scholarly journals Mitochondrial dysfunction impairs human neuronal development and reduces neuronal network activity and synchronicity

2019 ◽  
Author(s):  
T.M. Klein Gunnewiek ◽  
E. J. H. Van Hugte ◽  
M. Frega ◽  
G. Solé Guardia ◽  
K.B. Foreman ◽  
...  
Keyword(s):  
Energy Metabolism ◽  
Mitochondrial Dysfunction ◽  
Cortical Neurons ◽  
Nuclear Dna ◽  
Induced Pluripotent Stem Cell ◽  
Mitochondrial Diseases ◽  
Network Activity ◽  
Neural Structure ◽  
Neuronal Network Activity

SummaryEpilepsy, intellectual and cortical sensory deficits and psychiatric manifestations are among the most frequent manifestations of mitochondrial diseases. Yet, how mitochondrial dysfunction affects neural structure and function remains largely elusive. This is mostly due to the lack of a proper in vitro translational neuronal model system(s) with impaired energy metabolism. Leveraging the induced pluripotent stem cell technology, from a cohort of patients with the common pathogenic m.3243A>G variant of mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS), we differentiated excitatory cortical neurons (iNeurons) with normal (low heteroplasmy) and impaired (high heteroplasmy) mitochondrial function on an isogenic nuclear DNA background. iNeurons with high levels of heteroplasmy exhibited mitochondrial dysfunction, delayed neural maturation, reduced dendritic complexity and fewer functional excitatory synapses. Micro-electrode array recordings of neuronal networks with high heteroplasmy displayed reduced network activity and decreased synchronous network bursting. The impaired neural energy metabolism of iNeurons compromising the structural and functional integrity of neurons and neural networks, could be the primary driver of increased susceptibility to neuropsychiatric manifestations of mitochondrial disease.

scholarly journals Applicability of hiPSC-Derived Neuronal Cocultures and Rodent Primary Cortical Cultures for In Vitro Seizure Liability Assessment

2020 ◽  
Vol 178 (1) ◽  
pp. 71-87
Author(s):  
Anke M Tukker ◽  
Fiona M J Wijnolts ◽  
Aart de Groot ◽  
Remco H S Westerink
Keyword(s):  
Microelectrode Array ◽  
Activity Patterns ◽  
Primary Cultures ◽  
Induced Pluripotent Stem Cell ◽  
Network Activity ◽  
Neuronal Network Activity ◽  
Cortical Cultures ◽  
Life Threatening ◽  
Induced Pluripotent

Abstract Seizures are life-threatening adverse drug reactions which are investigated late in drug development using rodent models. Consequently, if seizures are detected, a lot of time, money and animals have been used. Thus, there is a need for in vitro screening models using human cells to circumvent interspecies translation. We assessed the suitability of cocultures of human-induced pluripotent stem cell (hiPSC)-derived neurons and astrocytes compared with rodent primary cortical cultures for in vitro seizure liability assessment using microelectrode arrays. hiPSC-derived and rodent primary cortical neuronal cocultures were exposed to 9 known (non)seizurogenic compounds (pentylenetetrazole, amoxapine, enoxacin, amoxicillin, linopirdine, pilocarpine, chlorpromazine, phenytoin, and acetaminophen) to assess effects on neuronal network activity using microelectrode array recordings. All compounds affect activity in hiPSC-derived cocultures. In rodent primary cultures all compounds, except amoxicillin changed activity. Changes in activity patterns for both cell models differ for different classes of compounds. Both models had a comparable sensitivity for exposure to amoxapine (lowest observed effect concentration [LOEC] 0.03 µM), linopirdine (LOEC 1 µM), and pilocarpine (LOEC 0.3 µM). However, hiPSC-derived cultures were about 3 times more sensitive for exposure to pentylenetetrazole (LOEC 30 µM) than rodent primary cortical cultures (LOEC 100 µM). Sensitivity of hiPSC-derived cultures for chlorpromazine, phenytoin, and enoxacin was 10-30 times higher (LOECs 0.1, 0.3, and 0.1 µM, respectively) than in rodent cultures (LOECs 10, 3, and 3 µM, respectively). Our data indicate that hiPSC-derived neuronal cocultures may outperform rodent primary cortical cultures with respect to detecting seizures, thereby paving the way towards animal-free seizure assessment.

Dementia with Lewy bodies—associated ß-synuclein mutations V70M and P123H cause mutation-specific neuropathological lesions

2021 ◽  
Author(s):  
Maryna Psol ◽  
Sofia Guerin Darvas ◽  
Kristian Leite ◽  
Sameehan U Mahajani ◽  
Mathias Bähr ◽  
...  
Keyword(s):  
Neuronal Network ◽  
Dementia With Lewy Bodies ◽  
Lewy Bodies ◽  
Sporadic Case ◽  
Network Activity ◽  
Proteinase K ◽  
Neuronal Network Activity ◽  
Distinct Disease

Abstract ß-Synuclein (ß-Syn) has long been considered to be an attenuator for the neuropathological effects caused by the Parkinson’s disease-related α-Synuclein (α-Syn) protein. However, recent studies demonstrated that overabundant ß-Syn can form aggregates and induce neurodegeneration in CNS neurons in vitro and in vivo, albeit at a slower pace as compared to α-Syn. Here we demonstrate that ß-Syn mutants V70M, detected in a sporadic case of Dementia with Lewy Bodies (DLB), and P123H, detected in a familial case of DLB, robustly aggravate the neurotoxic potential of ß-Syn. Intriguingly, the two mutations trigger mutually exclusive pathways. ß-Syn V70M enhances morphological mitochondrial deterioration and degeneration of dopaminergic and non-dopaminergic neurons, but has no influence on neuronal network activity. Conversely, ß-Syn P123H silences neuronal network activity, but does not aggravate neurodegeneration. ß-Syn WT, V70M and P123H formed proteinase K (PK) resistant intracellular fibrils within neurons, albeit with less stable C-termini as compared to α-Syn. Under cell free conditions, ß-Syn V70M demonstrated a much slower pace of fibril formation as compared to WT ß-Syn, and P123H fibrils present with a unique phenotype characterized by large numbers of short, truncated fibrils. Thus, it is possible that V70M and P123H cause structural alterations in ß-Syn, that are linked to their distinct neuropathological profiles. The extent of the lesions caused by these neuropathological profiles is almost identical to that of overabundant α-Syn, and thus likely to be directly involved into etiology of DLB. Over all, this study provides insights into distinct disease mechanisms caused by mutations of ß-Syn.

scholarly journals Neurotherapeutic Effect of Inula britannica var. Chinensis against H2O2-Induced Oxidative Stress and Mitochondrial Dysfunction in Cortical Neurons

Antioxidants ◽  
2021 ◽  
Vol 10 (3) ◽  
pp. 375
Author(s):  
Jin Young Hong ◽  
Hyunseong Kim ◽  
Junseon Lee ◽  
Wan-Jin Jeon ◽  
Seung Ho Baek ◽  
...  
Keyword(s):  
Oxidative Stress ◽  
Mitochondrial Dysfunction ◽  
Cortical Neurons ◽  
Inflammatory Diseases ◽  
Neuroprotective Effect ◽  
Neuroprotective Effects ◽  
Neuronal Viability ◽  
Inula Britannica ◽  
Oxidative Effects

Inula britannica var. chinensis (IBC) has been used as a traditional medicinal herb to treat inflammatory diseases. Although its anti-inflammatory and anti-oxidative effects have been reported, whether IBC exerts neuroprotective effects and the related mechanisms in cortical neurons remain unknown. In this study, we investigated the effects of different concentrations of IBC extract (5, 10, and 20 µg/mL) on cortical neurons using a hydrogen peroxide (H2O2)-induced injury model. Our results demonstrate that IBC can effectively enhance neuronal viability under in vitro-modeled reaction oxygen species (ROS)-generating conditions by inhibiting mitochondrial ROS production and increasing adenosine triphosphate level in H2O2-treated neurons. Additionally, we confirmed that neuronal death was attenuated by improving the mitochondrial membrane potential status and regulating the expression of cytochrome c, a protein related to cell death. Furthermore, IBC increased the expression of brain-derived neurotrophic factor and nerve growth factor. Furthermore, IBC inhibited the loss and induced the production of synaptophysin, a major synaptic vesicle protein. This study is the first to demonstrate that IBC exerts its neuroprotective effect by reducing mitochondria-associated oxidative stress and improving mitochondrial dysfunction.

Influence of albumin dialysis (MARS) on neuronal network activity in vitro

2001 ◽  
Vol 39 ◽  
pp. 40-40
Author(s):  
J Loock ◽  
J Stange ◽  
S Mitzner ◽  
R Schmidt ◽  
E W Keefer ◽  
...  
Keyword(s):  
Neuronal Network ◽  
Network Activity ◽  
Albumin Dialysis ◽  
Neuronal Network Activity

scholarly journals Pharmacological intervention to restore connectivity deficits of neuronal networks derived from ASD patient iPSC with a TSC2 mutation

2020 ◽  
Vol 11 (1) ◽  
Author(s):  
Mouhamed Alsaqati ◽  
Vivi M. Heine ◽  
Adrian J. Harwood
Keyword(s):  
Neuronal Network ◽  
Electrode Array ◽  
Network Connectivity ◽  
Autism Spectrum ◽  
Network Activity ◽  
Inhibitory Synapses ◽  
Pharmacological Intervention ◽  
Spatial Connectivity ◽  
Neuronal Network Activity

Abstract Background Tuberous sclerosis complex (TSC) is a rare genetic multisystemic disorder resulting from autosomal dominant mutations in the TSC1 or TSC2 genes. It is characterised by hyperactivation of the mechanistic target of rapamycin complex 1 (mTORC1) pathway and has severe neurodevelopmental and neurological components including autism, intellectual disability and epilepsy. In human and rodent models, loss of the TSC proteins causes neuronal hyperexcitability and synaptic dysfunction, although the consequences of these changes for the developing central nervous system are currently unclear. Methods Here we apply multi-electrode array-based assays to study the effects of TSC2 loss on neuronal network activity using autism spectrum disorder (ASD) patient-derived iPSCs. We examine both temporal synchronisation of neuronal bursting and spatial connectivity between electrodes across the network. Results We find that ASD patient-derived neurons with a functional loss of TSC2, in addition to possessing neuronal hyperactivity, develop a dysfunctional neuronal network with reduced synchronisation of neuronal bursting and lower spatial connectivity. These deficits of network function are associated with elevated expression of genes for inhibitory GABA signalling and glutamate signalling, indicating a potential abnormality of synaptic inhibitory–excitatory signalling. mTORC1 activity functions within a homeostatic triad of protein kinases, mTOR, AMP-dependent protein Kinase 1 (AMPK) and Unc-51 like Autophagy Activating Kinase 1 (ULK1) that orchestrate the interplay of anabolic cell growth and catabolic autophagy while balancing energy and nutrient homeostasis. The mTOR inhibitor rapamycin suppresses neuronal hyperactivity, but does not increase synchronised network activity, whereas activation of AMPK restores some aspects of network activity. In contrast, the ULK1 activator, LYN-1604, increases the network behaviour, shortens the network burst lengths and reduces the number of uncorrelated spikes. Limitations Although a robust and consistent phenotype is observed across multiple independent iPSC cultures, the results are based on one patient. There may be more subtle differences between patients with different TSC2 mutations or differences of polygenic background within their genomes. This may affect the severity of the network deficit or the pharmacological response between TSC2 patients. Conclusions Our observations suggest that there is a reduction in the network connectivity of the in vitro neuronal network associated with ASD patients with TSC2 mutation, which may arise via an excitatory/inhibitory imbalance due to increased GABA-signalling at inhibitory synapses. This abnormality can be effectively suppressed via activation of ULK1.

Corrigendum to “Ammonium chloride influences in vitro-neuronal network activity” [Experimental Neurology 235/1 (2008) 368–373]

2012 ◽  
Vol 236 (2) ◽  
pp. 240
Author(s):  
Clara-Sophie Schwarz ◽  
Stefano Ferrea ◽  
Kim Quasthoff ◽  
Janine Walter ◽  
Boris Görg ◽  
...  
Keyword(s):  
Ammonium Chloride ◽  
Neuronal Network ◽  
Network Activity ◽  
Experimental Neurology ◽  
Neuronal Network Activity

scholarly journals An in vitro bioengineered model of the human arterial neurovascular unit to study neurodegenerative diseases

2020 ◽  
Author(s):  
Jerome Robert ◽  
Nicholas Weilinger ◽  
Li-Ping Zao ◽  
Stefano Cataldi ◽  
Emily Button ◽  
...  
Keyword(s):  
Neurodegenerative Diseases ◽  
Cortical Neurons ◽  
Neurovascular Unit ◽  
Induced Pluripotent Stem Cell ◽  
Cell Types ◽  
Experimental Models ◽  
Flow Conditions ◽  
Anatomy And Physiology ◽  
Induced Pluripotent

Abstract Introduction: The neurovascular unit (NVU) – the interaction between the neurons and the cerebrovasculature – is increasingly important to interrogate through human-based experimental models. Although advanced models of cerebral capillaries have been developed in the last decade, there is currently noin vitro3-dimensional (3D) perfusible model of the human cortical arterial NVU. Method: We used a tissue-engineering technique to develop a scaffold-directed, perfusible, 3D human NVU that is cultured in native-like flow conditions that mimics the anatomy and physiology of cortical penetrating arteries. Results: This system, composed of primary human vascular cells (endothelial cells, smooth muscle cells and astrocytes) and induced pluripotent stem cell (iPSC) derived neurons, demonstrates a physiological multilayer organization of the involved cell types. It also reproduces key characteristics of cortical neurons and astrocytes, as well as the formation of a selective and functional endothelial barrier. We further provide proof-of-principle that our in vitro human arterial NVU may be suitable to study neurodegenerative diseases such as Alzheimer’s disease (AD), as we report both phosphorylated tau and beta-amyloid accumulation in our model over time. Finally, we show that our arterial NVU model enables the study of neuronal and glial fluid biomarkers. Conclusion: This model is a suitable tool to investigate arterial NVU functions such as neuronal electrophysiology in health and disease. Further the design of platform allows culture under native-like flow conditions for extended periods of time and yields sufficient tissue and media for downstream immunohistochemistry and biochemistry analyses.

scholarly journals Sodium channel Nav1.2-L1342P variant displaying complex biophysical properties renders hyperexcitability of cortical neurons derived from human iPSCs

2021 ◽  
Author(s):  
Zhefu Que ◽  
Maria I. Olivero-Acosta ◽  
Jingliang Zhang ◽  
Muriel Eaton ◽  
William C. Skarnes ◽  
...  
Keyword(s):  
Sodium Channel ◽  
Cortical Neurons ◽  
Sodium Current ◽  
Electrode Array ◽  
Induced Pluripotent Stem Cell ◽  
Epileptic Seizures ◽  
Action Potential Firing ◽  
Human Neurons ◽  
Human Ipscs

AbstractWith the wide adoption of whole-exome sequencing in children having seizures, an increasing number of SCN2A variants has been revealed as possible genetic causes of epilepsy. Voltage-gated sodium channel Nav1.2, encoded by gene SCN2A, is strongly expressed in the pyramidal excitatory neurons and supports action potential firing. One recurrent SCN2A variant is L1342P, which was identified in multiple patients with early-onset encephalopathy and intractable seizures. Our biophysical analysis and computational modeling predicted gain-of-function features of this epilepsy-associated Nav1.2 variant. However, the mechanism underlying L1342P mediated seizures and the pharmacogenetics of this variant in human neurons remain unknown. To understand the core phenotypes of the L1342P variant in human neurons, we took advantage of a reference human induced pluripotent stem cell (hiPSC) line, in which L1342P was engineered by CRISPR/Cas9 mediated genome-editing. Using patch-clamping and micro-electrode array (MEA) recording, we found that the cortical neurons derived from hiPSCs carrying heterozygous L1342P variant presented significantly increased intrinsic excitability, higher sodium current density, and enhanced bursting and synchronous network firing, showing clear hyperexcitability phenotypes. Interestingly, the L1342P neuronal culture displayed a degree of resistance to the anti-seizure medication (phenytoin), which likely recapitulated aspects of clinical observation of patients carrying the L1342P variant. In contrast, phrixotoxin-3 (PTx3), a Nav1.2 isoform-specific blocker, was able to potently alleviate spontaneous and chemical-induced hyperexcitability of neurons carrying the L1342P variant. Our results reveal a possible pathogenic underpinning of Nav1.2-L1342P mediated epileptic seizures, and demonstrate the utility of genome-edited hiPSCs as an in vitro platform to advance personalized phenotyping and drug discovery.

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