Project description:TDP-43 is an RNA and DNA binding protein that plays major roles in regulating RNA processing. In particular, TDP-43 dysfunction leads to the accumulation of cryptic splice isoforms that result from improperly spliced mRNAs. In addition to its role in regulating splicing, TDP-43 is also known to regulate the expression of transposable elements (TEs). TEs are mobile genetic elements which comprise a significant proportion of the human genome, but are normally silenced in healthy somatic cells. TEs are interspersed throughout the genome, both in gene-depleted regions and interspersed within gene introns and gene regulatory sequences. We used optimized long-read RNA sequencing assays to generate catalogs of mis-spliced and mis-expressed genes and TEs in human neurons depleted for TDP-43. In addition to known TDP-43 driven cryptic isoforms, we identified hundreds of TDP-43 dependent spliced RNAs formed as part of cryptic gene-TE fusion events that result from mis-splicing of TE sequences into gene transcripts. Among these TDP-43 dependent gene-TE cryptic transcripts (crypTEs), we found: TEs that provide alternate gene promoters/5’UTRs, TEs that act as cassette exons inside host gene mRNAs, as well as TEs that provide alternate transcript 3’ ends. These cryptic gene-TE fusions are predicted to induce: aberrant expression of ALS relevant genes, nonsense mediated decay (NMD) products, as well as novel peptides from gene-TE fusions within the gene coding sequence. We further verified that many of these crypTE transcripts are detected in ALS/FTD cortical tissues with TDP-43 pathology. In short, TDP-43 dependent CrypTE events represent a large reservoir of ALS/FTD relevant transcripts and peptides that are not captured by standard assays and analyses.

Project description:TDP-43 is an RNA and DNA binding protein that plays major roles in regulating RNA processing. In particular, TDP-43 dysfunction leads to the accumulation of cryptic splice isoforms that result from improperly spliced mRNAs. In addition to its role in regulating splicing, TDP-43 is also known to regulate the expression of transposable elements (TEs). TEs are mobile genetic elements which comprise a significant proportion of the human genome, but are normally silenced in healthy somatic cells. TEs are interspersed throughout the genome, both in gene-depleted regions and interspersed within gene introns and gene regulatory sequences. We used optimized long-read RNA sequencing assays to generate catalogs of mis-spliced and mis-expressed genes and TEs in human neurons depleted for TDP-43. In addition to known TDP-43 driven cryptic isoforms, we identified hundreds of TDP-43 dependent spliced RNAs formed as part of cryptic gene-TE fusion events that result from mis-splicing of TE sequences into gene transcripts. Among these TDP-43 dependent gene-TE cryptic transcripts (crypTEs), we found: TEs that provide alternate gene promoters/5’UTRs, TEs that act as cassette exons inside host gene mRNAs, as well as TEs that provide alternate transcript 3’ ends. These cryptic gene-TE fusions are predicted to induce: aberrant expression of ALS relevant genes, nonsense mediated decay (NMD) products, as well as novel peptides from gene-TE fusions within the gene coding sequence. We further verified that many of these crypTE transcripts are detected in ALS/FTD cortical tissues with TDP-43 pathology. In short, TDP-43 dependent CrypTE events represent a large reservoir of ALS/FTD relevant transcripts and peptides that are not captured by standard assays and analyses.

Project description:Transactive response DNA-binding protein 43 (TDP-43) is a key factor in maintaining the fidelity of neuronal RNA splicing, and its dysfunction is observed in amyotrophic lateral sclerosis (ALS) and Alzheimer’s disease (AD) with TDP-43 pathology. Although loss of TDP-43 can activate multiple cryptic splicing events, whether specific cryptic exons generate stable and toxic peptides remains unclear. Here, we identify a TDP-43–dependent cryptic splicing event (PKN1-5a1) in the serine/threonine kinase gene PKN1: in transcriptomes of ALS patient brains it is markedly activated, inserting a 127-bp unannotated exon and introducing multiple premature termination codons. We further show that this aberrant transcript can partially escape nonsense-mediated mRNA decay (NMD) and is translated into a truncated peptide, N207; in AD brains with TDP-43 pathology, N207 is also detected by a specific antibody. Functional studies indicate that N207 overexpression impairs cognitive behaviors and weakens synaptic plasticity. These results indicate that cryptic splicing resulting from dysregulated TDP-43 not only causes loss of protein function but can also generate truncated toxic peptides that evade NMD, providing a new molecular-level explanation for the pathogenesis of TDP-43–related proteinopathies.

Project description:The occurrence of extensive cryptic splicing following the depletion of nuclear TDP-43 results in impaired neuronal function and degeneration. Here, we show that oligonucleotides containing CA-repeat sequences can mimic TDP-43 pre-mRNA binding and broadly repress cryptic splicing events, reverse protein loss, and restore neuronal activity in TDP-43-depleted neurons. Our results indicate that (CA)n oligonucleotides are potential therapeutic agents to address global mis-splicing in TDP-43 proteinopathies.

Project description:The occurrence of extensive cryptic splicing following the depletion of nuclear TDP-43 results in impaired neuronal function and degeneration. Here, we show that oligonucleotides containing CA-repeat sequences can mimic TDP-43 pre-mRNA binding and broadly repress cryptic splicing events, reverse protein loss, and restore neuronal activity in TDP-43-depleted neurons. Our results indicate that (CA)n oligonucleotides are potential therapeutic agents to address global mis-splicing in TDP-43 proteinopathies.

Project description:The discovery that TDP-43 mutations cause familial ALS and that many patients display pathological TDP-43 mislocalization has nominated altered RNA metabolism as a potential disease mechanism. Despite its importance, the identity of RNAs regulated by TDP-43 in motor neurons remains poorly understood. Here, we report transcripts whose abundances in human motor neurons are sensitive to TDP-43 depletion. Notably, we found STMN2, which encodes a microtubule regulator, declined after TDP-43 knockdown, in patient-specific motor neurons, following TDP-43 mislocalization, and in the postmortem patient spinal cords. Loss of STMN2 upon reduced TDP-43 function was due to the emergence of a cryptic exon, which is of substantial functional importance, as we further demonstrate that STMN2 is necessary for both axonal outgrowth and repair. Importantly, post-translational stabilization of STMN2 could rescue neurite outgrowth and axon regeneration deficits induced by TDP-43 depletion. We propose restoring STMN2 expression warrants future examination as an ALS therapeutic strategy.

Project description:Through splicing analysis of a publicly available RNA-Seq dataset, we discovered TDP-43 represses a cryptic exon splicing event in UNC13A, a gene that had been associated with FTD/ALS through GWA studies. To confirm the sequences of the cryptic exons, we used shRNA to reduce TDP-43 levels in iPSC-derived motor neurons (iPSC-MNs) and by amplicon sequencing the RT-PCR product, we observed the insertion in cells with TDP-43 depletion but not in control shRNA-treated cells. Through sequence alignment, we verified the sequences of the cryptic exons.

Project description:Nuclear depletion and cytoplasmic aggregation of the RNA-binding protein TDP-43 is the hallmark of ALS, occurring in over 97% of cases. A key consequence of TDP-43 nuclear loss is the de-repression of cryptic exons. Whilst TDP-43 regulated cryptic splicing is increasingly well catalogued, cryptic alternative polyadenylation (APA) events, which define the 3’ end of last exons, have been largely overlooked, especially when not associated with novel upstream splice junctions. We developed a bioinformatic pipeline to reliably identify distinct APA event types: alternative last exons (ALE), 3’UTR extensions (3’Ext) and ‘ composite ’ intronic polyadenylation (IPA) events. We identified novel neuronal cryptic APA sites induced by TDP-43 loss of function by systematically applying our pipeline to a compendium of publicly available and in house datasets. We find that TDP-43 binding sites and target motifs are enriched at these cryptic events and that TDP-43 can have both repressive and enhancing action on APA. Importantly, all categories of cryptic APA can also be identified in ALS and FTD post mortem brain regions with TDP-43 proteinopathy underlining their potential disease relevance. RNA-seq and Ribo-seq analyses indicate that distinct cryptic APA categories have different downstream effects on transcript and translation. Intriguingly, cryptic 3’Exts occur in multiple transcription factors, such as ELK1 , SIX3, and TLX1, and lead to an increase in RNA stability. 3’Exts are localised to the cytoplasm and neurites and translated leading to an increase in wild-type protein levels. In summary, we demonstrate that TDP-43 nuclear depletion induces a novel category of cryptic RNA processing events and we expand the palette of TDP-43 loss consequences by showing this can also lead to an increase in normal protein translation.

Project description:Nuclear depletion and cytoplasmic aggregation of the RNA-binding protein TDP-43 is the hallmark of ALS, occurring in over 97% of cases. A key consequence of TDP-43 nuclear loss is the de-repression of cryptic exons. Whilst TDP-43 regulated cryptic splicing is increasingly well catalogued, cryptic alternative polyadenylation (APA) events, which define the 3’ end of last exons, have been largely overlooked, especially when not associated with novel upstream splice junctions. We developed a bioinformatic pipeline to reliably identify distinct APA event types: alternative last exons (ALE), 3’UTR extensions (3’Ext) and ‘ composite ’ intronic polyadenylation (IPA) events. We identified novel neuronal cryptic APA sites induced by TDP-43 loss of function by systematically applying our pipeline to a compendium of publicly available and in house datasets. We find that TDP-43 binding sites and target motifs are enriched at these cryptic events and that TDP-43 can have both repressive and enhancing action on APA. Importantly, all categories of cryptic APA can also be identified in ALS and FTD post mortem brain regions with TDP-43 proteinopathy underlining their potential disease relevance. RNA-seq and Ribo-seq analyses indicate that distinct cryptic APA categories have different downstream effects on transcript and translation. Intriguingly, cryptic 3’Exts occur in multiple transcription factors, such as ELK1 , SIX3, and TLX1, and lead to an increase in RNA stability. 3’Exts are localised to the cytoplasm and neurites and translated leading to an increase in wild-type protein levels. In summary, we demonstrate that TDP-43 nuclear depletion induces a novel category of cryptic RNA processing events and we expand the palette of TDP-43 loss consequences by showing this can also lead to an increase in normal protein translation.

Project description:Nuclear depletion and cytoplasmic aggregation of the RNA-binding protein TDP-43 is the hallmark of ALS, occurring in over 97% of cases. A key consequence of TDP-43 nuclear loss is the de-repression of cryptic exons. Whilst TDP-43 regulated cryptic splicing is increasingly well catalogued, cryptic alternative polyadenylation (APA) events, which define the 3’ end of last exons, have been largely overlooked, especially when not associated with novel upstream splice junctions. We developed a bioinformatic pipeline to reliably identify distinct APA event types: alternative last exons (ALE), 3’UTR extensions (3’Ext) and ‘ composite ’ intronic polyadenylation (IPA) events. We identified novel neuronal cryptic APA sites induced by TDP-43 loss of function by systematically applying our pipeline to a compendium of publicly available and in house datasets. We find that TDP-43 binding sites and target motifs are enriched at these cryptic events and that TDP-43 can have both repressive and enhancing action on APA. Importantly, all categories of cryptic APA can also be identified in ALS and FTD post mortem brain regions with TDP-43 proteinopathy underlining their potential disease relevance. RNA-seq and Ribo-seq analyses indicate that distinct cryptic APA categories have different downstream effects on transcript and translation. Intriguingly, cryptic 3’Exts occur in multiple transcription factors, such as ELK1 , SIX3, and TLX1, and lead to an increase in RNA stability. 3’Exts are localised to the cytoplasm and neurites and translated leading to an increase in wild-type protein levels. In summary, we demonstrate that TDP-43 nuclear depletion induces a novel category of cryptic RNA processing events and we expand the palette of TDP-43 loss consequences by showing this can also lead to an increase in normal protein translation.