Your search keyword '"human neurons"' showing total 268 results

1. APOE4 Increases Energy Metabolism in APOE-Isogenic iPSC-Derived Neurons.

Author

Budny, Vanessa, Knöpfli, Yannic, Meier, Debora, Zürcher, Kathrin, Bodenmann, Chantal, Peter, Siri L., Müller, Terry, Tardy, Marie, Cortijo, Cedric, and Tackenberg, Christian

Subjects

*INDUCED pluripotent stem cells, *CHIMERIC proteins, *DISEASE risk factors, *APOLIPOPROTEIN E4, *PLURIPOTENT stem cells, *APOLIPOPROTEIN E

Abstract

The apolipoprotein E4 (APOE4) allele represents the major genetic risk factor for Alzheimer's disease (AD). In contrast, APOE2 is known to lower the AD risk, while APOE3 is defined as risk neutral. APOE plays a prominent role in the bioenergetic homeostasis of the brain, and early-stage metabolic changes have been detected in the brains of AD patients. Although APOE is primarily expressed by astrocytes in the brain, neurons have also been shown as source for APOE. However, the distinct roles of the three APOE isoforms in neuronal energy homeostasis remain poorly understood. In this study, we generated pure human neurons (iN cells) from APOE-isogenic induced pluripotent stem cells (iPSCs), expressing either APOE2, APOE3, APOE4, or carrying an APOE knockout (KO) to investigate APOE isoform-specific effects on neuronal energy metabolism. We showed that endogenously produced APOE4 enhanced mitochondrial ATP production in APOE-isogenic iN cells but not in the corresponding iPS cell line. This effect neither correlated with the expression levels of mitochondrial fission or fusion proteins nor with the intracellular or secreted levels of APOE, which were similar for APOE2, APOE3, and APOE4 iN cells. ATP production and basal respiration in APOE-KO iN cells strongly differed from APOE4 and more closely resembled APOE2 and APOE3 iN cells, indicating a gain-of-function mechanism of APOE4 rather than a loss-of-function. Taken together, our findings in APOE isogenic iN cells reveal an APOE genotype-dependent and neuron-specific regulation of oxidative energy metabolism. [ABSTRACT FROM AUTHOR]

Published

2024

2. APOE4 Increases Energy Metabolism in APOE-Isogenic iPSC-Derived Neurons

Author

Vanessa Budny, Yannic Knöpfli, Debora Meier, Kathrin Zürcher, Chantal Bodenmann, Siri L. Peter, Terry Müller, Marie Tardy, Cedric Cortijo, and Christian Tackenberg

Subjects

apolipoprotein E (APOE), Alzheimer’s disease, induced pluripotent stem cells (iPSCs), human neurons, energy metabolism, glycolysis, Cytology, QH573-671

Abstract

The apolipoprotein E4 (APOE4) allele represents the major genetic risk factor for Alzheimer’s disease (AD). In contrast, APOE2 is known to lower the AD risk, while APOE3 is defined as risk neutral. APOE plays a prominent role in the bioenergetic homeostasis of the brain, and early-stage metabolic changes have been detected in the brains of AD patients. Although APOE is primarily expressed by astrocytes in the brain, neurons have also been shown as source for APOE. However, the distinct roles of the three APOE isoforms in neuronal energy homeostasis remain poorly understood. In this study, we generated pure human neurons (iN cells) from APOE-isogenic induced pluripotent stem cells (iPSCs), expressing either APOE2, APOE3, APOE4, or carrying an APOE knockout (KO) to investigate APOE isoform-specific effects on neuronal energy metabolism. We showed that endogenously produced APOE4 enhanced mitochondrial ATP production in APOE-isogenic iN cells but not in the corresponding iPS cell line. This effect neither correlated with the expression levels of mitochondrial fission or fusion proteins nor with the intracellular or secreted levels of APOE, which were similar for APOE2, APOE3, and APOE4 iN cells. ATP production and basal respiration in APOE-KO iN cells strongly differed from APOE4 and more closely resembled APOE2 and APOE3 iN cells, indicating a gain-of-function mechanism of APOE4 rather than a loss-of-function. Taken together, our findings in APOE isogenic iN cells reveal an APOE genotype-dependent and neuron-specific regulation of oxidative energy metabolism.

Published

2024

3. Identification of Molecular Mechanisms Responsible for the MMP-9-1562C/T Dependent Differential Regulation of Matrix Metalloproteinase-9 Expression in Human Neuron-like Cells.

Author

Pabian-Jewuła, Sylwia, Ambrożek-Latecka, Magdalena, Brągiel-Pieczonka, Aneta, Nowicka, Klaudia, and Rylski, Marcin

Subjects

*GENE expression, *ZINC-finger proteins, *GENETIC regulation, *GENETIC transcription regulation, *HISTONE deacetylase

Abstract

The MMP-9-1562C/T polymorphism exerts an impact on the occurrence and progression of numerous disorders affecting the central nervous system. Using luciferase assays and Q-RT-PCR technique, we have discovered a distinct allele-specific influence of the MMP-9-1562C/T polymorphism on the MMP-9 (Extracellular Matrix Metalloproteinase-9) promoter activity and the expression of MMP-9 mRNA in human neurons derived from SH-SY5Y cells. Subsequently, by employing a pull-down assay paired with mass spectrometry analysis, EMSA (Electromobility Shift Assay), and EMSA supershift techniques, as well as DsiRNA-dependent gene silencing, we have elucidated the mechanism responsible for the allele-specific impact of the MMP-9-1562C/T polymorphism on the transcriptional regulation of the MMP-9 gene. We have discovered that the activity of the MMP-9 promoter and the expression of MMP-9 mRNA in human neurons are regulated in a manner that is specific to the MMP-9-1562C/T allele, with a stronger upregulation being attributed to the C allele. Furthermore, we have demonstrated that the allele-specific action of the MMP-9-1562C/T polymorphism on the neuronal MMP-9 expression is related to HDAC1 (Histone deacetylase 1) and ZNF384 (Zinc Finger Protein 384) transcriptional regulators. We show that HDAC1 and ZNF384 bind to the C and the T alleles differently, forming different regulatory complexes in vitro. Moreover, our data demonstrate that HDAC1 and ZNF384 downregulate MMP-9 gene promoter activity and mRNA expression in human neurons acting mostly via the T allele. [ABSTRACT FROM AUTHOR]

Published

2023

4. Use of in vitro derived human neuronal models to study host-parasite interactions of Toxoplasma gondii in neurons and neuropathogenesis of chronic toxoplasmosis.

Author

Halonen, Sandra K.

Subjects

INDUCED pluripotent stem cells, TOXOPLASMA gondii, TOXOPLASMOSIS, NEURONS, SOMATIC cells

Abstract

Toxoplasma gondii infects approximately one-third of the world's population resulting in a chronic infection with the parasite located in cysts in neurons in the brain. In most immunocompetent hosts the chronic infection is asymptomatic, but several studies have found correlations between Toxoplasma seropositivity and neuropsychiatric disorders, including Schizophrenia, and some other neurological disorders. Host-parasite interactions of bradyzoites in cysts in neurons is not well understood due in part to the lack of suitable in vitro human neuronal models. The advent of stem cell technologies in which human neurons can be derived in vitro from human induced pluripotent stem cells (hiPSCs) or direct conversion of somatic cells generating induced neurons (iNs), affords the opportunity to develop in vitro human neuronal culture systems to advance the understanding of T. gondii in human neurons. Human neurons derived from hiPSCs or iNs, generate pure human neuron monolayers that express differentiated neuronal characteristics. hiPSCs also generate 3D neuronal models that better recapitulate the cytoarchitecture of the human brain. In this review, an overview of iPSC-derived neurons and iN protocols leading to 2D human neuron cultures and hiPSC-derived 3D cerebral organoids will be given. The potential applications of these 2D and 3D human neuronal models to address questions about host-parasite interactions of T. gondii in neurons and the parasite in the CNS, will be discussed. These human neuronal in vitro models hold the promise to advance the understanding of T. gondii in human neurons and to improve the understanding of neuropathogenesis of chronic toxoplasmosis. [ABSTRACT FROM AUTHOR]

Published

2023

5. Use of in vitro derived human neuronal models to study host-parasite interactions of Toxoplasma gondii in neurons and neuropathogenesis of chronic toxoplasmosis

Author

Sandra K. Halonen

Subjects

human neurons, human iPSCs, spontaneous cystogenesis, bradyzoites, cerebral organoids, Microbiology, QR1-502

Abstract

Toxoplasma gondii infects approximately one-third of the world’s population resulting in a chronic infection with the parasite located in cysts in neurons in the brain. In most immunocompetent hosts the chronic infection is asymptomatic, but several studies have found correlations between Toxoplasma seropositivity and neuropsychiatric disorders, including Schizophrenia, and some other neurological disorders. Host-parasite interactions of bradyzoites in cysts in neurons is not well understood due in part to the lack of suitable in vitro human neuronal models. The advent of stem cell technologies in which human neurons can be derived in vitro from human induced pluripotent stem cells (hiPSCs) or direct conversion of somatic cells generating induced neurons (iNs), affords the opportunity to develop in vitro human neuronal culture systems to advance the understanding of T. gondii in human neurons. Human neurons derived from hiPSCs or iNs, generate pure human neuron monolayers that express differentiated neuronal characteristics. hiPSCs also generate 3D neuronal models that better recapitulate the cytoarchitecture of the human brain. In this review, an overview of iPSC-derived neurons and iN protocols leading to 2D human neuron cultures and hiPSC-derived 3D cerebral organoids will be given. The potential applications of these 2D and 3D human neuronal models to address questions about host-parasite interactions of T. gondii in neurons and the parasite in the CNS, will be discussed. These human neuronal in vitro models hold the promise to advance the understanding of T. gondii in human neurons and to improve the understanding of neuropathogenesis of chronic toxoplasmosis.

Published

2023

6. Vesicular Glutamate Release from Feeder-FreehiPSC-Derived Neurons.

Author

Baldassari, Simona, Cervetto, Chiara, Amato, Sarah, Fruscione, Floriana, Balagura, Ganna, Pelassa, Simone, Musante, Ilaria, Iacomino, Michele, Traverso, Monica, Corradi, Anna, Scudieri, Paolo, Maura, Guido, Marcoli, Manuela, and Zara, Federico

Subjects

*NEUROTRANSMITTER receptors, *PLURIPOTENT stem cells, *GENE expression profiling, *NEURONS, *GLUTAMATE receptors, *DRUG discovery, *NEURONAL differentiation, *GLUTAMIC acid

Abstract

Human-induced pluripotent stem cells (hiPSCs) represent one of the main and powerful tools for the in vitro modeling of neurological diseases. Standard hiPSC-based protocols make use of animal-derived feeder systems to better support the neuronal differentiation process. Despite their efficiency, such protocols may not be appropriate to dissect neuronal specific properties or to avoid interspecies contaminations, hindering their future translation into clinical and drug discovery approaches. In this work, we focused on the optimization of a reproducible protocol in feeder-free conditions able to generate functional glutamatergic neurons. This protocol is based on a generation of neuroprecursor cells differentiated into human neurons with the administration in the culture medium of specific neurotrophins in a Geltrex-coated substrate. We confirmed the efficiency of this protocol through molecular analysis (upregulation of neuronal markers and neurotransmitter receptors assessed by gene expression profiling and expression of the neuronal markers at the protein level), morphological analysis, and immunfluorescence detection of pre-synaptic and post-synaptic markers at synaptic boutons. The hiPSC-derived neurons acquired Ca2+-dependent glutamate release properties as a hallmark of neuronal maturation. In conclusion, our study describes a new methodological approach to achieve feeder-free neuronal differentiation from hiPSC and adds a new tool for functional characterization of hiPSC-derived neurons. [ABSTRACT FROM AUTHOR]

Published

2022

7. A human iPSC-derived inducible neuronal model of Niemann-Pick disease, type C1

Author

Anika V. Prabhu, Insung Kang, Raffaella De Pace, Christopher A. Wassif, Hideji Fujiwara, Pamela Kell, Xuntian Jiang, Daniel S. Ory, Juan S. Bonifacino, Michael E. Ward, and Forbes D. Porter

Subjects

Human induced pluripotent stem cells, Human neurons, Niemann-Pick disease, type C1, Neurodegeneration, NPC1, Lysosomal disease, Biology (General), QH301-705.5

Abstract

Abstract Background Niemann-Pick disease, type C (NPC) is a childhood-onset, lethal, neurodegenerative disorder caused by autosomal recessive mutations in the genes NPC1 or NPC2 and characterized by impaired cholesterol homeostasis, a lipid essential for cellular function. Cellular cholesterol levels are tightly regulated, and mutations in either NPC1 or NPC2 lead to deficient transport and accumulation of unesterified cholesterol in the late endosome/lysosome compartment, and progressive neurodegeneration in affected individuals. Previous cell-based studies to understand the NPC cellular pathophysiology and screen for therapeutic agents have mainly used patient fibroblasts. However, these do not allow modeling the neurodegenerative aspect of NPC disease, highlighting the need for an in vitro system that permits understanding the cellular mechanisms underlying neuronal loss and identifying appropriate therapies. This study reports the development of a novel human iPSC-derived, inducible neuronal model of Niemann-Pick disease, type C1 (NPC1). Results We generated a null i3Neuron (inducible × integrated × isogenic) (NPC1 −/− i3Neuron) iPSC-derived neuron model of NPC1. The NPC1 −/− and the corresponding isogenic NPC1 +/+ i3Neuron cell lines were used to efficiently generate homogenous, synchronized neurons that can be used in high-throughput screens. NPC1 −/− i3Neurons recapitulate cardinal cellular NPC1 pathological features including perinuclear endolysosomal storage of unesterified cholesterol, accumulation of GM2 and GM3 gangliosides, mitochondrial dysfunction, and impaired axonal lysosomal transport. Cholesterol storage, mitochondrial dysfunction, and axonal trafficking defects can be ameliorated by treatment with 2-hydroxypropyl-β-cyclodextrin, a drug that has shown efficacy in NPC1 preclinical models and in a phase 1/2a trial. Conclusion Our data demonstrate the utility of this new cell line in high-throughput drug/chemical screens to identify potential therapeutic agents. The NPC1 −/− i3Neuron line will also be a valuable tool for the NPC1 research community to explore the pathological mechanisms contributing to neuronal degeneration. Graphical abstract

Published

2021

8. DYRK1A Regulates the Bidirectional Axonal Transport of APP in Human-Derived Neurons.

Author

Fernandez Bessone, Iván, Navarro, Jordi, Martinez, Emanuel, Karmirian, Karina, Holubiec, Mariana, Alloatti, Matias, Goto-Silva, Livia, Arnaiz Yepez, Cayetana, Martins-de-Souza, Daniel, Minardi Nascimento, Juliana, Bruno, Luciana, Saez, Trinidad M., Rehen, Stevens K., and Falzone, Tomás L.

Subjects

*AXONAL transport, *DOWN syndrome, *ALZHEIMER'S disease, *NEURONS, *MOBILE apps

Abstract

Dyrk1a triplication in Down's syndrome and its overexpression in Alzheimer's disease suggest a role for increased DYRK1A activity in the abnormal metabolism of APP. Transport defects are early phenotypes in the progression of Alzheimer's disease, which lead to APP processing impairments. However, whether DYRK1A regulates the intracellular transport and delivery of APP in human neurons remains unknown. From a proteomic dataset of human cerebral organoids treated with harmine, a DYRK1A inhibitor, we found expression changes in protein clusters associated with the control of microtubule-based transport and in close interaction with the APP vesicle. Live imaging of APP axonal transport in human-derived neurons treated with harmine or overexpressing a dominant negative DYRK1A revealed a reduction in APP vesicle density and enhanced the stochastic behavior of retrograde vesicle transport. Moreover, harmine increased the fraction of slow segmental velocities and changed speed transitions supporting a DYRK1A-mediated effect in the exchange of active motor configuration. Contrarily, the overexpression of DYRK1A in human polarized neurons increased the axonal density of APP vesicles and enhanced the processivity of retrograde APP. In addition, increased DYRK1A activity induced faster retrograde segmental velocities together with significant changes in slow to fast anterograde and retrograde speed transitions, suggesting the facilitation of the active motor configuration. Our results highlight DYRK1A as a modulator of the axonal transport machinery driving APP intracellular distribution in neurons, and stress DYRK1A inhibition as a putative therapeutic intervention to restore APP axonal transport in Down's syndrome and Alzheimer's disease. [ABSTRACT FROM AUTHOR]

Published

2022

9. Scalable Production of iPSC-Derived Human Neurons to Identify Tau-Lowering Compounds by High-Content Screening.

Author

Wang, Chao, Ward, Michael E, Chen, Robert, Liu, Kai, Tracy, Tara E, Chen, Xu, Xie, Min, Sohn, Peter Dongmin, Ludwig, Connor, Meyer-Franke, Anke, Karch, Celeste M, Ding, Sheng, and Gan, Li

Subjects

Neurons, Cells, Cultured, Cell Line, Humans, Glutamine, tau Proteins, Drug Evaluation, Preclinical, Cell Differentiation, Cell Survival, Gene Expression, Gene Expression Regulation, Membrane Potentials, Gene Order, Genetic Vectors, Drug Discovery, Induced Pluripotent Stem Cells, High-Throughput Screening Assays, Alzheimer’s disease, Tau-lowering, adrenergic receptor, frontotemporal dementia, high-content screening, human induced pluripotent stem cells, human neurons, neurodegeneration, neurogenin 2, tau, Cells, Cultured, Drug Evaluation, Preclinical, Biochemistry and Cell Biology, Clinical Sciences

Abstract

Lowering total tau levels is an attractive therapeutic strategy for Alzheimer's disease and other tauopathies. High-throughput screening in neurons derived from human induced pluripotent stem cells (iPSCs) is a powerful tool to identify tau-targeted therapeutics. However, such screens have been hampered by heterogeneous neuronal production, high cost and low yield, and multi-step differentiation procedures. We engineered an isogenic iPSC line that harbors an inducible neurogenin 2 transgene, a transcription factor that rapidly converts iPSCs to neurons, integrated at the AAVS1 locus. Using a simplified two-step protocol, we differentiated these iPSCs into cortical glutamatergic neurons with minimal well-to-well variability. We developed a robust high-content screening assay to identify tau-lowering compounds in LOPAC and identified adrenergic receptors agonists as a class of compounds that reduce endogenous human tau. These techniques enable the use of human neurons for high-throughput screening of drugs to treat neurodegenerative disease.

Published

2017

10. Modeling autism spectrum disorders with human neurons

Author

Beltrão-Braga, Patricia CB and Muotri, Alysson R

Subjects

Biomedical and Clinical Sciences, Neurosciences, Stem Cell Research, Mental Health, Stem Cell Research - Induced Pluripotent Stem Cell, Autism, Brain Disorders, Intellectual and Developmental Disabilities (IDD), Stem Cell Research - Induced Pluripotent Stem Cell - Human, Pediatric, Behavioral and Social Science, 2.1 Biological and endogenous factors, Mental health, Animals, Autism Spectrum Disorder, Humans, Neurons, Autism spectrum disorders, Disease modeling, Human induced pluripotent stem cells, Human neurons, Psychology, Cognitive Sciences, Neurology & Neurosurgery, Biological psychology

Abstract

Autism spectrum disorder (ASD) is a group of neurodevelopmental disorders characterized by impaired social communication and interactions and by restricted and repetitive behaviors. Although ASD is suspected to have a heritable or sporadic genetic basis, its underlying etiology and pathogenesis are not well understood. Therefore, viable human neurons and glial cells produced using induced pluripotent stem cells (iPSC) to reprogram cells from individuals affected with ASD provide an unprecedented opportunity to elucidate the pathophysiology of these disorders, providing novel insights regarding ASD and a potential platform to develop and test therapeutic compounds. Herein, we discuss the state of art with regards to ASD modeling, including limitations of this technology, as well as potential future directions. This article is part of a Special Issue entitled SI: Exploiting human neurons.

Published

2017

11. Exposure to ambient ultrafine particulate matter alters the expression of genes in primary human neurons

Author

Solaimani, Parrisa, Saffari, Arian, Sioutas, Constantinos, Bondy, Stephen C, and Campbell, Arezoo

Subjects

Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Neurosciences, Genetics, Climate-Related Exposures and Conditions, Biotechnology, Neurodegenerative, 2.1 Biological and endogenous factors, Aetiology, Neurological, Adenosine Triphosphate, Brain, Cells, Cultured, Fetus, Gene Expression Regulation, Humans, Metallothionein, Microarray Analysis, Neurons, Particulate Matter, RNA, Messenger, RNA, Untranslated, Tumor Necrosis Factor-alpha, Air pollution, Ultrafine particulate matter, Human neurons, Noncoding RNA, Neurodevelopment, Genetic imprinting, Toxicology, Pharmacology and pharmaceutical sciences

Abstract

Exposure to ambient particulate matter (PM) has been associated with the onset of neurodevelopmental and neurodegenerative disorders, but the mechanism of toxicity remains unclear. To gain insight into this neurotoxicity, this study sought to examine global gene expression changes caused by exposure to ambient ultrafine PM. Microarray analysis was performed on primary human neurons derived from fetal brain tissue after a 24h exposure to 20μg/mL of ambient ultrafine particles. We found a majority of the changes in noncoding RNAs, which are involved in epigenetic regulation of gene expression, and thereby could impact the expression of several other protein coding gene targets. Although neurons from biologically different lot numbers were used, we found a significant increase in the expression of metallothionein 1A and 1F in all samples after exposure to particulate matter as confirmed by quantitative PCR. These metallothionein 1 proteins are responsible for neuroprotection after exposure to environmental insult but prolonged induction can be toxic. Epidemiological studies have reported that in utero exposure to ultrafine PM not only leads to neurodevelopmental and behavioral abnormalities, but may also predispose the progeny to neurodegenerative disease later in life by genetic imprinting. Our results pinpoint some of the PM-induced genetic changes that may underlie these findings.

Published

2017

12. Advances in Human Stem Cell-Derived Neuronal Cell Culturing and Analysis

Author

Ylä-Outinen, Laura, Tanskanen, Jarno M. A., Kapucu, Fikret E., Hyysalo, Anu, Hyttinen, Jari A. K., Narkilahti, Susanna, Schousboe, Arne, Series Editor, Chiappalone, Michela, editor, Pasquale, Valentina, editor, and Frega, Monica, editor

Published

2019

13. The Human Model: Changing Focus on Autism Research

Author

Muotri, Alysson Renato

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Genetics, Neurosciences, Brain Disorders, Autism, Stem Cell Research, Stem Cell Research - Nonembryonic - Human, Mental Health, Intellectual and Developmental Disabilities (IDD), Human Genome, Aetiology, 2.1 Biological and endogenous factors, Underpinning research, 1.1 Normal biological development and functioning, Neurological, Generic health relevance, Good Health and Well Being, Animals, Autistic Disorder, Brain, Humans, Induced Pluripotent Stem Cells, Models, Biological, Autism spectrum disorders, Drug screening, Human induced pluripotent stem cells, Human neurons, Human-specific disease modeling, Medical and Health Sciences, Psychology and Cognitive Sciences, Psychiatry, Biological sciences, Biomedical and clinical sciences, Psychology

Abstract

The lack of live human brain cells for research has slowed progress toward understanding the mechanisms underlying autism spectrum disorders. A human model using reprogrammed patient somatic cells offers an attractive alternative, as it captures a patient's genome in relevant cell types. Despite the current limitations, the disease-in-a-dish approach allows for progressive time course analyses of target cells, offering a unique opportunity to investigate the cellular and molecular alterations before symptomatic onset. Understanding the current drawbacks of this model is essential for the correct data interpretation and extrapolation of conclusions applicable to the human brain. Innovative strategies for collecting biological material and clinical information from large patient cohorts are important for increasing the statistical power that will allow for the extraction of information from the noise resulting from the variability introduced by reprogramming and differentiation methods. Working with large patient cohorts is also important for understanding how brain cells derived from diverse human genetic backgrounds respond to specific drugs, creating the possibility of personalized medicine for autism spectrum disorders.

Published

2016

14. Electrophysiological- and Neuropharmacological-Based Benchmarking of Human Induced Pluripotent Stem Cell-Derived and Primary Rodent Neurons.

Author

Jezierski, Anna, Baumann, Ewa, Aylsworth, Amy, Costain, Willard J., Corluka, Slavisa, Banderali, Umberto, Sodja, Caroline, Ribecco-Lutkiewicz, Maria, Alasmar, Salma, Martina, Marzia, and Tauskela, Joseph S.

Subjects

*INDUCED pluripotent stem cells, *GABAERGIC neurons, *AMNIOTIC liquid, *NEURONS, *ION channels, *RODENTS, *PRINCIPAL components analysis

Abstract

Human induced pluripotent stem cell (iPSC)-derived neurons are of interest for studying neurological disease mechanisms, developing potential therapies and deepening our understanding of the human nervous system. However, compared to an extensive history of practice with primary rodent neuron cultures, human iPSC-neurons still require more robust characterization of expression of neuronal receptors and ion channels and functional and predictive pharmacological responses. In this study, we differentiated human amniotic fluid-derived iPSCs into a mixed population of neurons (AF-iNs). Functional assessments were performed by evaluating electrophysiological (patch-clamp) properties and the effect of a panel of neuropharmacological agents on spontaneous activity (multi-electrode arrays; MEAs). These electrophysiological data were benchmarked relative to commercially sourced human iPSC-derived neurons (CNS.4U from Ncardia), primary human neurons (ScienCell™) and primary rodent cortical/hippocampal neurons. Patch-clamp whole-cell recordings showed that mature AF-iNs generated repetitive firing of action potentials in response to depolarizations, similar to that of primary rodent cortical/hippocampal neurons, with nearly half of the neurons displaying spontaneous post-synaptic currents. Immunochemical and MEA-based analyses indicated that AF-iNs were composed of functional glutamatergic excitatory and inhibitory GABAergic neurons. Principal component analysis of MEA data indicated that human AF-iN and rat neurons exhibited distinct pharmacological and electrophysiological properties. Collectively, this study establishes a necessary prerequisite for AF-iNs as a human neuron culture model suitable for pharmacological studies. [ABSTRACT FROM AUTHOR]

Published

2022

15. A human iPSC-derived inducible neuronal model of Niemann-Pick disease, type C1.

Author

Prabhu, Anika V., Kang, Insung, De Pace, Raffaella, Wassif, Christopher A., Fujiwara, Hideji, Kell, Pamela, Jiang, Xuntian, Ory, Daniel S., Bonifacino, Juan S., Ward, Michael E., and Porter, Forbes D.

Subjects

*NIEMANN-Pick diseases, *CELL physiology, *HIGH throughput screening (Drug development), *AXONAL transport, *RECESSIVE genes, *FAMILIAL spastic paraplegia, *DYSPLASIA

Abstract

Background: Niemann-Pick disease, type C (NPC) is a childhood-onset, lethal, neurodegenerative disorder caused by autosomal recessive mutations in the genes NPC1 or NPC2 and characterized by impaired cholesterol homeostasis, a lipid essential for cellular function. Cellular cholesterol levels are tightly regulated, and mutations in either NPC1 or NPC2 lead to deficient transport and accumulation of unesterified cholesterol in the late endosome/lysosome compartment, and progressive neurodegeneration in affected individuals. Previous cell-based studies to understand the NPC cellular pathophysiology and screen for therapeutic agents have mainly used patient fibroblasts. However, these do not allow modeling the neurodegenerative aspect of NPC disease, highlighting the need for an in vitro system that permits understanding the cellular mechanisms underlying neuronal loss and identifying appropriate therapies. This study reports the development of a novel human iPSC-derived, inducible neuronal model of Niemann-Pick disease, type C1 (NPC1). Results: We generated a null i3Neuron (inducible × integrated × isogenic) (NPC1−/− i3Neuron) iPSC-derived neuron model of NPC1. The NPC1−/− and the corresponding isogenic NPC1+/+ i3Neuron cell lines were used to efficiently generate homogenous, synchronized neurons that can be used in high-throughput screens. NPC1−/− i3Neurons recapitulate cardinal cellular NPC1 pathological features including perinuclear endolysosomal storage of unesterified cholesterol, accumulation of GM2 and GM3 gangliosides, mitochondrial dysfunction, and impaired axonal lysosomal transport. Cholesterol storage, mitochondrial dysfunction, and axonal trafficking defects can be ameliorated by treatment with 2-hydroxypropyl-β-cyclodextrin, a drug that has shown efficacy in NPC1 preclinical models and in a phase 1/2a trial. Conclusion: Our data demonstrate the utility of this new cell line in high-throughput drug/chemical screens to identify potential therapeutic agents. The NPC1−/− i3Neuron line will also be a valuable tool for the NPC1 research community to explore the pathological mechanisms contributing to neuronal degeneration. [ABSTRACT FROM AUTHOR]

Published

2021

16. Human Neuropsychiatric Disease Modeling using Conditional Deletion Reveals Synaptic Transmission Defects Caused by Heterozygous Mutations in NRXN1

Author

Pak, ChangHui, Danko, Tamas, Zhang, Yingsha, Aoto, Jason, Anderson, Garret, Maxeiner, Stephan, Yi, Fei, Wernig, Marius, and Südhof, Thomas C

Subjects

Autism, Intellectual and Developmental Disabilities (IDD), Mental Health, Stem Cell Research, Genetics, Neurosciences, Schizophrenia, Regenerative Medicine, Brain Disorders, Stem Cell Research - Embryonic - Human, Neurological, Amino Acid Sequence, Calcium-Binding Proteins, Cell Adhesion Molecules, Neuronal, Cell Differentiation, Cell Membrane, Enzyme Stability, Gene Knockout Techniques, Gene Targeting, Guanylate Kinases, Heterozygote, Human Embryonic Stem Cells, Humans, Mental Disorders, Miniature Postsynaptic Potentials, Models, Biological, Molecular Sequence Data, Mutation, Nerve Tissue Proteins, Neural Cell Adhesion Molecules, Neurons, Neurotransmitter Agents, Phenotype, Synapses, Synaptic Transmission, Synaptic Vesicles, autism, human neurons, iN cells, neurexin, schizophrenia, synapse, synaptic cell adhesion, Biological Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Heterozygous mutations of the NRXN1 gene, which encodes the presynaptic cell-adhesion molecule neurexin-1, were repeatedly associated with autism and schizophrenia. However, diverse clinical presentations of NRXN1 mutations in patients raise the question of whether heterozygous NRXN1 mutations alone directly impair synaptic function. To address this question under conditions that precisely control for genetic background, we generated human ESCs with different heterozygous conditional NRXN1 mutations and analyzed two different types of isogenic control and NRXN1 mutant neurons derived from these ESCs. Both heterozygous NRXN1 mutations selectively impaired neurotransmitter release in human neurons without changing neuronal differentiation or synapse formation. Moreover, both NRXN1 mutations increased the levels of CASK, a critical synaptic scaffolding protein that binds to neurexin-1. Our results show that, unexpectedly, heterozygous inactivation of NRXN1 directly impairs synaptic function in human neurons, and they illustrate the value of this conditional deletion approach for studying the functional effects of disease-associated mutations.

Published

2015

17. The Use of Induced Pluripotent Stem Cell Technology to Advance Autism Research and Treatment

Author

Acab, Allan and Muotri, Alysson Renato

Subjects

Medical Biotechnology, Biomedical and Clinical Sciences, Autism, Mental Health, Pediatric, Behavioral and Social Science, Brain Disorders, Neurosciences, Genetics, Intellectual and Developmental Disabilities (IDD), Stem Cell Research - Induced Pluripotent Stem Cell - Human, Regenerative Medicine, Stem Cell Research - Nonembryonic - Human, Stem Cell Research, Stem Cell Research - Induced Pluripotent Stem Cell, Autism Spectrum Disorder, Drug Evaluation, Preclinical, Humans, Induced Pluripotent Stem Cells, Neural Stem Cells, Signal Transduction, Disease modeling, Human induced pluripotent stem cells, Human neurons, Brain, Drug screening, Autism spectrum disorders, Pharmacology and Pharmaceutical Sciences, Public Health and Health Services, Neurology & Neurosurgery, Pharmacology and pharmaceutical sciences, Biological psychology

Abstract

Autism spectrum disorders (ASDs) are a heterogeneous group of neurodevelopmental disorders sharing a core set of symptoms, including impaired social interaction, language deficits, and repetitive behaviors. While ASDs are highly heritable and demonstrate a clear genetic component, the cellular and molecular mechanisms driving ASD etiology remain undefined. The unavailability of live patient-specific neurons has contributed to the difficulty in studying ASD pathophysiology. The recent advent of induced pluripotent stem cells (iPSCs) has provided the ability to generate patient-specific human neurons from somatic cells. The iPSC field has quickly grown, as researchers have demonstrated the utility of this technology to model several diseases, especially neurologic disorders. Here, we review the current literature around using iPSCs to model ASDs, and discuss the notable findings, and the promise and limitations of this technology. The recent report of a nonsyndromic ASD iPSC model and several previous ASD models demonstrating similar results points to the ability of iPSC to reveal potential novel biomarkers and therapeutics.

Published

2015

18. Vesicular Glutamate Release from Feeder-FreehiPSC-Derived Neurons

Author

Simona Baldassari, Chiara Cervetto, Sarah Amato, Floriana Fruscione, Ganna Balagura, Simone Pelassa, Ilaria Musante, Michele Iacomino, Monica Traverso, Anna Corradi, Paolo Scudieri, Guido Maura, Manuela Marcoli, and Federico Zara

Subjects

stem cells, human-induced pluripotent stem cells (hiPSC), human neurons, diseases modelling, neurotransmitter release, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Human-induced pluripotent stem cells (hiPSCs) represent one of the main and powerful tools for the in vitro modeling of neurological diseases. Standard hiPSC-based protocols make use of animal-derived feeder systems to better support the neuronal differentiation process. Despite their efficiency, such protocols may not be appropriate to dissect neuronal specific properties or to avoid interspecies contaminations, hindering their future translation into clinical and drug discovery approaches. In this work, we focused on the optimization of a reproducible protocol in feeder-free conditions able to generate functional glutamatergic neurons. This protocol is based on a generation of neuroprecursor cells differentiated into human neurons with the administration in the culture medium of specific neurotrophins in a Geltrex-coated substrate. We confirmed the efficiency of this protocol through molecular analysis (upregulation of neuronal markers and neurotransmitter receptors assessed by gene expression profiling and expression of the neuronal markers at the protein level), morphological analysis, and immunfluorescence detection of pre-synaptic and post-synaptic markers at synaptic boutons. The hiPSC-derived neurons acquired Ca2+-dependent glutamate release properties as a hallmark of neuronal maturation. In conclusion, our study describes a new methodological approach to achieve feeder-free neuronal differentiation from hiPSC and adds a new tool for functional characterization of hiPSC-derived neurons.

Published

2022

19. Human iPSC 4R tauopathy model uncovers modifiers of tau propagation.

Author

Parra Bravo, Celeste, Giani, Alice Maria, Madero-Perez, Jesus, Zhao, Zeping, Wan, Yuansong, Samelson, Avi J., Wong, Man Ying, Evangelisti, Alessandro, Cordes, Ethan, Fan, Li, Ye, Pearly, Zhu, Daphne, Pozner, Tatyana, Mercedes, Maria, Patel, Tark, Yarahmady, Allan, Carling, Gillian K., Sterky, Fredrik H., Lee, Virginia M.Y., and Lee, Edward B.

Subjects

*TAUOPATHIES, *TAU proteins, *PROGRESSIVE supranuclear palsy, *INDUCED pluripotent stem cells, *ALZHEIMER'S disease

Abstract

Tauopathies are age-associated neurodegenerative diseases whose mechanistic underpinnings remain elusive, partially due to a lack of appropriate human models. Here, we engineered human induced pluripotent stem cell (hiPSC)-derived neuronal lines to express 4R Tau and 4R Tau carrying the P301S MAPT mutation when differentiated into neurons. 4R-P301S neurons display progressive Tau inclusions upon seeding with Tau fibrils and recapitulate features of tauopathy phenotypes including shared transcriptomic signatures, autophagic body accumulation, and reduced neuronal activity. A CRISPRi screen of genes associated with Tau pathobiology identified over 500 genetic modifiers of seeding-induced Tau propagation, including retromer VPS29 and genes in the UFMylation cascade. In progressive supranuclear palsy (PSP) and Alzheimer's Disease (AD) brains, the UFMylation cascade is altered in neurofibrillary-tangle-bearing neurons. Inhibiting the UFMylation cascade in vitro and in vivo suppressed seeding-induced Tau propagation. This model provides a robust platform to identify novel therapeutic strategies for 4R tauopathy. [Display omitted] • Human iPSC-derived 4R-P301S Tau neurons model seeding-induced tauopathy • Neuronal activity and endolysosome and retromer dysfunction enhance Tau propagation • CRISPRi screen identifies over 500 modifiers for seeding-induced tauopathy • UFMylation cascade is a novel key modifier of seeding-induced Tau propagation Robust and scalable iPSC-derived human neurons are generated to model 4R tauopathy phenotypes. CRISPRi-based functional genomic screening in this model identifies genetic modifiers of seeding-induced Tau propagation. [ABSTRACT FROM AUTHOR]

Published

2024

20. ROS-dependent degeneration of human neurons induced by environmentally relevant levels of micro- and nanoplastics of diverse shapes and forms.

Author

Vojnits, Kinga, de León, Andrés, Rathore, Harneet, Liao, Sophia, Zhao, Michael, Gibon, Julien, and Pakpour, Sepideh

Subjects

*GEOMETRIC shapes, *NEURODEGENERATION, *REACTIVE oxygen species, *CYTOTOXINS, *ENVIRONMENTAL health, *NOCICEPTORS

Abstract

Our study explores the pressing issue of micro- and nanoplastics (MNPs) inhalation and their subsequent penetration into the brain, highlighting a significant environmental health concern. We demonstrate that MNPs can indeed penetrate murine brain, warranting further investigation into their neurotoxic effects in humans. We then proceed to test the impact of MNPs at environmentally relevant concentrations, with focusing on variations in size and shape. Our findings reveal that these MNPs induce oxidative stress, cytotoxicity, and neurodegeneration in human neurons, with cortical neurons being more susceptible than nociceptors. Furthermore, we examine the role of biofilms on MNPs, demonstrating that MNPs can serve as a vehicle for pathogenic biofilms that significantly exacerbate these neurotoxic effects. This sequence of investigations reveals that minimal MNPs accumulation can cause oxidative stress and neurodegeneration in human neurons, significantly risking brain health and highlights the need to understand the neurological consequences of inhaling MNPs. Overall, our developed in vitro testing battery has significance in elucidating the effects of environmental factors and their associated pathological mechanisms in human neurons. [Display omitted] • MNPs accumulate in murine brain after intranasal low concentration administration. • MNPs exposure induces cytotoxicity and neurodegeneration in human neurons. • Degree of neurotoxicity depends on the concentration, size, or shape of MNPs. • MNPs can serve as a vehicle for pathogenic biofilms. • MNPs accumulation in neurons increases mitochondrial reactive oxygen species production. [ABSTRACT FROM AUTHOR]

Published

2024

21. Disease Modeling with Human Neurons Reveals LMNB1 Dysregulation Underlying DYT1 Dystonia.

Author

Baojin Ding, Yu Tang, Shuaipeng Ma, Akter, Masuma, Meng-Lu Liu, Tong Zang, and Chun-Li Zhang

Subjects

*MOVEMENT disorders, *INDUCED pluripotent stem cells, *NUCLEOCYTOPLASMIC interactions, *NUCLEAR transport, *MOTOR neurons, *DYSTONIA, *FIBROBLASTS

Abstract

DYT1 dystonia is a hereditary neurologic movement disorder characterized by uncontrollable muscle contractions. It is caused by a heterozygous mutation in Torsin A (TOR1A), a gene encoding a membrane-embedded ATPase. While animal models provide insights into disease mechanisms, significant species-dependent differences exist since animals with the identical heterozygous mutation fail to show pathology. Here, we model DYT1 by using human patient-specific cholinergic motor neurons (MNs) that are generated through either direct conversion of patients' skin fibroblasts or differentiation of induced pluripotent stem cells (iPSCs). These human MNs with the heterozygous TOR1A mutation show reduced neurite length and branches, markedly thickened nuclear lamina, disrupted nuclear morphology, and impaired nucleocytoplasmic transport (NCT) of mRNAs and proteins, whereas they lack the perinuclear "blebs" that are often observed in animal models. Furthermore, we uncover that the nuclear lamina protein LMNB1 is upregulated in DYT1 cells and exhibits abnormal subcellular distribution in a cholinergic MNs-specific manner. Such dysregulation of LMNB1 can be recapitulated by either ectopic expression of the mutant TOR1A gene or shRNA-mediated downregulation of endogenous TOR1A in healthy control MNs. Interestingly, downregulation of LMNB1 can largely ameliorate all the cellular defects in DYT1 MNs. These results reveal the value of disease modeling with human patient-specific neurons and indicate that dysregulation of LMNB1, a crucial component of the nuclear lamina, may constitute a major molecular mechanism underlying DYT1 pathology. [ABSTRACT FROM AUTHOR]

Published

2021

22. A Distinct Hibiscus sabdariffa Extract Prevents Iron Neurotoxicity, a Driver of Multiple Sclerosis Pathology

Author

Manoj Kumar Mishra, Jianxiong Wang, Reza Mirzaei, Rigel Chan, Helvira Melo, Ping Zhang, Chang-Chun Ling, Aldo Bruccoleri, Lin Tang, and V. Wee Yong

Subjects

experimental autoimmune encephalomyelitis, human neurons, iron, multiple sclerosis, neurodegeneration, neuroprotection, Cytology, QH573-671

Abstract

Iron deposition in the brain begins early in multiple sclerosis (MS) and continues unabated. Ferrous iron is toxic to neurons, yet the therapies used in MS do not counter iron neurotoxicity. Extracts of Hibiscus sabdariffa (HS) are used in many cultures for medicinal purposes. We collected a distinct HS extract and found that it abolished the killing of neurons by iron in culture; medications used in MS were ineffective when similarly tested. Neuroprotection by HS was not due to iron chelation or anthocyanin content. In free radical scavenging assays, HS was equipotent to alpha lipoic acid, an anti-oxidant being tested in MS. However, alpha lipoic acid was only modestly protective against iron-mediated killing. Moreover, a subfraction of HS without radical scavenging activity negated iron toxicity, whereas a commercial hibiscus preparation with anti-oxidant activity could not. The idea that HS might have altered properties within neurons to confer neuroprotection is supported by its amelioration of toxicity caused by other toxins: beta-amyloid, rotenone and staurosporine. Finally, in a mouse model of MS, HS reduced disability scores and ameliorated the loss of axons in the spinal cord. HS holds therapeutic potential to counter iron neurotoxicity, an unmet need that drives the progression of disability in MS.

Published

2022

23. Integrative Analysis Identifies Key Molecular Signatures Underlying Neurodevelopmental Deficits in Fragile X Syndrome.

Author

Utami, Kagistia Hana, Skotte, Niels H., Colaço, Ana R., Yusof, Nur Amirah Binte Mohammad, Sim, Bernice, Yeo, Xin Yi, Bae, Han-Gyu, Garcia-Miralles, Marta, Radulescu, Carola I., Chen, Qiyu, Chaldaiopoulou, Georgia, Liany, Herty, Nama, Srikanth, Peteri, Ulla-Kaisa A., Sampath, Prabha, Castrén, Maija L., Jung, Sangyong, Mann, Matthias, and Pouladi, Mahmoud A.

Subjects

*FRAGILE X syndrome, *PLURIPOTENT stem cells, *HUMAN stem cells, *PATCH-clamp techniques (Electrophysiology), *NEURAL stem cells

Abstract

Fragile X syndrome (FXS) is a neurodevelopmental disorder caused by epigenetic silencing of FMR1 and loss of FMRP expression. Efforts to understand the molecular underpinnings of the disease have been largely performed in rodent or nonisogenic settings. A detailed examination of the impact of FMRP loss on cellular processes and neuronal properties in the context of isogenic human neurons remains lacking. Using CRISPR (clustered regularly interspaced short palindromic repeats)/Cas9 to introduce indels in exon 3 of FMR1, we generated an isogenic human pluripotent stem cell model of FXS that shows complete loss of FMRP expression. We generated neuronal cultures and performed genome-wide transcriptome and proteome profiling followed by functional validation of key dysregulated processes. We further analyzed neurodevelopmental and neuronal properties, including neurite length and neuronal activity, using multielectrode arrays and patch clamp electrophysiology. We showed that the transcriptome and proteome profiles of isogenic FMRP-deficient neurons demonstrate perturbations in synaptic transmission, neuron differentiation, cell proliferation and ion transmembrane transporter activity pathways, and autism spectrum disorder–associated gene sets. We uncovered key deficits in FMRP-deficient cells demonstrating abnormal neural rosette formation and neural progenitor cell proliferation. We further showed that FMRP-deficient neurons exhibit a number of additional phenotypic abnormalities, including neurite outgrowth and branching deficits and impaired electrophysiological network activity. These FMRP-deficient related impairments have also been validated in additional FXS patient–derived human-induced pluripotent stem cell neural cells. Using isogenic human pluripotent stem cells as a model to investigate the pathophysiology of FXS in human neurons, we reveal key neural abnormalities arising from the loss of FMRP. [ABSTRACT FROM AUTHOR]

Published

2020

24. Differentiation of Human Pluripotent Stem Cells into Cortical Neurons

Author

Carromeu, Cassiano, Vessoni, Alexandre, Mendes, Ana Paula Diniz, Beltrão-Braga, Patricia Cristina Baleeiro, Ulrich, Henning, and Davidson Negraes, Priscilla

Published

2016

25. Fast and complex neural computation at the basis of cognition

Author

Wilbers, René and Wilbers, René

Abstract

In chapter 2, we recorded AP shapes and underlying Na+ and K+ currents in human cortical pyramidal neurons and compared them to rodents. We found that not only the AP shape, but also the underlying currents have remarkable stability, even when firing hundreds of consecutive APs at frequencies of 60 Hz. We then argued that biophysical adaptations in voltage-gated sodium and potassium channels must be responsible, and tested this by characterizing the voltage-dependent properties of the Na+ and K+ currents. We find that human Na+ and K+ currents had different biophysical features than their mouse counterparts. Then we used in silico models and found that indeed, the observed gating properties result in more stable APs. Furthermore, the models with human-like channel biophysics were able to reliably encode a larger range of inputs than models with rodent-like biophysics. Based on this we concluded that adaptations in the biophysical gating of Na+ and K+ channels contribute to the computational properties of human neurons. Fast Spiking interneurons (FSINs) are specialized in fast input-to-output conversion. The whole neuron is filled with adaptations that support this fast function. Therefore, this is the perfect neuron to study when interested in the speed limits of neural processing. In the human cortex, neurons are spaced further apart to make space for all the elaborate dendritic and axonal trees, which are much more interconnected than in rodents. This could potentially slow down neural signaling, as signals take time to travel and become weaker and slower over distance. Yet neural signaling seems not to be slow in human neurons. In this chapter, we investigated whether and how human FSINs can retain their fast function. We first characterized the dendritic morphology of these neurons and found that indeed, their dendritic paths are much longer. However, when we made paired recordings we did not find a slowdown of input and output, indicating that some compensatory

Published

2023

26. Scalable Production of iPSC-Derived Human Neurons to Identify Tau-Lowering Compounds by High-Content Screening

Author

Chao Wang, Michael E. Ward, Robert Chen, Kai Liu, Tara E. Tracy, Xu Chen, Min Xie, Peter Dongmin Sohn, Connor Ludwig, Anke Meyer-Franke, Celeste M. Karch, Sheng Ding, and Li Gan

Subjects

human induced pluripotent stem cells, human neurons, Tau-lowering, neurogenin 2, high-content screening, adrenergic receptor, Alzheimer’s disease, tau, frontotemporal dementia, neurodegeneration, Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Lowering total tau levels is an attractive therapeutic strategy for Alzheimer's disease and other tauopathies. High-throughput screening in neurons derived from human induced pluripotent stem cells (iPSCs) is a powerful tool to identify tau-targeted therapeutics. However, such screens have been hampered by heterogeneous neuronal production, high cost and low yield, and multi-step differentiation procedures. We engineered an isogenic iPSC line that harbors an inducible neurogenin 2 transgene, a transcription factor that rapidly converts iPSCs to neurons, integrated at the AAVS1 locus. Using a simplified two-step protocol, we differentiated these iPSCs into cortical glutamatergic neurons with minimal well-to-well variability. We developed a robust high-content screening assay to identify tau-lowering compounds in LOPAC and identified adrenergic receptors agonists as a class of compounds that reduce endogenous human tau. These techniques enable the use of human neurons for high-throughput screening of drugs to treat neurodegenerative disease.

Published

2017

27. Organs to Cells and Cells to Organoids: The Evolution of in vitro Central Nervous System Modelling

Author

Dario Pacitti, Riccardo Privolizzi, and Bridget E. Bax

Subjects

CNS, hiPSC, human neurons, human glia, neurogenesis, neurological disorders, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

With 100 billion neurons and 100 trillion synapses, the human brain is not just the most complex organ in the human body, but has also been described as “the most complex thing in the universe.” The limited availability of human living brain tissue for the study of neurogenesis, neural processes and neurological disorders has resulted in more than a century-long strive from researchers worldwide to model the central nervous system (CNS) and dissect both its striking physiology and enigmatic pathophysiology. The invaluable knowledge gained with the use of animal models and post mortem human tissue remains limited to cross-species similarities and structural features, respectively. The advent of human induced pluripotent stem cell (hiPSC) and 3-D organoid technologies has revolutionised the approach to the study of human brain and CNS in vitro, presenting great potential for disease modelling and translational adoption in drug screening and regenerative medicine, also contributing beneficially to clinical research. We have surveyed more than 100 years of research in CNS modelling and provide in this review an historical excursus of its evolution, from early neural tissue explants and organotypic cultures, to 2-D patient-derived cell monolayers, to the latest development of 3-D cerebral organoids. We have generated a comprehensive summary of CNS modelling techniques and approaches, protocol refinements throughout the course of decades and developments in the study of specific neuropathologies. Current limitations and caveats such as clonal variation, developmental stage, validation of pluripotency and chromosomal stability, functional assessment, reproducibility, accuracy and scalability of these models are also discussed.

Published

2019

28. What single neurons can tell us

Author

Elaine N Miller and Chet C Sherwood

Subjects

human neurons, dendrites, pyramidal cells, intelligence, iq scores, human cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

IQ scores are correlated with the morphology and activity of certain neurons in the human temporal cortex.

Published

2019

29. Large and fast human pyramidal neurons associate with intelligence

Author

Natalia A Goriounova, Djai B Heyer, René Wilbers, Matthijs B Verhoog, Michele Giugliano, Christophe Verbist, Joshua Obermayer, Amber Kerkhofs, Harriët Smeding, Maaike Verberne, Sander Idema, Johannes C Baayen, Anton W Pieneman, Christiaan PJ de Kock, Martin Klein, and Huibert D Mansvelder

Subjects

human neurons, dendrites, pyramidal cells, intelligence, action potentials, human cortex, Medicine, Science, Biology (General), QH301-705.5

Abstract

It is generally assumed that human intelligence relies on efficient processing by neurons in our brain. Although grey matter thickness and activity of temporal and frontal cortical areas correlate with IQ scores, no direct evidence exists that links structural and physiological properties of neurons to human intelligence. Here, we find that high IQ scores and large temporal cortical thickness associate with larger, more complex dendrites of human pyramidal neurons. We show in silico that larger dendritic trees enable pyramidal neurons to track activity of synaptic inputs with higher temporal precision, due to fast action potential kinetics. Indeed, we find that human pyramidal neurons of individuals with higher IQ scores sustain fast action potential kinetics during repeated firing. These findings provide the first evidence that human intelligence is associated with neuronal complexity, action potential kinetics and efficient information transfer from inputs to output within cortical neurons.

Published

2018

30. Fast and complex neural computation at the basis of cognition

Subjects

cognition, computational modeling, neurowetenschappen, biofysica, intelligence, neurofysiologie, electrophysiology, morfologie, neuroscience, elektrofysiologie, intelligentie, humane neuronen, biophysics, morphology, cognitie, computationele modellen, neurophysiology, human neurons

Abstract

In chapter 2, we recorded AP shapes and underlying Na+ and K+ currents in human cortical pyramidal neurons and compared them to rodents. We found that not only the AP shape, but also the underlying currents have remarkable stability, even when firing hundreds of consecutive APs at frequencies of 60 Hz. We then argued that biophysical adaptations in voltage-gated sodium and potassium channels must be responsible, and tested this by characterizing the voltage-dependent properties of the Na+ and K+ currents. We find that human Na+ and K+ currents had different biophysical features than their mouse counterparts. Then we used in silico models and found that indeed, the observed gating properties result in more stable APs. Furthermore, the models with human-like channel biophysics were able to reliably encode a larger range of inputs than models with rodent-like biophysics. Based on this we concluded that adaptations in the biophysical gating of Na+ and K+ channels contribute to the computational properties of human neurons. Fast Spiking interneurons (FSINs) are specialized in fast input-to-output conversion. The whole neuron is filled with adaptations that support this fast function. Therefore, this is the perfect neuron to study when interested in the speed limits of neural processing. In the human cortex, neurons are spaced further apart to make space for all the elaborate dendritic and axonal trees, which are much more interconnected than in rodents. This could potentially slow down neural signaling, as signals take time to travel and become weaker and slower over distance. Yet neural signaling seems not to be slow in human neurons. In this chapter, we investigated whether and how human FSINs can retain their fast function. We first characterized the dendritic morphology of these neurons and found that indeed, their dendritic paths are much longer. However, when we made paired recordings we did not find a slowdown of input and output, indicating that some compensatory mechanism must be at play. This could not be explained by sodium channel gating, as we find similar sodium current properties in human and mouse FSINs. Using biophysical modeling we find that a combination of enlarged synaptic inputs, reduced dendritic complexity and fast outputs in human FSINs are responsible for conserving a fast signaling speed even over large distances. In this chapter, we take the concept of cellular properties as important determinant for computational power of neurons and see how that relates to the function of the brain as a whole. Although we know that genetics and thickness of the cortex play an important role in IQ differences between individual humans, we do not know it’s structural and functional basis. In this first-of-its-kind study, we obtained IQ scores as well as cellular measurements from individuals. We find that high IQ score does not only go together with large cortical thickness of the temporal cortex, but also with increased dendritic complexity and fast AP shapes. This provided the first evidence that human intelligence is related to complexity and speed of information exchange between individual neurons. Strikingly, the increase in cortical thickness with IQ was found to be purely specific to layers 2 and 3 of the cortex. Apparently, these cortical layers, which serve as important computational layers between input and output layers, are pivotal for intelligence. We then confirmed that high IQ relates to lower cell density, larger cells, more complex dendrites and faster AP signaling all specifically to the pyramidal neurons in layers 2 and 3. Furthermore, we find that verbal intelligence correlates with all these microstructural and cellular features, but only on left, not right, temporal cortex.

Published

2023

31. Untangling Intertwined Pathways: Cholesterol Metabolism, APP Processing, and Tau Phosphorylation in Alzheimer’s Disease

Author

Langness, Vanessa Francine

Subjects

Molecular biology, Cellular biology, Alzheimer's Disease, Amyloid-beta, Cholesterol, Dimer, human neurons, iPSC

Abstract

Alzheimer’s disease (AD) is a progressive neurodegenerative disease that results in loss of neurons and synapses. The dementia associated with AD is devastating for families and poses an increasing social and economic burden as our population ages. Currently there are no drugs available that can revert or even slow disease progression. Brains from human patients with AD exhibit two defining pathological changes: 1) Accumulation of extracellular amyloid plaques which are composed of amyloid beta (Aß), and; 2) accumulation of intracellular neurofibrillary tangles which are made up of hyperphosphorylated tau (pTau) protein. These changes are thought to be toxic and contribute to the devastating neurodegeneration that occurs in AD. Recent developments in disease modeling using human induced pluripotent stem cells (hiPSCs) have allowed for modeling of Alzheimer’s disease in human neurons in a dish. We can measure Aß and pTau levels in these hiPSC derived neurons allowing us to study how the levels of these proteins become dysregulated in AD.Genetic, biochemical, pharmacological, and epidemiological data suggest a role for cholesterol in AD pathogenesis. Recent studies have shown that amyloid precursor protein (APP), the precursor to Aß contains a cholesterol binding site. We use cholesterol lowering drugs, CRISPR/CAS9 genome editing, and fluorescent complementation assays to study how cholesterol levels and mutations that abolish APP-Cholesterol binding influence Aß and pTau burden. Our data indicate that cholesterol metabolism influences levels of these toxic proteins. We also show that APP can influence cholesterol homeostasis by regulating transport of cholesterol between different cell types in the brain. Our work sheds light on a pathway which unites the variety of genetic and environmental factors that contribute to AD risk. Targeting cholesterol metabolic pathways may be a promising approach in the search for drugs which can treat or prevent AD.

Published

2019

32. Identification of neurotoxic cross-linked amyloid-β dimers in the Alzheimer's brain.

Author

Brinkmalm, Gunnar, Hong, Wei, Wang, Zemin, Liu, Wen, O'Malley, Tiernan T, Sun, Xin, Frosch, Matthew P, Selkoe, Dennis J, Portelius, Erik, Zetterberg, Henrik, Blennow, Kaj, and Walsh, Dominic M

Subjects

*DIMERS, *POLYACRYLAMIDE gel electrophoresis, *ALZHEIMER'S disease, *MASS spectrometry, *SODIUM sulfate, *PEPTIDE analysis, *ANIMAL experimentation, *BIOCHEMISTRY, *BRAIN, *COMPARATIVE studies, *PHENOMENOLOGY, *RESEARCH methodology, *MEDICAL cooperation, *MICE, *PEPTIDES, *RESEARCH, *TISSUE culture, *EVALUATION research, *PHYSIOLOGY, BRAIN metabolism

Abstract

The primary structure of canonical amyloid-β-protein was elucidated more than 30 years ago, yet the forms of amyloid-β that play a role in Alzheimer's disease pathogenesis remain poorly defined. Studies of Alzheimer's disease brain extracts suggest that amyloid-β, which migrates on sodium dodecyl sulphate polyacrylamide gel electrophoresis with a molecular weight of ∼7 kDa (7kDa-Aβ), is particularly toxic; however, the nature of this species has been controversial. Using sophisticated mass spectrometry and sensitive assays of disease-relevant toxicity we show that brain-derived bioactive 7kDa-Aβ contains a heterogeneous mixture of covalently cross-linked dimers in the absence of any other detectable proteins. The identification of amyloid-β dimers may open a new phase of Alzheimer's research and allow a better understanding of Alzheimer's disease, and how to monitor and treat this devastating disorder. Future studies investigating the bioactivity of individual dimers cross-linked at known sites will be critical to this effort. [ABSTRACT FROM AUTHOR]

Published

2019

33. Organs to Cells and Cells to Organoids: The Evolution of in vitro Central Nervous System Modelling.

Author

Pacitti, Dario, Privolizzi, Riccardo, and Bax, Bridget E.

Subjects

PLURIPOTENT stem cells, CENTRAL nervous system, CELLULAR evolution, INDUCED pluripotent stem cells, DEVELOPMENTAL biology, HUMAN body

Abstract

With 100 billion neurons and 100 trillion synapses, the human brain is not just the most complex organ in the human body, but has also been described as "the most complex thing in the universe." The limited availability of human living brain tissue for the study of neurogenesis, neural processes and neurological disorders has resulted in more than a century-long strive from researchers worldwide to model the central nervous system (CNS) and dissect both its striking physiology and enigmatic pathophysiology. The invaluable knowledge gained with the use of animal models and post mortem human tissue remains limited to cross-species similarities and structural features, respectively. The advent of human induced pluripotent stem cell (hiPSC) and 3-D organoid technologies has revolutionised the approach to the study of human brain and CNS in vitro , presenting great potential for disease modelling and translational adoption in drug screening and regenerative medicine, also contributing beneficially to clinical research. We have surveyed more than 100 years of research in CNS modelling and provide in this review an historical excursus of its evolution, from early neural tissue explants and organotypic cultures, to 2-D patient-derived cell monolayers, to the latest development of 3-D cerebral organoids. We have generated a comprehensive summary of CNS modelling techniques and approaches, protocol refinements throughout the course of decades and developments in the study of specific neuropathologies. Current limitations and caveats such as clonal variation, developmental stage, validation of pluripotency and chromosomal stability, functional assessment, reproducibility, accuracy and scalability of these models are also discussed. [ABSTRACT FROM AUTHOR]

Published

2019

34. Minute-scale periodicity of neuronal firing in the human entorhinal cortex.

Author

M. Aghajan, Zahra, Kreiman, Gabriel, and Fried, Itzhak

Abstract

Grid cells in the entorhinal cortex demonstrate spatially periodic firing, thought to provide a spatial map on behaviorally relevant length scales. Whether such periodicity exists for behaviorally relevant time scales in the human brain remains unclear. We investigate neuronal firing during a temporally continuous experience by presenting 14 neurosurgical patients with a video while recording neuronal activity from multiple brain regions. We report on neurons that modulate their activity in a periodic manner across different time scales—from seconds to many minutes, most prevalently in the entorhinal cortex. These neurons remap their dominant periodicity to shorter time scales during a subsequent recognition memory task. When the video is presented at two different speeds, a significant percentage of these temporally periodic cells (TPCs) maintain their time scales, suggesting a degree of invariance. The TPCs' temporal periodicity might complement the spatial periodicity of grid cells and together provide scalable spatiotemporal metrics for human experience. [Display omitted] • When watching a movie, the activity of human neurons exhibits minute-scale periodicity in time • Different neurons maintain or remap their periodicity when playback speed is altered • During recognition memory, most neurons remap their periodicity to shorter time scales Aghajan et al. report that neurons in the human brain exhibit minute-scale periodicity when participants watch a movie. Different units maintain or remap their time scale at different playback speeds or during memory test. Temporal periodicity of these units may complement spatial periodicity of grid cells to provide spatiotemporal representation. [ABSTRACT FROM AUTHOR]

Published

2023

35. A neural code for time and space in the human brain.

Author

Schonhaut, Daniel R., Aghajan, Zahra M., Kahana, Michael J., and Fried, Itzhak

Abstract

Time and space are primary dimensions of human experience. Separate lines of investigation have identified neural correlates of time and space, yet little is known about how these representations converge during self-guided experience. Here, 10 subjects with intracranially implanted microelectrodes play a timed, virtual navigation game featuring object search and retrieval tasks separated by fixed delays. Time cells and place cells activate in parallel during timed navigation intervals, whereas a separate time cell sequence spans inter-task delays. The prevalence, firing rates, and behavioral coding strengths of time cells and place cells are indistinguishable—yet time cells selectively remap between search and retrieval tasks, while place cell responses remain stable. Thus, the brain can represent time and space as overlapping but dissociable dimensions. Time cells and place cells may constitute a biological basis for the cognitive map of spatiotemporal context onto which memories are written. [Display omitted] • Human medial temporal lobe and prefrontal cortex neurons encode time during task-free delays • Time and place are independently represented during timed navigation • Time cells remap between contextually similar events with stable place cell firing • Population neural activity represents time across multiple events in a sequence Schonhaut et al. record direct neural firing while subjects play a timed, virtual navigation game with object search and retrieval tasks separated by fixed delays. The authors find that neural codes for time and space are simultaneously active, context-specific, and dissociable, providing a putative mechanism for representing spatiotemporal context. [ABSTRACT FROM AUTHOR]

Published

2023

36. Visualizing the Synaptic and Cellular Ultrastructure in Neurons Differentiated from Human Induced Neural Stem Cells—An Optimized Protocol

Author

Philipp Capetian, Lorenz Müller, Jens Volkmann, Manfred Heckmann, Süleyman Ergün, and Nicole Wagner

Subjects

transmission electron microscopy, human neurons, induced neural stem cells, synapse, synaptic vesicles, high contrast, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The size of the synaptic subcomponents falls below the limits of visible light microscopy. Despite new developments in advanced microscopy techniques, the resolution of transmission electron microscopy (TEM) remains unsurpassed. The requirements of tissue preservation are very high, and human post mortem material often does not offer adequate quality. However, new reprogramming techniques that generate human neurons in vitro provide samples that can easily fulfill these requirements. The objective of this study was to identify the culture technique with the best ultrastructural preservation in combination with the best embedding and contrasting technique for visualizing neuronal elements. Two induced neural stem cell lines derived from healthy control subjects underwent differentiation either adherent on glass coverslips, embedded in a droplet of highly concentrated Matrigel, or as a compact neurosphere. Afterward, they were fixed using a combination of glutaraldehyde (GA) and paraformaldehyde (PFA) followed by three approaches (standard stain, Ruthenium red stain, high contrast en-bloc stain) using different combinations of membrane enhancing and contrasting steps before ultrathin sectioning and imaging by TEM. The compact free-floating neurospheres exhibited the best ultrastructural preservation. High-contrast en-bloc stain offered particularly sharp staining of membrane structures and the highest quality visualization of neuronal structures. In conclusion, compact neurospheres growing under free-floating conditions in combination with a high contrast en-bloc staining protocol, offer the optimal preservation and contrast with a particular focus on visualizing membrane structures as required for analyzing synaptic structures.

Published

2020

37. hsa-let-7c miRNA Regulates Synaptic and Neuronal Function in Human Neurons

Author

Heather McGowan, Vincent R. Mirabella, Aula Hamod, Aziz Karakhanyan, Nicole Mlynaryk, Jennifer C. Moore, Jay A. Tischfield, Ronald P. Hart, and Zhiping P. Pang

Subjects

non-coding RNA, microRNA, synaptic transmission, human neurons, stem cells, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Non-coding RNA, including microRNA (miRNA) serves critical regulatory functions in the developing brain. The let-7 family of miRNAs has been shown to regulate neuronal differentiation, neural subtype specification, and synapse formation in animal models. However, the regulatory role of human let-7c (hsa-let-7c) in human neuronal development has yet to be examined. Let-7c is encoded on chromosome 21 in humans and therefore may be overexpressed in human brains in Trisomy 21 (T21), a complex neurodevelopmental disorder. Here, we employ recent developments in stem cell biology to show that hsa-let-7c mediates important regulatory epigenetic functions that control the development and functional activity of human induced neuronal cells (iNs). We show that overexpression of hsa-let-7c in human iNs derived from induced pluripotent stem (iPS), as well as embryonic stem (ES), cells leads to morphological as well as functional deficits including impaired neuronal morphologic development, synapse formation and synaptic strength, as well as a marked reduction of neuronal excitability. Importantly, we have assessed these findings over three independent genetic backgrounds, showing that some of these effects are subject to influence by background genetic variability with the most robust and reproducible effect being a striking reduction in spontaneous neural firing. Collectively, these results suggest an important function for let-7 family miRNAs in regulation of human neuronal development and raise implications for understanding the complex molecular etiology of neurodevelopmental disorders, such as T21, where let-7c gene dosage is increased.

Published

2018

38. Mechanistic Insights Into MicroRNA-Induced Neuronal Reprogramming of Human Adult Fibroblasts.

Author

Lu, Ya-Lin and Yoo, Andrew S.

Subjects

MICRORNA, FIBROBLASTS, SOMATIC cells

Abstract

The use of transcriptional factors as cell fate regulators are often the primary focus in the direct reprogramming of somatic cells into neurons. However, in human adult fibroblasts, deriving functionally mature neurons with high efficiency requires additional neurogenic factors such as microRNAs (miRNAs) to evoke a neuronal state permissive to transcription factors to exert their reprogramming activities. As such, increasing evidence suggests brain-enriched miRNAs, miR-9/9∗ and miR-124, as potent neurogenic molecules through simultaneously targeting of anti-neurogenic effectors while allowing additional transcription factors to generate specific subtypes of human neurons. In this review, we will focus on methods that utilize neuronal miRNAs and provide mechanistic insights by which neuronal miRNAs, in synergism with brain-region specific transcription factors, drive the conversion of human fibroblasts into clinically relevant subtypes of neurons. Furthermore, we will provide insights into the age signature of directly converted neurons and how the converted human neurons can be utilized to model late-onset neurodegenerative disorders. [ABSTRACT FROM AUTHOR]

Published

2018

39. Organelle mapping in dendrites of human iPSC-derived neurons reveals dynamic functional dendritic Golgi structures.

Author

Wang, Jingqi, Daniszewski, Maciej, Hao, Marlene M., Hernández, Damián, Pébay, Alice, Gleeson, Paul A., and Fourriere, Lou

Abstract

Secretory pathways within dendrites of neurons have been proposed for local transport of newly synthesized proteins. However, little is known about the dynamics of the local secretory system and whether the organelles are transient or stable structures. Here, we quantify the spatial and dynamic behavior of dendritic Golgi and endosomes during differentiation of human neurons generated from induced pluripotent stem cells (iPSCs). In early neuronal development, before and during migration, the entire Golgi apparatus transiently translocates from the soma into dendrites. In mature neurons, dynamic Golgi elements, containing cis and trans cisternae, are transported from the soma along dendrites, in an actin-dependent process. Dendritic Golgi outposts are dynamic and display bidirectional movement. Similar structures were observed in cerebral organoids. Using the retention using selective hooks (RUSH) system, Golgi resident proteins are transported efficiently into Golgi outposts from the endoplasmic reticulum. This study reveals dynamic, functional Golgi structures in dendrites and a spatial map for investigating dendrite trafficking in human neurons. [Display omitted] • Human neurons from iPSCs are polarized, functionally active, and fire spontaneously • Live imaging reveals distinct dynamics of the Golgi and endosomes within dendrites • Functional, mobile, dendritic Golgi mini-stacks are derived from the somatic Golgi • Actin, myosin II, and ROCK are required for the formation of Golgi outposts Wang et al. map the intracellular organelles of human iPSC-derived neurons and quantify the spatial and dynamic behavior of the Golgi and endosomes during neuronal differentiation. They demonstrate the existence of highly dynamic Golgi outposts in the dendrites of human neurons, which are dependent on actin and actin signaling. [ABSTRACT FROM AUTHOR]

Published

2023

40. Roads of growth: cytoskeleton-mediated mechanisms during neurodevelopment

Author

Kooistra, Robbelien and Kooistra, Robbelien

Abstract

Our brain contains billions of brain cells, neurons, that form networks to communicate information and is responsible for all bodily functions. To correctly perform these challenging tasks, neurons have a typical form. They consist of multiple components: they have a central cell body from which grow multiple heavily branched processes that can receive input from other cells, the dendrites. An axon also grows from the cell body; this is a relatively long and thin projection that can transmit information to other cells. To obtain and keep this particular form neurons have a cytoskeleton. Other than our own skeleton, the cytoskeleton is highly dynamic, and the organisation of the cytoskeleton is important for the growth of neurons. This thesis describes multiple studies that focus on changes in the cytoskeleton during neuronal development. Several types of cells are used: neurons inside a small, living worm (C. elegans), rat neurons that grow in a petri-dish, and human neurons derived from stem cells. Multiple processes that affect the organisation of the cytoskeleton during neurodevelopment have been identified. Some general mechanisms occur in the different species, but variations in developmental processes have also been found. This research increases our understanding of the development of young neurons and the growth of a healthy, well-functioning brain.

Published

2022

41. Development of engineered human-derived brain-on-a-chip models for electrophysiological recording

Author

Muzzi, Lorenzo

Subjects

brain-on-a-chip, 3D neuronal network, Settore BIO/13 - Biologia Applicata, microelectrodes array, human-induced pluripotent stem cells, electrophysiological activity, functional test, human neurons, network dynamics, rapid differentiation, Settore ING-INF/06 - Bioingegneria Elettronica e Informatica, Settore ING-IND/34 - Bioingegneria Industriale

Published

2022

42. Roads of growth: cytoskeleton-mediated mechanisms during neurodevelopment

Subjects

axon development, neurodevelopment, axonogenese, neurons, cytoskeleton, axonogenesis, neuronen, microtubules, nervous system, neuronale ontwikkeling, humane neuronen, axon ontwikkeling, microtubuli, human neurons, celskelet

Abstract

Our brain contains billions of brain cells, neurons, that form networks to communicate information and is responsible for all bodily functions. To correctly perform these challenging tasks, neurons have a typical form. They consist of multiple components: they have a central cell body from which grow multiple heavily branched processes that can receive input from other cells, the dendrites. An axon also grows from the cell body; this is a relatively long and thin projection that can transmit information to other cells. To obtain and keep this particular form neurons have a cytoskeleton. Other than our own skeleton, the cytoskeleton is highly dynamic, and the organisation of the cytoskeleton is important for the growth of neurons. This thesis describes multiple studies that focus on changes in the cytoskeleton during neuronal development. Several types of cells are used: neurons inside a small, living worm (C. elegans), rat neurons that grow in a petri-dish, and human neurons derived from stem cells. Multiple processes that affect the organisation of the cytoskeleton during neurodevelopment have been identified. Some general mechanisms occur in the different species, but variations in developmental processes have also been found. This research increases our understanding of the development of young neurons and the growth of a healthy, well-functioning brain.

Published

2022

43. Verbal and General IQ Associate with Supragranular Layer Thickness and Cell Properties of the Left Temporal Cortex

Author

Huibert D. Mansvelder, C.P.J. de Kock, Eline J. Mertens, Natalia A. Goriounova, Anna A. Galakhova, Braak S, Ed S. Lein, Martin Klein, René Wilbers, P. C. de Witt Hamer, Djai B. Heyer, M L Muijtjens, Medea McGraw, Matthijs B. Verhoog, Hunt S, E Hartsema, Johannes C. Baayen, Sander Idema, Neurosurgery, Amsterdam Neuroscience - Systems & Network Neuroscience, Medical psychology, Amsterdam Neuroscience - Cellular & Molecular Mechanisms, Integrative Neurophysiology, Amsterdam Neuroscience - Compulsivity, Impulsivity & Attention, CCA - Cancer biology and immunology, and CCA - Imaging and biomarkers

Subjects

Temporal cortex, Neurons, language, Intelligence quotient, Mental ability, dendrites, Cognitive Neuroscience, Pyramidal Cells, Intelligence, Action Potentials, Brodmann area 21, Biology, intelligence, Verbal reasoning, Layer thickness, Temporal Lobe, Cellular and Molecular Neuroscience, medicine.anatomical_structure, action potential, medicine, Verbal iq, Humans, Neuron, human neurons, Neuroscience

Abstract

The left temporal lobe is an integral part of the language system and its cortical structure and function associate with general intelligence. However, whether cortical laminar architecture and cellular properties of this brain area relate to verbal intelligence is unknown. Here, we addressed this using histological analysis and cellular recordings of neurosurgically resected temporal cortex in combination with presurgical IQ scores. We find that subjects with higher general and verbal IQ scores have thicker left (but not right) temporal cortex (Brodmann area 21, BA21). The increased thickness is due to the selective increase in layers 2 and 3 thickness, accompanied by lower neuron densities, and larger dendrites and cell body size of pyramidal neurons in these layers. Furthermore, these neurons sustain faster action potential kinetics, which improves information processing. Our results indicate that verbal mental ability associates with selective adaptations of supragranular layers and their cellular micro-architecture and function in left, but not right temporal cortex.

Published

2022

44. Current In Vitro Models to Study Varicella Zoster Virus Latency and Reactivation

Author

Nicholas L. Baird, Shuyong Zhu, Catherine M. Pearce, and Abel Viejo-Borbolla

Subjects

varicella zoster virus, stem cells, human neurons, latency, reactivation, neurotrophic factors, Microbiology, QR1-502

Abstract

Varicella zoster virus (VZV) is a highly prevalent human pathogen that causes varicella (chicken pox) during primary infection and establishes latency in peripheral neurons. Symptomatic reactivation often presents as zoster (shingles), but it has also been linked to life-threatening diseases such as encephalitis, vasculopathy and meningitis. Zoster may be followed by postherpetic neuralgia, neuropathic pain lasting after resolution of the rash. The mechanisms of varicella zoster virus (VZV) latency and reactivation are not well characterized. This is in part due to the human-specific nature of VZV that precludes the use of most animal and animal-derived neuronal models. Recently, in vitro models of VZV latency and reactivation using human neurons derived from stem cells have been established facilitating an understanding of the mechanisms leading to VZV latency and reactivation. From the models, c-Jun N-terminal kinase (JNK), phosphoinositide 3-kinase (PI3K) and nerve growth factor (NGF) have all been implicated as potential modulators of VZV latency/reactivation. Additionally, it was shown that the vaccine-strain of VZV is impaired for reactivation. These models may also aid in the generation of prophylactic and therapeutic strategies to treat VZV-associated pathologies. This review summarizes and analyzes the current human neuronal models used to study VZV latency and reactivation, and provides some strategies for their improvement.

Published

2019

45. L’impact de NKG2D et de ses ligands sur la motilité des lymphocytes T CD8 et sur la progression de l’encéphalomyélite auto-immune expérimentale

Author

Carpentier Solorio, Yves and Arbour, Nathalie

Subjects

cytométrie en flux, astrocytes humains, flow cytometry, experimental autoimmune encephalomyelitis, CD8 T cells, live imaging, encéphalomyélite auto-immune expérimentale, MULT1, multiple sclerosis, lymphocytes T CD8, NKG2D, neurones humains, ULBP4, sclérose en plaques, micropsie en temps réel, human astrocytes, human neurons

Abstract

La sclérose en plaques (SEP) est une maladie inflammatoire du système nerveux central (SNC). Le système immunitaire joue un rôle clé en SEP, cependant la contribution de molécules spécifiques reste à élucider. Nous avons identifié NKG2D, un récepteur immunitaire, comme joueur clef dans les interactions entre les cellules neurales et les lymphocytes dans la SEP. L’expression de ULBP4, un ligand de NKG2D, est élevée dans le cerveau des patients SEP, et présente sous forme soluble dans le liquide céphalorachidien (LCR). NKG2D joue un rôle délétère dans l’encéphalomyélite auto-immune expérimentale passive (EAE), un modèle de la SEP. MULT1, un ligand NKG2D, est élevé dans le SNC et le LCR au pic de la maladie EAE. Ainsi, nous avons émis l’hypothèse que la voie NKG2D module l’interaction entre les cellules neurales et les lymphocytes T. A l’aide d’imagerie en temps réel, nous avons montré que le blocage de NKG2D diminue les interactions stables entre les lymphocytes T CD8+ et les astrocytes humains in vitro. L’ajout d’ULBP4 soluble diminue les interactions stables entre ces lymphocytes et les astrocytes et ce avec une plus grande importance chez les patients SEP. Finalement, dans l’EAE, augmenter l’expression de MULT1 par injection intrathécale d’un vecteur viral augmente la sévérité des déficits moteurs. Cela corrèle avec une augmentation de la production d’IFNγ par les lymphocytes T infiltrants le SNC. Somme toute, NKG2D et ses ligands participent aux interactions entre les lymphocytes T et les cellules neurales en contexte de SEP et sont des cibles thérapeutiques potentielles à investiguer., Multiple sclerosis is an inflammatory disease of the central nervous system (CNS). Although the key role of the immune system in MS is well established, the contribution of immune molecules remains incompletely unresolved. We identified NKG2D, an activating immune (co)receptor, as a key factor shaping the interactions between CNS and lymphocytes in MS. We have shown that expression of ULBP4, an NKG2D ligand, is elevated in brain from MS patients and increased in cerebrospinal fluid (CSF) as a soluble form. We have demonstrated that NKG2D contributes to disease progression in passive experimental autoimmune encephalomyelitis (EAE). We showed that one NKG2D ligand called MULT1 is upregulated in the CNS and in the CSF of EAE mice at disease peak. Thus, we hypothesized that the NKG2D pathway impacts the interactions between CNS cells and infiltrating T lymphocytes. Using our live-imaging co-culture model, we show that blocking NKG2D reduces stable interactions between CD8+ T lymphocytes and human astrocytes in vitro. Moreover, we observed that soluble ULBP4 decreases CD8 T cell-astrocyte stable interactions and modifies their behaviour with a stronger effect in MS patients. Finally, we saw in active EAE that increasing the expression of MULT1 in the CNS with an intrathecal injection of a viral vector increases motor deficits in mice. This correlates with a higher production of IFNγ by T lymphocytes. Thus, NKG2D and its ligands play important role in the interactions of CNS cells and T lymphocytes in the context of MS and are potential therapeutic targets to further investigate.

Published

2022

46. Psychosis Risk Candidate ZNF804A Localizes to Synapses and Regulates Neurite Formation and Dendritic Spine Structure.

Author

Deans, P.J. Michael, Raval, Pooja, Sellers, Katherine J., Gatford, Nicholas J.F., Halai, Sanjay, Duarte, Rodrigo R.R., Shum, Carole, Warre-Cornish, Katherine, Kaplun, Victoria E., Cocks, Graham, Hill, Matthew, Bray, Nicholas J., Price, Jack, and Srivastava, Deepak P.

Subjects

*PSYCHIATRIC treatment, *PSYCHOSES, *ZINC-finger proteins, *SYNAPSES, *NEUROPLASTICITY, *DENDRITIC spines, *GENETIC transcription, *PLURIPOTENT stem cells

Abstract

Background Variation in the gene encoding zinc finger binding protein 804A ( ZNF804A ) is associated with schizophrenia and bipolar disorder. Evidence suggests that ZNF804A is a regulator of gene transcription and is present in nuclear and extranuclear compartments. However, a detailed examination of ZNF804A distribution and its neuronal functions has yet to be performed. Methods The localization of ZNF804A protein was examined in neurons derived from human neural progenitor cells, human induced pluripotent stem cells, or in primary rat cortical neurons. In addition, small interfering RNA-mediated knockdown of ZNF804A was conducted to determine its role in neurite formation, maintenance of dendritic spine morphology, and responses to activity-dependent stimulations. Results Endogenous ZNF804A protein localized to somatodendritic compartments and colocalized with the putative synaptic markers in young neurons derived from human neural progenitor cells and human induced pluripotent stem cells. In mature rat neurons, Zfp804A, the homolog of ZNF804A, was present in a subset of dendritic spines and colocalized with synaptic proteins in specific nanodomains, as determined by super-resolution microscopy. Interestingly, knockdown of ZNF804A attenuated neurite outgrowth in young neurons, an effect potentially mediated by reduced neuroligin-4 expression. Furthermore, knockdown of ZNF804A in mature neurons resulted in the loss of dendritic spine density and impaired responses to activity-dependent stimulation. Conclusions These data reveal a novel subcellular distribution for ZNF804A within somatodendritic compartments and a nanoscopic organization at excitatory synapses. Moreover, our results suggest that ZNF804A plays an active role in neurite formation, maintenance of dendritic spines, and activity-dependent structural plasticity. [ABSTRACT FROM AUTHOR]

Published

2017

47. Modeling autism spectrum disorders with human neurons.

Author

Beltrão-Braga, Patricia C.B. and Muotri, Alysson R.

Subjects

*AUTISM spectrum disorders, *NEURODEVELOPMENTAL treatment, *COMMUNICATIVE disorders, *INDUCED pluripotent stem cells, *PATHOLOGICAL physiology, *NEURONS, *NEUROGLIA, TREATMENT of developmental disabilities

Abstract

Autism spectrum disorder (ASD) is a group of neurodevelopmental disorders characterized by impaired social communication and interactions and by restricted and repetitive behaviors. Although ASD is suspected to have a heritable or sporadic genetic basis, its underlying etiology and pathogenesis are not well understood. Therefore, viable human neurons and glial cells produced using induced pluripotent stem cells (iPSC) to reprogram cells from individuals affected with ASD provide an unprecedented opportunity to elucidate the pathophysiology of these disorders, providing novel insights regarding ASD and a potential platform to develop and test therapeutic compounds. Herein, we discuss the state of art with regards to ASD modeling, including limitations of this technology, as well as potential future directions. This article is part of a Special Issue entitled SI: Exploiting human neurons . [ABSTRACT FROM AUTHOR]

Published

2017

48. Networks of Cultured iPSC-Derived Neurons Reveal the Human Synaptic Activity-Regulated Adaptive Gene Program.

Author

Pruunsild, Priit, Bengtson, C. Peter, and Bading, Hilmar

Abstract

Summary Long-term adaptive responses in the brain, such as learning and memory, require synaptic activity-regulated gene expression, which has been thoroughly investigated in rodents. Using human iPSC-derived neuronal networks, we show that the human and the mouse synaptic activity-induced transcriptional programs share many genes and both require Ca 2+ -regulated synapse-to-nucleus signaling. Species-specific differences include the noncoding RNA genes BRE - AS1 and LINC00473 and the protein-coding gene ZNF331 , which are absent in the mouse genome, as well as several human genes whose orthologs are either not induced by activity or are induced with different kinetics in mice. These results indicate that lineage-specific gain of genes and DNA regulatory elements affects the synaptic activity-regulated gene program, providing a mechanism driving the evolution of human cognitive abilities. [ABSTRACT FROM AUTHOR]

Published

2017

49. Unique membrane properties and enhanced signal processing in human neocortical neurons

Author

Guy Eyal, Matthijs B Verhoog, Guilherme Testa-Silva, Yair Deitcher, Johannes C Lodder, Ruth Benavides-Piccione, Juan Morales, Javier DeFelipe, Christiaan PJ de Kock, Huibert D Mansvelder, and Idan Segev

Subjects

compartmental modeling, human neurons, neurons computation, membrane properties, Medicine, Science, Biology (General), QH301-705.5

Abstract

The advanced cognitive capabilities of the human brain are often attributed to our recently evolved neocortex. However, it is not known whether the basic building blocks of the human neocortex, the pyramidal neurons, possess unique biophysical properties that might impact on cortical computations. Here we show that layer 2/3 pyramidal neurons from human temporal cortex (HL2/3 PCs) have a specific membrane capacitance (Cm) of ~0.5 µF/cm2, half of the commonly accepted 'universal' value (~1 µF/cm2) for biological membranes. This finding was predicted by fitting in vitro voltage transients to theoretical transients then validated by direct measurement of Cm in nucleated patch experiments. Models of 3D reconstructed HL2/3 PCs demonstrated that such low Cm value significantly enhances both synaptic charge-transfer from dendrites to soma and spike propagation along the axon. This is the first demonstration that human cortical neurons have distinctive membrane properties, suggesting important implications for signal processing in human neocortex.

Published

2016

50. Maintenance of age in human neurons generated by microRNA-based neuronal conversion of fibroblasts

Author

Christine J Huh, Bo Zhang, Matheus B Victor, Sonika Dahiya, Luis FZ Batista, Steve Horvath, and Andrew S Yoo

Subjects

aging, neuronal conversion, human neurons, Medicine, Science, Biology (General), QH301-705.5

Abstract

Aging is a major risk factor in many forms of late-onset neurodegenerative disorders. The ability to recapitulate age-related characteristics of human neurons in culture will offer unprecedented opportunities to study the biological processes underlying neuronal aging. Here, we show that using a recently demonstrated microRNA-based cellular reprogramming approach, human fibroblasts from postnatal to near centenarian donors can be efficiently converted into neurons that maintain multiple age-associated signatures. Application of an epigenetic biomarker of aging (referred to as epigenetic clock) to DNA methylation data revealed that the epigenetic ages of fibroblasts were highly correlated with corresponding age estimates of reprogrammed neurons. Transcriptome and microRNA profiles reveal genes differentially expressed between young and old neurons. Further analyses of oxidative stress, DNA damage and telomere length exhibit the retention of age-associated cellular properties in converted neurons from corresponding fibroblasts. Our results collectively demonstrate the maintenance of age after neuronal conversion.

Published

2016