Human motor units in microfluidic devices are impaired by FUS mutations and improved by HDAC6 inhibition

Dittlau, Katarina Stoklund; Krasnow, Emily N.; Fumagalli, Laura; Vandoorne, Tijs; Baatsen, Pieter; Kerstens, Axelle; Giacomazzi, Giorgia; Pavie, Benjamin; Rossaert, Elisabeth; Beckers, Jimmy; Sampaolesi, Maurilio; Damme, Philip Van; Bosch, Ludo Van Den

doi:10.1016/j.stemcr.2021.03.029

Cited by 51 publications

(78 citation statements)

References 61 publications

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“…In neurodegenerative diseases such as ALS, microfluidic models have shown promise in the investigation of the effectiveness of drugs delivered to the distal axons located outside the CNS as opposed to delivery to the soma, which is more difficult to target with treatment in vivo ( Marshall and Farah, 2021 ). Microfluidic models using ALS patient specific iPSC derived MNs expressing mutant FUS demonstrated a reduction in neurite outgrowth and the number of total NMJs and showed that histone deacetylase 6 inhibition could rescue outgrowth impairments and improve NMJ formation ( Stoklund Dittlau et al, 2021 ). Another study using a 3D microfluidic approach demonstrated that motor units using iPSC derived motor neurons from a patient with sporadic ALS produced weaker muscle cell contractions compared to healthy donor derived controls, and treatment with mTOR pathway inhibitors increased muscle contractile force and improved motor neuron survival in the ALS model ( Osaki et al, 2018 ).…”

Section: Discussionmentioning

confidence: 99%

Validation of Functional Connectivity of Engineered Neuromuscular Junction With Recombinant Monosynaptic Pseudotyped ΔG-Rabies Virus Tracing

Bauer

Fiskum

Nair

et al. 2022

Front. Integr. Neurosci.

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Current preclinical models of neurodegenerative disease, such as amyotrophic lateral sclerosis (ALS), can significantly benefit from in vitro neuroengineering approaches that enable the selective study and manipulation of neurons, networks, and functional units of interest. Custom-designed compartmentalized microfluidic culture systems enable the co-culture of different relevant cell types in interconnected but fluidically isolated microenvironments. Such systems can thus be applied for ALS disease modeling, as they enable the recapitulation and study of neuromuscular junctions (NMJ) through co-culturing of motor neurons and muscle cells in separate, but interconnected compartments. These in vitro systems are particularly relevant for investigations of mechanistic aspects of the ALS pathological cascade in engineered NMJ, as progressive loss of NMJ functionality may constitute one of the hallmarks of disease related pathology at early onset, in line with the dying back hypothesis. In such models, ability to test whether motor neuron degeneration in ALS starts at the nerve terminal or at the NMJ and retrogradely progresses to the motor neuron cell body largely relies on robust methods for verification of engineered NMJ functionality. In this study, we demonstrate the functionality of engineered NMJs within a microfluidic chip with a differentially perturbable microenvironment using a designer pseudotyped ΔG-rabies virus for retrograde monosynaptic tracing.

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Section: Discussionmentioning

confidence: 99%

Validation of Functional Connectivity of Engineered Neuromuscular Junction With Recombinant Monosynaptic Pseudotyped ΔG-Rabies Virus Tracing

Bauer

Fiskum

Nair

et al. 2022

Front. Integr. Neurosci.

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“…For example, human iPSC-derived co-cultures of astrocytes and motor neurons were recently used in a study showing that astrocytes exhibit non-cell autonomous effects on motor neurons in an in vitro ALS model ( Zhao et al, 2020 ). For studies on neuromuscular disease, co-cultures of iPSC-derived motor neurons with skeletal muscle cells (such as those derived from C2C12 mouse myoblasts, primary human-derived myoblasts, or differentiated from hiPSCs, with varying degrees of difficulty and availability) to simulate a simplified version of the neuromuscular system present in vivo , and allowing for assays of NMJ function ( Demestre et al, 2015 ; Picchiarelli et al, 2019 ; Lin et al, 2020 ; Yoshioka et al, 2020 ; Stoklund Dittlau et al, 2021 ). Furthermore, organoid culture systems allow for the differentiation of multiple cell types to form a miniature version and experimentally approachable model of the tissue of interest ( Vieira de Sa et al, 2021 ).…”

Section: Enhancing Cell Maturity and Exploring Cell Biological Mechanismsmentioning

confidence: 99%

An Integrated Approach to Studying Rare Neuromuscular Diseases Using Animal and Human Cell-Based Models

Hines

Lutz

Murray

et al. 2022

Front. Cell Dev. Biol.

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As sequencing technology improves, the identification of new disease-associated genes and new alleles of known genes is rapidly increasing our understanding of the genetic underpinnings of rare diseases, including neuromuscular diseases. However, precisely because these disorders are rare and often heterogeneous, they are difficult to study in patient populations. In parallel, our ability to engineer the genomes of model organisms, such as mice or rats, has gotten increasingly efficient through techniques such as CRISPR/Cas9 genome editing, allowing the creation of precision human disease models. Such in vivo model systems provide an efficient means for exploring disease mechanisms and identifying therapeutic strategies. Furthermore, animal models provide a platform for preclinical studies to test the efficacy of those strategies. Determining whether the same mechanisms are involved in the human disease and confirming relevant parameters for treatment ideally involves a human experimental system. One system currently being used is induced pluripotent stem cells (iPSCs), which can then be differentiated into the relevant cell type(s) for in vitro confirmation of disease mechanisms and variables such as target engagement. Here we provide a demonstration of these approaches using the example of tRNA-synthetase-associated inherited peripheral neuropathies, rare forms of Charcot-Marie-Tooth disease (CMT). Mouse models have led to a better understanding of both the genetic and cellular mechanisms underlying the disease. To determine if the mechanisms are similar in human cells, we will use genetically engineered iPSC-based models. This will allow comparisons of different CMT-associated GARS alleles in the same genetic background, reducing the variability found between patient samples and simplifying the availability of cell-based models for a rare disease. The necessity of integrating mouse and human models, strategies for accomplishing this integration, and the challenges of doing it at scale are discussed using recently published work detailing the cellular mechanisms underlying GARS-associated CMT as a framework.

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“…Moreover, the knowledge acquired from these publications should lay the groundwork for the development of diseased models employing human patient‐specific cells to be used for the investigation of the pathological mechanisms underlying NMJ damage and neurodegenerative diseases. [ 18–20 ] In particular, the study of the NMJ contribution in muscular dystrophies progression is still poorly explored as compared to other neuromuscular disorders and would widely benefit from the microfluidics approach. The NMJ pathological derangement has been characterized in the Duchenne Muscular Dystrophy (DMD) and pointed out numerous differences in the structure, function, and gene expression between the healthy and pathologic condition.…”

Section: Introductionmentioning

confidence: 99%

Dystrophic Muscle Affects Motoneuron Axon Outgrowth and NMJ Assembly

Fornetti

Testa

Paolis

et al. 2022

Adv Materials Technologies

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The Neuromuscular Junction (NMJ) is a chemical synapse localized between the terminal branches of the spinal motor neurons and myofibers. In the past two decades coculture systems to generate the NMJ in culture are developed to address concerns about animal models, despite the complexity of its highly specialized structure makes the in vitro modeling a challenging task. Microfluidics, unlike mass cocultures, allow spatial and temporal control over different microenvironment by manipulating either neural cells or muscle cell populations independently. Therefore, exploiting an organ‐on‐a‐chip approach, the aim is to obtain a reliable and predictive in vitro human model of NMJ in physiological and pathological conditions, to investigate the occurrence of synapse detriment in α‐sarcoglycanopathy, a subtype of limb‐girdle muscular dystrophy. For this purpose, motor neurons derived from human induced pluripotent stem cells (hiPSCs) and either healthy or α‐sarcoglycan mutant human myogenic progenitors are seeded in two separated chambers of a microfluidic device. Differentiated myotubes and hiPSCs‐derived motor neurons on‐chip are able to establish points of interaction where pre‐ and postsynaptic structures colocalize. Moreover, the attraction of motor neurons axons by muscle fibers and the NMJ maturation appear to be affected by the muscular compartment, being impaired by the dystrophic cellular component.

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Human motor units in microfluidic devices are impaired by FUS mutations and improved by HDAC6 inhibition

Cited by 51 publications

References 61 publications

Validation of Functional Connectivity of Engineered Neuromuscular Junction With Recombinant Monosynaptic Pseudotyped ΔG-Rabies Virus Tracing

Validation of Functional Connectivity of Engineered Neuromuscular Junction With Recombinant Monosynaptic Pseudotyped ΔG-Rabies Virus Tracing

An Integrated Approach to Studying Rare Neuromuscular Diseases Using Animal and Human Cell-Based Models

Dystrophic Muscle Affects Motoneuron Axon Outgrowth and NMJ Assembly

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