Project description:Aims: Loss of nuclear TDP-43 characterises sporadic and most familial forms of amyotrophic lateral sclerosis (ALS). TDP-43 (encoded by TARDBP) has multiple roles in RNA processing. We aimed to determine whether 1) RNA splicing dysregulation is present in lower motor neurons in ALS and in a motor neuron-like cell model, and 2) TARDBP mutations (mtTARDBP) are associated with aberrant RNA splicing using patient-derived fibroblasts. Methods: Affymetrix exon arrays were used to study mRNA expression and splicing in lower motor neurons obtained by laser capture microdissection of autopsy tissue from individuals with sporadic ALS and TDP-43 proteinopathy. Findings were confirmed by qRT-PCR and in NSC34 motor neuronal cells following shRNA-mediated TDP-43 depletion. Exon arrays and immunohistochemistry were used to study mRNA splicing and TDP-43 expression in fibroblasts from patients with mtTARDBP-associated, sporadic and mutant SOD1-associated ALS. Results: We found altered expression of spliceosome components in motor neurons and widespread aberrations of mRNA splicing that specifically affected genes involved in ribonucleotide binding. This was confirmed in TDP-43 depleted NSC34 cells. Fibroblasts with mtTARDBP showed loss of nuclear TDP-43 protein and demonstrated similar changes in splicing and gene expression, that were not present in fibroblasts from patients with sporadic or SOD1-related ALS. Conclusion: Loss of nuclear TDP-43 is associated with RNA processing abnormalities in ALS motor neurons, patient-derived cells with mtTARDBP, and following artificial TDP-43 depletion, suggesting that splicing dysregulation directly contributes to disease pathogenesis. Key functional pathways affected include those central to RNA metabolism. RNA was extracted from lower motor neurons obtained by laser capture microdissection from autopsy material from neurologically healthy controls (n=6) and cases of sporadic ALS (n=3) and ALS due to C9ORF72 mutations (n=3).

Project description:To clarify the functional properties of Tdp-43, we established the differentially expressed alternative exons in Tdp-43-silenced primary cortical neurons by using exon-sensitive microarray technology. We analyzed total RNA of primary motor neuron infected with lentivirus expressing shRNA against mouse Tdp-43 or control. RNA was harvested 11 days after transfection.

Project description:UNC13A contains a novel cryptic exon which is expressed upon TDP-43 knockdown. However, it also features TDP-43 regulated intron retention of a downstream intron. To investigate the correlation of these two events, we performed Nanopore sequencing of amplicons from SHSY5Y cells with inducible TDP-43 knockdown, and FTD patient RNA samples

Project description:We identify the RNA targets of TAR DNA-binding protein 43 (TDP-43) from cortical neurons by RNA immunoprecipitation followed by deep sequencing (RIP-seq). We identify 4352 highly enriched RNA targets of TDP-43. We determined that the canonical TDP-43 binding site (TG)n was 55.1-fold enriched in our TDP-43 library. Moreover, our analysis shows there is often an adenine in the middle of the motif, (TG)nTA(TG)m. TDP-43 RNA targets are particularly enriched for Gene Ontology terms related to RNA metabolism, neuronal development, and synaptic function. Examination of TDP-43 RNA targets in rat cortical neurons by RIP-seq. Chantelle F. Sephton isolated the TDP-43:RNA complexes and generated the cDNA library for deep sequencing. Email: chantelle.sephton@utsouthwestern.edu Phone: 214-648-4119 Fax: 214-648-1801 ULR: http://www8.utsouthwestern.edu/utsw/cda/dept120915/files/151135.html Organization name: University of Texas Southwestern Medical Center at Dallas Department: Neuroscience Lab: Gang Yu lab Street: 6000 Harry Hines Blvd. City: Dallas State: Texas ZIP: 75390 Country: USA

Project description:Transactive response DNA-binding protein of 43 kDa (TDP-43), a heterogeneous nuclear ribonucleoprotein (hnRNP) with diverse activities, is a common denominator in several neurodegenerative disorders including amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD). Orthologs of TDP-43 exist from mammals to invertebrates, but their functions in lower organisms remain poorly understood. Here we systematically studied mutant Caenorhabditis elegans lacking the nematode TDP-43 ortholog, TDP-1. To understand the global gene expression regulation induced by the loss of tdp-1, the C. elegans transcriptomes were compared between the N2 WT animals and the tdp-1(ok803lf) mutant. Transcriptional profiling demonstrated that the loss of TDP-1 altered expression of genes functioning in RNA processing and protein folding. These results suggest that the C. elegans TDP-1 as an RNA-processing protein may have a role in the regulation of protein homeostasis and aging. Global gene expression profiling was performed to compare the transcriptome of wild-type (N2) Caenorabditis elegans and that of tdp-1(ok803) loss-of-function mutant. We analyzed mixed stages of Caenorabditis elegans, wild-type N2 versus tdp-1(ok803), using the Affymetrix C. elegans genome array. Three biological replicates were performed.

Project description:MicroRNAs (miRNAs) play important roles in a wide range of cellular processes. Aberrant regulation of miRNA genes contributes to human diseases, including cancer. The TAR DNA binding protein 43 (TDP-43), a DNA/RNA binding protein associated with neurodegeneration, is involved in miRNA biogenesis. Here, we systematically examined miRNAs whose expression levels are regulated by TDP-43 using RNA-Seq coupled with siRNA-mediated knockdown approach. TDP-43 knocking down affected the expression of a number of miRNAs. Alterations in isomiR patterns and miRNA arm selection after TDP-43 knockdown suggest a role of TDP-43 in miRNA editing. We examined correlation of selected TDP-43 associated miRNAs and their candidate target genes in human cancers. Our data reveal highly complex roles of TDP-43 in regulating different miRNAs and their target genes. Our results suggest that TDP-43 may promote migration of lung cancer cells by regulating miR-423-3p expression. On the other hand, TDP-43 increases miR-500a-3p expression and binds to the mature miR-500a-3p sequence. Low expression of miR-500a-3p was associated with poor survival of lung cancer patients, suggesting that TDP-43 may have a suppressive role in cancer by regulating miR-500a-3p. Our experiments reveal that cancer-associated genes LIF and PAPPA may be targets of miR-500a-3p. Together with other studies, our work suggests that TDP-43-regulated miRNAs may play multi-facet roles in the pathogenesis of cancer. small RNA seq in SH-SY-5Y, SNB-19 and HT22 (TDP-43 siRNA VS Control siRNA)

Project description:Exploring the intricate link between sleep and brain degeneration holds great promise for the development of effective therapeutics. Here we provide novel insights into the role of TDP-43 and Atx2 in regulating sleep and neurodegeneration using Drosophila. We demonstrate that expression of TDP-43 severely disrupts sleep, resulting in reduced sleep duration of the affected animals. Sleep disruption by TDP-43 is completely rescued by Atx2 knockdown. To unravel the underlying mechanism of TDP43 sleep disruption and Atx2-mediated rescue, we conducted brain RNA sequencing analysis from flies expressing TDP-43 with or without Atx2 knockdown. Among RNAseq changes, we observed upregulation of genes associated with small molecule metabolism with TDP-43 expression, followed by their subsequent downregulation upon Atx2 knockdown. Utilizing these Atx2-regulated genes, we conducted an RNAi screen to identify additional sleep modifiers that interact with TDP-43.

Project description:Through substitution mapping studies, we previously identified that a <330kb region from a rat strain with no renal pathology (the Lewis rat), which when introgressed onto the genetic background of a rat with renal disease (the Dahl Salt-sensitive (S) rat), caused an increase rather than the expected decrease in proteinuria. The purpose of this study was to prioritize a candidate gene and further delineate the mechanism underlying the observed increased in proteinuria. A higher level of proteinuria independent of dietary salt was observed in the congenic rat at a very young age (50-52 day old). The critical congenic segment was further mapped to <42.5kb containing a single candidate gene, rififylin. Rififylin was expressed 1.59 fold higher in the congenic strain compared with S. Overexpression of rififylin is known to delay recycling of endosomes. Renal transcriptome analysis indicated that Atp1a1 one of the most highly differentially expressed genes. Atp1a1 was 5.33 fold higher in the congenic strain compared with S. The protein product of Atp1a1, the alpha subunit of Na+K+ATPase, was also significantly higher in the endosomes of proximal tubules from the congenic strain compared with S. To determine whether the higher amounts of this protein in the endosomes is due to a delay in recycling of endosomes caused by the overexpression of rififylin in the congenic strain, recycling of exogenously labeled-transferrin by single cell cultures of proximal tubules was monitored by confocal microscopy. Recycling of transferrin was significantly delayed in the congenic strain compared with S. These results suggest that impaired endosomal recycling in the proximal tubules from the congenic strain caused by the overexpression of rififylin is a novel molecular mechanism linked to the observed increase in proteinuria of the congenic strain.

Project description:TDP-43 is a key splicing regulator. Here, we perform ribosome profiling on iPSC-derived neurons to examine how translation is affected by TDP-43 knockdown.

Project description:In this study, we discovered that TDP-43 expression followed a rhythmic pattern, which was influenced by sleep deprivation. Knockdown of TDP-43 altered the mRNA and protein expression of multiple circadian genes, including BMAL1, CLOCK, CRY1, and PER2. Furthermore, TDP-43 knockdown affected the autonomous circadian wheel behavior, as well as the cognitive and balance abilities of mice. We also revealed that TDP-43 regulated the deubiquitination of BMAL1 by influencing the alternative splicing of USP13, thereby affecting the expression of USP13 and the ubiquitin-mediated degradation of BMAL1. Additionally, TDP-43 modulated the AMPK signaling pathway, leading to changes in cellular glucose uptake and ATP production.