#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Genome wide analysis reveals heparan sulfate epimerase modulates TDP-43 proteinopathy


Authors: Nicole F. Liachko aff001;  Aleen D. Saxton aff001;  Pamela J. McMillan aff003;  Timothy J. Strovas aff001;  C. Dirk Keene aff004;  Thomas D. Bird aff001;  Brian C. Kraemer aff001
Authors place of work: Geriatrics Research Education and Clinical Center, Veterans Affairs Puget Sound Health Care System, Seattle, Washington, United States of America aff001;  Division of Gerontology and Geriatric Medicine, Department of Medicine, University of Washington, Seattle, Washington, United States of America aff002;  Department of Psychiatry and Behavioral Sciences, University of Washington, Seattle, Washington, United States of America aff003;  Department of Pathology, University of Washington, Seattle, Washington, United States of America aff004;  Department of Neurology, University of Washington, Seattle, Washington, United States of America aff005;  Division of Medical Genetics, Department of Medicine, University of Washington, Seattle, Washington, United States of America aff006
Published in the journal: Genome wide analysis reveals heparan sulfate epimerase modulates TDP-43 proteinopathy. PLoS Genet 15(12): e32767. doi:10.1371/journal.pgen.1008526
Category: Research Article
doi: https://doi.org/10.1371/journal.pgen.1008526

Summary

Pathological phosphorylated TDP-43 protein (pTDP) deposition drives neurodegeneration in amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD-TDP). However, the cellular and genetic mechanisms at work in pathological TDP-43 toxicity are not fully elucidated. To identify genetic modifiers of TDP-43 neurotoxicity, we utilized a Caenorhabditis elegans model of TDP-43 proteinopathy expressing human mutant TDP-43 pan-neuronally (TDP-43 tg). In TDP-43 tg C. elegans, we conducted a genome-wide RNAi screen covering 16,767 C. elegans genes for loss of function genetic suppressors of TDP-43-driven motor dysfunction. We identified 46 candidate genes that when knocked down partially ameliorate TDP-43 related phenotypes; 24 of these candidate genes have conserved homologs in the human genome. To rigorously validate the RNAi findings, we crossed the TDP-43 transgene into the background of homozygous strong genetic loss of function mutations. We have confirmed 9 of the 24 candidate genes significantly modulate TDP-43 transgenic phenotypes. Among the validated genes we focused on, one of the most consistent genetic modifier genes protecting against pTDP accumulation and motor deficits was the heparan sulfate-modifying enzyme hse-5, the C. elegans homolog of glucuronic acid epimerase (GLCE). We found that knockdown of human GLCE in cultured human cells protects against oxidative stress induced pTDP accumulation. Furthermore, expression of glucuronic acid epimerase is significantly decreased in the brains of FTLD-TDP cases relative to normal controls, demonstrating the potential disease relevance of the candidate genes identified. Taken together these findings nominate glucuronic acid epimerase as a novel candidate therapeutic target for TDP-43 proteinopathies including ALS and FTLD-TDP.

Keywords:

Caenorhabditis elegans – RNA interference – Motor proteins – Phosphorylation – Suppressor genes – Genetic screens – Amyotrophic lateral sclerosis – Motor neurons

Introduction

Amyotrophic lateral sclerosis (ALS) is a devastating neurodegenerative disease characterized by loss of motor neurons, leading to progressive muscle wasting and death typically by respiratory failure. Aggregates of the protein TDP-43 in disease-affected neurons are the hallmark of most cases of ALS, while mutations in the gene coding for TDP-43, TARDBP, have been identified in ~4% of families with heritable ALS directly linking TDP-43 dysfunction with disease [1]. TDP-43 is also the primary aggregating protein in about 50% of cases of frontotemporal lobar degeneration (FTLD-TDP) [2]. Furthermore, TDP-43 positive aggregates occur as secondary pathologies in a subset of other neurodegenerative diseases including Alzheimer’s disease (AD) [3]. The presence of TDP-43 co-pathology correlates with a greater likelihood of clinical dementia and more rapid cognitive decline after diagnosis, indicating the presence or absence of pathological TDP-43 influences disease severity [4, 5]. Given the prevalence of TDP-43 pathology in neurodegenerative diseases, it is critical to understand the molecular pathways that interact with TDP-43 and promote disease.

Within inclusions in disease-affected neurons, TDP-43 exhibits post-translational modifications not observed in healthy neurons, including shorter C-terminal protein species, ubiquitination, acetylation, SUMOylation, and phosphorylation [69]. Of these modifications, abnormal phosphorylation of TDP-43 represents the most consistent pathological feature of ALS and FTLD-TDP; pTDP is used as a neuropathological marker to identify TDP-43-positive protein inclusions in brain and spinal cord post-mortem [10]. Phosphorylation at S409/410 of TDP-43 (pTDP) potentiates a number of toxic disruptions in normal TDP-43 metabolism, including decreased TDP-43 protein turnover, increased TDP-43 stabilization, cellular mislocalization of TDP-43, protein aggregation, and neurodegeneration [1116]. Phosphorylation may also alter the ability of TDP-43 to appropriately participate in liquid-liquid phase separated membrane-less organelles or granules [17, 18].

Unbiased molecular genetic screens in a variety of model systems provide a powerful way to identify novel modifiers of proteinopathy driven neurodegeneration and to elucidate key cellular pathways that contribute to disease [1926]. Several reverse genetic screens targeting pathological TDP-43 have been performed in model systems including yeast, Drosophila, and cultured cells [2733], and have nominated TDP-43 modifiers including ataxin 2, Dbr1, ITPR1, Wnd, p38, JNK, GSK, hat-trick, xmas-2, hnRNPs, and TCERG1, among others. These modifiers implicate diverse pathways affecting disease, including polyglutamine repeat size, RNA lariat debranching, mRNA splicing and export, nucleocytoplasmic shuttling, innate immunity, chromatin remodeling, and TDP-43 autoregulation. These screens differ in their methods of modeling TDP-43 toxicity as well as the readouts for suppression or enhancement of phenotypes. Moreover, the hits identified among them are also predominantly non-overlapping indicating these screens have not saturated the identification of TDP-43 modifiers. It is likely that additional screening may identify new modifiers with relevance to TDP-43 mechanisms of disease.

To model TDP-43 proteinopathy, we previously developed a Caenorhabditis elegans model that expresses full-length familial ALS (fALS) mutant TDP-43 pan-neuronally [16]. C. elegans provides a tractable, simple model useful for genetic manipulations, behavioral assays, biochemistry, in vivo imaging, and large-scale screening. Importantly, they also have a well-characterized differentiated nervous system that includes the major neuronal types found in humans [34]. TDP-43 transgenic C. elegans (TDP-43 tg) exhibit phosphorylation of TDP-43 at S409/410, accumulation of insoluble TDP-43, severe motor abnormalities, neurodegeneration, and shortened lifespan [16]. In C. elegans, prevention of phosphorylation at S409/410 protects against TDP-43 neurotoxic phenotypes.

Using this C. elegans model of ALS, we have conducted a genome-wide RNAi screen for genes that control TDP-43-driven phenotypes. This is the first large-scale genetic screen in C. elegans for TDP-43 modifying genes. From this work, we have identified genetic suppressors of TDP-43 neurotoxicity that fall into a variety of molecular categories. Finally, we have shown that the extracellular matrix modifying enzyme HSE-5/ GLCE impacts TDP-43 pathology and is decreased in FTLD-TDP.

Results

To identify genes and molecular pathways that modify TDP-43 toxicity, we performed an unbiased genome-wide RNAi screen in a C. elegans model of TDP-43 proteinopathy. This model expresses human fALS mutant TDP-43 (M337V) pan-neuronally (TDP-43 tg) and exhibits robust progressive motor dysfunction [16]. We used this phenotype to screen for visible suppression of motor dysfunction following RNAi-mediated gene inactivation. 16,757 RNAi clones, targeting 86% of the C. elegans genome [35], were individually screened for changes in behavior relative to control treated animals (Fig 1A). Following first-pass screening for candidate suppressors of TDP-43 tg motor dysfunction, hits were retested in non-transgenic C. elegans to eliminate those that affect C. elegans movement independent of TDP-43. Candidates with no effects on non-transgenic C. elegans were then retested against TDP-43 tg C. elegans in three biological replicate experiments to confirm the initial screen results. After the retesting of first-pass hits, 46 suppressor RNAi clones were identified that consistently improved motor function (Table 1 and Supplemental Table 1). While all the RNAi targets identified are potentially interesting TDP-43 modifiers, we prioritized candidates with translational relevance to human disease for follow-up experiments. To this end, we surveyed for conserved human homologs of candidate genes using the NCBI basic local alignment search tool (BLAST) [36]. Of the TDP-43 tg modifying genes, we found 24 suppressors with significant homology to human genes (Table 1). These gene lists were then annotated for roles in vivo using both searches of published literature and predictive gene functions from protein domain architecture. These genes fall into several functional classes, including genes involved in energy production and metabolism (cox-10, F23F12.3, F55G1.5, paqr-1, and cox-6A), extracellular matrix and cytoskeleton (col-89, gly-8, hse-5, sax-2, vab-9, and zig-3), ion transport (cnnm-3, C13B4.1, unc-77), nucleic acid function (dna-2, tbx-11, umps-1), proteostasis (C47E12.3, gpx-7, pcp-5), and signaling (F31E3.2, F40B5.2, Y44E3A.4) (Fig 1B). As RNAi-mediated inactivation of these genes partially suppressed toxic TDP-43 phenotypes, their normal cellular functions may promote TDP-43 toxicity, making them potential targets for treating TDP-43 proteinopathy.

Tab. 1. TDP-43 modifying genes with human homologs.
TDP-43 modifying genes with human homologs.
Fig. 1. Genome-wide RNAi screen identifies TDP-43 suppressors in several functional categories.
Genome-wide RNAi screen identifies TDP-43 suppressors in several functional categories.
(A) Flowchart of the RNAi screen for modifiers of TDP-43-induced uncoordinated locomotion (Unc). (B) Percentage of suppressors identified in each functional group. Genes with no significant alignment within the human genome were not classified into functional groups.

RNAi is a rapid and powerful tool to decrease gene expression in vivo. However, a single RNAi clone has the potential to target multiple genes simultaneously if the genes have a stretch of identical nucleotide sequence. Thus, we used genetic loss-of-function mutations in candidate genes to confirm RNAi phenotypes. 15 existing C. elegans null mutations were available for candidate modifiers with human homologs (Table 2). We also selected two null mutations for testing from the candidates without human homologs. This cohort of mutants includes alleles from at least one gene per functional category, allowing us to test the contribution of these gene classes to TDP-43 phenotypes. Each of these mutant strains were crossed to TDP-43 tg C. elegans to evaluate changes in motor dysfunction. For genes that were present on the same chromosome as our primary TDP-43 tg transgenic strain (chromosome IV), we crossed to another fALS mutant TDP-43 (A315T) transgenic strain with the TDP-43 expression cassette integrated into a different chromosome (chromosome II), TDP-43 tg2. We observed significant improvement in locomotion, consistent with the RNAi screening results, in 9 of the 17 loss of function cross strains (Fig 2A and 2B, Table 2).

Tab. 2. Loss of function mutations in TDP-43 modifier genes.
Loss of function mutations in TDP-43 modifier genes.
Fig. 2. Suppressors of TDP-43 improve C. elegans motor function and reduce levels of toxic TDP-43.
Suppressors of TDP-43 improve <i>C</i>. <i>elegans</i> motor function and reduce levels of toxic TDP-43.
(A) Motor function of animals doubly homozygous for the human mutant TDP-43 (M337V) transgene, TDP-43 tg, and loss-of-function mutations for the indicated suppressor genes was assessed. Dispersal velocity of developmentally staged L4 larvae was measured by calculating the radial distance traveled from a designated central starting point over time, N>200 for all strains tested. Significance was evaluated using one-way analysis of variance with Tukey’s multiple comparison test among strains tested. ***p<0.0001, *p<0.01 versus TDP-43 tg. non-Tg (N2) animals move 3.712 μm/ sec. (B) To assay the effects of loss-of-function mutations in suppressor genes present on the same chromosome as the TDP-43 tg transgene (Chr IV), a second human mutant TDP-43 (A315T) transgene was utilized on a different chromosome (Chr II), TDP-43 tg2. Animals doubly homozygous for the TDP-43 tg2 transgene and loss-of-function mutations for the TDP-43 suppressor genes indicated were assessed for motor function as above, N>200 for all strains tested. ***p<0.0001, **p<0.001, *p<0.01 versus TDP-43 tg2. (C-G) Measurement of levels of total and phosphorylated TDP-43 protein by immunoblot. Data shown are representative of triplicate independent experiments. Graphs plot relative total TDP-43 or phosphorylated TDP-43 signal normalized to tubulin protein levels from three or more independent replicate experiments. Significance was evaluated using Mann-Whitney test between strains tested. *p<0.05.

Improvements in TDP-43 tg C. elegans motor dysfunction could be the result of decreased TDP-43 transgene expression, or reduced levels of total TDP-43 protein or phosphorylation at amino acid residues S409 and S410 [16]. To determine if TDP-43 mRNA expression levels were altered in these strains, we performed quantitative reverse-transcription PCR (qRT-PCR) and found that expression of the TDP-43 is not decreased in the mutant strains (S1A and S1B Fig). Therefore, we tested whether the suppressor mutants crossed to TDP-43 tg exhibited changes in TDP-43 protein abundance or phosphorylation by immunoblot. We found that 5 of the mutants tested had decreased levels of total or phosphorylated TDP-43 protein (Fig 2C–2G). Interestingly, these results indicate the remaining 4 suppressor genes that improve TDP-43 motor dysfunction do so without a significant impact on TDP-43 phosphorylation or protein levels (S1 Fig).

Based on its predicted function and consistent partial suppression of TDP-43 tg motor phenotypes in C. elegans, we chose hse-5 for more detailed characterization. hse-5(tm472) animals have similar locomotion to non-Tg (N2) C. elegans (S2A Fig), indicating the improved motility of TDP-43 tg; hse-5(tm472) is not due to hyperactivity. hse-5(tm472) was initially identified as a suppressor of mutant human TDP-43 (M337V). To see whether it can also suppress wild-type TDP-43 toxicity, we crossed hse-5(tm472) with C. elegans expressing wild-type human TDP-43 pan-neuronally (WT TDP-43 tg; hse-5(tm472)) and assayed their motor function. We found that hse-5(tm472) can also suppress motility defects of WT TDP-43 tg (S2B Fig). To explore the possibility that hse-5 generally protects against aggregating or hyperphosphorylated neurodegenerative disease proteins, we crossed hse-5(tm472) with C. elegans expressing wild-type or mutant tau protein (tau tg (WT); hse-5(tm472) or tau tg (V337M); hse-5(tm472)). However, hse-5(tm472) did not suppress tau tg motor defects (S2C and S2D Fig), and conversely somewhat worsened tau tg motility. Therefore, hse-5(tm472) may be a specific suppressor of TDP-43.

Although predominantly expressed in the hypodermis and intestine, hse-5 has been previously shown in C. elegans to control axon pathfinding, and loss of hse-5 function (hse-5(tm472)) causes nerve cord defasciculation, aberrant axonal branching and extra processes [37, 38]. In addition, hse-5 may regulate the connectivity of neurons controlling stereotyped behaviors such as C. elegans male mating [39]. The human homolog of hse-5, GLCE, encodes the heparan sulfate-modifying enzyme glucuronic acid epimerase (GLCE). As a linear polysaccharide, heparan sulfate (HS) can be covalently attached to a protein core to form proteoglycans. HS proteoglycans play roles in both cellular and extracellular functions: they comprise part of the basement membrane matrix, are present in secretory vesicles, interact with regulatory factors such as cytokines and growth factors, facilitate cell-cell and cell-ECM interactions, and act as receptors for numerous signaling processes [40]. GLCE catalyzes the inversion stereochemistry of D-glucuronic acid to L-iduronic acid, which increases the flexibility of HS and promotes HS mediated ligand interaction and cellular signaling [41]. GLCE is an essential enzyme, and its targeted disruption results in murine neonatal lethality [42]. Additionally, loss of GLCE has been shown to promote neuritogenesis, supporting a neuronal role for this protein [43].

hse-5(tm472) may protect against TDP-43 neurotoxicity through a pro-longevity pathway. Therefore, we assayed whether hse-5(tm472) protects against the shortened lifespan of TDP-43 tg C. elegans. Surprisingly, hse-5(tm472) was significantly long-lived relative to non-Tg C. elegans, but did not rescue the shortened lifespan of TDP-43 tg (S2E Fig). TDP-43 tg animals display degeneration of specific neuronal types with aging, including gamma-aminobutyric acid (GABA) positive inhibitory motor neurons [16]. hse-5(tm472) may directly protect neuron cell viability, resulting in the improved movement observed in Fig 2A. C. elegans neuronal integrity can be assessed in vivo using a GABAergic D-type motor neuron reporter, Punc-47::GFP, which drives expression of GFP in all 19 D-type motor neurons [44]. To determine whether motor neurons are protected in TDP-43 tg; hse-5(tm472) animals, we used the Punc-47::GFP fluorescent reporter to score intact GABAergic motor neurons in vivo. We first scored animals at larval stage 4 (L4), when the first apparent neuronal loss occurs with TDP-43 tg. Surprisingly, we found that TDP-43 tg; hse-5(tm472) on average lost significantly more neurons than TDP-43 tg alone (Fig 3A). However, by day 1 of adulthood, there are no significant differences in numbers of neurons lost between TDP-43 tg and TDP-43 tg; hse-5(tm472) (Fig 3B). Therefore, the behavioral improvement seen in Fig 2A is not the result of hse-5(tm472) protection against aging or neurodegeneration.

Fig. 3. hse-5 loss of function restores synaptic transmission in TDP-43 tg C. elegans.
<i>hse-5 loss of function</i> restores synaptic transmission in TDP-43 tg <i>C</i>. <i>elegans</i>.
(A) (A) To assess neurodegeneration, GFP-labeled D-type GABAergic motor neurons were counted at L4 stage in vivo in living worms. TDP-43 tg; hse-5(tm472) animals lose slightly more neurons than TDP-43 tg alone, N>33 for all strains tested. Significance was evaluated using one-way analysis of variance with Tukey’s multiple comparison test among strains tested. *p<0.05, non-Tg versus TDP-43 tg and TDP-43 tg versus TDP-43 tg; hse-5(tm472), NS = not significant. (B) At day 1 adult, there are no differences in the number of D-type GABAergic motor neurons between TDP-43 tg versus TDP-43 tg; hse-5(tm472), N>33 for all strains tested. NS = not significant. p<0.0001 for non-Tg versus TDP-43tg and TDP-43 tg; hse-5(tm472). (C) hse-5(tm472) exhibit numerous axonal abnormalities including aberrant branching, looping, and inter-axonal connections. These non-canonical processes are increased in TDP-43 tg; hse-5(tm472) animals, N>33 for all strains tested. ***p<0.0001 for non-Tg versus hse-5(tm472), TDP-43tg, and TDP-43 tg; hse-5(tm472), and for TDP-43tg versus TDP-43 tg; hse-5(tm472). (D) Wild-type control axons ascend linearly from the ventral nerve cord without branching, looping, or inter-axonal connections. (E-F) TDP-43 tg; hse-5(tm472) axons frequently exhibit unusual branches, loops, or inter-axonal connections. (G) Pre-synaptic transmission was assessed using an aldicarb sensitivity assay. Animals were scored at the indicated time points for paralysis. Triplicate independent experiments are plotted. TDP-43 tg animals (orange diamond, p<0.005 at hours 3–7) are strongly resistant to aldicarb relative to non-Tg animals (blue circle) indicating decreased or defective synaptic transmission, while hse-5(tm472) animals (red square, p<0.05 at hours 3–4) are more modestly resistant to aldicarb. TDP-43 tg; hse-5(tm472) animals (black circle, p<0.05 at hours 3–5) have synaptic transmission restored to hse-5(tm472) levels. unc-29(e1072) (purple inverted triangle, p<0.05 at hours 3–7) and unc-31(e928) (green triangle, p<0.05 at hours 3 and 4) are controls for decreased aldicarb sensitivity. Significance was evaluated using two-way ANOVA with Tukey’s multiple comparisons test; p-values compared to non-Tg.

Loss of hse-5 causes aberrant axonal connectivity including non-canonical axonal branching [37]; these abnormalities were apparent when examining hse-5(tm472) mutant animals expressing the Punc-47::GFP reporter (Fig 3C–3F). In fact, the additional branches and processes appeared to create a more complex neuronal network in C. elegans, with non-standard axonal contacts between adjacent neurons and increased nerve cord contacts for some neurons (Fig 3E). When we quantitated the number of axonal abnormalities observed in individual worms, we found that while both hse-5(tm472) and TDP-43 tg alone had moderate numbers of axonal abnormalities, the TDP-43 tg; hse-5(tm472) had significantly more (Fig 3C). hse-5(tm472) may restore neuronal function in TDP-43 tg animals. One assay to measure synaptic transmission determines the sensitivity of C. elegans to the acetycholinesterase inhibitor aldicarb. Aldicarb prevents acetycholinesterase from breaking down acetycholine in the pre-synaptic cleft. This results in a build-up of acetylcholine, hyperactivation of cholinergic receptors, and eventual paralysis due to hypercontraction. Animals with defects in pre-synaptic transmission can have reduced pre-synaptic acetycholine release, making them resistant to the effects of aldicarb [45]. TDP-43 tg animals exhibit significant resistance to aldicarb, indicating they have a severe defect in synaptic transmission (Fig 3G). hse-5(tm472) has a moderate defect in synaptic transmission independent of TDP-43 tg. However, we found that TDP-43 tg; hse-5(tm472) aldicarb sensitivity is similar to the more modest defects of hse-5(tm472) alone, indicating that hse-5(tm472) restores TDP-43 tg synaptic transmission.

Loss of C. elegans hse-5 protects against accumulation of phosphorylated TDP-43 (Fig 2C). However, it is unknown whether reduced expression of the human homolog, GLCE, would similarly protect against phosphorylated TDP-43 accumulation. To test this, we utilized a mammalian cell culture model that exhibits robust phosphorylation of endogenous TDP-43 driven by an oxidative chemical trigger [46]. Cells were treated with a GLCE-targeting siRNA and tested for their accumulation of phosphorylated TDP-43. We found that GLCE-targeted siRNA treatment reduced TDP-43 phosphorylation by 60–80% (Fig 4A and 4B), indicating a functional genetic interaction between hse-5/ GLCE and TDP-43 remains conserved between C. elegans and mammals.

Fig. 4. GLCE changes in mammalian cultured cells and in FTLD-TDP.
GLCE changes in mammalian cultured cells and in FTLD-TDP.
(A-B) Cultured HEK293 cells treated with ethacrynic acid (EA) accumulate robust levels of phosphorylated TDP-43. (A) Representative immunoblots of cells treated with GLCE-targeted siRNA exhibit reduced pTDP accumulation in the presence of EA. (B) Triplicate independent experiments were quantified and graphed. Significance was evaluated using one-way analysis of variance with Tukey’s multiple comparison test among strains tested. **p = 0.0029, ***p = 0.0002 versus EA treated. (C-D) GLCE immunoreactivity is reduced in patients with FTLD-TDP compared with normal controls. (C) Quantitation of GLCE immunoreactivity in the deep layers of the frontal cortex (mid-frontal gyrus) from 14 patients with FTLD-TDP and 12 normal controls. Significance was evaluated using an unpaired t-test, *p = 0.0116. (D) Representative images of GLCE immunostaining in the frontal cortex of patients and controls. pTDP-43 accumulation is apparent in FTLD-TDP patients in this same brain region. Scale bar = 50um.

To test whether GLCE protein alterations occur in a human TDP-43 proteinopathy disorder, we examined GLCE immunoreactivity in the frontal cortex of 14 FTLD-TDP patients and 12 normal control cases. We found that GLCE immunoreactivity is robust in the frontal cortex of normal control subjects. In contrast, GLCE immunopositive neurons are sparse in the frontal cortex of FTLD-TDP patients and the neurons that are immunoreactive display much weaker staining. Quantitative immunohistochemistry within the deep layers of the frontal cortex (layers 5/6) revealed that the average optical density of GLCE positive immunostaining is significantly lower in patients with FTLD-TDP compared to controls without TDP-43 proteinopathy (Fig 4C and 4D). All FTLD-TDP patients exhibit robust phosphorylated TDP-43 pathology within this same brain region. These data indicate that decreased GLCE is a feature of FTLD-TDP and may represent a protective response to extend neuron function during disease.

Discussion

We have conducted an RNAi screen of 16,757 RNAi clones, targeting 86% of the C. elegans genome, for suppressors of TDP-43 toxicity in C. elegans. We found 46 genes that suppressed TDP-43 motor dysfunction following RNAi-targeted reduction in gene expression, 24 of which had human homologs. None of these genes have been previously implicated as potential modifiers of ALS through genome-wide association studies (GWAS) [47]. These genes fall into a variety of pathways, including energy production and metabolism, extracellular matrix and cytoskeleton, ion transport, nucleic acids, proteostasis, and cell signaling (Table 1). These TDP-43 suppressor genes increase our understanding of the mechanisms of TDP-43 toxicity by nominating involved cellular pathways and processes. Further, these genes and pathways represent potential new therapeutic targets for treating TDP-43 proteinopathies such as FTLD-TDP.

We identified 5 genes that participate in energy production and metabolism: cox-10, F23F12.3, F55G1.5, paqr-1, and cox-6A. Three of these, cox-10, cox-6A, and F23F12.3 function in mitochondria. Cytochrome C oxidase (COX) is the terminal enzyme in the electron transport chain and cox-10/ COX10 and cox-6A/ COX6A1 are a COX assembly factor and structural component, respectively. Mutations in COX6A1 and COX10 are associated with Charcot-Marie-Tooth (CMT) disease and mitochondrial disorders [4850]. F55G1.5/ SLC25A18 catalyzes the unidirectional transport of glutamate into mitochondria [51]. Two of the genes, F23F12.3 and paqr-1, are involved in fatty acid metabolism. F23F12.3/ SLC22A5 is a sodium dependent carnitine cotransporter required for beta-oxidation of long-chain fatty acids to produce ATP and is associated with primary systemic carnitine deficiency [52]. paqr-1/ ADIPOR1/2 is an adiponectin receptor mediating AMPK and PPARα activities to regulates glucose uptake and fatty acid oxidation by adiponectin [53].

Six of the suppressors are involved in the extracellular matrix and cytoskeleton: col-89, gly-8, hse-5, sax-2, vab-9, and zig-3. col-89/ COL22A1 functions as a collagen in cell adhesion ligand maintaining vascular integrity [54]. gly-8/ GALNT11 is an N-acetylgalactosaminyltransferase initiating O-linked glycosylation that regulates left-right asymmetry (through Notch signaling) and cilia during development [55]. hse-5/ GLCE is a D-glucuronyl C5-epimerase that modifies heparan sulfate, a key component of the extracellular matrix, and regulates neuronal migration and axonal pathfinding [56]. sax-2/ FRYL binds microtubules and aids in the maintenance of nerve ring structure and control of sensory dendrite termination points in C. elegans [5759]. vab-9/ TMEM47 is a transmembrane protein localized to the ER and plasma membrane that regulates organization of actin at tight junctions [60]. Finally, zig-3/ HMCN1 is a Ca2+ binding extracellular matrix protein that maintains mature axon positioning. Mutations in HMCN1 are associated with age-related macular degeneration [61].

We found three genes involved in ion transport: cnnm-3, C13B4.1, and unc-77. cnnm-3/ CNNM4 is a metal ion transporter, and mutations in CNNM4 cause Jalili syndrome, a disorder that includes retinal cone-rod dystrophy and amelogenesis imperfecta [62, 63]. C13B4.1/ FRRS1 is a ferric chelate reductase that reduces ferric to ferrous iron before its transport from the endosome to the cytoplasm. unc-77/ NALCN is a voltage-gated sodium channel that propagates neuronal activity from cell bodies to synapses. Recessive mutations in NALCN cause infantile hypotonia, developmental delay, and retardation [64].

Three genes have nucleic acid functions: dna-2, tbx-11, and umps-1. dna-2/ DNA2 is a DNA-dependent ATPase, helicase, and endonuclease that maintains mitochondrial and nuclear DNA stability. Mutations in DNA2 cause progressive external ophthalmoplegia with mitochondrial DNA deletions-6 and Seckel syndrome [65]. tbx-11/ TBR1 is a T-box transcription factor that regulates neuronal migration and axon pathfinding [66]. umps-1/ UMPS is a uridine monophosphate synthetase that catalyzes pyrimidine biosynthesis by converting orotate to uridine monophosphate. Mutations in UMPS are associated with orotic aciduria [67].

We also found three genes involved in proteostasis: C47E12.3, gpx-7, and pcp-5. C47E12.3/ EDEM1 is an ER degradation-enhancing alpha-mannosidase that targets misfolded glycoproteins for degradation [68]. gpx-7/ GPX4 is a glutathione peroxidase that reduces phospholipid hydroperoxides within membranes and lipoproteins, inhibiting lipid peroxidation. Mutations in GPX4 cause spondylometaphyseal dysplasia [69]. pcp-5/ PRCP is a prolylcarboxypeptidase that cleaves proline-linked C-terminal amino acids in the lysosome.

Three genes have roles in cell signaling: F31E3.2, F40B5.2, and Y44E3A.4. F31E3.2/ SGK494 is a serine/ threonine kinase, F40B5.2/ TMPPE is a transmembrane metallophosphoesterase, and Y44EA.4/ SH3KBP1 is an adaptor protein that regulates diverse signal transduction pathways.

Of the genes identified in our screen, several have previously been implicated in ALS pathobiology by the work of others. For instance, HMCN1, the human homolog of zig-3, was identified as being one of several cell adhesion and extracellular matrix genes aberrantly spliced in sporadic cases of ALS [70]. In addition, expression of the mouse homolog of TBR1/ tbx-11 is downregulated in a conditional TDP-43 knockout model [71], and GPX4/ gpx-7 is differentially expressed in a transgenic mouse model expressing human A315T mutant TDP-43 [72], indicating potentially conserved roles for these genes in disease that warrants further testing. Taken together, the previous identification of some of the hits from our screen reinforces the potential disease relevance of our findings. However, most of the TDP-43 modifying genes identified in our study have not been previously implicated in ALS or other TDP-43 proteinopathies. The C. elegans model used here expresses human mutant TDP-43 pan-neuronally, resulting in severe progressive motor impairment, neurodegeneration, and shortened lifespan. Most prominently, these animals accumulate robust phosphorylated TDP-43, making this a powerful model to study the regulation and biological effects of post-translationally modified TDP-43 [16].

17 of the RNAi-mediated suppressors were tested for protection against TDP-43 tg phenotypes using deletion loss-of-function mutants, and 9 of these recapitulated the RNAi results. Of those with human homologs, paqr-1/ ADIPOR1/2, gly-8/ GALNT11, hse-5/ GLCE, sax-2/ FRYL, and zig-3/ HMCN1 suppressed TDP-43-dependent motor dysfunction and reduced accumulation of total or phosphorylated TDP-43. vab-9/ TMEM47 and pcp-5/ PRCP suppressed TDP-43 tg motor dysfunction but did not significantly change accumulation of TDP-43, which indicates these genes may modulate TDP-43 toxicity indirectly rather than through a direct effect on TDP-43 protein.

Our subsequent analysis focused on the C. elegans homolog of GLCE, hse-5, a heparan sulfate epimerase. hse-5(tm472) protects against TDP-43-driven motor dysfunction and prevents accumulation of phosphorylated TDP-43. We found that while hse-5(tm472) does not prevent TDP-43-driven neurodegeneration, TDP-43 tg; hse-5(tm472) animals have numerous aberrant axonal connections among neurons and between nerve cords, consistent with previous work identifying roles for hse-5 in axonal outgrowth and regeneration [37, 38, 7375]. We also find that loss of hse-5 partially restored TDP-43 tg synaptic transmission, identifying a novel role for hse-5 in synapse function. hse-5 mediated changes in neuronal connectivity and function may account for the improved movement of TDP-43 tg; hse-5(tm472) animals by maintaining neuronal activity better in the face of neuronal loss. This could also be through the developmental role of hse-5(tm472) in mediating extracellular matrix cues driving axon guidance along the midline or neuroblast migration [38, 76]. Alternatively, hse-5(tm472) may exacerbate TDP-43 neurodegeneration (Fig 3A), but still have a net protective effect by promoting clearance of phosphorylated TDP-43 and delaying neuronal dysfunction. In support of this, we found that GLCE-targeted siRNAs in human cultured cells reduced accumulation of pTDP. Furthermore, in FTLD-TDP patient brain neurons, we found decreased GLCE protein compared to controls. Reduction in GLCE in FTLD-TDP may represent a protective response in neurons to decrease accumulation of toxic phosphorylated TDP-43. In fact, the expression of a number of extracellular matrix genes was found to be significantly disrupted in sporadic ALS motor neurons, highlighting the importance of local cell to cell communication between neighboring neurons in parallel, as well as between synapse connected neurons in series, to support motor neuron health [70]. Based on these results, our working model supports two parallel mechanisms by which loss of hse-5/ GLCE function is protective. First, normal activity of hse-5/ GLCE promotes TDP-43 phosphorylation, likely through indirect effects on cell homeostasis or transmission of intercellular signaling. Second, hse-5/ GLCE also controls axonal outgrowth and synaptic transmission, influencing neuronal signaling. Loss of hse-5/ GLCE thus simultaneously decreases accumulation of phosphorylated TDP-43 and alters synaptic transmission, protecting against TDP-43-induced neuronal dysfunction.

In summary, this work has identified new target genes and molecular pathways controlling TDP-43 toxicity. Additional investigation of these genes in mammalian systems will be important future work. Preliminary characterization of GLCE suggests it can act to detoxify pTDP and is a therapeutic target worth further examination.

Materials and methods

Ethics statement

We obtained samples of postmortem tissue from the University of Washington Alzheimer’s Disease Research Center (ADRC) Neuropathology Core (PI, Dr. C. Dirk Keene) after receiving human subjects approval (University of Washington Human Subjects Division approval: HSD# 06-0492-E/A 01). FTLD-TDP cases were selected on the basis of having an autopsy-confirmed neuropathological diagnosis of FTLD with TDP-43 deposits according to consensus criteria [81]. Control samples were from neurologically healthy control participants, who were of a similar age with low levels of AD pathology (Braak stage III or less and CERAD scores of none or sparse) [82, 83]. All patients or their next of kin provided written, informed consent.

C. elegans strains and transgenics

Wild-type C. elegans (Bristol strain N2) was maintained as previously described [77]. Transgenic strains used were CK674 eri-1(mg366); lin-15b(n744); bkIs674[Psnb-1::hTDP-43(M337V)+Pmyo-2::dsRED] (primary RNAi screen and retesting), CK423 bkIs423[Psnb-1::hTDP-43(M337V)+Pmyo-2::dsRED], and CK426 bkIs426[Psnb-1::hTDP-43(A315T)+Pmyo-2::dsRED] [16, 78]. GR1373 eri-1(mg366) was used for screen counter-selection. CK423 was crossed with the following loss-of-function alleles: vab-9(gk398617) II, T24H10.4(gk637193) II, hse-5(tm472) III, sax-2(ky216) III, tbx-11(gk681547) III, F31E3.2(ok2044) III, pcp-5(gk446) III, umps-1(zu456) III, F40B5.2(gk920502) X, and pqn-18(gk805921) X. CK426 was crossed with the following loss-of-function alleles: gly-8(tm1156) III, unc-77(e625) IV, paqr-1(tm3262) IV, F55G1.5(gk1250) IV, T28C6.7(tm5935) IV, C47E12.3(ok2898) IV, gpx-7(tm2166) X, and zig-3(tm924) X. hse-5(tm472) was crossed with CK410 bkIs410[Psnb-1::hTDP-43(WT)+Pmyo-2::dsRED], CK10 bkIs10[Paex-3::hTau(V337M)+Pmyo-2::GFP], and CK144 bkIs144[Paex-3::hTau(WT)+Pmyo-2::GFP] for motility assays. OH1487 hse-5(tm472), DA509 unc-31(e928), and CB1072 unc-29(e1072) were used as controls.

C. elegans RNAi screening

Initial screening of the feeding RNAi Ahringer library was conducted essentially as described [79]. Bacterial cultures were grown over night and 40μL were seeded on twelve well plates of Nematode Growth Medium (NGM) supplemented with 25μg/mL carbenicillin and 2mM isopropyl-b-D-thiolgalactophyranoside (IPTG) and allowed to dry for two days. Embryos were isolated by hypochlorite treatment of gravid adult worms, placed onto 12 well RNAi plates at a density of approximately 15 eggs per well, and allowed to grow for 10–12 days at 16°C until the F2 generation were young adults. Controls including RNAi vector alone, RNAi targeting human TDP-43 (suppressor control), and RNAi targeting unc-22 (enhancer control) were screened in parallel for all experiments. Follow-up screening of putative positives was carried out on individual 60mm plates and were given a semi-quantitative overall score from 0 to 5, where 0 is unable to differentiate from the empty L4440 vector control, and 5 is complete suppression to N2 wild-type behavior. All RNAi clones from the Ahringer library that passed initial screening were analyzed by Sanger sequencing to validate clone targeting.

Behavioral analysis

Assessments of C. elegans locomotion were carried out as previously described with minor modifications [16]. In brief, 15–20 animals were placed at the center of a 100mm plate of 5x concentrated peptone nematode growth media uniformly seeded with OP-50 bacteria. Animals were allowed to move freely for 30–60 minutes, and the radial distance traveled from the start point was recorded. Distance traveled was converted to micrometers per minute. Statistical significance was analyzed using Prism statistical software.

Neurodegeneration and axon abnormality assays

Strains with GFP marked gamma-aminobutyric acid (GABA)-ergic motor neurons were generated by crossing hse-5(tm472) with CK423 and the reporter strain EG1285 oxIs12[Punc-47::GFP + lin-15(+)]. Animals were grown to the indicated stage at 20°C before scoring. Living animals were immobilized on a 2% agarose pad with 0.01% sodium azide, and intact GABA-ergic neurons (L4 or day 1 adult) or axon abnormalities (L4 stage) were scored under fluorescence microscopy on a DeltaVision Elite (GE) imaging system using an Olympus 60x oil objective. Statistical significance was analyzed using Prism statistical software.

Microscopy, image acquisition, and processing

Images were acquired using a Leica SP5 confocal microscope with a 40x oil immersion lens. Z-plane stacked images were flattened into a maximum intensity projection using Imaris x64 software. Images were minimally processed using Adobe Photoshop to enhance visibility of fluorescent signal.

Aldicarb sensitivity assay

C. elegans were grown to L4 stage at 20°C, and then transferred to NGM plates containing the indicated concentrations of aldicarb (Sigma). Animals were scored for paralysis using a gentle touch on the head and tail with a platinum wire [45].

Immunoblotting

Stage-matched day 1 adult C. elegans were harvested and snap frozen. Protein was extracted by resuspending pellets in 1X sample buffer, 20 s sonication, and 5 minutes boiling. 10 μL of samples were loaded onto precast 4–15% gradient Tris: HCL gels (Biorad). Total human TDP-43 was detected with mouse monoclonal antibody ab57105 (Abcam) and phosphorylated TDP-43 was detected with mouse monoclonal antibody TIP-PTD-M01 (CosmoBio). Beta-Tubulin antibody E7 (DSHB) was used as a load control for all samples.

Quantitative reverse-transcription PCR (qRT-PCR)

RNA was extracted using Trizol (Sigma), and cDNA was prepared using iScript Reverse Transcription Supermix for RT-qPCR (Bio-Rad). Each genotype was tested with three biological replicates. qPCR was performed using the iTaq Universal SYBR Green Supermix kit (Bio-Rad) on a CFX Connect Real-Time PCR Instrument (BioRad). Data were normalized within samples using an internal reference control gene (act-1).

Lifespan assay

C. elegans were grown at 20°C following a short (4–6 hour) egglay to L4 stage on NGM plates seeded with E. coli OP50, and then transferred onto seeded NGM plates with added 5-fluoro-2’-deoxyuridine (FUDR, 0.05 mg/mL) to inhibit growth of progeny. Individuals were scored every 2–3 days by gentle touching with a platinum wire. Failure to respond to touch was scored as dead. Statistical analysis was performed using GraphPad Prism software.

Cell culture, RNA interference, and EA treatment

HEK293 cells were cultured under standard tissue culture conditions (DMEM, 10% defined fetal bovine serum, Penicillin (1000 IU/mL) Streptomycin (1000μg/mL)) as previously described [80]. RNA interference was conducted following manufacture’s protocol (RNAiMAX, Invitrogen). Induction of pTDP-43 with ethacrynic acid was conducted as previously described [80].

Immunohistochemistry and quantification

Immunohistochemistry was performed on paraffin embedded frontal cortex sections from 14 patients with FTLD-TDP and 12 normal control cases. Antigen retrieval consisted of autoclaving in a citrate buffer. Sections were treated for endogenous peroxidases, blocked in 5% non-fat milk in PBS, and incubated overnight at 4°C with anti-GLCE polyclonal antibody (ThermoFisher Sci, 1:75). Biotinylated secondary antibody was applied, followed by incubation in an avidin-biotin complex (Vector’s Vectastain Elite ABC kit, Burlingame, CA) and the reaction product was visualized with 0.05% diaminobenzidine (DAB)/0.01% hydrogen peroxide in PBS. FTLD-TDP cases were also stained with an anti-phospho TDP-43 antibody (409/410 CosmoBio, 1:1000) to confirm TDP-43 pathology. In order to minimize variability, sections from all cases (normal and affected subjects) were stained simultaneously. Digital images were obtained using a Leica DM6 microscope with the DFC 7000 digital camera and LAS X imaging software. HALO digital image software (Indica Labs) was used to quantify GLCE immunoreactivity in the deep layers of the frontal cortex (layers 5/6) using the “Area Quantification” setting. Data represent the average optical density value of DAB staining within the region of interest and are displayed as mean +/- SEM. A two tailed Student’s t-test was used to assess differences in GLCE expression between cases and controls.

Supporting information

S1 Fig [a]
Characterization of TDP-43 transgene expression levels and immunoblot analysis of suppressors without an effect on TDP-43 protein.

S2 Fig [a]
Characterization of in non-Tg, WT TDP-43 tg, and tau tg . .


Zdroje

1. Tan RH, Ke YD, Ittner LM, Halliday GM. ALS/FTLD: experimental models and reality. Acta Neuropathologica. 2017:1–20. doi: 10.1007/s00401-016-1666-6 28058507

2. Mann DMA, Snowden JS. Frontotemporal lobar degeneration: Pathogenesis, pathology and pathways to phenotype. Brain Pathol. 2017. doi: 10.1111/bpa.12486 28100023.

3. Chornenkyy Y, Fardo DW, Nelson PT. Tau and TDP-43 proteinopathies: kindred pathologic cascades and genetic pleiotropy. Lab Invest. 2019. doi: 10.1038/s41374-019-0196-y 30742063.

4. Wilson RS, Yu L, Trojanowski JQ, Chen EY, Boyle PA, Bennett DA, et al. TDP-43 pathology, cognitive decline, and dementia in old age. JAMA Neurol. 2013;70(11):1418–24. doi: 10.1001/jamaneurol.2013.3961 24080705

5. James BD, Wilson RS, Boyle PA, Trojanowski JQ, Bennett DA, Schneider JA. TDP-43 stage, mixed pathologies, and clinical Alzheimer’s-type dementia. Brain. 2016;139(11):2983–93. doi: 10.1093/brain/aww224 27694152

6. Cohen TJ, Hwang AW, Restrepo CR, Yuan CX, Trojanowski JQ, Lee VM. An acetylation switch controls TDP-43 function and aggregation propensity. Nat Commun. 2015;6:5845. doi: 10.1038/ncomms6845 25556531

7. Seyfried NT, Gozal YM, Dammer EB, Xia Q, Duong DM, Cheng D, et al. Multiplex SILAC analysis of a cellular TDP-43 proteinopathy model reveals protein inclusions associated with SUMOylation and diverse polyubiquitin chains. Mol Cell Proteomics. 2010;9(4):705–18. Epub 2010/01/0610. doi: 10.1074/mcp.M800390-MCP200 20047951.

8. Neumann M, Sampathu DM, Kwong LK, Truax AC, Micsenyi MC, Chou TT, et al. Ubiquitinated TDP-43 in frontotemporal lobar degeneration and amyotrophic lateral sclerosis. Science. 2006;314(5796):130–3. Epub 2006/10/07. doi: 10.1126/science.1134108 17023659.

9. Arai T, Hasegawa M, Akiyama H, Ikeda K, Nonaka T, Mori H, et al. TDP-43 is a component of ubiquitin-positive tau-negative inclusions in frontotemporal lobar degeneration and amyotrophic lateral sclerosis. Biochem Biophys Res Commun. 2006;351(3):602–11. Epub 2006/11/07. doi: 10.1016/j.bbrc.2006.10.093 17084815.

10. Neumann M, Kwong LK, Lee EB, Kremmer E, Flatley A, Xu Y, et al. Phosphorylation of S409/410 of TDP-43 is a consistent feature in all sporadic and familial forms of TDP-43 proteinopathies. Acta Neuropathol. 2009;117(2):137–49. doi: 10.1007/s00401-008-0477-9 19125255

11. Liachko NF, McMillan PJ, Guthrie CR, Bird TD, Leverenz JB, Kraemer BC. CDC7 inhibition blocks pathological TDP-43 phosphorylation and neurodegeneration. Ann Neurol. 2013;74(1):39–52. doi: 10.1002/ana.23870 23424178

12. Ayala YM, Zago P, D’Ambrogio A, Xu YF, Petrucelli L, Buratti E, et al. Structural determinants of the cellular localization and shuttling of TDP-43. J Cell Sci. 2008;121(Pt 22):3778–85. Epub 2008/10/30. doi: 10.1242/jcs.038950 18957508.

13. Hasegawa M, Arai T, Nonaka T, Kametani F, Yoshida M, Hashizume Y, et al. Phosphorylated TDP-43 in frontotemporal lobar degeneration and amyotrophic lateral sclerosis. Ann Neurol. 2008;64(1):60–70. doi: 10.1002/ana.21425 18546284

14. Zhang YJ, Gendron TF, Xu YF, Ko LW, Yen SH, Petrucelli L. Phosphorylation regulates proteasomal-mediated degradation and solubility of TAR DNA binding protein-43 C-terminal fragments. Mol Neurodegener. 2010;5:33. Epub 2010/09/02. doi: 10.1186/1750-1326-5-33 20804554

15. Brady OA, Meng P, Zheng Y, Mao Y, Hu F. Regulation of TDP-43 aggregation by phosphorylation and p62/SQSTM1. J Neurochem. 2011;116(2):248–59. Epub 2010/11/11. doi: 10.1111/j.1471-4159.2010.07098.x 21062285.

16. Liachko NF, Guthrie CR, Kraemer BC. Phosphorylation Promotes Neurotoxicity in a Caenorhabditis elegans Model of TDP-43 Proteinopathy. J Neurosci. 2010;30(48):16208–19. Epub 2010/12/03. doi: 10.1523/JNEUROSCI.2911-10.2010 21123567.

17. Li HR, Chiang WC, Chou PC, Wang WJ, Huang JR. TAR DNA-binding protein 43 (TDP-43) liquid-liquid phase separation is mediated by just a few aromatic residues. J Biol Chem. 2018;293(16):6090–8. doi: 10.1074/jbc.AC117.001037 29511089

18. Conicella AE, Zerze GH, Mittal J, Fawzi NL. ALS Mutations Disrupt Phase Separation Mediated by alpha-Helical Structure in the TDP-43 Low-Complexity C-Terminal Domain. Structure. 2016;24(9):1537–49. doi: 10.1016/j.str.2016.07.007 27545621

19. Ritson GP, Custer SK, Freibaum BD, Guinto JB, Geffel D, Moore J, et al. TDP-43 mediates degeneration in a novel Drosophila model of disease caused by mutations in VCP/p97. J Neurosci. 2010;30(22):7729–39. Epub 2010/06/04. doi: 10.1523/JNEUROSCI.5894-09.2010 20519548

20. Nollen EA, Garcia SM, van Haaften G, Kim S, Chavez A, Morimoto RI, et al. Genome-wide RNA interference screen identifies previously undescribed regulators of polyglutamine aggregation. Proc Natl Acad Sci U S A. 2004;101(17):6403–8. doi: 10.1073/pnas.0307697101 15084750

21. Kraemer BC, Burgess JK, Chen JH, Thomas JH, Schellenberg GD. Molecular pathways that influence human tau-induced pathology in Caenorhabditis elegans. Hum Mol Genet. 2006;15(9):1483–96. doi: 10.1093/hmg/ddl067 16600994

22. Karsten SL, Sang TK, Gehman LT, Chatterjee S, Liu J, Lawless GM, et al. A genomic screen for modifiers of tauopathy identifies puromycin-sensitive aminopeptidase as an inhibitor of tau-induced neurodegeneration. Neuron. 2006;51(5):549–60. doi: 10.1016/j.neuron.2006.07.019 16950154

23. Dimitriadi M, Sleigh JN, Walker A, Chang HC, Sen A, Kalloo G, et al. Conserved genes act as modifiers of invertebrate SMN loss of function defects. PLoS Genet. 2010;6(10):e1001172. doi: 10.1371/journal.pgen.1001172 21124729

24. Manzo E, O’Conner AG, Barrows JM, Shreiner DD, Birchak GJ, Zarnescu DC. Medium-Chain Fatty Acids, Beta-Hydroxybutyric Acid and Genetic Modulation of the Carnitine Shuttle Are Protective in a Drosophila Model of ALS Based on TDP-43. Front Mol Neurosci. 2018;11:182. doi: 10.3389/fnmol.2018.00182 29904341

25. Wang J, Farr GW, Hall DH, Li F, Furtak K, Dreier L, et al. An ALS-linked mutant SOD1 produces a locomotor defect associated with aggregation and synaptic dysfunction when expressed in neurons of Caenorhabditis elegans. PLoS Genet. 2009;5(1):e1000350. doi: 10.1371/journal.pgen.1000350 19165329

26. Berson A, Goodman LD, Sartoris AN, Otte CG, Aykit JA, Lee VM, et al. Drosophila Ref1/ALYREF regulates transcription and toxicity associated with ALS/FTD disease etiologies. Acta Neuropathol Commun. 2019;7(1):65. doi: 10.1186/s40478-019-0710-x 31036086.

27. Elden AC, Kim HJ, Hart MP, Chen-Plotkin AS, Johnson BS, Fang X, et al. Ataxin-2 intermediate-length polyglutamine expansions are associated with increased risk for ALS. Nature. 2010;466(7310):1069–75. doi: 10.1038/nature09320 20740007

28. Armakola M, Higgins MJ, Figley MD, Barmada SJ, Scarborough EA, Diaz Z, et al. Inhibition of RNA lariat debranching enzyme suppresses TDP-43 toxicity in ALS disease models. Nat Genet. 2012;44(12):1302–9. doi: 10.1038/ng.2434 23104007

29. Kim SH, Zhan L, Hanson KA, Tibbetts RS. High-content RNAi screening identifies the Type 1 inositol triphosphate receptor as a modifier of TDP-43 localization and neurotoxicity. Hum Mol Genet. 2012;21(22):4845–56. doi: 10.1093/hmg/dds321 22872699

30. Sreedharan J, Neukomm LJ, Brown RH, Jr., Freeman MR. Age-Dependent TDP-43-Mediated Motor Neuron Degeneration Requires GSK3, hat-trick, and xmas-2. Curr Biol. 2015;25(16):2130–6. doi: 10.1016/j.cub.2015.06.045 26234214

31. Zhan L, Xie Q, Tibbetts RS. Opposing roles of p38 and JNK in a Drosophila model of TDP-43 proteinopathy reveal oxidative stress and innate immunity as pathogenic components of neurodegeneration. Hum Mol Genet. 2015;24(3):757–72. doi: 10.1093/hmg/ddu493 25281658

32. Appocher C, Mohagheghi F, Cappelli S, Stuani C, Romano M, Feiguin F, et al. Major hnRNP proteins act as general TDP-43 functional modifiers both in Drosophila and human neuronal cells. Nucleic Acids Res. 2017;45(13):8026–45. doi: 10.1093/nar/gkx477 28575377

33. Pons M, Prieto S, Miguel L, Frebourg T, Campion D, Sune C, et al. Identification of TCERG1 as a new genetic modulator of TDP-43 production in Drosophila. Acta Neuropathol Commun. 2018;6(1):138. doi: 10.1186/s40478-018-0639-5 30541625

34. White JG, Southgate E, Thomson JN, Brenner S. The structure of the nervous system of the nematode Caenorhabditis elegans. Philos Trans R Soc Lond B Biol Sci. 1986;314(1165):1–340. doi: 10.1098/rstb.1986.0056 22462104.

35. Kamath RS F A, Dong Y, Poulin G, Durbin R, Gotta M, Kanapin A, Le Bot N, Moreno S, Sohrmann M, Welchman DP, Zipperlen P, Ahringer J. Systematic functional analysis of the Caenorhabditis elegans genome using RNAi. Nature. 2003;421((6920)):231–7. doi: 10.1038/nature01278 12529635

36. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ. Basic local alignment search tool. J Mol Biol. 1990;215(3):403–10. Epub 1990/10/05. doi: 10.1016/S0022-2836(05)80360-2 2231712.

37. Rhiner C, Gysi S, Frohli E, Hengartner MO, Hajnal A. Syndecan regulates cell migration and axon guidance in C. elegans. Development. 2005;132(20):4621–33. doi: 10.1242/dev.02042 16176946.

38. Bulow HE, Hobert O. Differential sulfations and epimerization define heparan sulfate specificity in nervous system development. Neuron. 2004;41(5):723–36. doi: 10.1016/s0896-6273(04)00084-4 15003172.

39. Lazaro-Pena MI, Diaz-Balzac CA, Bulow HE, Emmons SW. Synaptogenesis Is Modulated by Heparan Sulfate in Caenorhabditis elegans. Genetics. 2018;209(1):195–208. doi: 10.1534/genetics.118.300837 29559501

40. Sarrazin S, Lamanna WC, Esko JD. Heparan sulfate proteoglycans. Cold Spring Harb Perspect Biol. 2011;3(7). doi: 10.1101/cshperspect.a004952 21690215

41. Jia J, Maccarana M, Zhang X, Bespalov M, Lindahl U, Li JP. Lack of L-iduronic acid in heparan sulfate affects interaction with growth factors and cell signaling. J Biol Chem. 2009;284(23):15942–50. doi: 10.1074/jbc.M809577200 19336402

42. Li JP, Gong F, Hagner-McWhirter A, Forsberg E, Abrink M, Kisilevsky R, et al. Targeted disruption of a murine glucuronyl C5-epimerase gene results in heparan sulfate lacking L-iduronic acid and in neonatal lethality. J Biol Chem. 2003;278(31):28363–6. doi: 10.1074/jbc.C300219200 12788935.

43. Li J, Fang J, Qin Y, Liao W, Liu H, Zhou Y, et al. GLCE regulates PC12 cell neuritogenesis induced by nerve growth factor through activating SMAD/ID3 signalling. Biochem J. 2014;459(2):405–15. doi: 10.1042/BJ20131360 24499487.

44. McIntire SL, Reimer RJ, Schuske K, Edwards RH, Jorgensen EM. Identification and characterization of the vesicular GABA transporter. Nature. 1997;389(6653):870–6. doi: 10.1038/39908 9349821.

45. Mahoney TR, Luo S, Nonet ML. Analysis of synaptic transmission in Caenorhabditis elegans using an aldicarb-sensitivity assay. Nat Protoc. 2006;1(4):1772–7. doi: 10.1038/nprot.2006.281 17487159.

46. Iguchi Y, Katsuno M, Takagi S, Ishigaki S, Niwa J, Hasegawa M, et al. Oxidative stress induced by glutathione depletion reproduces pathological modifications of TDP-43 linked to TDP-43 proteinopathies. Neurobiol Dis. 2012;45(3):862–70. doi: 10.1016/j.nbd.2011.12.002 22198567.

47. Nicolas A, Kenna KP, Renton AE, Ticozzi N, Faghri F, Chia R, et al. Genome-wide Analyses Identify KIF5A as a Novel ALS Gene. Neuron. 2018;97(6):1268–83 e6. doi: 10.1016/j.neuron.2018.02.027 29566793

48. Antonicka H, Leary SC, Guercin GH, Agar JN, Horvath R, Kennaway NG, et al. Mutations in COX10 result in a defect in mitochondrial heme A biosynthesis and account for multiple, early-onset clinical phenotypes associated with isolated COX deficiency. Hum Mol Genet. 2003;12(20):2693–702. doi: 10.1093/hmg/ddg284 12928484.

49. Timmerman V, Strickland AV, Zuchner S. Genetics of Charcot-Marie-Tooth (CMT) Disease within the Frame of the Human Genome Project Success. Genes (Basel). 2014;5(1):13–32. doi: 10.3390/genes5010013 24705285

50. Tamiya G, Makino S, Hayashi M, Abe A, Numakura C, Ueki M, et al. A mutation of COX6A1 causes a recessive axonal or mixed form of Charcot-Marie-Tooth disease. Am J Hum Genet. 2014;95(3):294–300. doi: 10.1016/j.ajhg.2014.07.013 25152455

51. Fiermonte G, Palmieri L, Todisco S, Agrimi G, Palmieri F, Walker JE. Identification of the mitochondrial glutamate transporter. Bacterial expression, reconstitution, functional characterization, and tissue distribution of two human isoforms. J Biol Chem. 2002;277(22):19289–94. doi: 10.1074/jbc.M201572200 11897791.

52. Magoulas PL, El-Hattab AW. Systemic primary carnitine deficiency: an overview of clinical manifestations, diagnosis, and management. Orphanet J Rare Dis. 2012;7:68. doi: 10.1186/1750-1172-7-68 22989098

53. Parker-Duffen JL, Nakamura K, Silver M, Zuriaga MA, MacLauchlan S, Aprahamian TR, et al. Divergent roles for adiponectin receptor 1 (AdipoR1) and AdipoR2 in mediating revascularization and metabolic dysfunction in vivo. J Biol Chem. 2014;289(23):16200–13. doi: 10.1074/jbc.M114.548115 24742672

54. Ton QV, Leino D, Mowery SA, Bredemeier NO, Lafontant PJ, Lubert A, et al. Collagen COL22A1 maintains vascular stability and mutations in COL22A1 are potentially associated with intracranial aneurysms. Dis Model Mech. 2018;11(12). doi: 10.1242/dmm.033654 30541770

55. Boskovski MT, Yuan S, Pedersen NB, Goth CK, Makova S, Clausen H, et al. The heterotaxy gene GALNT11 glycosylates Notch to orchestrate cilia type and laterality. Nature. 2013;504(7480):456–9. doi: 10.1038/nature12723 24226769

56. Li JP. Glucuronyl C5-epimerase an enzyme converting glucuronic acid to iduronic acid in heparan sulfate/heparin biosynthesis. Prog Mol Biol Transl Sci. 2010;93:59–78. doi: 10.1016/S1877-1173(10)93004-4 20807641.

57. Benard C, Tjoe N, Boulin T, Recio J, Hobert O. The small, secreted immunoglobulin protein ZIG-3 maintains axon position in Caenorhabditis elegans. Genetics. 2009;183(3):917–27. doi: 10.1534/genetics.109.107441 19737747

58. Gallegos ME, Bargmann CI. Mechanosensory neurite termination and tiling depend on SAX-2 and the SAX-1 kinase. Neuron. 2004;44(2):239–49. doi: 10.1016/j.neuron.2004.09.021 15473964.

59. Jia L, Emmons SW. Genes that control ray sensory neuron axon development in the Caenorhabditis elegans male. Genetics. 2006;173(3):1241–58. doi: 10.1534/genetics.106.057000 16624900

60. Simske JS, Koppen M, Sims P, Hodgkin J, Yonkof A, Hardin J. The cell junction protein VAB-9 regulates adhesion and epidermal morphology in C. elegans. Nat Cell Biol. 2003;5(7):619–25. doi: 10.1038/ncb1002 12819787.

61. Fisher SA, Rivera A, Fritsche LG, Keilhauer CN, Lichtner P, Meitinger T, et al. Case-control genetic association study of fibulin-6 (FBLN6 or HMCN1) variants in age-related macular degeneration (AMD). Hum Mutat. 2007;28(4):406–13. doi: 10.1002/humu.20464 17216616.

62. Parry DA, Mighell AJ, El-Sayed W, Shore RC, Jalili IK, Dollfus H, et al. Mutations in CNNM4 cause Jalili syndrome, consisting of autosomal-recessive cone-rod dystrophy and amelogenesis imperfecta. Am J Hum Genet. 2009;84(2):266–73. doi: 10.1016/j.ajhg.2009.01.009 19200525

63. Polok B, Escher P, Ambresin A, Chouery E, Bolay S, Meunier I, et al. Mutations in CNNM4 cause recessive cone-rod dystrophy with amelogenesis imperfecta. Am J Hum Genet. 2009;84(2):259–65. doi: 10.1016/j.ajhg.2009.01.006 19200527

64. Al-Sayed MD, Al-Zaidan H, Albakheet A, Hakami H, Kenana R, Al-Yafee Y, et al. Mutations in NALCN cause an autosomal-recessive syndrome with severe hypotonia, speech impairment, and cognitive delay. Am J Hum Genet. 2013;93(4):721–6. doi: 10.1016/j.ajhg.2013.08.001 24075186

65. Ronchi D, Di Fonzo A, Lin W, Bordoni A, Liu C, Fassone E, et al. Mutations in DNA2 link progressive myopathy to mitochondrial DNA instability. Am J Hum Genet. 2013;92(2):293–300. doi: 10.1016/j.ajhg.2012.12.014 23352259

66. McKenna WL, Betancourt J, Larkin KA, Abrams B, Guo C, Rubenstein JL, et al. Tbr1 and Fezf2 regulate alternate corticofugal neuronal identities during neocortical development. J Neurosci. 2011;31(2):549–64. doi: 10.1523/JNEUROSCI.4131-10.2011 21228164

67. Suchi M, Mizuno H, Kawai Y, Tsuboi T, Sumi S, Okajima K, et al. Molecular cloning of the human UMP synthase gene and characterization of point mutations in two hereditary orotic aciduria families. Am J Hum Genet. 1997;60(3):525–39. 9042911

68. Molinari M, Calanca V, Galli C, Lucca P, Paganetti P. Role of EDEM in the release of misfolded glycoproteins from the calnexin cycle. Science. 2003;299(5611):1397–400. doi: 10.1126/science.1079474 12610306.

69. Smith AC, Mears AJ, Bunker R, Ahmed A, MacKenzie M, Schwartzentruber JA, et al. Mutations in the enzyme glutathione peroxidase 4 cause Sedaghatian-type spondylometaphyseal dysplasia. J Med Genet. 2014;51(7):470–4. doi: 10.1136/jmedgenet-2013-102218 24706940.

70. Rabin SJ, Kim JM, Baughn M, Libby RT, Kim YJ, Fan Y, et al. Sporadic ALS has compartment-specific aberrant exon splicing and altered cell-matrix adhesion biology. Hum Mol Genet. 2010;19(2):313–28. Epub 2009/10/30. doi: 10.1093/hmg/ddp498 19864493

71. Wu LS, Cheng WC, Chen CY, Wu MC, Wang YC, Tseng YH, et al. Transcriptomopathies of pre- and post-symptomatic frontotemporal dementia-like mice with TDP-43 depletion in forebrain neurons. Acta Neuropathol Commun. 2019;7(1):50. doi: 10.1186/s40478-019-0674-x 30922385

72. Stribl C, Samara A, Trumbach D, Peis R, Neumann M, Fuchs H, et al. Mitochondrial dysfunction and decrease in body weight of a transgenic knock-in mouse model for TDP-43. J Biol Chem. 2014;289(15):10769–84. doi: 10.1074/jbc.M113.515940 24515116

73. Blanchette CR, Thackeray A, Perrat PN, Hekimi S, Benard CY. Functional Requirements for Heparan Sulfate Biosynthesis in Morphogenesis and Nervous System Development in C. elegans. PLoS Genet. 2017;13(1):e1006525. doi: 10.1371/journal.pgen.1006525 28068429

74. Bulow HE, Tjoe N, Townley RA, Didiano D, van Kuppevelt TH, Hobert O. Extracellular sugar modifications provide instructive and cell-specific information for axon-guidance choices. Curr Biol. 2008;18(24):1978–85. doi: 10.1016/j.cub.2008.11.023 19062279

75. Edwards TJ, Hammarlund M. Syndecan promotes axon regeneration by stabilizing growth cone migration. Cell Rep. 2014;8(1):272–83. doi: 10.1016/j.celrep.2014.06.008 25001284

76. Wang X, Liu J, Zhu Z, Ou G. The heparan sulfate-modifying enzyme glucuronyl C5-epimerase HSE-5 controls Caenorhabditis elegans Q neuroblast polarization during migration. Dev Biol. 2015;399(2):306–14. doi: 10.1016/j.ydbio.2015.01.007 25614236.

77. Brenner S. The genetics of Caenorhabditis elegans. Genetics. 1974;77:71–94. 4366476

78. Liachko NF, McMillan PJ, Guthrie CR, Bird TD, Leverenz JB, Kraemer BC. CDC7 inhibition blocks pathological TDP-43 phosphorylation and neurodegeneration. Ann Neurol. 2013. doi: 10.1002/ana.23870 23424178.

79. Kamath RS, Ahringer J. Genome-wide RNAi screening in Caenorhabditis elegans. Methods. 2003;30:313–21. doi: 10.1016/s1046-2023(03)00050-1 12828945

80. Liachko NF, Saxton AD, McMillan PJ, Strovas TJ, Currey HN, Taylor LM, et al. The phosphatase calcineurin regulates pathological TDP-43 phosphorylation. Acta Neuropathologica. 2016;132(4):545–61. doi: 10.1007/s00401-016-1600-y 27473149

81. Mackenzie IR, Neumann M, Baborie A, Sampathu DM, Du Plessis D, Jaros E, et al. A harmonized classification system for FTLD-TDP pathology. Acta Neuropathol. 2011;122(1):111–3. doi: 10.1007/s00401-011-0845-8 21644037

82. Braak H, Braak E. Neuropathological stageing of Alzheimer-related changes. Acta Neuropathol. 1991;82(4):239–59. doi: 10.1007/bf00308809 1759558.

83. Mirra SS, Heyman A, McKeel D, Sumi SM, Crain BJ, Brownlee LM, et al. The Consortium to Establish a Registry for Alzheimer’s Disease (CERAD). Part II. Standardization of the neuropathologic assessment of Alzheimer’s disease. Neurology. 1991;41(4):479–86. doi: 10.1212/wnl.41.4.479 2011243.

Štítky
Genetika Reprodukční medicína

Článek vyšel v časopise

PLOS Genetics


2019 Číslo 12
Nejčtenější tento týden
Nejčtenější v tomto čísle
Kurzy

Zvyšte si kvalifikaci online z pohodlí domova

Důležitost adherence při depresivním onemocnění
nový kurz
Autoři: MUDr. Eliška Bartečková, Ph.D.

Koncepce osteologické péče pro gynekology a praktické lékaře
Autoři: MUDr. František Šenk

Sekvenční léčba schizofrenie
Autoři: MUDr. Jana Hořínková, Ph.D.

Hypertenze a hypercholesterolémie – synergický efekt léčby
Autoři: prof. MUDr. Hana Rosolová, DrSc.

Multidisciplinární zkušenosti u pacientů s diabetem
Autoři: Prof. MUDr. Martin Haluzík, DrSc., prof. MUDr. Vojtěch Melenovský, CSc., prof. MUDr. Vladimír Tesař, DrSc.

Všechny kurzy
Přihlášení
Zapomenuté heslo

Zadejte e-mailovou adresu, se kterou jste vytvářel(a) účet, budou Vám na ni zaslány informace k nastavení nového hesla.

Přihlášení

Nemáte účet?  Registrujte se

#ADS_BOTTOM_SCRIPTS#