Project description:Dravet syndrome is a developmental and epileptic encephalopathy characterized by seizures, behavioral abnormalities, developmental deficits, and elevated risk of sudden unexpected death in epilepsy (SUDEP). Most patient cases are caused by de novo loss-of-function mutations in the gene SCN1A, causing a haploinsufficiency of the alpha subunit of the voltage-gated sodium channel NaV1.1. Within the brain, NaV1.1 is primarily localized to the axons of inhibitory neurons, and decreased NaV1.1 function is hypothesized to reduce GABAergic inhibitory neurotransmission within the brain, driving neuronal network hyperexcitability and subsequent pathology. We have developed a human in vitro model of Dravet syndrome using differentiated neurons derived from patient iPSC and enriched for GABA expressing neurons. Neurons were plated on high definition multielectrode arrays (HD-MEAs), permitting recordings from the same cultures over the 7-weeks duration of study at the network, single cell, and subcellular resolution. Using this capability, we characterized the features of axonal morphology and physiology. Neurons developed increased spiking activity and synchronous network bursting. Recordings were processed through a spike sorting pipeline for curation of single unit activity and to assess the effects of pharmacological treatments. At 7-weeks, the application of the GABAAR receptor agonist muscimol eliminated network bursting, indicating the presence of GABAergic neurotransmission. To identify the role of NaV1.1 on neuronal and network activity, cultures were treated with a dose-response of the NaV1.1 potentiator δ-theraphotoxin-Hm1a. This resulted in a strong increase in firing rates of putative GABAergic neurons, an increase in the intraburst firing rate, and eliminated network bursting. These results validate that potentiation of NaV1.1 in Dravet patient iPSC-derived neurons results in decreased firing synchrony in neuronal networks through increased GABAergic neuron activity and support the use of human neurons and HD-MEAs as viable high-throughput electrophysiological platform to enable therapeutic discovery.

Project description:Epigenetic insights into GABAergic development in Dravet Syndrome iPSC and therapeutic implications

Project description:Dravet syndrome (DS) is a severe epileptic encephalopathy caused by heterozygous loss-of-function mutations in the SCN1A gene, indicating a haploinsufficient genetic mechanism underlining this pathology. Here, we tested whether dCas9-mediated Scn1a gene activation could rescue Scn1a haploinsufficiency and restore physiological levels of its gene product, the Nav1.1 voltage-gated sodium channel. We screeened sgRNAs for their ability to stimulate Scn1a gene transcription in association with the dCas9 activation system. Interestingly, we identified one single sgRNA able to significantly increase Scn1a gene expression levels in cell lines as well as in primary neurons, with high specificity. Accordingly, levels of Nav1.1 protein were sufficiently augmented to potentiate firing ability of wild-type immature GABAergic interneurons. A similar effect in activating the Scn1a transcription was elicited in Dravet GABAergic interneurons rescuing their dysfunctional properties. To determine whether this approach could have therapeutic effect, we packaged adeno-associated viruses with the Scn1a-dCas9 activation system and showed their ability to ameliorate the febrile epileptic crises in DS mice. Our results pave the way for exploiting the dCas9-based gene activation as an effective and targeted approach to DS and other similar disorders resulting from altered gene dosage.

Project description:Next-generation sequencing facilitates quantitative analysis of the transcriptomes of FOXG1 100% dosage GABA interneurons, FOXG1 60% dosage GABA interneurons, FOXG1 30% dosage GABA interneurons, and FOXG1 0% dosage GABA interneurons derived from human embryonic stem cells. We report a genetic manipulation system that enable precise dosage control of FOXG1 protein in human pluripotent stem cells (hPSCs). Using this system, we explored how the various reduced dosage affect human ventrol GABA interneuron development. We employed RNA seq on hPSC-derived GABA interneurons (day 60) to invest the expression pattern under different FOXG1 dosage conditions. RNA-Seq on GABA interneurons (Day 60) indicates that compared to the FOXG1 100% group, variable insufficiency of FOXG1 produces more than 1000 differently expressed genes (DEGs), and more DEGs in the group with less FOXG1 dosage. Heat map on Pearson Correlation indicates that groups with more discriminated FOXG1 exhibit much weaker correlation. Venn diagram reveals that each group has a set of distinct DEGs, suggesting that each FOXG1 protein dosage could results in different expression pattern during differentiation. The DEGs can be divided into two clusters, with one showing dosage-dependent regulation by FOXG1 and the other one typical binary. Key regulatory genes for GABA interneuron induction (NKX2-1, NKX6-2, GAD1, etc.) and for functional GABAergic-specific synapse formation (GABBR1, GABRA1, GABRB1, GABRG1, GABRQ, SHANK1, etc.) are down regulated along with reduction of FOXG1 protein.

Project description:Transplantation of GABAergic interneurons (INs) can sustain long-standing benefits in animal models of epilepsy and other neurological disorders. In a therapeutic perspective, a renewable source of functional GABAergic INs is needed. Here, we identified five factors (Foxg1, Sox2, Ascl1, Dlx5 and Lhx6) able to convert fibroblasts directly into induced GABAergic INs (iGABA-INs), displaying the molecular signature of telencephalic INs. The selected factors recapitulate in fibroblasts the activation of transcriptional networks required for the specification of GABAergic fate during telencephalon development. iGABA-INs exhibited progressively maturing firing patterns comparable to those of cortical INs, had synaptic currents and released GABA. Importantly, upon grafting in the hippocampus, iGABA-INs survived, matured and their optogenetic stimulation triggered GABAergic transmission and inhibited the activity of connected granule cells. The five factors also converted human cells into functional GABAergic neurons. These properties define iGABA-INs as a promising tool for disease modeling and cell-based therapeutic approaches. Comparison of iGABA-INs transcriptional profile with those of starting fibroblasts and GAD67-GFP+ cortical interneurons.

Project description:Autism spectrum disorders (ASDs) are a neurodevelopmental disorder characterized by impairments in social interactions and stereotyped behaviors. While ASD has a strong genetic background, environmental factors including toxins, pesticides, infection and drugs are also known to confer autism susceptibility, likely by inducing epigenetic changes. Exposure to Valproic acid (VPA), a drug for epilepsy and bipolar disorders, during pregnancy is highly associated with the risk of ASD children. In rodents, in utero VPA exposure can precipitate behavioral phenotypes related to ASD in the offspring. Since VPA is an inhibitor of histone deacethytransferase (HDAC) activity, it thought to cause ASD with epigenetic modification. However, the core mechanism by which prenatal VPA exposure causes onset of ASD is still not fully uncovered. Here we revealed that prenatal VPA exposure strongly influences development of vasoactive intestinal peptide (VIP) - positive neurons, a subtype of cortical GABAergic interneurons. The number of VIP+ interneurons was severely reduced in somatosensory area of VPA-exposed ASD animals. We then found that the reduction in VIP+ interneurons is caused by the inhibition of HDAC3 activity upon prenatal VPA exposure. Importantly, prenatal HDAC3 inhibition caused not only the selective reduction in VIP+ interneurons but also the ASD-like behaviors in mice. We then demonstrated that the HDAC3 inhibition aberrantly activates Notch signaling, which influences the cell fate determination of VIP+ interneuron progenitors in caudal ganglionic eminence. Thus, this study uncovers the mechanism by which specific HDAC inhibition during development influences a specific type of GABAergic interneurons in the ASD model. The findings provide a novel insight into the understanding of ASD pathophysiology.

Project description:Valproic acid (VPA) is one of the most commonly used anti-epileptic drugs with pharmacological actions on GABA and blocking voltage-gated ion channels. VPA also inhibits histone deacetylase (HDAC) activity. Suberoylanilide hydroxamic acid is also a member of a larger class of compounds that inhibit HDACs. At the time of this article, there are 123 active international clinical trials for VPA (also known as valproate, convulex, divalproex, and depakote) and SAHA (vorinostat, zolinza). While it is well known that VPA and SAHA influence the accumulation of acetylated lysine residues on histones, their true epigenetic complexity remains poorly understood. Primary human cells were exposed to VPA and SAHA to understand the extent of histone acetylation (H3K9/14ac) using chromatin immunoprecipitation followed by sequencing (ChIP-seq). Because histone acetylation is often associated with modification of lysine methylation, we also examined H3K4me3 and H3K9me3. To assess the influence of the HDAC inhibitors on gene expression, we used RNA sequencing (RNA-seq).

Project description:Severe myoclonic epilepsy of infancy (SMEI), or Dravet syndrome (DS), is a catastrophic pediatric epilepsy with severe intellectual disability, impaired social development, and persistent drug-resistant seizures. One of its primary monogenic causes is a mutation in SCN1A (Nav1.1), a type I voltage-gated sodium channel. In mice, Nav1.1 mutation is associated with reduced sodium current, altered interneuron firing, cognitive deficits, autistic-like traits and seizures. Here we describe a larval zebrafish Nav1.1 mutant that recapitulates salient features of the human SCN1A mutation phenotype. Between three and seven days post-fertilization, Nav1.1 mutants exhibit spontaneous abnormal electrographic activity, hyperactivity and convulsive behaviors. Transcriptomic analysis of Nav1.1 mutants was remarkable for the relatively small fraction of genes that were differentially expressed (~2%) and the lack of compensatory changes in expression for other SCN subunits. Pharmacological studies confirmed an antiepileptic action for the ketogenic diet, benzodiazepine, valproate, potassium bromide and stiripentol in Nav1.1 mutants; acetazolamide, phenytoin, ethosuximide had no effect, carbamazepine and vigabatrin made seizures worse. Using this mutant, we screened a chemical library of 320 compounds and identified four compounds that reduced spontaneous seizure-like behavior and one compound (clemizole) that inhibited convulsive behavior and electrographic seizures. Drug-resistant scn1a zebrafish mutants described here represent a new direction in modeling pediatric epilepsy and could be used to identify novel lead compounds for DS patients 4 Control sibling samples (sample= 10 pooled larvae) and 4 Nav1.1 mutants (sample= 10 pooled larvae) were collected at 6 dpf (days post fertilization). The Nav1.1 mutants were selected based on phenotype (dark color).

Project description:Neuronal activity-dependent gene expression is essential for healthy brain development. Emerging studies implicate alterations in GABAergic neuronal circuits in neurodevelopmental and psychiatric disorders. We conducted an activity-dependent transcriptional and epigenetic profiling of human iPSC-derived GABAergic neurons.

Project description:The piriform cortex (PC) plays a critical role in epileptogenesis, where an excitation/inhibition imbalance contributes to epilepsy etiology. However, the epileptic dynamics of the GABA system and the precise role of GABAergic neurons within the PC in epilepsy remain unclear. Here, we combined Ca2+ and GABA sensors to investigate the dynamics of Gad2-expressing neurons and GABA levels, and selectively manipulated GABAergic neurons in the PC through chemogenetic inhibition and caspase3-mediated apoptosis targeting Gad2 interneurons. The chronic deficiency of PC Gad2 neurons triggered spontaneous recurrent seizures. These findings uncover the dynamic interplay within PC inhibitory components and elaborate counteractive mechanisms in seizure regulation.