splicing enhancers and promoting exon inclusion in targets like BIN1 and S6K1. Similarly, core splice site mutations, such as those creating or disrupting 5' or 3' splice sites, directly alter isoform ratios in proto-oncogenes; for example, mutations in the gene's splice sites generate dominant-negative isoforms that impair tumor suppression. A prominent example of oncogenic splicing is the skipping of exon 11 in the receptor (MST1R), yielding the ΔRON isoform that confers invasive and metastatic properties to epithelial cells. This skipping event, upregulated in colorectal, , and tumors due to enhanced activity of silencers like hnRNP A1 or SF2/ASF, activates downstream pathways such as Rac1/PAK1, promoting epithelial-mesenchymal transition without stimulation. Another critical case involves the BCL2L1 gene, where alternative splicing favors the anti-apoptotic isoform over the pro-apoptotic Bcl-xS in over 60% of analyzed tumors, inhibiting mitochondrial outer membrane permeabilization and conferring resistance to . These aberrations are therapeutically targetable, as demonstrated by spliceostatin A, a natural compound that binds SF3B1 and inhibits function, selectively killing SF3B1-mutant MDS cells by inducing aberrant splicing of survival genes like and MCL1. H3B-8800 was investigated in clinical trials for splicing factor-mutant myeloid malignancies but development was discontinued in 2024 due to lack of efficacy. As of 2025, research continues into novel spliceosome-targeted therapies to exploit cancer-specific vulnerabilities.

Neurological and Other Disorders

Alternative splicing plays a critical role in function, with over 90% of multi-exon genes undergoing alternative splicing events that contribute to neuronal diversity and . Dysregulation of these processes is implicated in various neurological disorders, often through mechanisms such as sequestration of splicing factors by toxic RNA expansions or loss of nuclear function in RNA-binding proteins, leading to aberrant exon inclusion or skipping. In spinal muscular atrophy (SMA), a neurodegenerative disease characterized by motor neuron loss, the survival motor neuron 2 (SMN2) gene undergoes inefficient splicing of exon 7 due to a weak 3' splice site created by a C-to-T mutation, resulting in frequent exon skipping and production of truncated, unstable SMN protein. This skipping reduces functional SMN protein levels, essential for snRNP biogenesis and splicing fidelity, exacerbating motor neuron degeneration. Therapeutic intervention with nusinersen, an antisense oligonucleotide, targets an intronic splicing silencer in SMN2 intron 7, blocking the binding of repressive factors like hnRNP A1/A2 and promoting exon 7 inclusion to restore SMN protein production. Clinical trials have demonstrated that nusinersen increases full-length SMN2 transcripts and improves motor function in SMA patients. Amyotrophic lateral sclerosis (ALS), a , frequently involves misregulation of (TDP-43), which normally represses cryptic exons in target transcripts. In ALS, cytoplasmic mislocalization and depletion of nuclear TDP-43 lead to derepression and inclusion of a cryptic exon in stathmin-2 (STMN2) pre-mRNA, generating non-functional transcripts that reduce STMN2 protein levels critical for axonal stability and regeneration. This cryptic exon inclusion is observed in ALS patient brains and spinal cords, correlating with TDP-43 pathology and contributing to neurodegeneration. Similar TDP-43-dependent cryptic splicing events occur in other ALS/FTD-related genes, highlighting a broader mechanism of splicing disruption. Myotonic dystrophy type 1 (DM1), a multisystem disorder affecting muscle and brain, arises from CTG trinucleotide expansions in the DMPK 3' UTR, producing toxic CUG-repeat that sequesters muscleblind-like (MBNL) splicing factors into nuclear foci. MBNL sequestration disrupts its regulatory role in alternative splicing, leading to aberrant inclusion or exclusion of exons in targets like CLCN1 (causing ) and fetal-like splicing patterns in neuronal genes, contributing to cognitive deficits. This toxic mechanism parallels factor sequestration in other disorders but manifests in widespread splicing misregulation across muscle and brain tissues. Alternative splicing aberrations in synaptic genes are also linked to autism spectrum disorders (ASD), where dysregulation affects neuronal connectivity and synaptic transmission. Genes such as neurexin-1 (NRXN1), neuroligin-3 (NLGN3), and SHANK3 exhibit altered splicing patterns in brains, with specific isoforms influencing trans-synaptic adhesion and excitatory/inhibitory balance. For instance, mutations affecting splicing in NLGN4X disrupt synaptic function, and RNA-binding proteins like RBFOX1, often mutated in , regulate splicing of hundreds of synaptic targets, with their loss leading to network-wide dysregulation. These changes underscore how splicing defects in converge on synaptic organization, distinct from oncogenic splicing but sharing therapeutic potential in splice-modulating approaches.

Analysis and Computational Approaches

Transcriptome-Wide Profiling

Transcriptome-wide profiling of alternative splicing (AS) has revolutionized the study of isoform diversity by enabling the detection and quantification of splicing events across thousands of genes simultaneously. High-throughput RNA sequencing (RNA-seq) techniques, particularly short-read RNA-seq, serve as the cornerstone for identifying AS events through the mapping of junction-spanning reads that skip exons or include alternative junctions. This approach allows for the genome-wide annotation of splicing patterns, revealing tissue-specific and condition-dependent regulation, as demonstrated in early deep-sequencing studies of human transcriptomes. A key metric in short-read RNA-seq profiling is the percent spliced in (PSI or Ψ), which quantifies the inclusion level of a specific exon or cassette in the mature mRNA population by comparing the density of inclusion versus exclusion junction reads. PSI values range from 0 (complete exclusion) to 1 (complete inclusion) and provide a robust measure for comparing splicing efficiency across samples. For differential AS analysis, tools like replicate multivariate analysis of transcript splicing (rMATS) employ statistical models to identify significant changes in PSI between conditions, accounting for biological replicates and multiple testing, thereby facilitating the discovery of regulated events in large-scale datasets. Long-read sequencing technologies, such as (PacBio) and (ONT), complement short-read methods by enabling full-length isoform assembly without fragmentation, which is particularly advantageous for resolving complex splicing patterns involving multiple variable exons or overlapping transcripts that confound short-read . These platforms capture entire transcripts in single reads, allowing reconstruction of isoforms and precise quantification of low-abundance variants that are often missed in short-read data. Recent advances extend transcriptome-wide profiling to finer resolutions, including single-cell (scRNA-seq), which uncovers cell-type-specific AS heterogeneity by analyzing splicing in individual cells, revealing dynamic isoform usage that underlies cellular identity and responses. Time-series further elucidates temporal dynamics of AS, such as during or , by modeling isoform abundance changes over multiple time points to detect coordinated splicing shifts. These approaches can inform downstream predictive modeling for AS regulation. However, challenges persist, including alignment biases from repetitive genomic regions or multi-mapping reads, which can skew junction detection, and the under-detection of low-expression isoforms due to insufficient read depth or stochastic noise in sparse data.

Predictive Modeling and Tools

Predictive modeling of alternative splicing relies on computational algorithms that analyze genomic sequences to forecast splice site usage, exon inclusion, and isoform production. Early approaches employed techniques, such as support vector machines (SVMs), to identify splicing regulatory motifs like exonic splicing enhancers (ESEs) and silencers (ESSs) by training on sequence features that promote or inhibit recognition. These methods extract motifs from pre-mRNA contexts and classify potential regulatory elements with accuracies approaching 90% in motif detection tasks. Thermodynamic models complement sequence-based predictions by simulating RNA secondary structure folding, which influences splice site accessibility and alternative isoform formation. These models compute free energy minima for RNA conformations, integrating base-pairing probabilities to predict how structural motifs near splice junctions affect splicing efficiency. For instance, thermodynamic frameworks have been applied to donor splice site recognition, achieving high specificity in identifying functional sites across eukaryotic genes. Such approaches unify evolutionary conservation with folding to refine predictions of splice site strength. A seminal tool for splice site strength prediction is MaxEntScan, which uses maximum entropy modeling to score consensus sequences at 5' and 3' splice sites based on positional frequencies and dinucleotide dependencies. Developed in 2004, it quantifies the likelihood of site usage, with scores typically ranging from 0 to 12 for strong sites, and has become a standard for evaluating variant impacts on splicing. MaxEntScan is integrated into plugins for the Ensembl Variant Effect Predictor (VEP), enabling rapid assessment of how single variants alter splice site potentials in genomic datasets. Deep learning has advanced predictive capabilities, particularly with SpliceAI, a 32-layer convolutional neural network trained on human genomic data to predict splice junctions and cryptic site activation from raw pre-mRNA sequences up to 10 kb in length. Released in 2019, SpliceAI incorporates sequence context over long ranges, outperforming traditional tools in detecting variant-induced splicing aberrations, with an area under the receiver operating characteristic curve (AUROC) exceeding 0.95 for acceptor and donor site prediction.31629-5) In variant effect prediction, it identifies ~75% of cryptic splice variants validated by RNA-seq, making it valuable for clinical genomics applications like prioritizing pathogenic mutations in rare diseases. These models are routinely applied in pipelines for variant interpretation, such as VEP integrations that flag splicing disruptions in data, aiding prioritization of non-coding variants with potential regulatory effects. Overall accuracies for predicting common alternative splicing events, like or inclusion, hover around 80-90% when benchmarked against reporter assays, though performance varies by event type and context. Transcriptome-wide profiling data from sources like GTEx serve as gold standards for validating these predictions. Post-2020 advancements leverage transformer architectures to address gaps in tissue-specific and isoform-level predictions. SpliceTransformer, introduced in 2024, employs self-attention mechanisms to model long-range dependencies in splicing patterns across 49 human tissues, achieving superior AUROC scores (up to 0.98) for tissue-aware splice site usage compared to prior models. For isoform simulation, generative transformer-based approaches like TrASPr enable de novo design of sequences with desired splicing outcomes, capturing probabilistic distributions of isoforms with state-of-the-art accuracy on GTEx datasets.

Databases and Resources

Major Splicing Databases

Ensembl serves as a primary repository for alternative splicing data through its integration of GENCODE annotations, which provide comprehensive catalogs of protein-coding and non-coding isoforms for and genomes. As of release 112 (October 2024), GENCODE annotations (version 47) emphasize the diversity of alternative splicing events, including , alternative donors and acceptors, and retention, with detailed tracks in Ensembl displaying isoform structures and splicing patterns for over 20,000 genes. These resources enable researchers to explore tissue-specific and developmental splicing variations, supported by evidence from short- and long-read sequencing alignments. The UCSC Genome Browser offers visualization-focused resources for alternative splicing, featuring tracks that depict splice junctions derived from aligned mRNA, ESTs, and gene predictions. Its alternative splicing track (altGraphX) summarizes exon-intron structures and potential isoform variants in current assemblies like hg38 and hg39, while custom tracks allow users to upload and overlay personal datasets, such as RNA-seq-derived junctions, for comparative analysis. Post-2020 updates have incorporated long-read sequencing data, including Capture Long-Seq tracks for full-length transcripts in human (hg38) and mouse (mm10) assemblies, enhancing the resolution of complex splicing events like mutually exclusive exons. ASTALAVISTA provides a specialized catalog of splicing events extracted from genomic annotations across multiple species, classifying patterns into standardized types such as tandem cassettes, alternative positions, and complex events using a coordinate-based . Originally developed for custom datasets, it processes annotations from sources like Ensembl to generate comprehensive event inventories, facilitating cross-species comparisons of splicing and . The core tool relies on short-read alignments, but it has been applied in studies post-2020 integrating long-read-derived transcriptomes to improve detection of rare isoforms in non-model organisms. Additional resources include the Alternative Splicing and Transcript Diversity (ASTD) database, which integrates data on alternative transcripts, including transcription initiation, , and splicing variants across human tissues as of its 2025 update. These databases form the backbone for computational tools in alternative splicing analysis, supplying annotated data for predictive modeling and event quantification.

Annotation and Visualization Tools

Annotation and visualization tools for alternative splicing facilitate the quantification, , and graphical representation of splicing events derived from data, often leveraging outputs from major splicing databases for contextual annotation. These tools enable researchers to identify isoform diversity, detect regulatory changes, and explore spatial aspects of splice sites without requiring extensive manual curation. SUPPA is a suite of software designed for rapid quantification of alternative splicing events, computing percent spliced-in () values across seven event types from transcript abundance estimates produced by aligners like . The original SUPPA tool emphasizes speed by avoiding read realignment, processing large datasets in minutes, while SUPPA2 extends this with and splicing using beta-binomial models for improved accuracy in comparing conditions. SUPPA's supports isoform switching detection by tracking changes in profiles across samples, aiding in the identification of context-specific splicing regulation. The Integrative Genomics Viewer (IGV) serves as a high-performance platform for visualizing alignments, highlighting splice s as arcs connecting exons to reveal alternative splicing patterns, such as or mutually exclusive exons, in real-time interactive sessions. Users can overlay junction tracks with annotations to inspect read coverage and evidence of novel isoforms, making it invaluable for validating predictions from quantification tools. IGV's ability to handle BAM files directly allows for zooming into specific loci, where split reads illustrate retention or alternative donor/acceptor usage. LeafCutter provides an annotation-independent approach to splicing analysis by clustering into excision sets based on shared splice junctions from reads, then deriving intron excision ratios as proxies for splicing efficiency. This method excels in detecting differential splicing in large cohorts, such as GTEx tissues, by focusing on local intron clusters rather than full transcripts, reducing bias from incompleteness. LeafCutter's output, including per-cluster PSI-like metrics, supports downstream analysis of splicing factor-target interactions when combined with regulatory data. Advanced features in these tools include automated isoform switching detection, where shifts in dominant isoforms are flagged via PSI deltas exceeding thresholds (e.g., >0.1), and integration with graph-based methods for visualizing splicing factor networks, such as those linking to target exons. Emerging web-based platforms like SpliceWiz enable interactive R-based exploration of splicing landscapes, generating coverage plots, sashimi-style junction visualizations, and enrichments for differentially spliced events. For three-dimensional structure visualization tied to splicing, tools like RNAfold extensions in web interfaces model secondary structures of alternatively spliced isoforms to predict functional impacts on folding. Post-2023 AI-integrated tools, such as TrASPr, employ generative models to annotate and predict tissue-specific splicing outcomes from sequence data, achieving high fidelity in simulating isoform probabilities via . Splam, another recent AI-driven annotator, pinpoints splice sites with precision surpassing traditional tools by training on diverse datasets to distinguish canonical from cryptic junctions. These AI approaches enhance by generating probabilistic heatmaps of splice site usage. Most annotation and tools, including SUPPA, IGV, LeafCutter, and SpliceWiz, are open-source under licenses like GPL, promoting widespread , whereas proprietary options like some genome browsers offer enhanced support but limit customization. Integration with workflows streamlines pipelines, allowing seamless chaining of SUPPA quantification with IGV-like previews and LeafCutter clustering within a reproducible, web-accessible .

References

  1. [1]
    Alternative Splicing - National Human Genome Research Institute
    Alternative splicing is a cellular process in which exons from the same gene are joined in different combinations, leading to different, but related, mRNA ...
  2. [2]
    https://www.nature.com/scitable/topicpage/rna-splicing-introns-exons-and-spliceosome-12375
  3. [3]
    Origin of Spliceosomal Introns and Alternative Splicing - PMC
    First hypothesized by Gilbert (1978), this process, known as alternative splicing (AS), appears to be widespread in eukaryotes, seemingly reaching its apex in ...
  4. [4]
    Mechanism of alternative splicing and its regulation - PMC
    Alternative splicing of precursor mRNA is an essential mechanism to increase the complexity of gene expression, and it plays an important role in cellular ...
  5. [5]
    Alternative splicing and related RNA binding proteins in human ...
    Feb 2, 2024 · Alternative splicing (AS) serves as a pivotal mechanism in transcriptional regulation, engendering transcript diversity, and modifications ...
  6. [6]
    Discovery of RNA splicing and genes in pieces - PNAS
    The Problem: Short-Lived Heterogeneous Nuclear RNA. During the 1960s and 1970s, there was a major conundrum in eukaryotic molecular biology regarding the ...
  7. [7]
    Reflections on the history of pre-mRNA processing and highlights of ...
    This review discusses more than thirty years of experimental data relating to the processing of pre-messenger RNA.
  8. [8]
    The Nobel Prize in Physiology or Medicine 1993 - Press release
    Roberts and Phillip A. Sharp in 1977 independently discovered that genes could be discontinuous, that is, a given gene could be present in the genetic material ...
  9. [9]
    A map of cytoplasmic RNA transcripts from lytic adenovirus type 2 ...
    A map of cytoplasmic RNA transcripts from lytic adenovirus type 2, determined by electron microscopy of RNA:DNA hybrids. Cell. 1977 Aug;11(4):819-36. doi ...Missing: visualization loops introns
  10. [10]
    1977: Introns Discovered
    Apr 26, 2013 · Richard Roberts' and Phil Sharp's labs showed that eukaryotic genes contain many interruptions, called introns.
  11. [11]
    Are snRNPs involved in splicing? - Nature
    Jan 10, 1980 · Here we present several lines of evidence that suggest a direct involvement of snRNPs in the splicing of hnRNA.Missing: discovery | Show results with:discovery
  12. [12]
    Spliceosome Structure and Function - PMC - PubMed Central - NIH
    The U2-dependent spliceosome is assembled from the U1, U2, U5, and U4/U6 snRNPs and numerous non-snRNP proteins. The main subunits of the U12-dependent ...Missing: EABC | Show results with:EABC
  13. [13]
    The Spliceosome: Design Principles of a Dynamic RNP Machine
    Feb 20, 2009 · Second, during the A complex to B complex and B complex to C complex transitions, a large number of additional spliceosomal proteins are ...
  14. [14]
    Mechanism of spliceosome remodeling by the ATPase/helicase ...
    The ATPase/helicase Prp2 associates with the activated spliceosome and translocates the single-stranded pre-mRNA toward its 3′ end.
  15. [15]
    The Spliceosome and Its Metal Ions - PubMed
    The spliceosome is a magnesium-dependent enzyme that utilizes catalytic metal ions to stabilize both transition states during the two phosphoryl transfer steps ...
  16. [16]
    a split consensus reveals two major 5′ splice site classes - Journals
    Jan 15, 2025 · The 5′ exon remains in the active site, but the intron lariat is removed and replaced by the 3′ splice site for the exon-ligation reaction ( ...
  17. [17]
    The pathogenicity of splicing defects: mechanistic insights into pre ...
    Pre‐mRNA splicing requires precise recognition of cis‐acting sequences on the pre‐mRNA by spliceosomal components and additional RNA‐binding factors, and ...<|control11|><|separator|>
  18. [18]
    Pick one, but be quick: 5′ splice sites and the problems of too many ...
    Here we review the history of research on 5′ss selection, highlighting the difficulties of establishing how base-pairing strength determines splicing outcomes.Sr Proteins Bound To Exon... · Srsf1 Shifts Splicing To... · U1 Snrnps May Bind...
  19. [19]
    A cooperative interaction between U2AF65 and mBBP/SF1 ...
    In this paper we demonstrate that the mBBP/SF1-U2AF65 interaction promotes cooperative binding to a branchpoint sequence-polypyrimidine tract-containing RNA, ...
  20. [20]
    Recognition of RNA Branch Point Sequences by the KH Domain of ...
    SF1/mBBP utilizes a “maxi-K homology” (maxi-KH) domain for recognition of the single-stranded BPS and requires a cooperative interaction with splicing factor ...
  21. [21]
    A sequential binding mechanism for 5′ splice site recognition and ...
    Oct 10, 2024 · The snRNA region that base pairs with the 5'SS is found at the very 5′ end and can form up to 11 contiguous base pairs, flanking both sides of ...
  22. [22]
    Multi-step recognition of potential 5' splice sites by the ... - eLife
    Aug 12, 2022 · The yeast U1 snRNP recognizes multiple features of target RNAs to reversibly identify splicing-competent 5' splice sites.
  23. [23]
    Conserved and divergent signals in 5' splice site sequences across ...
    Oct 13, 2023 · We investigated two-site statistical patterns to identify conserved and divergent signals embedded in the 5' splice sites of 30 eukaryotic species.
  24. [24]
    Phylogenetic comparison and splice site conservation of eukaryotic ...
    Jun 17, 2021 · The blue arrows indicate conserved sequences found in various species. The yellow arrows indicate the conserved splice site located in the ...
  25. [25]
    Alternative splicing: Human disease and quantitative analysis from ...
    1) Exon skipping (also known as cassette exons) is reported to be the most common alternative splicing event in mammalian cells, which results in complete ...<|control11|><|separator|>
  26. [26]
    ExonSkipDB: functional annotation of exon skipping event in human
    Oct 23, 2019 · Abstract. Exon skipping (ES) is reported to be the most common alternative splicing event due to loss of functional domains/sites or shifting ...
  27. [27]
    Exon Identity Established through Differential Antagonism between ...
    SR proteins recognize exonic splicing enhancer (ESE) elements and promote exon use, whereas certain hnRNP proteins bind to exonic splicing silencer (ESS) ...
  28. [28]
    Variants Affecting Exon Skipping Contribute to Complex Traits - PMC
    Oct 25, 2012 · Exon skipping is the first alternative splicing (AS) mode accounting for 40% of AS events in higher eukaryotes [53], [54]. Alternative 3′/5 ...
  29. [29]
    Assessing the number of ancestral alternatively spliced exons in the ...
    Oct 24, 2006 · Exon skipping is the most abundant type in human, composing ~40% of all alternative splicing events in the genome [18]. Events such as mutually ...
  30. [30]
    Thousands of exon skipping events differentiate among splicing ...
    We found over 150,000 candidate alternative splicing events, including roughly 27,000 exon skipping events, most of which (65%) were novel. New introns (15,958) ...
  31. [31]
    Predicting the structural impact of human alternative splicing
    Sep 17, 2025 · ... Exon skipping and alternative last exons tend to increase the surface charge and radius of gyration. Splicing also buries or exposes ...
  32. [32]
    Extended base pair complementarity between U1 snRNA and the 5 ...
    We have previously shown that RNA duplex formation between U1 snRNA and the 5′ splice site can protect pre-mRNAs from degradation prior to splicing. This ...
  33. [33]
    Evidence for the widespread coupling of alternative splicing ... - PNAS
    Evidence for the widespread coupling of alternative splicing and nonsense-mediated mRNA decay in humans. Benjamin P. Lewis, Richard E. Green, and Steven E ...
  34. [34]
    changing paradigm of intron retention: regulation, ramifications and ...
    Nov 14, 2019 · Intron retention (IR) is a form of alternative splicing that has long been neglected in mammalian systems although it has been studied for decades in non- ...
  35. [35]
    Alternative Splicing and Protein Diversity: Plants Versus Animals
    Intron retention is the most prevalent AS event in plants with observed frequencies between 28% to as high as 64% (Figure 1) depending upon growth condition, ...
  36. [36]
    IRFinder: assessing the impact of intron retention on mammalian ...
    Mar 15, 2017 · Analysis of 2573 samples showed that IR occurs in all tissues analyzed, affects over 80% of all coding genes and is associated with cell ...Missing: prevalence | Show results with:prevalence
  37. [37]
    Intron retention is a stress response in sensor genes and is restored ...
    Jul 1, 2022 · Intron retention (IR) is a regulatory mechanism that can retard protein production by acting at the level of mRNA processing.
  38. [38]
    https://academic.oup.com/nar/article/47/22/11497/5625532
  39. [39]
    Mutually exclusive splicing of alpha-tropomyosin exons enforced by ...
    Alternative splicing of alpha-tropomyosin pre-mRNA involves mutually exclusive utilization of exons 2 and 3, exon 3 being preferentially selected in most cells.Missing: mechanism example
  40. [40]
    Widespread intron retention in mammals functionally tunes ... - NIH
    We find that IR is far more frequent in mammals than previously appreciated, affecting transcripts from most genes. A set of distinct cis features reliably ...
  41. [41]
    Programmable mutually exclusive alternative splicing for generating ...
    Jun 17, 2019 · Mutually exclusive splicing of α-tropomyosin exons enforced by an unusual lariat branch point location: Implications for constitutive splicing.
  42. [42]
    https://www.cell.com/fulltext/S0092-8674(05)00963-3
  43. [43]
    Splicing regulation: From a parts list of regulatory elements to an ...
    Splicing is regulated by cis-elements (ESE, ESS, ISS, and ISE) and trans-acting splicing factors (SR proteins, hnRNP, and unknown factors).
  44. [44]
    RNA structure and the mechanisms of alternative splicing - PMC - NIH
    Alternative splicing increases protein diversity and regulates gene expression. RNA secondary structures play an underappreciated role in this process.
  45. [45]
    ESEfinder: a web resource to identify exonic splicing enhancers - PMC
    ESEfinder is a web-based tool that rapidly analyzes exon sequences to identify exonic splicing enhancers (ESEs) using weight matrices.
  46. [46]
    Alternative splicing and cancer: a systematic review - Nature
    Feb 24, 2021 · The SR proteins and hnRNP family are two essential auxiliary factors in enhancing or repressing splice-site usage by the recognition of specific ...
  47. [47]
    RNA-Binding Proteins: Splicing Factors and Disease - PMC - NIH
    Splicing is a major regulatory component in higher eukaryotes. Disruptions in splicing are a major contributor to human disease.
  48. [48]
    The role of U2AF35 and U2AF65 in enhancer-dependent splicing
    Most importantly, we find that splicing activators promote the binding of both U2AF65 and U2AF35 to weak 3' splice sites under splicing conditions. Finally, we ...Missing: trans- | Show results with:trans-
  49. [49]
    Splicing Factor U2AF - an overview | ScienceDirect Topics
    Two other proteins, U2 auxiliary factors 35 and 65 (U2AF35 and U2AF65), bind to the 3′SS and polypyrimidine tract, respectively. This is the earliest splicing- ...
  50. [50]
    The SF3b complex: splicing and beyond
    Mar 5, 2020 · This review summarizes the current knowledge on the SF3b complex and highlights its multiple roles in splicing and beyond.
  51. [51]
    Phosphorylation of SRSF1 is modulated by replicational stress - PMC
    Notably, SRSF1 has been recently shown to regulate an alternative splicing network linking cell-cycle control to apoptosis (15). In this study we use 46BR.1G1 ...
  52. [52]
    Emerging Functions of SRSF1, Splicing Factor and Oncoprotein, in ...
    SRSF1 also regulates alternative splicing of factors affecting cellular signaling pathways, proliferation, and cell-cycle progression. As mentioned above, these ...
  53. [53]
    Positive autoregulation of sex-lethal by alternative splicing maintains ...
    Sex-lethal is a binary switch gene that controls all aspects of Drosophila sexual dimorphism. It must be active in females and inactive in males.
  54. [54]
    Binding of the Drosophila sex-lethal gene product to the alternative ...
    Mar 29, 1990 · We find that female Sxl-encoded protein binds specifically to the tra transcript at or near the non-sex-specific acceptor site.
  55. [55]
    Control of doublesex Alternative Splicing by transformer ... - Science
    Sex-specific alternative processing of doublesex (dsx) precursor messenger RNA (pre-mRNA) regulates somatic sexual differentiation in Drosophila melanogaster.
  56. [56]
    https://aacrjournals.org/mcr/article/12/9/1195/89476/Emerging-Functions-of-SRSF1-Splicing-Factor-and
  57. [57]
    Apoptosis and expression of soluble Fas mRNA in systemic lupus ...
    In comparison with healthy subjects, Fas alternative splicing was skewed toward the soluble form of Fas in SLE and RA. Apoptosis after T cell activation in ...Missing: isoform | Show results with:isoform
  58. [58]
    Alternative Splicing: A New Cause and Potential Therapeutic Target ...
    Aug 17, 2021 · Spliced Isoforms in SLE. SLE is a chronic autoimmune disease of unknown etiology. It more frequently affects women in their reproductive age.
  59. [59]
    Can the HIV-1 splicing machinery be targeted for drug discovery?
    Mar 10, 2017 · HIV-1 is able to express multiple protein types and isoforms from a single 9 kb mRNA transcript. These proteins are also expressed at particular ...Missing: compact | Show results with:compact
  60. [60]
    Alternative splicing: regulation of HIV‐1 multiplication as a target for ...
    Jan 27, 2010 · In summary, hnRNP H and hnRNP A1 bind to the ESS2p and ESS2 elements, respectively, to repress activity at splice site A3. ESS2 initiates the ...Missing: seminal | Show results with:seminal
  61. [61]
    Genetic variation and function of the HIV-1 Tat protein - PMC
    The second exon of Tat is less conserved compared to the first exon and is classically characterized as its own distinct domain [17], but has been demonstrated ...
  62. [62]
    RNA Splicing at Human Immunodeficiency Virus Type 1 3
    Splicing of Tat mRNA, which is present at relatively low levels in infected cells, is repressed by the presence of exonic splicing silencers (ESS) within the ...
  63. [63]
    hnRNP A/B proteins are required for inhibition of HIV‐1 pre‐mRNA ...
    Splicing inhibition is restored by addition of recombinant hnRNP A/B proteins to the depleted extract. A high‐affinity hnRNP A1‐binding sequence can substitute ...Missing: seminal papers
  64. [64]
    The hnRNP A1 protein regulates HIV-1 tat splicing via a novel intron ...
    hnRNP A1 inhibits U2 snRNP binding, but not U2AF65 binding. SF2/ASF-mediated activation of tat splicing correlates with an increased level of U2AF65 binding to ...Missing: seminal papers
  65. [65]
    HIV-1: To Splice or Not to Splice, That Is the Question - MDPI
    In general, cellular transcripts that are not completely spliced are not exported from the nucleus and so HIV-1 unspliced and partially spliced transcripts ( ...
  66. [66]
    Negative and Positive mRNA Splicing Elements Act Competitively ...
    Our results suggest that a novel ESE downstream of HIV-1 3′ss A1 promotes the inclusion of exon 2, as well as the creation of vif mRNA. ESE elements bind to ...
  67. [67]
    Global detection of human variants and isoforms by deep proteome ...
    Mar 23, 2023 · However, although the human genome contains approximately 20,000 protein-coding genes ... 95% of multi-exon genes undergo alternative splicing.
  68. [68]
    Alternative splicing: Human disease and quantitative analysis ... - NIH
    Dec 24, 2020 · 2) Mutually exclusive exons are a rare subtype where two or more splicing events are no longer independent. They are executed or disabled in a ...
  69. [69]
    Neuronal calcium channels: Splicing for optimal performance - PMC
    Alternative splicing occurs at sites important for controlling calcium channel activity, creating an array of functionally distinct calcium channels. Thus each ...
  70. [70]
    Diversification of the muscle proteome through alternative splicing
    Mar 6, 2018 · In this review, we discuss the current knowledge with respect to the mechanisms that allow pre-mRNA transcripts to undergo muscle-specific alternative splicing.
  71. [71]
    Alternative Splicing at N Terminus and Domain I Modulates Ca V 1.2 ...
    Jul 3, 2018 · These exons showed tissue selectivity in their expression patterns: heart variant 1a/8a, one smooth-muscle variant 1/8, and a brain isoform 1/8a ...
  72. [72]
    Hypoxia is a Key Driver of Alternative Splicing in Human Breast ...
    Jun 22, 2017 · Adaptation to hypoxia, a hallmark feature of many tumors, is an important driver of cancer cell survival, proliferation and the development ...
  73. [73]
    Alternative Splicing at the Intersection of Biological Timing ...
    Transcription fidelity and control of alternative splicing contribute to heat stress survival in Arabidopsis · Targeted genetic manipulation and yeast-like ...
  74. [74]
    The fitness cost of mis-splicing is the main determinant of alternative ...
    Here we present a comprehensive characterization of AS in the transcriptomes of normal and NMD-deficient paramecia to test the AS-NMD and noisy splicing models.Missing: quantitative | Show results with:quantitative
  75. [75]
    Global impact of unproductive splicing on human gene expression
    Sep 2, 2024 · Alternative splicing (AS) in human genes is widely viewed as a mechanism for enhancing proteomic diversity. AS can also impact gene expression ...
  76. [76]
    Origin and evolution of spliceosomal introns | Biology Direct | Full Text
    Apr 16, 2012 · Conversely, splicing errors gave rise to alternative splicing, a major contribution to the biological complexity of multicellular eukaryotes.
  77. [77]
    Alternative splicing across the tree of life | eLife
    Oct 17, 2025 · The authors examined the frequency of alternative splicing across prokaryotes and eukaryotes and found that the rate of alternative splicing ...
  78. [78]
    Variation in sequence and organization of splicing regulatory ... - NIH
    The classical splice site and putative branch site signals are completely conserved across the vertebrates studied (human, mouse, pufferfish, and zebrafish), ...
  79. [79]
    Conservation of human alternative splice events in mouse - PubMed
    It is apparent that many, and probably most, alternative splicing events are conserved between human and mouse.Missing: core universal 60%
  80. [80]
    Evolutionarily conserved and diverged alternative splicing events ...
    We found conserved alternative splicing most enriched in brain-expressed signaling pathways. Diverged alternative splicing is more prevalent in testis and ...Missing: core universal
  81. [81]
    Alternative splicing: A missing piece in the puzzle of intron gain | PNAS
    ... mutation creates a new acceptor site ... These minor splice forms originate via mutations that introduce new splice sites inside preexisting intron sequences.
  82. [82]
    The importance of alternative splicing in adaptive evolution
    Jan 30, 2022 · Intron retention is thought to be the predominant type of alternative splicing in plants, while exon skipping is most common in animals ( ...Missing: prevalence | Show results with:prevalence
  83. [83]
    Exon Shuffling Played a Decisive Role in the Evolution of the ... - NIH
    Mar 8, 2021 · We have shown that the majority of the multidomain proteins involved in cell–cell and cell–matrix interactions of Metazoa have been assembled by exon shuffling.
  84. [84]
    The “Alternative” Choice of Constitutive Exons throughout Evolution
    Therefore, a mutation that affects exon selection in exons flanked by longer introns might be prone to shift the exon to alternative splicing. The two known ...
  85. [85]
    Aberrant splicing and defective mRNA production induced ... - Nature
    Sep 7, 2018 · SF3B1 mutation was significantly associated with 3831 alternative splicing events in either BMMNCs or CD34+ cells (Fig. 1c). SF3B1 mutation was ...
  86. [86]
    Decoding a cancer-relevant splicing decision in the RON proto ...
    Aug 17, 2018 · Mathematical modelling of splicing kinetics enables us to identify more than 1000 mutations affecting RON exon 11 skipping, which corresponds to ...
  87. [87]
    Phase I First-in-Human Dose Escalation Study of the oral SF3B1 ...
    Jun 25, 2021 · SF3B1 mutations were the most common ones in MDS patients (15 missense mutations in 41 patients, 36.6%), particularly in lower-risk MDS (57%) ( ...
  88. [88]
    Alternative splicing during mammalian organ development - Nature
    May 3, 2021 · 5). For example, 75% of devAS events in the human brain occur in genes with broad spatial expression (tissue specificity <0.5; Fig. 1f).
  89. [89]
    An Overview of Alternative Splicing Defects Implicated in Myotonic ...
    This review focuses on the cause and effects of MBNL and CELF1 deregulation in DM1, describing the molecular mechanisms underlying alternative splicing ...2.1. Mbnl-Dependent Splicing... · 2.2. Mbnl And Celf1... · Table 2
  90. [90]
    Mechanism of Splicing Regulation of Spinal Muscular Atrophy Genes
    Jun 29, 2018 · The only approved drug for SMA is an antisense oligonucleotide (Spinraza™/Nusinersen), which corrects SMN2 exon 7 splicing by blocking intronic ...
  91. [91]
    Diverse targets of SMN2-directed splicing-modulating small ...
    Apr 7, 2023 · Skipping of SMN2 exon 7 is driven primarily by a weak 3′ splice site (3′ss) created due to a critical C-to-T mutation at the sixth position (C6U ...
  92. [92]
    Counteracting chromatin effects of a splicing-correcting antisense ...
    Nusinersen targets the splicing silencer located in SMN2 intron 7 pre-mRNA and, by blocking the binding of hnRNPA1 and A2, it promotes higher E7 inclusion, ...
  93. [93]
    Nusinersen as a Therapeutic Agent for Spinal Muscular Atrophy
    Mar 25, 2020 · Nusinersen is an antisense oligonucleotide, approved by the FDA, which specifically binds to the repressor within SMN2 exon 7 to enhance exon 7 ...
  94. [94]
    TDP-43 represses cryptic exon inclusion in the FTD–ALS ... - Nature
    Feb 23, 2022 · The discovery of STMN2 cryptic exon splicing in ALS and FTLD-TDP highlights a key mRNA target—we aimed to identify other possible mRNA targets.
  95. [95]
    Mechanism of STMN2 cryptic splice-polyadenylation and ... - Science
    Mar 16, 2023 · Loss of functional TDP-43 is accompanied by misprocessing of the STMN2 RNA precursor, which is driven by use of cryptic splicing and polyadenylation sites.Missing: misregulation | Show results with:misregulation
  96. [96]
    The era of cryptic exons: implications for ALS-FTD
    Mar 15, 2023 · Crucially, the STMN2 cryptic exon was confirmed to be detectable also in ALS-FTD brains and spinal cords where TDP-43 pathology is present and ...
  97. [97]
    Cryptic splicing of stathmin-2 and UNC13A mRNAs is a pathological ...
    Jan 4, 2024 · Loss of TDP-43 nuclear function leads to the aberrant incorporation of cryptic exons into messenger RNAs, which are detectable in tissues from ...Missing: misregulation | Show results with:misregulation
  98. [98]
    Muscleblind proteins regulate alternative splicing | The EMBO Journal
    Loss of MBNL function due to sequestration on CUG repeat RNA is proposed to play a role in DM pathogenesis (Miller et al, 2000). Consistent with this proposal, ...Results · Mbnl1 Directly Binds To... · Discussion
  99. [99]
    rbFOX1/MBNL1 competition for CCUG RNA repeats binding ...
    May 22, 2018 · Titration of the MBNL proteins within CUG or CCUG RNA foci leads to specific alternative splicing changes. Hence, we tested whether the release ...
  100. [100]
    Synaptic Signaling and Aberrant RNA Splicing in Autism Spectrum ...
    These trans-synaptic interactions are regulated by alternative splicing of CAM RNAs, which ultimately determines neurotransmitter phenotype. The diverse ...Atypical Splice Variant... · Syndromic Asd Genes As... · Effect Of Splicing On...
  101. [101]
    The spectrum of pre‐mRNA splicing in autism - Engal - 2024
    Mar 20, 2024 · Eighty genes exhibited alternative splicing in both cortex locations where intron retention was the most common event (43%). This group of ...DISCOVERY OF... · SPLICING FACTORS... · NOVA ALTERNATIVE... · RBFOX1
  102. [102]
    Misregulation of an Activity-Dependent Splicing Network as a ...
    Dec 15, 2016 · Our results thus demonstrate that an alternative splicing program comprising hundreds of events, including a significant fraction of neural ...
  103. [103]
    Alternative splicing analysis in a Spanish ASD (Autism Spectrum ...
    Mar 28, 2025 · Notably, splicing genes appear to be predominantly associated with synaptic organization and transmission, in contrast to non-splicing genes ( ...
  104. [104]
    Challenges in estimating percent inclusion of alternatively spliced ...
    Apr 19, 2012 · This comparison demonstrates the challenges in estimating the percent inclusion of alternatively spliced junctions and illuminates the tradeoffs between ...
  105. [105]
    Isoform Age - Splice Isoform Profiling Using Long-Read Technologies
    Aug 1, 2021 · In this review, we discuss current and emerging long-read sequencing methodologies for full-length RNA isoform detection and quantification.Progress and Applications of... · Long Read Profiling of... · Targeted Long-Read...<|separator|>
  106. [106]
    Technological advances and computational approaches for ...
    Single-cell alternative splicing is an emerging area of research with the promise to reveal transcriptomic dynamics invisible to bulk- and gene-level analysis.
  107. [107]
    Statistical modeling of isoform splicing dynamics from RNA-seq time ...
    DICEseq explicitly models the correlations between different RNA-seq experiments to aid the quantification of isoforms across experiments.
  108. [108]
    Coverage-dependent bias creates the appearance of binary splicing ...
    Jun 29, 2020 · Our simulations show that low gene expression and low capture efficiency distort the observed distribution of isoforms. This gives the appearance of binary ...
  109. [109]
    Automatic detection of exonic splicing enhancers (ESEs) using SVMs
    Exonic splicing enhancers (ESEs) activate nearby splice sites and promote the inclusion (vs. exclusion) of exons in which they reside, while being a binding ...Missing: ESS | Show results with:ESS
  110. [110]
    Automatic Detection of Exonic Splicing Enhancers (ESEs) Using SVMs
    Sep 10, 2008 · We developed a motif-oriented data-extraction method that extracts exon sequences around experimentally or theoretically determined ESE patterns.Missing: ESS | Show results with:ESS
  111. [111]
    Thermodynamic modeling of donor splice site recognition in pre ...
    Apr 26, 2004 · We model this interaction thermodynamically to identify splice sites. Applied to a set of 65 annotated genes, our “finding with binding” method achieves a ...
  112. [112]
    Unifying evolutionary and thermodynamic information for RNA ...
    Computational methods for determining the secondary structure of RNA sequences from given alignments are currently either based on thermodynamic folding, ...Introduction · Materials And Methods · Results<|separator|>
  113. [113]
    A plugin for the Ensembl Variant Effect Predictor that uses ...
    The plugin uses MaxEntScan to predict splice site loss/gain for variants, using a sliding window algorithm and a maximum entropy model.
  114. [114]
    Predicting Splicing from Primary Sequence with Deep Learning
    Jan 24, 2019 · We describe a deep neural network that accurately predicts splice junctions from an arbitrary pre-mRNA transcript sequence, enabling precise prediction of ...
  115. [115]
    Benchmarking splice variant prediction algorithms using massively ...
    Dec 21, 2023 · We benchmark eight widely used splicing effect prediction algorithms, leveraging massively parallel splicing assays (MPSAs) as a source of experimentally ...Missing: fitness | Show results with:fitness
  116. [116]
    SpliceTransformer predicts tissue-specific splicing linked to human ...
    Oct 23, 2024 · We present SpliceTransformer (SpTransformer), a deep-learning framework that predicts tissue-specific RNA splicing alterations linked to human diseases based ...
  117. [117]
    Generative modeling for RNA splicing predictions and design - eLife
    Mar 20, 2025 · We introduce TrASPr+BOS, a generative AI model with Bayesian Optimization for predicting and designing RNA for tissue-specific splicing outcomes.
  118. [118]
    reference annotation for the human and mouse genomes in 2023
    GENCODE annotation is rich in its representation of alternative splicing within protein-coding and lncRNA loci, its assignment of 'biotypes' describing ...
  119. [119]
    GENCODE 2025: reference gene annotation for human and mouse
    Nov 20, 2024 · Abstract. GENCODE produces comprehensive reference gene annotation for human and mouse. Entering its twentieth year, the project remains ...
  120. [120]
    UCSC Genome Browser database: 2022 update - Oxford Academic
    Oct 28, 2021 · The site's tools are engineered to allow users to attach data generated in their own lab through mechanisms known as custom tracks, track hubs, ...<|separator|>
  121. [121]
    Alt-Splicing Track Settings - UCSC Genome Browser
    Description. This track summarizes alternative splicing shown in the mRNA and EST tracks. The blocks represent exons; lines indicate possible splice ...Missing: visualizations | Show results with:visualizations
  122. [122]
    UCSC Genome Browser: News Archives
    New Capture long-seq (CLS) long-read lncRNAs tracks are available for hg38 and mm10. These tracks represent the results of targeted long-read RNA sequencing ...
  123. [123]
    ASTALAVISTA: dynamic and flexible analysis of alternative splicing ...
    Historically, four main AS events have been reported in literature: exon skipping, intron retention, alternative donor and acceptor splice sites. Obviously, the ...
  124. [124]
    ASTALAVISTA: dynamic and flexible analysis of alternative splicing ...
    ASTALAVISTA (alternative splicing transcriptional landscape visualization tool) employs an intuitive and complete notation system to univocally identify such ...
  125. [125]
    Analysis of Alternative Splicing Events in Custom Gene Datasets by ...
    Aug 6, 2025 · We show how to practically employ AStalavista to study AS variation in complex transcriptomes, as characterized by the human GENCODE annotation.