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Dravet syndrome is a catastrophic, pharmacoresistant epileptic encephalopathy. Disease onset occurs in the first year of life, followed by developmental delay with cognitive and behavioral dysfunction and substantially elevated risk of premature death. The majority of affected individuals harbor a loss-of-function mutation in one allele of SCN1A, which encodes the voltage-gated sodium channel NaV1.1. Brain NaV1.1 is primarily localized to fast-spiking inhibitory interneurons; thus the mechanism of epileptogenesis in Dravet syndrome is hypothesized to be reduced inhibitory neurotransmission leading to brain hyperexcitability. We show that selective activation of NaV1.1 by venom peptide Hm1a restores the function of inhibitory interneurons from Dravet syndrome mice without affecting the firing of excitatory neurons. Intracerebroventricular infusion of Hm1a rescues Dravet syndrome mice from seizures and premature death. This precision medicine approach, which specifically targets the molecular deficit in Dravet syndrome, presents an opportunity for treatment of this intractable epilepsy.

Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels carry a non-selective cationic conductance, Ih, which is important for modulating neuron excitability. Four genes (HCN1-4) encode HCN channels, with each gene having distinct expression and biophysical profiles. Here we use multiplex nucleic acid in situ hybridization to determine HCN4 mRNA expression within the adult mouse brain. We take advantage of this approach to detect HCN4 mRNA simultaneously with either HCN1 or HCN2 mRNA and markers of excitatory (VGlut-positive) and inhibitory (VGat-positive) neurons, which was not previously reported. We have developed a Fiji-based analysis code that enables quantification of mRNA expression within identified cell bodies. The highest HCN4 mRNA expression was found in the habenula (medial and lateral) and the thalamus. HCN4 mRNA was particularly high in the medial habenula with essentially no co-expression of HCN1 or HCN2 mRNA. An absence of Ih-mediated ‘sag’ in neurons recorded from the medial habenula of knockout mice confirmed that HCN4 channels are the predominant subtype in this region. Analysis in the thalamus revealed HCN4 mRNA in VGlut2-positive excitatory neurons that was always co-expressed with HCN2 mRNA. In contrast, HCN4 mRNA was undetectable in the nucleus reticularis. HCN4 mRNA expression was high in a subset of VGat-positive cells in the globus pallidus external. The majority of these neurons co-expressed HCN2 mRNA while a smaller subset also co-expressed HCN1 mRNA. In the striatum, a small subset of large cells which are likely to be giant cholinergic interneurons co-expressed high levels of HCN4 and HCN2 mRNA. The amygdala, cortex and hippocampus expressed low levels of HCN4 mRNA. This study highlights the heterogeneity of HCN4 mRNA expression in the brain and provides a morphological framework on which to better investigate the functional roles of HCN4 channels.

Febrile seizures are a common childhood seizure disorder and a defining feature of genetic epilepsy with febrile seizures plus (GEFS+), a syndrome frequently associated with Na+ channel mutations. Here, we describe the creation of a knockin mouse heterozygous for the C121W mutation of the beta1 Na+ channel accessory subunit seen in patients with GEFS+. Heterozygous mice with increased core temperature displayed behavioral arrest and were more susceptible to thermal challenge than wild-type mice. Wild-type beta1 was most concentrated in the membrane of axon initial segments (AIS) of pyramidal neurons, while the beta1(C121W) mutant subunit was excluded from AIS membranes. In addition, AIS function, an indicator of neuronal excitability, was substantially enhanced in hippocampal pyramidal neurons of the heterozygous mouse specifically at higher temperatures. Computational modeling predicted that this enhanced excitability was caused by hyperpolarized voltage activation of AIS Na+ channels. This heat-sensitive increased neuronal excitability presumably contributed to the heightened thermal seizure susceptibility and epileptiform discharges seen in patients and mice with beta1(C121W) subunits. We therefore conclude that Na+ channel beta1 subunits modulate AIS excitability and that epilepsy can arise if this modulation is impaired.

Spider venom is a rich source of peptides, many targeting ion channels. We assessed a venom peptide, Hm1a, as a potential targeted therapy for Dravet syndrome, the genetic epilepsy linked to a mutation in the gene encoding the sodium channel alpha subunit Na V 1.1. Cell-based assays showed Hm1a was selective for hNa V 1.1 over other sodium and potassium channels. Utilizing a mouse model of Dravet syndrome, Hm1a restored inhibitory neuron function and significantly reduced seizures and mortality in heterozygote mice. Evidence from the structure of Hm1a and modeling suggest Hm1a interacts with Na V 1.1 inactivation domains, providing a structural correlate of the functional mechanisms. This proof-of-concept study provides a promising strategy for future drug development in genetic epilepsy and other neurogenetic disorders. Dravet syndrome is a catastrophic, pharmacoresistant epileptic encephalopathy. Disease onset occurs in the first year of life, followed by developmental delay with cognitive and behavioral dysfunction and substantially elevated risk of premature death. The majority of affected individuals harbor a loss-of-function mutation in one allele of SCN1A , which encodes the voltage-gated sodium channel Na V 1.1. Brain Na V 1.1 is primarily localized to fast-spiking inhibitory interneurons; thus the mechanism of epileptogenesis in Dravet syndrome is hypothesized to be reduced inhibitory neurotransmission leading to brain hyperexcitability. We show that selective activation of Na V 1.1 by venom peptide Hm1a restores the function of inhibitory interneurons from Dravet syndrome mice without affecting the firing of excitatory neurons. Intracerebroventricular infusion of Hm1a rescues Dravet syndrome mice from seizures and premature death. This precision medicine approach, which specifically targets the molecular deficit in Dravet syndrome, presents an opportunity for treatment of this intractable epilepsy.

We describe the visualization of the barrel cortex of the primary somatosensory area (S1) of ex vivo adult mouse brain with short-tracks track density imaging (stTDI). stTDI produced much higher definition of barrel structures than conventional fractional anisotropy (FA), directionally-encoded color FA maps, spin-echo T1- and T2-weighted imaging and gradient echo T1/T2*-weighted imaging. 3D high angular resolution diffusion imaging (HARDI) data were acquired at 48micron isotropic resolution for a (3mm)3 block of cortex containing the barrel field and reconstructed using stTDI at 10micron isotropic resolution. HARDI data were also acquired at 100micron isotropic resolution to image the whole brain and reconstructed using stTDI at 20micron isotropic resolution. The 10micron resolution stTDI maps showed exceptionally clear delineation of barrel structures. Individual barrels could also be distinguished in the 20micron stTDI maps but the septa separating the individual barrels appeared thicker compared to the 10micron maps, indicating that the ability of stTDI to produce high quality structural delineation is dependent upon acquisition resolution. Close homology was observed between the barrel structure delineated using stTDI and reconstructed histological data from the same samples. stTDI also detects barrel deletions in the posterior medial barrel sub-field in mice with infraorbital nerve cuts. The results demonstrate that stTDI is a novel imaging technique that enables three-dimensional characterization of complex structures such as the barrels in S1 and provides an important complementary non-invasive imaging tool for studying synaptic connectivity, development and plasticity of the sensory system. •Mouse barrel cortex can be visualized in high definition using stTDI.•stTDI produced superior barrel visualization compared to conventional MRI and FA maps.•stTDI is a novel imaging technique for 3D characterization of the barrel cortex.•stTDI can detect barrel changes resulting from infraorbital nerve cut.

Dravet syndrome is a catastrophic, pharmacoresistant epileptic encephalopathy. Disease onset occurs in the first year of life, followed by developmental delay with cognitive and behavioral dysfunction and substantially elevated risk of premature death. The majority of affected individuals harbor a loss-of-function mutation in one allele of SCN1A, which encodes the voltage-gated sodium channel NaV1.1. Brain NaV1.1 is primarily localized to fast-spiking inhibitory interneurons; thus the mechanism of epileptogenesis in Dravet syndrome is hypothesized to be reduced inhibitory neurotransmission leading to brain hyperexcitability. We show that selective activation of NaV1.1 by venom peptide Hm1a restores the function of inhibitory interneurons from Dravet syndrome mice without affecting the firing of excitatory neurons. Intracerebroventricular infusion of Hm1a rescues Dravet syndrome mice from seizures and premature death. This precision medicine approach, which specifically targets the molecular deficit in Dravet syndrome, presents an opportunity for treatment of this intractable epilepsy.

Cortical tubers are benign lesions that develop in patients with tuberous sclerosis complex (TSC), often resulting in drug-resistant epilepsy. Surgical resection may be required for seizure control, but the extent of the resection required is unclear. Many centres include resection of perituberal cortex, which may be associated with neurological deficits. Also, patients with tubers in eloquent cortex may be excluded from epilepsy surgery. Our electrophysiological and MRI studies indicate that the tuber centre is the source of seizures, suggesting that smaller resections may be sufficient for seizure control. Here we report five epilepsy surgeries in four children with TSC and focal motor seizures from solitary epileptogenic tubers in the sensorimotor cortex in whom the resection was limited to the tuber centre, leaving the tuber rim and surrounding perituberal cortex intact. Seizures were eliminated in all cases, and no functional deficits were observed. On routine histopathology we observed an apparent increase in density of dysmorphic neurons at the tuber centre, which we confirmed using unbiased stereology which demonstrated a significantly greater density of dysmorphic neurons within the resected tuber centre (1951 ± 215 cells/mm3) compared to the biopsied tuber rim (531 ± 189 cells/mm3, n = 4, p = 0.008). Taken together with our previous electrophysiological and MRI studies implicating the tuber centre as the focus of epileptic activity, and other electrophysiological studies of dysmorphic neurons in focal cortical dysplasia, this study supports the hypothesis that dysmorphic neurons concentrated at the tuber centre are the seizure generators in TSC. Furthermore, our results support limiting resection to the tuber centre, decreasing the risk of neurological deficits when tubers are located within eloquent cortex.

Cortical tubers are benign, well-circumscribed hamartomas that develop in patients with tuberous sclerosis complex, often resulting in drug-resistant epilepsy. Surgical resection may be required for seizure control, but the minimal extent of resection required for complete seizure control is unclear. Many epilepsy centres perform extensive resections, including perituberal cortex, which may be associated with adverse neurological complications. This approach also reduces the number of patients thought appropriate for epilepsy surgery by excluding those with tubers in eloquent cortical areas. In vivo and ex vivo electrophysiological studies have recently identified the tuber centre as the source of seizures, suggesting smaller resections may be sufficient for effective seizure control. Here we report five epilepsy surgeries performed in four children with TSC and focal motor seizures resulting from solitary epileptogenic tubers in the primary sensorimotor cortex. The resection was limited to the tuber centre, leaving the tuber rim and surrounding perituberal cortex intact. Seizures were eliminated in all cases, and no functional deficits were observed. We hypothesised that this optimal surgical outcome was due to removing dysplastic tissue at the tuber centre, which contained a high density of dysmorphic neurons. Unbiased stereology identified a significantly greater density of dysmorphic neurons within the tuber centre (1951 ± 215) compared to the tuber rim (531 ± 189, n = 4, p = 0.002). This study provides the first quantitative evidence of differences in dysmorphic neuron distribution within cortical tubers, with the centre showing the highest density. Taken together with previous electrophysiological studies implicating the tuber centre as the source of epileptic activity, this study supports the hypothesis that dysmorphic neurons are seizure generators within this tissue region. Our results suggest that limiting resection to the tuber centre may provide equivalent reductions in seizure burden to current surgical practice while decreasing the risk of adverse outcomes when tubers are located within eloquent cortical areas such as the motor cortex. Altered surgical practice may result in epilepsy surgery being a viable option for a larger number of patients with TSC and associated malformations of cortical development.

X-linked diseases typically exhibit more severe phenotypes in males than females. In contrast, Protocadherin 19 (PCDH19) mutations cause epilepsy in heterozygous females but spare hemizygous males. The cellular mechanism responsible for this unique pattern of X-linked inheritance is unknown. We show that PCDH19 contributes to highly specific combinatorial adhesion codes such that mosaic expression of Pcdh19 in heterozygous female mice leads to striking sorting between WT PCDH19- and null PCDH19-expressing cells in the developing cortex, correlating with altered network activity. Complete deletion of PCDH19 in heterozygous mice abolishes abnormal cell sorting and restores normal network activity. Furthermore, we identify variable cortical malformations in PCDH19 epilepsy patients. Our results highlight the role of PCDH19 in determining specific adhesion codes during cortical development and how disruption of these codes is associated with the unique X-linked inheritance of PCDH19 epilepsy.