Project description:We established several iPSCs from healthy donors, familial ALS (FALS) patients, and sporadic ALS (SALS) patients. Using our differentiation protocol originally developed, we differentiated these iPSCs toward spinal motor neurons (MNs) and reproduced ALS pathology in a dish. In addition, we screened a drug candidate which suppressed the detected ALS-related phenotypes of these ALS models. For clarifying the molecular mechanisms of the ALS pathologies and the screened drug, we used microarrays to detail the global program of gene expression reflecting the MN pathology of FALS/SALS, and carefully compared with healthy donors and/or drug-treated ALS models based on their expression profiles.

Project description:Knowledge about the nature and timepoint of pathomolecular alterations preceding onset of symptoms in amyotrophic lateral sclerosis (ALS) is largely lacking. It could not only pave the way for valuable therapeutic targets but might also govern future concepts of pre-manifest disease modifying treatments. MicroRNAs (miRNAs) are central regulators of transcriptome plasticity and participate in pathogenic cascades and/or mirror cellular adaptation to insults. We obtained expression profiles of miRNAs as well as other non-coding RNAs (ncRNAs) in the serum of sporadic ALS patients (sALS), familial ALS cases (fALS), asymptomatic mutation carriers and healthy controls. We observed a strikingly homogenous ncRNA profile in fALS patients that, to a large extend, was independent to the underlying disease gene and different to heterogeneous ncRNA signatures in sALS patients. Moreover, we identified 68 significantly dysregulated ncRNAs in pre-manifest ALS mutation carriers, more than 20 years before the estimated time window of disease onset. 91% of ncRNA alterations in mutation carriers overlapped with the fALS patients revealing progressive changes towards and during the disease. Our data thus demonstrate a high epigenetic heterogeneity amongst sALS patients and suggest common denominators regarding molecular pathogenesis of different ALS genes. We describe the earliest pathomolecular alterations in ALS known to date, which provide a basis for the development of predictors of disease onset as well as the discovery of novel therapeutic targets and strongly argue for studies evaluating pre-symptomatic disease-modifying treatment in ALS. Serum ncRNA pofiles of sporadic and familiar ALS patients as well as asymptomatic ALS mutation carriers were compared to age and gender matched healthy controls using a total of 53 Affymetrix miRNA 3.0 arrays. In detail, a total of 9 fALS patients (analyzed in 6 arrays) were compared to 10 controls, a total of 18 ALS mutation carriers (analyzed in 12 arrays) were compared to 8 controls and 18 sALS patients were compared to 16 controls.

Project description:We established iPSCs from healthy donors, SOD1-ALS and TDP43-ALS patients. Using our differentiation protocol originally developed by Reinhardt et al.,2013, we diferentiated these iPSCs toward spinal motor neurons (MNs) and reproduce ALS pathology in a dish. To extend our understanding of finding different molecular mechanisms and pathways related to SOD1- and TDP43 mutations in ALS disease, we have performed a comprehensive gene expression profiling study using RNA-Seq of the iPSC-derived MN models from control individuals and carefully compared with those from SOD1-ALS and TDP43-ALS patients. To generate novel hypotheses of putative underlying molecular mechanisms in ALS, we used human induced pluripotent stem cell (hiPSCs)-derived motor neurons (MNs) from SOD1- and TARDBP (TDP-43 protein)-mutant-ALS patients and healthy controls to perform high-throughput RNA-sequencing (RNA-Seq). An integrated bioinformatics approach was employed to identify differentially expressed genes (DEGs) and key pathways underlying these familial forms of the disease (fALS). In TDP43-ALS, we found dysregulation of transcripts encoding components of the transcriptional machinery and transcripts involved in splicing regulation were particularly affected. In contrast, less is known about the role of SOD1 in RNA metabolism in motor neurons. Here we found that many transcripts relevant for mitochondrial function were specifically altered in SOD1-ALS, indicating transcriptional signatures and expression patterns can vary significantly depending on the causal gene that is mutated. Surprisingly, however, we identified a clear downregulation of genes involved in protein translation in SOD1-ALS suggesting that ALS-causing SOD1 mutations shift cellular RNA abundance profiles to cause neural dysfunction. Altogether, we provided here an extensive profiling of mRNA expression in two ALS models at the cellular level, corroborating the major role of RNA metabolism and protein translation as a common pathomechanism in ALS

Project description:Amyotrophic lateral sclerosis (ALS) has been linked to nucleoporin loss in patient neurons. In the ESCRT-III pathway, CHMP7 protein accumulation in the nucleus triggers ALS by damaging nuclear pores and disrupting cellular transport. Genes controlling CHMP7's nuclear presence remain unidentified. Our Craft-ID analysis revealed that RNA binding proteins involved in assembling small nuclear ribonucleoprotein particles control CHMP7 nuclear localization. This regulation ultimately impacts splicing processes and can lead to pore injury. Using IP-MS, we discovered that CHMP7 interacts with the survival of motor neuron (SMN) complex (SmD1-3, Gemins), mediated by U1 snRNP and direct interactions between CHMP7. Reducing expression of the core SMN complex component SmD1 was observed in ALS iPSC- Motor Neurons (MNs), affecting CHMP7 localization. However, restoring its levels can rescue the cytoplasmic localization of CHMP7 in sALS iPSC-MNs. Our discoveries hint at an early ALS pathway involving SMN core complex dysregulation, influencing disease onset.

Project description:Amyotrophic lateral sclerosis (ALS) has been linked to nucleoporin loss in patient neurons. In the ESCRT-III pathway, CHMP7 protein accumulation in the nucleus triggers ALS by damaging nuclear pores and disrupting cellular transport. Genes controlling CHMP7's nuclear presence remain unidentified. Our Craft-ID analysis revealed that RNA binding proteins involved in assembling small nuclear ribonucleoprotein particles control CHMP7 nuclear localization. This regulation ultimately impacts splicing processes and can lead to pore injury. Using IP-MS, we discovered that CHMP7 interacts with the survival of motor neuron (SMN) complex (SmD1-3, Gemins), mediated by U1 snRNP and direct interactions between CHMP7. Reducing expression of the core SMN complex component SmD1 was observed in ALS iPSC- Motor Neurons (MNs), affecting CHMP7 localization. However, restoring its levels can rescue the cytoplasmic localization of CHMP7 in sALS iPSC-MNs. Our discoveries hint at an early ALS pathway involving SMN core complex dysregulation, influencing disease onset.

Project description:iPSC-derived motor neurons form sporadic ALS and Controls. 4 sALS iPSC lines and 4 Ctrl iPSC lines.

Project description:Despite the discovery of many genetic risk factors, the cause of the motor neuron death that drives terminal pathology in Amyotrophic Lateral Sclerosis (ALS) remains unknown. We report that the skeletal muscle of ALS patients secretes exosomal vesicles that are specifically toxic to motor neurons. This could not be attributed to a trivial down-stream consequence of muscle denervation. In a study of muscle biopsies and biopsy-derived denervation-naïve differentiated muscle stem cells (myotubes) from 67 human subjects, including healthy and disease controls, ALS myotubes had a consistent signature of disrupted exosome biogenesis and RNA-processing, and their exosomes induced shortened, less branched, neurites, greater death, and disrupted localization of RNA and RNA-processing proteins in motor neurons. Toxicity was dependent on presence of the FUS protein, which is highly expressed in recipient motor neurons. As part of this work, we carried out gene expression analysis of myotubes (differentiated myoblasts) comparing ALS against two other motor neuron disorders as disease controls (SBMA, Spinal and bulbar muscular atrophy; and Spinal Muscular Atrophy Type 4, SMA-IV) and healthy controls.

Project description:Sporadic amyotrophic lateral sclerosis (sALS) is the most common (~90%) form of ALS. There are no animal models of sALS and exact molecular mechanisms remain elusive. Here, we elucidate gene-expression profiles in laser capture microdissected enriched surviving motor neurons (MNs) from sALS lumbar spinal cords in patients who had rostral onset and caudal progression. A strong signature was detected and immunological signals were computationally filtered. The filtered dataset showed clustering groups that were significantly explained by levels of phosphorylated TDP-43 (pTDP-43). Transcriptome-pathology correlations and enhanced crosslinking and immunoprecipitation combined with sequencing (eCLIP-seq) identified that Casein kinase 1ε (CSNK1E) had the highest correlation with pTDP-43 status and TDP-43 binding in its 3’UTR. Furthermore, CSNK1E interacted with TDP-43 on protein level and its overexpression lead to increased cytoplasmic pTDP-43 accumulations in iPSC-MNs, suggesting CSNK1E directly mediates TDP-43 phosphorylation. Therefore, we report an essential framework for molecular disease classification and transcriptome – pathology correlation in sALS to identify candidate genes for elucidating disease mechanisms and potential therapeutic interventions.

Project description:Amyotrophic lateral sclerosis (ALS) is an incurable neurological disease featuring progressive loss of motor neuron (MN) function in the brain and spinal cord. Mutations in TARDBP, encoding the RNA-binding protein TDP-43, are one cause of ALS and TDP-43 mislocalization in MNs is a key pathological feature of >95% of ALS cases. While numerous studies support altered RNA regulation by TDP-43 as a major cause of disease, specific changes within MNs that trigger disease onset remain unclear. Here, we combined Translating Ribosome Affinity Purification (TRAP) with RNA sequencing to identify molecular changes in spinal MNs of TDP-43–driven ALS at motor symptom onset. By comparing the MN translatome of hTDP-43A315T mice to littermate controls and to mice expressing wildtype hTDP-43, we identify hundreds of mRNAs that were selectively up- or downregulated in MNs. We validated effects on Tex26, Syngr4, and Plekhb1 mRNAs in an independent TRAP experiment. Moreover, by quantitative immunostaining of spinal cord MNs we found corresponding protein level changes for SYNGR4 and PLEKHB1. We also observed these changes in spinal MNs of an independent ALS mouse model caused by a different patient mutant allele of TDP-43, suggesting that they may be a general feature of TDP-43-driven ALS. Thus, we have identified two new proteins deregulated in MNs at motor symptom onset in TDP-43-driven ALS models. This spatial and temporal pattern suggests that deregulation of these proteins could be functionally important for driving the transition to the symptomatic phase of disease.

Project description:Heterogeneous and predominantly sporadic neurodegenerative diseases such as amyotrophic lateral sclerosis (ALS) remain highly challenging to model. Patient-derived induced pluripotent stem cell (iPSC) technologies offer great promise for these diseases, however large-scale studies demonstrating accelerated neurodegeneration from sporadic patients are limited. We generated an iPSC library from 100 sporadic ALS (SALS) patients and conducted population-wide phenotypic screening. SALS patient-derived motor neurons recapitulated key aspects of SALS, including reduced survival, accelerated neurite degeneration correlating with donor survival, transcriptional dysfunction, and pharmacological rescue by riluzole. Here we sought to determine if riluzole treatment reversed the disease process in patient-derived motor neurons by RNAseq profiling of riluzole treated vs untreated motor neurons from 9 ALS donors.