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1. An intronic RNA element modulates Factor VIII exon-16 splicing

   https://doi.org/10.1093/nar/gkad1034  

   Tse, Victor; Chacaltana, Guillermo; Gutierrez, Martin; Forino, Nicholas M; Jimenez, Arcelia G; Tao, Hanzhang; Do, Phong H; Oh, Catherine; Chary, Priyanka; Quesada, Isabel; et al (November 2023, Nucleic Acids Research)

   Abstract Pathogenic variants in the human Factor VIII (F8) gene cause Hemophilia A (HA). Here, we investigated the impact of 97 HA-causing single-nucleotide variants on the splicing of 11 exons from F8. For the majority of F8 exons, splicing was insensitive to the presence of HA-causing variants. However, splicing of several exons, including exon-16, was impacted by variants predicted to alter exonic splicing regulatory sequences. Using exon-16 as a model, we investigated the structure–function relationship of HA-causing variants on splicing. Intriguingly, RNA chemical probing analyses revealed a three-way junction structure at the 3′-end of intron-15 (TWJ-3–15) capable of sequestering the polypyrimidine tract. We discovered antisense oligonucleotides (ASOs) targeting TWJ-3–15 partially rescue splicing-deficient exon-16 variants by increasing accessibility of the polypyrimidine tract. The apical stem loop region of TWJ-3–15 also contains two hnRNPA1-dependent intronic splicing silencers (ISSs). ASOs blocking these ISSs also partially rescued splicing. When used in combination, ASOs targeting both the ISSs and the region sequestering the polypyrimidine tract, fully rescue pre-mRNA splicing of multiple HA-linked variants of exon-16. Together, our data reveal a putative RNA structure that sensitizes F8 exon-16 to aberrant splicing. 

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2. Influence of FTDP-17 mutants on circular tau RNAs

   https://doi.org/10.1016/j.bbadis.2024.167036  

   Margvelani, Giorgi; Welden, Justin R; Maquera, Andrea Arizaca; Van_Eyk, Jennifer E; Murray, Christopher; Miranda_Sardon, Sandra C; Stamm, Stefan (April 2024, Biochimica et Biophysica Acta (BBA) - Molecular Basis of Disease)

   At least 53 mutations in the microtubule associated protein tau gene (MAPT) have been identified that cause frontotemporal dementia. 47 of these mutations are localized between exons 7 and 13. They could thus affect the formation of circular RNAs (circRNAs) from the MAPT gene that occurs through backsplicing from exon 12 to either exon 10 or exon 7. We analyzed representative mutants and found that five FTDP-17 mutations increase the formation of 12➔7 circRNA and three different mutations increase the amount of 12➔10 circRNA. CircRNAs are translated after undergoing adenosine to inosine RNA editing, catalyzed by ADAR enzymes. We found that the interferon induced ADAR1-p150 isoform has the strongest effect on circTau RNA translation. ADAR1-p150 activity had a stronger effect on circTau RNA expression and strongly decreased 12➔7 circRNA, but unexpectedly increased 12➔10 circRNA. In both cases, ADAR-activity strongly promoted translation of circTau RNAs. Unexpectedly, we found that the 12➔7 circTau protein interacts with eukaryotic initiation factor 4B (eIF4B), which is reduced by four FTDP-17 mutations located in the second microtubule domain. These are the first studies of the effect of human mutations on circular RNA formation and translation. They show that point mutations influence circRNA expression levels, likely through changes in pre-mRNA structures. The effect of the mutations is surpassed by editing of the circular RNAs, leading to their translation. Thus, circular RNAs and their editing status should be considered when analyzing FTDP-17 mutations. 

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3. RNA localization to nuclear speckles follows splicing logic

   https://doi.org/10.1101/2025.05.28.656493  

   Wen, Li; Arias, Mauricio A; Fan, Xinqi; Paul, Sneha; Liao, Susan E; Sobczyk, Marek; Regev, Oded; Fei, Jingyi (May 2025, bioRxiv)

   Summary Nuclear speckles are membraneless organelles implicated in multiple RNA processing steps. In this work, we systematically characterize the sequence logic determining RNA localization to nuclear speckles. We find extensive similarities between the speckle localization code and the RNA splicing code, even for transcripts that do not undergo splicing. Specifically, speckle localization is enhanced by the presence of unspliced exon-like or intron-like sequence features. We demonstrate that interactions required for early splicesomal complex assembly contribute to speckle localization. We also show that speckle localization of isolated endogenous exons is reduced by disease-associated single nucleotide variants. Finally, we find that speckle localization strongly correlates with splicing kinetics of splicing-competent constructs and is tightly linked to the decision between exon inclusion and skipping. Together, these results suggest a model in which RNA speckle localization is associated with the formation of the early spliceosomal complex and enhances the efficiency of splicing reactions. HighlightsSequences containing hallmarks of pre-mRNA dictate speckle localizationRNA speckle localization is coupled to early spliceosome assemblyDisease-associated single nucleotide variants reduce localization of isolated exonsRNA speckle localization strongly correlates with splicing kineticsGraphical Abstract 

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4. OpenASO: RNA Rescue — designing splice-modulating antisense oligonucleotides through community science

   https://doi.org/10.1261/rna.080288.124  

   Tse, Victor; Guiterrez, Martin; Townley, Jill; Romano, Jonathan; Pearl, Jennifer; Chacaltana, Guillermo; Players, Eterna; Das, Rhiju; Sanford, Jeremy; Stone, Michael (May 2025, RNA)

   Splice-modulating antisense oligonucleotides (ASOs) are precision RNA-based drugs that are becoming an established modality to treat human disease. Previously, we reported the discovery of ASOs that target a novel, putative intronic RNA structure to rescue splicing of multiple pathogenic variants of F8 exon 16 that cause hemophilia A. However, the conventional approach to discovering splice-modulating ASOs is both laborious and expensive. Here, we describe a novel approach that integrates data-driven RNA structure prediction and community science to discover splice-modulating ASOs. Using a splicing-deficient pathogenic variant of F8 exon 16 as a model, we show that 25% of the top-scoring molecules designed in the Eterna OpenASO challenge have a statistically significant impact on enhancing exon 16 splicing. Additionally, we show that a distinct combination of ASOs designed by Eterna players can additively enhance the inclusion of the splicing-deficient exon 16 variant. Together, our data suggests that crowdsourcing designs from a community of citizen scientists may accelerate and complement traditional avenues for the discovery of splice-modulating ASOs with potential to treat human disease. 

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5. Alternative Splicing Dynamics in Plant Adaptive Responses to Stress

   https://doi.org/10.1146/annurev-arplant-083123-090055  

   Alhabsi, Abdulrahman; Ling, Yu; Crespi, Martin; Reddy, Anireddy SN; Mahfouz, Magdy (May 2025, Annual Review of Plant Biology)

   Plants thrive in dynamic environments by activating sophisticated molecular networks that fine-tune their responses to stress. A key component of these networks is gene regulation at multiple levels, including precursor messenger RNA (pre-mRNA) splicing, which shapes the transcriptome and proteome landscapes. Through the precise action of the spliceosome complex, noncoding introns are removed and coding exons are joined to produce spliced RNA transcripts. While constitutive splicing always generates the same messenger RNA (mRNA), alternative splicing (AS) produces multiple mRNA isoforms from a single pre-mRNA, enriching proteome diversity. Remarkably, 80% of multiexon genes in plants generate multiple isoforms, underscoring the importance of AS in shaping plant development and responses to abiotic and biotic stresses. Recent advances in CRISPR-Cas genome and transcriptome editing technologies offer revolutionary tools to dissect AS regulation at molecular levels, unveiling the functional significance of specific isoforms. In this review, we explore the intricate mechanisms of pre-mRNA splicing and AS in plants, with a focus on stress responses. Additionally, we examine how leveraging AS insights can unlock new opportunities to engineer stress-resilient crops, paving the way for sustainable agriculture in the face of global environmental challenges. 

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