Caractérisation fonctionnelle chez le poisson zèbre de l'isoforme protéique WNK1/HSN2 mutée dans la neuropathie héréditaire sensitive et autonome de type 2

La neuropathie humaine sensitive et autonome de type 2 (NHSA 2) est une pathologie héréditaire rare caractérisée par une apparition précoce des symptômes et une absence d’affectation motrice. Cette pathologie entraîne la perte de perception de la douleur, de la chaleur et du froid ainsi que de la pression (toucher) dans les membres supérieurs et inférieurs et est due à des mutations autosomales récessives confinées à l’exon HSN2 de la protéine kinase à sérine/thréonine WNK1 (with-no-lysine protein kinase 1). Cet exon spécifique permettrait de conférer une spécificité au système nerveux à l’isoforme protéique WNK1/HSN2. La kinase WNK1 est étudiée en détails, en particulier au niveau du rein, mais son rôle au sein du système nerveux demeure inconnu. Considérant le début précoce de la neuropathie et le manque d’innervation sensorielle révélé par des biopsies chez les patients NHSA2, notre hypothèse de recherche est que les mutations tronquantes menant à la NHSA de type 2 causent une perte de fonction de l’isoforme WNK1/HSN2 spécifique au système nerveux entraînant un défaut dans le développement du système nerveux sensoriel périphérique. Chez l’embryon du poisson zèbre, WNK1/HSN2 est exprimé au niveau des neuromastes de la ligne latérale postérieure, un système mécanosensoriel périphérique. Nous avons obtenu des embryons knockdown pour WNK1/HSN2 par usage d’oligonucléotides morpholino antisens (AMO). Nos trois approches AMO ont révélé des embryons présentant des défauts d’établissement au niveau de la ligne latérale postérieure. Afin de déterminer la voie pathogène impliquant l’isoforme WNK1/HSN2, nous nous sommes intéressés à l’interaction rapportée entre la kinase WNK1 et le co-transporteur neuronal KCC2. Ce dernier est une cible de phosphorylation de WNK1 et son rôle dans la promotion de la neurogenèse est bien connu. Nous avons détecté l’expression de KCC2 au niveau de neuromastes de la ligne latérale postérieure et observé une expression accrue de KCC2 chez les embryons knockdown pour WNK1/HSN2 à l’aide de RT-PCR semi-quantitative. De plus, une sur-expression d’ARN humain de KCC2 chez des embryons a produit des défauts dans la ligne latérale postérieure, phénocopiant le knockdown de WNK1/HSN2. Ces résultats furent validés par un double knockdown, produisant des embryons n’exprimant ni KCC2, ni WNK1/HSN2, dont le phénotype fut atténué. Ces résultats nous mènent à suggérer une voie de signalisation où WNK1/HSN2 est en amont de KCC2, régulant son activation, et possiblement son expression. Nous proposons donc que la perte de fonction de l’isoforme spécifique cause un débalancement dans les niveaux de KCC2 activée, menant à une prolifération et une différenciation réduites des progéniteurs neuronaux du système nerveux périphérique. Les défauts associés à la NHSA de type 2 seraient donc de nature développementale et non neurodégénérative.Human sensory and autonomic neuropathy type 2 (HSNA2) is a rare human hereditary pathology characterized by an early onset severe sensory loss (for all modalities) in the distal limbs. It is due to autosomal recessive mutations confined to exon HSN2 of the WNK1 (with-no-lysine protein kinase 1) serine-threonine kinase; the specific exon confers nervous system specificity to target isoform WNK1/HSN2. While this kinase is widely studied in the kidneys, little is known about its role in the nervous system. Due to its role in HSAN type 2, we hypothesized that the truncating mutations present in the HSN2 exon lead to a loss-of-function of the WNK1 kinase, impairing development of the peripheral sensory system. In order to investigate the mechanisms by which the lack of the WNK1/HSN2 isoform acts to cause HSAN type 2, we examined its expression pattern in our zebrafish model and observed strong expression in neuromasts of the peripheral sensory lateral line system. We then knocked down the HSN2 exon in zebrafish embryos using antisense morpholino oligonucleotides. Our three approaches to knockdown the WNK1/HSN2 isoform led to embryos with a defective lateral line. In order to establish a pathogenic pathway involving the WNK1/HSN2 isoform, we investigated the reported interaction between the WNK1 kinase and neuronal potassium chloride co-transporter KCC2. This transporter is a target of WNK1 phosphorylation and also has a known role in promoting neurogenesis. We have also showed its expression in mature neuromasts of the posterior lateral line, and observed an increased expression of KCC2 in WNK1/HSN2 knockdown embryos by semi-quantitative RT-PCR, lending credence to our interaction hypothesis. Furthermore, overexpression of human KCC2 RNA in embryos led to an impaired mechanosensory lateral line system, phenocopying the WNK1/HSN2 knockdown. We then validated these results by obtaining double knockdown embryos, both for WNK1/HSN2 and KCC2, which alleviated the lateral line defect phenotype. These results led us to suggest a pathway in which WNK1/HSN2 is upstream of the KCC2 co-transporter. WNK1 is believed to regulate the level of activation, and possibly level of expression, of KCC2 and we therefore hypothesize that the loss-of-function of the specific isoform causes an imbalance in the levels of activated KCC2. This would then lead to decreased progenitor proliferation and hindered differentiation of neurons, causing the defects associated with HSAN type 2

Zebrafish as a Model for the Study of Live in vivo Processive Transport in Neurons

Motor proteins are responsible for transport of vesicles and organelles within the cell cytoplasm. They interact with the actin cytoskeleton and with microtubules to ensure communication and supply throughout the cell. Much work has been done in vitro and in silico to unravel the key players, including the dynein motor complex, the kinesin and myosin superfamilies, and their interacting regulatory complexes, but there is a clear need for in vivo data as recent evidence suggests previous models might not recapitulate physiological conditions. The zebrafish embryo provides an excellent system to study these processes in intact animals due to the ease of genetic manipulation and the optical transparency allowing live imaging. We present here the advantages of the zebrafish embryo as a system to study live in vivo processive transport in neurons and provide technical recommendations for successful analysis

HNRNPK alleviates RNA toxicity by counteracting DNA damage in C9orf72 ALS

A 'GGGGCC' repeat expansion in the first intron of the C9orf72 gene is the most common genetic cause of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). The exact mechanism resulting in these neurodegenerative diseases remains elusive, but C9 repeat RNA toxicity has been implicated as a gain-of-function mechanism. Our aim was to use a zebrafish model for C9orf72 RNA toxicity to identify modifiers of the ALS-linked phenotype. We discovered that the RNA-binding protein heterogeneous nuclear ribonucleoprotein K (HNRNPK) reverses the toxicity of both sense and antisense repeat RNA, which is dependent on its subcellular localization and RNA recognition, and not on C9orf72 repeat RNA binding. We observed HNRNPK cytoplasmic mislocalization in C9orf72 ALS patient fibroblasts, induced pluripotent stem cell (iPSC)-derived motor neurons and post-mortem motor cortex and spinal cord, in line with a disrupted HNRNPK function in C9orf72 ALS. In C9orf72 ALS/FTD patient tissue, we discovered an increased nuclear translocation, but reduced expression of ribonucleotide reductase regulatory subunit M2 (RRM2), a downstream target of HNRNPK involved in the DNA damage response. Last but not least, we showed that increasing the expression of HNRNPK or RRM2 was sufficient to mitigate DNA damage in our C9orf72 RNA toxicity zebrafish model. Overall, our study strengthens the relevance of RNA toxicity as a pathogenic mechanism in C9orf72 ALS and demonstrates its link with an aberrant DNA damage response, opening novel therapeutic avenues for C9orf72 ALS/FTD.</p

ALS-associated KIF5A mutations abolish autoinhibition resulting in a toxic gain of function

Understandingthepathogenicmechanismsof diseasemutations is critical toadvancingtreatments.ALS-associated mutations in the gene encoding the microtubulemotor KIF5A result in skipping of exon 27 (KIF5ADExon27) and the encoding of a protein with a novel 39 amino acid residue C-terminal sequence. Here, we report that expression of ALS-linked mutant KIF5A results in dysregulated motor activity, cellular mislocalization, altered axonal transport, and decreased neuronal survival. Single-molecule analysis revealed that the altered C terminus of mutant KIF5A results in a constitutively active state. Furthermore,mutant KIF5A possesses altered protein and RNA interactions and its expression results in altered gene expression/splicing. Taken together, our data support the hypothesis that causative ALS mutations result in a toxic gain of function in the intracellular motor KIF5A that disrupts intracellular trafficking and neuronal homeostasis

FUS and TARDBP but Not SOD1 Interact in Genetic Models of Amyotrophic Lateral Sclerosis

Mutations in the SOD1 and TARDBP genes have been commonly identified in Amyotrophic Lateral Sclerosis (ALS). Recently, mutations in the Fused in sarcoma gene (FUS) were identified in familial (FALS) ALS cases and sporadic (SALS) patients. Similarly to TDP-43 (coded by TARDBP gene), FUS is an RNA binding protein. Using the zebrafish (Danio rerio), we examined the consequences of expressing human wild-type (WT) FUS and three ALS–related mutations, as well as their interactions with TARDBP and SOD1. Knockdown of zebrafish Fus yielded a motor phenotype that could be rescued upon co-expression of wild-type human FUS. In contrast, the two most frequent ALS–related FUS mutations, R521H and R521C, unlike S57Δ, failed to rescue the knockdown phenotype, indicating loss of function. The R521H mutation caused a toxic gain of function when expressed alone, similar to the phenotype observed upon knockdown of zebrafish Fus. This phenotype was not aggravated by co-expression of both mutant human TARDBP (G348C) and FUS (R521H) or by knockdown of both zebrafish Tardbp and Fus, consistent with a common pathogenic mechanism. We also observed that WT FUS rescued the Tardbp knockdown phenotype, but not vice versa, suggesting that TARDBP acts upstream of FUS in this pathway. In addition we observed that WT SOD1 failed to rescue the phenotype observed upon overexpression of mutant TARDBP or FUS or upon knockdown of Tardbp or Fus; similarly, WT TARDBP or FUS also failed to rescue the phenotype induced by mutant SOD1 (G93A). Finally, overexpression of mutant SOD1 exacerbated the motor phenotype caused by overexpression of mutant FUS. Together our results indicate that TARDBP and FUS act in a pathogenic pathway that is independent of SOD1

Dynactin1 mutations associées à la sclérose latérale amyotrophique et leur effet sur le transport axonal et la formation de jonction neuromusculaire

Amyotrophic lateral sclerosis (ALS) is an adult-onset neurodegenerative disease, which is mainly sporadic in nature. This progressive pathology has an estimated incidence of 1:1000 and generally leads to death within 2-5 years of diagnosis due to muscle wasting and severe motor neuron loss. Over the last years, mutations have been identified in both sporadic and familial ALS patients, interfering with the function of many genes, including DCTN1, which encodes for a subunit of the motor protein complex subunit dynactin. The dynactin complex serves as an adaptor for the dynein motor complex, responsible for retrograde axonal transport, and it is believed to regulate dynein activity and the binding capacity for cargos. We set out to characterize a mutant zebrafish line for dynactn1a (named mikre okom632, mokm632), looking specifically at caudal primary motor neurons (CaPs), with regard to axonal development, formation and stability of the neuromuscular junction (NMJ) and the behavioral phenotype produced in embryos, as well as axonal transport metrics. We suggest a role for dynactin1 in synapse stability, where the loss-of-function of this gene leads to growth defects, electrophysiological abnormalities and behavioral deficits. This role appears to be independent of its known function as a regulator of dynein, its implication in axonal transport, or its regulation of microtubule dynamics. With this study, we hope to elucidate key molecular mechanisms in ALS etiology by revealing the role of dynactin1 in NMJ development and maintenance.La sclérose latérale amyotrophique (SLA) est une pathologie neurodégénerative progressive se déclarant vers 50-60 ans. Elle est majoritairement de nature sporadique son incidence est estimée à 1 :1000. La SLA mène à une paralysie progressive et entraine généralement à la mort des patients de 2 à 5 ans suivant le diagnostic aux suite d’une fonte musculaire importante liée à la perte des neurones moteurs. Au cours des années, plusieurs mutations ont été identifiées autant chez les patients atteints de SLA sporadique que de SLA familiale. Ces mutations interfèrent avec la fonction de gènes variés, tels que DCTN1, codant pour la protéine dynactine1, sous-unité du complexe multimoléculaire dynactine. Ce complexe sert d’adaptateur au moteur moléculaire dynéine, chargé du transport axonal rétrograde, où sa fonction permettrait de régir l’activité du complexe moteur et sa capacité à lier divers cargos. Nous avons donc entrepris la caractérisation d’une lignée de poissons zèbre mutants pour dynactin1a (nommés mikre okom632, mokm632), plus particulière en terme du développement d’un type de neurone moteur primaire (les CaPs), afin de déterminer l’effet de la perte de fonction de ce gène sur l’axonogenèse, la formation et la stabilisation de la jonction neuromusculaire, sur le comportement de l’embryon, ainsi que sur le transport axonal.Nous suggérons que dynactin1 favorise la stabilité synaptique, où une perte de fonction de ce gène entraine des défauts de croissance, des anomalies éléctrophysiologiques et un comportement anormal. Ce rôle semble être indépendant des fonctions connues de régulateur du moteur dynéine

Zebrafish as a Model for the Study of Live in vivo Processive Transport in Neurons

Motor proteins are responsible for transport of vesicles and organelles within the cell cytoplasm. They interact with the actin cytoskeleton and with microtubules to ensure communication and supply throughout the cell. Much work has been done in vitro and in silico to unravel the key players, including the dynein motor complex, the kinesin and myosin superfamilies, and their interacting regulatory complexes, but there is a clear need for in vivo data as recent evidence suggests previous models might not recapitulate physiological conditions. The zebrafish embryo provides an excellent system to study these processes in intact animals due to the ease of genetic manipulation and the optical transparency allowing live imaging. We present here the advantages of the zebrafish embryo as a system to study live in vivo processive transport in neurons and provide technical recommendations for successful analysis.status: publishe

WNK1/HSN2 Mutation in Human Peripheral Neuropathy Deregulates <em>KCC2</em> Expression and Posterior Lateral Line Development in Zebrafish (<em>Danio rerio</em>)

<div><p>Hereditary sensory and autonomic neuropathy type 2 (HSNAII) is a rare pathology characterized by an early onset of severe sensory loss (all modalities) in the distal limbs. It is due to autosomal recessive mutations confined to exon “HSN2” of the WNK1 (with-no-lysine protein kinase 1) serine-threonine kinase. While this kinase is well studied in the kidneys, little is known about its role in the nervous system. We hypothesized that the truncating mutations present in the neural-specific HSN2 exon lead to a loss-of-function of the WNK1 kinase, impairing development of the peripheral sensory system. To investigate the mechanisms by which the loss of WNK1/HSN2 isoform function causes HSANII, we used the embryonic zebrafish model and observed strong expression of WNK1/HSN2 in neuromasts of the peripheral lateral line (PLL) system by immunohistochemistry. Knocking down wnk1/hsn2 in embryos using antisense morpholino oligonucleotides led to improper PLL development. We then investigated the reported interaction between the WNK1 kinase and neuronal potassium chloride cotransporter KCC2, as this transporter is a target of WNK1 phosphorylation. <em>In situ</em> hybridization revealed <em>kcc2</em> expression in mature neuromasts of the PLL and semi-quantitative RT–PCR of wnk1/hsn2 knockdown embryos showed an increased expression of <em>kcc2</em> mRNA. Furthermore, overexpression of human KCC2 mRNA in embryos replicated the wnk1/hsn2 knockdown phenotype. We validated these results by obtaining double knockdown embryos, both for wnk1/hsn2 and kcc2, which alleviated the PLL defects. Interestingly, overexpression of inactive mutant KCC2-C568A, which does not extrude ions, allowed a phenocopy of the PLL defects. These results suggest a pathway in which WNK1/HSN2 interacts with KCC2, producing a novel regulation of its transcription independent of KCC2's activation, where a loss-of-function mutation in WNK1 induces an overexpression of KCC2 and hinders proper peripheral sensory nerve development, a hallmark of HSANII.</p> </div

TUBA4A downregulation as observed in ALS post-mortem motor cortex causes ALS-related abnormalities in zebrafish

Disease-associated variants of TUBA4A (alpha-tubulin 4A) have recently been identified in familial ALS. Interestingly, a downregulation of TUBA4A protein expression was observed in familial as well as sporadic ALS brain tissue. To investigate whether a decreased TUBA4A expression could be a driving factor in ALS pathogenesis, we assessed whether TUBA4A knockdown in zebrafish could recapitulate an ALS-like phenotype. For this, we injected an antisense oligonucleotide morpholino in zebrafish embryos targeting the zebrafish TUBA4A orthologue. An antibody against synaptic vesicle 2 was used to visualize motor axons in the spinal cord, allowing the analysis of embryonic ventral root projections. Motor behavior was assessed using the touch-evoked escape response. In post-mortem ALS motor cortex, we observed reduced TUBA4A levels. The knockdown of the zebrafish TUBA4A orthologue induced a motor axonopathy and a significantly disturbed motor behavior. Both phenotypes were dose-dependent and could be rescued by the addition of human wild-type TUBA4A mRNA. Thus, TUBA4A downregulation as observed in ALS post-mortem motor cortex could be modeled in zebrafish and induced a motor axonopathy and motor behavior defects reflecting a motor neuron disease phenotype, as previously described in embryonic zebrafish models of ALS. The rescue with human wild-type TUBA4A mRNA suggests functional conservation and strengthens the causal relation between TUBA4A protein levels and phenotype severity. Furthermore, the loss of TUBA4A induces significant changes in post-translational modifications of tubulin, such as acetylation, detyrosination and polyglutamylation. Our data unveil an important role for TUBA4A in ALS pathogenesis, and extend the relevance of TUBA4A to the majority of ALS patients, in addition to cases bearing TUBA4A mutations

In-vivo fast non-linear microscopy reveals intraneuronal transport impairment induced by slight molecular motor imbalances in the brain of zebrafish larvae

International audienceMotor proteins are responsible for the intracellular transport of critical cargoes such as organelles and vesicles along the cytoskeleton. This transport is an vital process, especially in neurons. Axonal transport deficit is found in neurological disorders and is a hallmark of neurodegenerative diseases1.Conventional methods used to measure intraneuronal transport are limited by moderate spatiotemporal resolutions, preventing the observation of events of short duration. We developed a method using photostable optically active nanocrystals (NC) tracer spontaneously internalized in endosomes2.Here we demonstrate the application of this assay to zebrafish (Zf) larvae. We used NC exhibiting large second-order non-linear optical properties, injected in Zf brain. We harnessed these properties combined with fast raster scanning of the infrared laser beam to achieve 20 frames/s rate, allowing us to detect short pausing duration underpinning complex molecular mechanisms otherwise smeared out by low temporal resolution.Using this method in axons of neurons with known polarization, we were able to separate the retrograde from the anterograde phase of motion. We developed a pipeline of video dataset analysis, which extracts the statistical distribution of various transport metrics for both directions, in normal and perturbed situations. To test the sensitivity of our measurement to small perturbations, we modulated the concentration of specific molecular motors, either by applying dynapyrazole3, a retrograde motor dynein inhibiting drug, or by using transgenic Zf engineered with loss-of-function alleles of the anterograde motor protein Kif5aa4. Dynapyrazole induces a reduction 32% of mobile NC, with a 37% reduction of their retrograde run length. In kif5aa mutants the retrograde run length is increased by 46% compared to wildtype.The high sensitivity of our intraneuronal transport measurement assay opens prospects in screening the functional impacts of neurodegenerative disease genetic factors in the animal model of zebrafish larvae for which genetic tools are largely available.References 1.S. Millecamps and J.-P. Julien, Nat. Rev. Neurosci., 2013, 14, 161–176.2.S. Haziza, et al., Nat. Nanotechnol., 2017, 12, 322–328.3.J. B. Steinman, et al., Elife, 2017, 6, e25174.4.T. O. Auer, et al., Elife, 2015, 4, 1–26.5.S. E. Encalada and L. S. B. B. Goldstein, Annu. Rev. Biophys., 2014, 43, 141–69