Heterotopic Neurons Research Articles

Somatic variants in SLC35A2 leading to defects in N-glycosylation in mild malformation of cortical development with oligodendroglial hyperplasia in epilepsy (MOGHE).

Mild malformation of cortical development with oligodendroglial hyperplasia in epilepsy (MOGHE) is a new histopathological entity identified in the surgically resected brain tissue of patients with drug-resistant epilepsy. Somatic variants in SLC35A2 have been increasingly identified in MOGHE brain resections. SLC35A2 protein transports uridine 5'-diphosphogalactose (UDP-Gal) into the Golgi lumen, playing a crucial role in the process of N-glycosylation. Currently, research on the pathogenic mechanism of SLC35A2 variants in MOGHE is limited. Here we conducted genetic testing on brain samples and paired blood samples from 28 pediatric patients pathologically diagnosed with MOGHE. We performed an in-depth functional analysis of somatic variants identified in SLC35A2, integrating glycan labeling and intact glycopeptide profiling to assess N-glycosylation defects. With whole-exome sequencing and validation with ultra-deep amplicon sequencing, we identified 101 potentially pathogenic somatic variants (PPSVs) across 87 genes. Nine PPSVs in SLC35A2 were found in 10 samples. The 9 identified variants of SLC35A2, characterized by various mutation types (4 frameshift, 3 missense and 2 nonsense variants), were all confirmed to be loss-of-function via altered glycan chains. Intact glycopeptide analysis at the cellular level indicated an increase in truncated N-glycan glycoforms. Analysis of brain tissue revealed N-glycosylated proteins and glycosites modified with agalactosylated glycoforms, and glycoproteins bearing agalactosylated N-glycans were significantly enriched in cell adhesion and axon guidance-related pathways. Additionally, chemoenzymatic glycan labeling in lesions demonstrated N-glycan damage of heterotopic neurons, suggesting a potential diagnostic approach for MOGHE. Our findings provide a comprehensive somatic landscape of MOGHE and a rich resource of somatic SLC35A2 variant-related glycoform and glycoprotein abnormalities, thereby unveiling valuable insights into compromised N-glycosylation and MOGHE formation.

A unique presentation of trigeminal neuralgia related to a central nervous tissue choristoma along the trigeminal nerve root: illustrative case.

Trigeminal neuralgia (TNa), or tic douloureux, is characterized by severe facial pain triggered by everyday activities. Recurring and intense TNa pain results from localized demyelination within the affected nerve segment. The primary cause of TNa is typically vascular compression, with the superior cerebellar artery being the most common vessel. Tumors, multiple sclerosis, and infectious diseases such as herpes are less frequent causes of TNa. The authors present a unique case in which TNa was caused by an aberrant mass resembling a schwannoma during surgery. However, histological examination revealed heterotopic benign central nervous neurons and myelinated axons, which could represent a choristoma in the cisternal segment of the portio major of the trigeminal nerve. Following surgery, the patient's TNa was completely resolved. To the best of the authors' knowledge, this is the first documented case of a central nervous tissue choristoma causing TNa and responding positively to surgical intervention, aside from one previous report that did not specifically use the term "choristoma" in identifying the lesion. This case highlights the challenges involved in diagnosing and managing a rare TNa presentation, with a particular focus on pathology findings. It underscores the potential role of surgery for patients whose condition is resistant to medical intervention. https://thejns.org/doi/10.3171/CASE24384.

Laser Ablation of Periventricular Nodular Heterotopia for Medically Refractory Epilepsy.

Periventricular nodular heterotopia (PVNH) is the most common neuronal heterotopia, frequently resulting in pharmaco-resistant epilepsy. Here, we characterize variables that predict good epilepsy outcomes following surgical intervention using stereo-electroencephalography (SEEG) -informed magnetic resonance-guided laser interstitial thermal therapy (MRgLITT). A retrospective review of consecutive cases from a single high-volume epilepsy referral center identified patients who underwent SEEG evaluation for PVNH to characterize the intervention and outcomes. Thirty-nine patients underwent SEEG-guided MRgLITT of the seizure onset zone (SoZ) in PVNH and associated epileptic tissue. PVNH and polymicrogyria (PMG) were densely sampled with a mean of 16.5 (SD = 2)/209.4 (SD = 36.9) SEEG probes/recording contacts per patient. Ablation principally targeted just the PVNH and cortex that was abnormal on imaging was ablated (5 patients) only if implicated in the SoZ. Volumetric analyses revealed a high percentage of PVNH SoZ ablation (96.6%, SD = 5.3%) in unilateral and bilateral (92.9%, SD = 7.2%) cases. Mean follow-up duration was 31.4 months (SD = 20.9). Seizure freedom (ILAE 1) was excellent: unilateral PVNH without other imaging abnormalities, 80%; PVNH with mesial temporal sclerosis (MTS) or PMG, 63%; bilateral PVNH, 50%. SoZ ablation percentage significantly impacted surgical outcomes (p < 0.001). PVNH plays a central role in seizure genesis as revealed by dense recordings and selective targeting by LITT. MRgLITT represents a transformative technological advance in PVNH-associated epilepsy with seizure control outcomes consistent with those seen in focal lesional epilepsies. In localized unilateral cases and otherwise normal imaging, PVNH ablation without invasive recordings may be considered, and this approach deserves to be explored further. ANN NEUROL 2024;96:1174-1184.

SLC35A2 somatic variants in drug resistant epilepsy: FCD and MOGHE

De novo somatic (post-zygotic) gene mutations affecting neuroglial progenitor cell types in embryonic cerebral cortex are increasingly identified in patients with drug resistant epilepsy (DRE) associated with malformations of cortical development, in particular, focal cortical dysplasias (FCD). Somatic variants in at least 16 genes have been linked to FCD type II, all encoding components of the mechanistic target of rapamycin (mTOR) pathway. FCD type II is characterized histopathologically by cytomegalic dysmorphic neurons and balloon cells. In contrast, the molecular pathogenesis of FCD I subtypes is less well understood, and histological features are characterized by alterations in columnar or laminar organization without cytomegalic dysmorphic neurons or balloon cells. In 2018, we reported somatic mutations in Solute Carrier Family 35 member A2 (SLC35A2) linked to DRE underlying FCD type I and subsequently to a new histopathological phenotype: excess oligodendrocytes and heterotopic neurons in subcortical white matter known as MOGHE (mild malformation of cortical development with oligodendroglial hyperplasia). These discoveries opened the door to studies linking somatic mutations to FCD. In this review, we discuss the biology of SLC35A2 somatic mutations in epilepsy in FCD and MOGHE, and insights into SLC35A2 epilepsy pathogenesis, describing progress to date and critical areas for investigation.

Metformin rescues migratory deficits of cells derived from patients with periventricular heterotopia.

Periventricular neuronal heterotopia (PH) is one of the most common forms of cortical malformation in the human cortex. We show that human neuronal progenitor cells (hNPCs) derived from PH patients with a DCHS1 or FAT4 mutation as well as isogenic lines had altered migratory dynamics when grafted in the mouse brain. The affected migration was linked to altered autophagy as observed in vivo with an electron microscopic analysis of grafted hNPCs, a Western blot analysis of cortical organoids, and time-lapse imaging of hNPCs in the presence of bafilomycin A1. We further show that deficits in autophagy resulted in the accumulation of paxillin, a focal adhesion protein involved in cell migration. Strikingly, a single-cell RNA-seq analysis of hNPCs revealed similar expression levels of autophagy-related genes. Bolstering AMPK-dependent autophagy by metformin, an FDA-approved drug, promoted migration of PH patients-derived hNPCs. Our data indicate that transcription-independent homeostatic modifications in autophagy contributed to the defective migratory behavior of hNPCs in vivo and suggest that modulating autophagy in hNPCs might rescue neuronal migration deficits in some forms of PH.

Microglia Maintain Homeostatic Conditions in the Developing Rostral Migratory Stream (P10-9.005)

<h3>Objective:</h3> This work examines how microglia maintain the homeostatic conditions permissive to neuroblast migration in the rostral migratory stream (RMS) during the early postnatal period. <h3>Background:</h3> Microglia phagocytosis is essential during critical periods of development to clear the results of over-exuberant neurogenesis, including defective and apoptotic cells. The importance of microglia in mediating homeostasis during neurodevelopment was underscored by the case of a child born without microglia, who exhibited neuronal heterotopias and ventriculomegaly (Oosterhof et al., 2019). <h3>Design/Methods:</h3> To illustrate microglia phagocytosis of neuroblasts in the postnatal RMS, P7 <i>CX3CR-1</i><i>^GFP/+</i><i>;DCX</i><i>^DsRed/+</i> mice were stained with primary antibodies against CD68, CLEC7A, and MERTK. Fluorescent liposomes were injected into the cerebral lateral ventricles of P1 <i>CX3CR-1</i><i>^GFP/+</i> mice to demonstrate microglia phagocytic capacity. To selectively deplete microglia <i>in vivo, Cx3cr1</i><i>^CreER/+</i><i>; ROSA26</i><i>^eGFP-DTA/+</i> mice were injected with tamoxifen i.p. at P0 and were either sacrificed at P3 or injected with tamoxifen every 4 days until sacrifice at P14. To label microglia, neuroblasts and apoptotic cells, immunohistochemistry was performed with primary antibodies against Iba1, doublecortin (DCX) and cleaved caspase-3 (CC3), respectively. <h3>Results:</h3> Microglia express phagocytic markers, engulf extracellular material and “wrap” migrating neuroblasts in the early postnatal RMS. Microglia depletion was associated with a significant increase in the density of CC3+ apoptotic neuroblasts in the RMS start and RMS descent at both P3 and P14. All five mice that expressed the DTA subunit showed patent olfactory ventricles following 14 days of tamoxifen injection. <h3>Conclusions:</h3> Microglia expressing phagocytic markers closely interact with migrating neuroblasts in the developing RMS, suggesting phagocytosis of neuroblasts. Microglia ablation compromised the homeostasis of the early postnatal RMS, causing an accumulation of apoptotic neuroblasts that broadened the RMS domain and an extended patency of the lateral ventricle extension. Microglia may thus regulate neuroblast migratory corridors through the elimination of surplus neuroblasts and phagocytosis of apoptotic debris. <b>Disclosure:</b> Dr. Meller has received research support from National Institutes of Health Grant NIDCD F31DC018469-01. The institution of Prof. GREER has received research support from NIH.

Human periventricular nodular heterotopia shows several interictal epileptic patterns and hyperexcitability of neuronal firing.

Periventricular nodular heterotopia (PNH) is a malformation of cortical development that frequently causes drug-resistant epilepsy. The epileptogenicity of ectopic neurons in PNH as well as their role in generating interictal and ictal activity is still a matter of debate. We report the first in vivo microelectrode recording of heterotopic neurons in humans. Highly consistent interictal patterns (IPs) were identified within the nodules: (1) Periodic Discharges PLUS Fast activity (PD+F), (2) Sporadic discharges PLUS Fast activity (SD+F), and (3) epileptic spikes (ES). Neuronal firing rates were significantly modulated during all IPs, suggesting that multiple IPs were generated by the same local neuronal populations. Furthermore, firing rates closely followed IP morphologies. Among the different IPs, the SD+F pattern was found only in the three nodules that were actively involved in seizure generation but was never observed in the nodule that did not take part in ictal discharges. On the contrary, PD+F and ES were identified in all nodules. Units that were modulated during the IPs were also found to participate in seizures, increasing their firing rate at seizure onset and maintaining an elevated rate during the seizures. Together, nodules in PNH are highly epileptogenic and show several IPs that provide promising pathognomonic signatures of PNH. Furthermore, our results show that PNH nodules may well initiate seizures.

Familial posterior predominant subcortical band heterotopia caused by a CEP85L missense mutation

Lissencephaly comprises a spectrum of cortical malformations caused by disruption of neuronal migration. The lissencephaly spectrum includes agyria defined as cortex lacking gyri with sulci >3 cm apart, pachygyria defined as abnormally broad gyri with sulci 1.5–3 cm apart, and subcortical band heterotopia (SBH) characterised by a band of heterotopic neurons beneath the cortex, separated by a thin layer of white matter [1]. Lissencephaly has heterogeneous genetic aetiologies, including both single gene mutations (for example, LIS1 and DCX variants) and locus deletions (for example, 17p13.3 deletion causing Miller-Dieker syndrome) [1].

Subcortical band heterotopia: analysis of 5 cases

Subcortical band heterotopia (SBH) is a diffuse deterioration of cortical development, which is characterized by the location of heterotopic neurons in deep and subcortical regions of the brain parallel to the cortex, which creates the illusion of duplication of the cortex, from what this variant was named the «double cortex» syndrome. Data of five patients including three girls and 2 boys were analyzed. The average age was 12.6 years (from 5 to 15). In all cases, heterotopia was bilaterally symmetrical: in 2 cases - diffuse, in 1 it was fronto-parietal, in 1 - temporal-occipital, and in 1 it was fronto-parietal-occipital. Concomitant cerebral malformations were presented in all patients: ventriculomegaly in 5 cases (100%), frontal pachygyria in 1 case (20.0%), diffuse pachygyria in 1 case (20.0%), and dysgyria in 1 case (20.0%). All 5 (100%) patients had epilepsy. The age of onset of epileptic seizures was 6.1 [5.6; 7.5] years. In 3 (60.0%) people epilepsy was focal, in 2 (40.0%) - generalized. There were the following types of epileptic seizures: infantile spasms - 1 (20.0%), focal - 3 (60.0%), tonic-clonic - 4 (80.0%), myoclonic - 2 (40.0%), attacks of cessation of motor activity - 1 (20.0%), atonic - 1 (20.0%). Status epilepticus and febrile-provoked seizures were no observed in any case. Interictal epileptiform activity was presented in all cases: regional in 3 (60.0%), diffuse in 1 (20.0%), and multiregional + diffuse in 1 (20.0%). Drug resistant course was in 3 (60.0%) people. Intellectual impairments were detected in 3 (60.0%) patients: mild - in 1 (20.0%), moderate - in 1 (20.0%), severe - in 1 (20.0%). In 2 (40.0%) observations, intelligence was intact, and in both cases these were patients without drug-resistant epilepsy and without concomitant pachygyria. Speech disorder was detected in 3 (60.0%) people, mild movement disorders - in 1 (20.0%), microcephaly - in 1 (20.0%). Thus, the leading clinical manifestation of SBH is epilepsy with a predominantly drug resistant course. More data are needed on the possibility of using alternative drug treatments.

Neuropathology findings in KCNQ2 neonatal epileptic encephalopathy.

PurposeKCNQ2-epileptic encephalopathy (EE) is a neonatal epilepsy syndrome characterized by a typical clinical presentation and EEG recording, but without any brain or cortical abnormal development on MRI. Most of the patients have a severe developmental impairment. The epileptogenic mechanisms are thought to be the result of the changes of the M-current density causing a change of brain excitability. Although recent studies allow us to better understand the physiopathology of KCNQ2-EE, the neuropathology of this ion channel dysfunction has only been previously described in a single case report. MethodsWe report the neuropathology study of a case of KCNQ2-EE with a typical electro-phenotype due to a de novo heterozygous single nucleotide pathogenic variant in the exon 5 of the KCNQ2 gene (NM_172107.2:c.802C>T; p.Leu268Phe). ResultsAt the macroscopic level, the brain had a normal structure with a normal neocortical gyral pattern. At the histological level, the cortex had a usual six-layer lamination in all lobes but blurred gray-white matter boundaries due to excessive heterotopic neurons in deep white matter were observed. This diffuse mild malformation of cortical development is suggestive of a neuronal migration disorder. ConclusionIn recent years, our understanding of the role of ion channel dysfunctions in early brain development has expanded from the occurrence of EE to brain malformation. Through this rare neuropathological report, we emphasize the role of KCNQ2 channels in the process of cortical development. As for other genetic neonatal onset epilepsies, more reports are needed to further delineate the range of neuropathological abnormalities for KCNQ2-EE.

NPRL3 loss alters neuronal morphology, mTOR localization, cortical lamination and seizure threshold.

Mutations in nitrogen permease regulator-like 3 (NPRL3), a component of the GATOR1 complex within the mTOR pathway, are associated with epilepsy and malformations of cortical development. Little is known about the effects of NPRL3 loss on neuronal mTOR signalling and morphology, or cerebral cortical development and seizure susceptibility. We report the clinical phenotypic spectrum of a founder NPRL3 pedigree (c.349delG, p.Glu117LysFS; n = 133) among Old Order Mennonites dating to 1727. Next, as a strategy to define the role of NPRL3 in cortical development, CRISPR/Cas9 Nprl3 knockout in Neuro2a cells in vitro and in foetal mouse brain in vivo was used to assess the effects of Nprl3 knockout on mTOR activation, subcellular mTOR localization, nutrient signalling, cell morphology and aggregation, cerebral cortical cytoarchitecture and network integrity. The NPRL3 pedigree exhibited an epilepsy penetrance of 28% and heterogeneous clinical phenotypes with a range of epilepsy semiologies, i.e. focal or generalized onset, brain imaging abnormalities, i.e. polymicrogyria, focal cortical dysplasia or normal imaging, and EEG findings, e.g. focal, multi-focal or generalized spikes, focal or generalized slowing. Whole exome analysis comparing a seizure-free group (n = 37) to those with epilepsy (n = 24) to search for gene modifiers for epilepsy did not identify a unique genetic modifier that explained the variability in seizure penetrance in this cohort. Nprl3 knockout in vitro caused mTOR pathway hyperactivation, cell soma enlargement and the formation of cellular aggregates seen in time-lapse videos that were prevented with the mTOR inhibitors rapamycin or torin1. In Nprl3 knockout cells, mTOR remained localized on the lysosome in a constitutively active conformation, as evidenced by phosphorylation of ribosomal S6 and 4E-BP1 proteins, even under nutrient starvation (amino acid-free) conditions, demonstrating that Nprl3 loss decouples mTOR activation from neuronal metabolic state. To model human malformations of cortical development associated with NPRL3 variants, we created a focal Nprl3 knockout in foetal mouse cortex by in utero electroporation and found altered cortical lamination and white matter heterotopic neurons, effects which were prevented with rapamycin treatment. EEG recordings showed network hyperexcitability and reduced seizure threshold to pentylenetetrazol treatment. NPRL3 variants are linked to a highly variable clinical phenotype which we propose results from mTOR-dependent effects on cell structure, cortical development and network organization.

Histopathological Correlations of Qualitative and Quantitative Temporopolar MRI Analyses in Patients With Hippocampal Sclerosis.

Hippocampal sclerosis (HS) is a common cause of pharmacoresistant focal epilepsy. Here, we (1) performed a histological approach to the anterior temporal pole of patients with HS to evaluate cortical and white matter (WM) cell populations, alteration of myelin integrity and markers of neuronal activity, and (2) correlated microscopic data with magnetic resonance imaging (MRI) findings. Our aim was to contribute with the understanding of neuroimaging and pathophysiological mechanisms of temporal lobe epilepsy (TLE) associated with HS. We examined MRIs and surgical specimens from the anterior temporal pole from TLE-HS patients (n = 9) and compared them with 10 autopsy controls. MRIs from healthy volunteers (n = 13) were used as neuroimaging controls. Histological techniques were performed to assess oligodendrocytes, heterotopic neurons, cellular proliferative index, and myeloarchitecture integrity of the WM, as well as markers of acute (c-fos) and chronic (ΔFosB) activities of neocortical neurons. Microscopic data were compared with neuroimaging findings, including T2-weighted/FLAIR MRI temporopolar blurring and values of fractional anisotropy (FA) from diffusion-weighed imaging (DWI). We found a significant increase in WM oligodendrocyte number, both in hematoxylin and eosin, and in Olig2-stained sections. The frequencies of oligodendrocytes in perivascular spaces and around heterotopic neurons were significantly higher in patients with TLE–HS compared with controls. The percentage of 2',3'-cyclic-nucleotide 3'-phosphodiesterase (CNPase; a marker of myeloarchitecture integrity) immunopositive area in the WM was significantly higher in TLE-HS, as well as the numbers of c-fos- and ΔFosB-immunostained neocortical neurons. Additionally, we demonstrated a decrease in axonal bundle integrity on neuroimaging, with a significant reduction in the FA in the anterior temporal pole. No differences were detected between individuals with and without temporopolar blurring on visual MRI analysis, considering the number of oligodendroglial cells and percentage of WM CNPase-positive areas. Also, there was no relationship between T2 relaxometry and oligodendrocyte count. In conclusion, our histopathological data support the following: (1) the hypothesis that repetitive neocortical neuronal activity could induce changes in the WM cellular constitution and myelin remodeling in the anterior temporal pole from patients with TLE-HS, (2) that oligodendroglial hyperplasia is not related to temporal blurring or T2 signal intensity on MRI, and (3) that reduced FA is a marker of increase in Olig2-immunopositive cells in superficial temporopolar WM from patients with TLE-HS.

The neuropathological findings of developmental and epileptic encephalopathy-43 (DEE43) and delineation of a the molecular spectrum of novel case

Developmental and epileptic encephalopathies (DEE) constitute an expanding group of severely disabling and, most frequently, drug-resistant disorders starting in the first year of life. Among them, there is DEE43, caused by dominant mutations in the GABRB3 gene. We present first neuropathological findings in a novel, molecularly confirmed case with the fatal course. The neuropathological analysis revealed co-existing developmental anomalies and retardation of myelination resulting from disturbed early brain growth as well as lesions caused by epileptic hypoxic-ischemic episodes. Developmental anomalies included misplaced neurons in the cerebellar white matter, heterotopic neurons in the cortical molecular layer and in the molecular layer of the hippocampal dentate gyrus, dysmorphic cerebellar dentate nuclei and inferior olivary nuclei in the medulla oblongata. The migrational and maturational disorders leading to the neuronal network dysfunction could be the cause of both the lack of development and the ineffectiveness of antiepileptic treatment in children affected by DEE. Giving the presented neuropathological description and based on the literature, we discuss the pathomechanism of the disease, to improve current understanding of both the lack of development and the ineffectiveness of treatment of affected children.

Neurological outcome in WDR62 primary microcephaly.

To characterize the cortical structure, developmental, and cognitive profiles of patients with WD repeat domain 62 (WDR62)-related primary microcephaly. In this observational study, we describe the developmental, neurological, cognitive, and brain imaging characteristics of 17 patients (six males, 11 females; mean age 12y 3mo standard deviation [SD] 5y 8mo, range 5y-24y 6mo) and identify 14 new variants of WDR62. We similarly analyse the phenotypes and genotypes of the 59 previously reported families. Brain malformations, including pachygyria, neuronal heterotopia, schizencephaly, and microlissencephaly, were present in 11 out of 15 patients. The mean full-scale IQ of the 11 assessed patients was 51.8 (standard deviation [SD] 12.6, range 40-70). Intellectual disability was severe in four patients, moderate in four, and mild in three. Scores on the Vineland Adaptive Behavior Scales obtained from 10 patients were low for communication and motor skills (mean 38.29, SD 7.74, and 37.71, SD 5.74 respectively). The socialization score was higher (mean 47.14, SD 12.39). We found a significant difference between scores for communication and daily living skills (mean 54.43, SD 11.6; p=0.001, one-way analysis of variance). One patient displayed progressive ataxia. WDR62-related cognitive consequences may be less severe than expected because 3 out of 11 of the assessed patients had only mild intellectual disability and relatively preserved abilities of autonomy in daily life. We identified progressive ataxia in the second decade of life in one patient, which should encourage clinicians to follow up patients in the long term.

Malformations of Cortical Development, Cognitive Involvementand Epilepsy: A Single Institution Experience in 19 Young Patients.

Background. Malformations of cortical development (MCD) include a wide range of congenital disorders mostly causing severe cognitive dysfunction and epilepsy. Objective: to report on clinical features including cognitive involvement, epileptic seizures with response to antiseizure medications, comorbidities in young patients affected by MCD and followed in a single tertiary hospital. Patients and methods: A retrospective review of the medical records and magnetic resonance images (MRI) of 19 young patients with an age ranging between eight days and fifteen years affected by MCD and admitted to Pediatrics Department University of Catania, Italy from October 2009 and October 2020 were selected. Patients were distinguished in three groups following the Barcovich et al. 2012 classification for MCD: 4 (21%) in Group I; 8 (42%) in Group II; and, and 7 (37%) in Group III. Clinical features and MRI of the patients including cognitive involvement, epilepsy type and response to drugs treatment were analyzed. Results: In Group I, two patients showed cortical dysplasia and two dysembryoplastic neuroepithelial tumors plus focal cortical dysplasia; developmental delay/intellectual disability (DD/ID) was severe in one, moderate in one and absent in two; the type of seizures was in all the cases focal to bilateral tonic-clonic (FBTCs), and drug resistant was found in one case. In Group II, three patients showed neuronal hetero-topias and five had pachygyria-lissencephaly: DD/ID was severe in four, moderate in two, and absent in two; the type of seizure was focal (FS) in five, focal to bilateral tonic-clonic (FBTCs) in two, infantile spasms (IS) in one, and drug resistant was found in three. In Group III, six showed polymicrogyria and one schizencephaly: DD/ID was found severe in five, moderate in two, and the type of seizure was focal (FS) in five, FBTCS in two, and drug resistance was found in three.

Neuropathological hallmarks of fetal hydrocephalus linked to CCDC88C pathogenic variants

The prevalence of congenital hydrocephalus has been estimated at 1.1 per 1000 infants when including cases diagnosed before 1 year of age after exclusion of neural tube defects. Classification criteria are based either on CSF dynamics, pathophysiological mechanisms or associated lesions. Whereas inherited syndromic hydrocephalus has been associated with more than 100 disease-causing genes, only four genes are currently known to be linked to congenital hydrocephalus either isolated or as a major clinical feature: L1CAM, AP1S2, MPDZ and CCDC88C. In the past 10 years, pathogenic variants in CCDC88C have been documented but the neuropathology remains virtually unknown. We report the neuropathology of two foetuses from one family harbouring two novel compound heterozygous pathogenic variants in the CCDC88C gene: a maternally inherited indel in exon 22, c.3807_3809delinsACCT;p.(Gly1270Profs*53) and a paternally inherited deletion of exon 23, c.3967-?_c.4112-?;p.(Leu1323Argfs*10). Medical termination of pregnancy was performed at 18 and 23 weeks of gestation for severe bilateral ventriculomegaly. In both fetuses, brain lesions consisted of multifocal atresia-forking along the aqueduct of Sylvius and the central canal of the medulla, periventricular neuronal heterotopias and choroid plexus hydrops. The second fetus also presented lumbar myelomeningocele, left diaphragmatic hernia and bilateral renal agenesis. CCDC88C encodes the protein DAPLE which contributes to ependymal cell planar polarity by inhibiting the non-canonical Wnt signaling pathway and interacts with MPDZ and PARD3. Interestingly, heterozygous variants in PARD3 result in neural tube defects by defective tight junction formation and polarization process of the neuroepithelium. Besides, during organ formation Wnt signalling is a prerequisite for planar cell polarity pathway activation, and mutations in planar cell polarity genes lead to heart, lung and kidney malformations. Hence, candidate variants in CCDC88C should be carefully considered whether brain lesions are isolated or associated with malformations suspected to result from disorders of planar cell polarity.

Magnetic resonance imaging findings and clinical characteristics in mild malformation of cortical development with oligodendroglial hyperplasia and epilepsy in a predominantly adult cohort.

We aimed to better characterize the magnetic resonance imaging (MRI) findings of mild malformation of cortical development with oligodendroglial hyperplasia (MOGHE), a rare clinicopathological entity associated with pharmacoresistance recently described in patients with frontal lobe epilepsy. We studied 12 patients who underwent epilepsy surgery and whose surgical specimens showed histopathological findings of MOGHE, characterized by preserved cortical lamination, blurred gray-white matter interface due to increased number of oligodendrocytes, and heterotopic neurons in the white matter. The age at MRI evaluation ranged from 11 to 58years, except for one 4.5-year-old patient. Following a detailed MRI analysis using an in-house protocol, we found abnormalities in all cases. The lesion was circumscribed in the frontal lobe in six (50%) and in the temporal lobe in three (25%) patients. In the remaining three patients (25%), the lesion was multilobar (frontotemporal and temporoparieto-occipital). Cortical thickening was mild in all patients, except in the 4.5-year-old patient, who had pronounced cortical thickening and white matter blurring. We also identified cortical/subcortical hyperintense T2/fluid-attenuated inversion recovery signal associated with gray/white matter blurring in all but one patient. When present, cleft cortical dimple, and deep sulci aided in localizing the lesion. Overall, the MRI findings were like those in focal cortical dysplasia (FCD) Type IIa. Surgical outcome was excellent in five patients (Engel Class I in 25% and II in 17%). The remaining seven patients (58%) had worthwhile seizure reduction (Engle Class III). Incomplete lesion resection was significantly associated with worse outcomes. MRI findings associated with MOGHE are similar to those described in FCD Type IIa. Although more frequent in the frontal lobe, MOGHE also occurred in the temporal lobe or involved multiple lobes. Multilobar or extensive MOGHE MRI lesions are associated with less favorable surgical outcomes. Because this is a rare condition, multicenter studies are necessary to characterize MOGHE further.

Intravital Imaging of Neocortical Heterotopia Reveals Aberrant Axonal Pathfinding and Myelination around Ectopic Neurons.

Neocortical heterotopia consist of ectopic neuronal clusters that are frequently found in individuals with cognitive disability and epilepsy. However, their pathogenesis remains poorly understood due in part to a lack of tractable animal models. We have developed an inducible model of focal cortical heterotopia that enables their precise spatiotemporal control and high-resolution optical imaging in live mice. Here, we report that heterotopia are associated with striking patterns of circumferentially projecting axons and increased myelination around neuronal clusters. Despite their aberrant axonal patterns, in vivo calcium imaging revealed that heterotopic neurons remain functionally connected to other brain regions, highlighting their potential to influence global neural networks. These aberrant patterns only form when heterotopia are induced during a critical embryonic temporal window, but not in early postnatal development. Our model provides a new way to investigate heterotopia formation in vivo and reveals features suggesting the existence of developmentally modulated, neuron-derived axon guidance and myelination factors.

Frequent SLC35A2 brain mosaicism in mild malformation of cortical development with oligodendroglial hyperplasia in epilepsy (MOGHE)

Focal malformations of cortical development (MCD) are linked to somatic brain mutations occurring during neurodevelopment. Mild malformation of cortical development with oligodendroglial hyperplasia in epilepsy (MOGHE) is a newly recognized clinico-pathological entity associated with pediatric drug-resistant focal epilepsy, and amenable to neurosurgical treatment. MOGHE is histopathologically characterized by clusters of increased oligodendroglial cell densities, patchy zones of hypomyelination, and heterotopic neurons in the white matter. The molecular etiology of MOGHE remained unknown so far. We hypothesized a contribution of mosaic brain variants and performed deep targeted gene sequencing on 20 surgical MOGHE brain samples from a single-center cohort of pediatric patients. We identified somatic pathogenic SLC35A2 variants in 9/20 (45%) patients with mosaic rates ranging from 7 to 52%. SLC35A2 encodes a UDP-galactose transporter, previously implicated in other malformations of cortical development (MCD) and a rare type of congenital disorder of glycosylation. To further clarify the histological features of SLC35A2-brain tissues, we then collected 17 samples with pathogenic SLC35A2 variants from a multicenter cohort of MCD cases. Histopathological reassessment including anti-Olig2 staining confirmed a MOGHE diagnosis in all cases. Analysis by droplet digital PCR of pools of microdissected cells from one MOGHE tissue revealed a variant enrichment in clustered oligodendroglial cells and heterotopic neurons. Through an international consortium, we assembled an unprecedented series of 26 SLC35A2-MOGHE cases providing evidence that mosaic SLC35A2 variants, likely occurred in a neuroglial progenitor cell during brain development, are a genetic marker for MOGHE.

WWOX is a Risk Factor for Alzheimer’s Disease: How and Why?

A recent large genome-wide association meta-analysis revealed that the human WWOX gene is regarded as one of the five newly identified risk factors for Alzheimer’s disease (AD). However, this study did not functionally characterize how WWOX protein deficiency affects AD initiation, progression and neurodegeneration. In this review, evidence and perspectives are provided regarding how WWOX works in limiting neurodegeneration. Firstly, loss of WWOX/Wwox gene leads to severe neural diseases with degeneration, metabolic disorder and early death in the newborns. Downregulation of pY33-WWOX may start at middle ages, and this leads to slow aggregation of a cascade of proteins, namely TRAPPC6A[Formula: see text], TIAF1 and SH3GLB2, that leads to amyloid-beta (A[Formula: see text]) formation and tau tangle formation in old-aged AD patients. Secondly, functional antagonism between tumor suppressors p53 and WWOX may occur in vivo, in which p53-mediated inflammation is blocked by WWOX. Loss of balance in the functional antagonism leads to aggregation of pathogenic proteins for AD such as tau and A[Formula: see text] in the brain cortex and hippocampus. Thirdly, downregulation of pY33-WWOX is accompanied by upregulation of pS14-WWOX. The event frequently correlates with enhanced AD progression and cancer cell growth in vivo. A small peptide Zfra4-10 dramatically suppresses pS14-WWOX and restores memory loss in triple transgenic (3xTg) mice, and inhibits cancer growth in mice as well. Finally, a supporting scenario is that WWOX deficiency induces enhanced cell migration and loss of cell-to-cell recognition. This allows the generation of neuronal heterotopia and associated epileptic seizure in WWOX-deficient newborn patients.