Convergent Pathways in Idiopathic Autism Revealed by Time Course Transcriptomic Analysis of Patient-Derived Neurons

DeRosa, Brooke A.; Hokayem, Jimmy El; Artimovich, Elena; Garcia‐Serje, Catherine; Phillips, André W.; Booven, Derek Van; Nestor, Jonathan E.; Wang, Lily; Cuccaro, Michael L.; Vance, Jeffery M.; Pericak‐Vance, Margaret A.; Cukier, Holly N.; Nestor, Michael W.; Dykxhoorn, Derek M.

doi:10.1038/s41598-018-26495-1

Cited by 71 publications

(87 citation statements)

References 80 publications

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“…Dysregulation in neuronal differentiation and synaptic and dendritic deficits may underlie the decreased spontaneous activity and decreased excitability found in many studies. These are often observed in neurons derived from individuals with idiopathic forms of ASD [112,116,167], as well as from individuals with genetically defined forms of ASD such as SHANK3 [127,130], 16p11.2 deletion and duplication [125], Angelman syndrome [121], Dup15q syndrome [122], NRXN1 mutations [133,135,137], and PTCHD1-AS [140]. Decreases in spontaneous neuronal activity were also found in five out of ten genes associated with ASD when mutations were introduced into neurons derived from typically developing individuals (ATRX, AFF2, KCNQ2, SCN2A, and ASTN2; see Table 1 for the full list of genes tested) [147].…”

Section: Neuronal Signaling and Synaptic Functionmentioning

confidence: 99%

“…Two kinds of genetic modeling have been performed using cells either from individuals whose genetic contributions are unknown or undefined, so called idiopathic [59,60,[112][113][114][115][116][117][118][119][120], or from individuals harboring major effect mutations that are presumed causal or which have been engineered to carry these mutations. These mutations include ASD-associated CNVs such as 15q11q13 deletion (Angelman syndrome) [121] and duplication (Dup15q syndrome) [122], 22q11.2 deletion (DiGeorge syndrome) [123,124], 16p11.2 deletion and duplication [125], and 15q13.3 deletion [126], as well as single-gene mutations including SHANK3 [127][128][129][130], CHD8 [131,132], NRXN1 [133][134][135][136][137], NLGN4 [138], EHMT1 (Kleefstra syndrome) [139], PTCHD1-AS [140], UBE3A (Angelman's syndrome) [141], and CACNA1C (Timothy syndrome) [142] (summarized in Table 1).…”

Section: Main Findings From Stem Cell Models Of Asd To Datementioning

confidence: 99%

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Human in vitro models for understanding mechanisms of autism spectrum disorder

Gordon

Geschwind

2020

Molecular Autism

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Early brain development is a critical epoch for the development of autism spectrum disorder (ASD). In vivo animal models have, until recently, been the principal tool used to study early brain development and the changes occurring in neurodevelopmental disorders such as ASD. In vitro models of brain development represent a significant advance in the field. Here, we review the main methods available to study human brain development in vitro and the applications of these models for studying ASD and other psychiatric disorders. We discuss the main findings from stem cell models to date focusing on cell cycle and proliferation, cell death, cell differentiation and maturation, and neuronal signaling and synaptic stimuli. To be able to generalize the results from these studies, we propose a framework of experimental design and power considerations for using in vitro models to study ASD. These include both technical issues such as reproducibility and power analysis and conceptual issues such as the brain region and cell types being modeled.Early development as a critical period for ASD susceptibility

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Section: Neuronal Signaling and Synaptic Functionmentioning

confidence: 99%

Section: Main Findings From Stem Cell Models Of Asd To Datementioning

confidence: 99%

Human in vitro models for understanding mechanisms of autism spectrum disorder

Gordon

Geschwind

2020

Molecular Autism

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“…From the published literature, studies performing MEA experiments using primary cultures of rodent cortical neurons have a range of reported age of cultures: DIV post plating from dissected brain, and the time of analysis ranges from DIV7 to DIV35, although DIV14 -DIV28 is most common (Table 2). Conversely, studies that instead used neuronal cultures derived from stem cells have a range of culture ages differing to a greater degree, over 30 d (DeRosa et al, 2018;Russo et al, 2018), including up to DIV70 (García-León et al, 2018). This broad range is expected given the variety of differentiation protocols used and increased interval until these cells become electrically active.…”

Section: Changes In Spontaneous Firing Across Arrays With Culture Matmentioning

confidence: 99%

Assessment of Spontaneous Neuronal ActivityIn VitroUsing Multi-Well Multi-Electrode Arrays: Implications for Assay Development

Negri

Menon

Young‐Pearse

2020

eNeuro

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Multi-electrode arrays (MEAs) are being more widely used by researchers as an instrument platform for monitoring prolonged, non-destructive recordings of spontaneously firing neurons in vitro for applications in modeling Alzheimer's, Parkinson's, schizophrenia, and many other diseases of the human CNS. With the more widespread use of these instruments, there is a need to examine the prior art of studies utilizing MEAs and delineate best practices for data acquisition and analysis to avoid errors in interpretation of the resultant data. Using a dataset of recordings from primary rat (Rattus norvegicus) cortical cultures, methods and statistical power for discerning changes in neuronal activity on the array level are examined. Further, a method for unsupervised spike sorting is implemented, allowing for the resolution of action potential incidents down to the single neuron level. Following implementation of spike sorting, the dynamics of firing frequency across populations of individual neurons and networks are examined longitudinally. Finally, the ability to detect a frequency independent phenotype, the change in action potential amplitude, is demonstrated through the use of pore-forming neurotoxin treatments. Taken together, this study provides guidance and tools for users wishing to incorporate multi-well MEA usage into their studies.

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“…183 A transcriptomic profiling study of iPSC-derived neurons from individuals with idiopathic ASD shows enriched differentially expressed genes in functional pathways related to axon guidance, neuronal migration, and synaptic function. 184 Interestingly, POU3F2 has been identified as a candidate risk gene located within rs238834 through a recent ASD GWAS meta-analysis. 13 POU3F2 encodes for member of the POU-III class of neural transcription factor that plays a role in cortical neuron migration and layering.…”

Section: Genetic Evidencementioning

confidence: 99%

Probing disrupted neurodevelopment in autism using human stem cell‐derived neurons and organoids: An outlook into future diagnostics and drug development

Yang

Shcheglovitov

2019

Developmental Dynamics

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Autism spectrum disorders (ASDs) represent a spectrum of neurodevelopmental disorders characterized by impaired social interaction, repetitive or restrictive behaviors, and problems with speech. According to a recent report by the Centers for Disease Control and Prevention, one in 68 children in the US is diagnosed with ASDs. Although ASD-related diagnostics and the knowledge of ASD-associated genetic abnormalities have improved in recent years, our understanding of the cellular and molecular pathways disrupted in ASD remains very limited. As a result, no specific therapies or medications are available for individuals with ASDs. In this review, we describe the neurodevelopmental processes that are likely affected in the brains of individuals with ASDs and discuss how patient-specific stem cellderived neurons and organoids can be used for investigating these processes at the cellular and molecular levels. Finally, we propose a discovery pipeline to be used in the future for identifying the cellular and molecular deficits and developing novel personalized therapies for individuals with idiopathic ASDs.

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Convergent Pathways in Idiopathic Autism Revealed by Time Course Transcriptomic Analysis of Patient-Derived Neurons

Cited by 71 publications

References 80 publications

Human in vitro models for understanding mechanisms of autism spectrum disorder

Human in vitro models for understanding mechanisms of autism spectrum disorder

Assessment of Spontaneous Neuronal ActivityIn VitroUsing Multi-Well Multi-Electrode Arrays: Implications for Assay Development

Probing disrupted neurodevelopment in autism using human stem cell‐derived neurons and organoids: An outlook into future diagnostics and drug development

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