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Brain : a Journal of Neurology Jun 2021Constitutional heterozygous mutations of ATP1A2 and ATP1A3, encoding for two distinct isoforms of the Na+/K+-ATPase (NKA) alpha-subunit, have been associated with...
Constitutional heterozygous mutations of ATP1A2 and ATP1A3, encoding for two distinct isoforms of the Na+/K+-ATPase (NKA) alpha-subunit, have been associated with familial hemiplegic migraine (ATP1A2), alternating hemiplegia of childhood (ATP1A2/A3), rapid-onset dystonia-parkinsonism, cerebellar ataxia-areflexia-progressive optic atrophy, and relapsing encephalopathy with cerebellar ataxia (all ATP1A3). A few reports have described single individuals with heterozygous mutations of ATP1A2/A3 associated with severe childhood epilepsies. Early lethal hydrops fetalis, arthrogryposis, microcephaly, and polymicrogyria have been associated with homozygous truncating mutations in ATP1A2. We investigated the genetic causes of developmental and epileptic encephalopathies variably associated with malformations of cortical development in a large cohort and identified 22 patients with de novo or inherited heterozygous ATP1A2/A3 mutations. We characterized clinical, neuroimaging and neuropathological findings, performed in silico and in vitro assays of the mutations' effects on the NKA-pump function, and studied genotype-phenotype correlations. Twenty-two patients harboured 19 distinct heterozygous mutations of ATP1A2 (six patients, five mutations) and ATP1A3 (16 patients, 14 mutations, including a mosaic individual). Polymicrogyria occurred in 10 (45%) patients, showing a mainly bilateral perisylvian pattern. Most patients manifested early, often neonatal, onset seizures with a multifocal or migrating pattern. A distinctive, 'profound' phenotype, featuring polymicrogyria or progressive brain atrophy and epilepsy, resulted in early lethality in seven patients (32%). In silico evaluation predicted all mutations to be detrimental. We tested 14 mutations in transfected COS-1 cells and demonstrated impaired NKA-pump activity, consistent with severe loss of function. Genotype-phenotype analysis suggested a link between the most severe phenotypes and lack of COS-1 cell survival, and also revealed a wide continuum of severity distributed across mutations that variably impair NKA-pump activity. We performed neuropathological analysis of the whole brain in two individuals with polymicrogyria respectively related to a heterozygous ATP1A3 mutation and a homozygous ATP1A2 mutation and found close similarities with findings suggesting a mainly neural pathogenesis, compounded by vascular and leptomeningeal abnormalities. Combining our report with other studies, we estimate that ∼5% of mutations in ATP1A2 and 12% in ATP1A3 can be associated with the severe and novel phenotypes that we describe here. Notably, a few of these mutations were associated with more than one phenotype. These findings assign novel, 'profound' and early lethal phenotypes of developmental and epileptic encephalopathies and polymicrogyria to the phenotypic spectrum associated with heterozygous ATP1A2/A3 mutations and indicate that severely impaired NKA pump function can disrupt brain morphogenesis.
Topics: Adolescent; Animals; Brain Diseases; COS Cells; Child; Child, Preschool; Chlorocebus aethiops; Epilepsy; Female; Genotype; Humans; Infant; Infant, Newborn; Male; Mutation; Phenotype; Polymicrogyria; Sodium-Potassium-Exchanging ATPase
PubMed: 33880529
DOI: 10.1093/brain/awab052 -
JAMA Neurology Sep 2023Polymicrogyria is the most commonly diagnosed cortical malformation and is associated with neurodevelopmental sequelae including epilepsy, motor abnormalities, and...
IMPORTANCE
Polymicrogyria is the most commonly diagnosed cortical malformation and is associated with neurodevelopmental sequelae including epilepsy, motor abnormalities, and cognitive deficits. Polymicrogyria frequently co-occurs with other brain malformations or as part of syndromic diseases. Past studies of polymicrogyria have defined heterogeneous genetic and nongenetic causes but have explained only a small fraction of cases.
OBJECTIVE
To survey germline genetic causes of polymicrogyria in a large cohort and to consider novel polymicrogyria gene associations.
DESIGN, SETTING, AND PARTICIPANTS
This genetic association study analyzed panel sequencing and exome sequencing of accrued DNA samples from a retrospective cohort of families with members with polymicrogyria. Samples were accrued over more than 20 years (1994 to 2020), and sequencing occurred in 2 stages: panel sequencing (June 2015 to January 2016) and whole-exome sequencing (September 2019 to March 2020). Individuals seen at multiple clinical sites for neurological complaints found to have polymicrogyria on neuroimaging, then referred to the research team by evaluating clinicians, were included in the study. Targeted next-generation sequencing and/or exome sequencing were performed on probands (and available parents and siblings) from 284 families with individuals who had isolated polymicrogyria or polymicrogyria as part of a clinical syndrome and no genetic diagnosis at time of referral from clinic, with sequencing from 275 families passing quality control.
MAIN OUTCOMES AND MEASURES
The number of families in whom genetic sequencing yielded a molecular diagnosis that explained the polymicrogyria in the family. Secondarily, the relative frequency of different genetic causes of polymicrogyria and whether specific genetic causes were associated with co-occurring head size changes were also analyzed.
RESULTS
In 32.7% (90 of 275) of polymicrogyria-affected families, genetic variants were identified that provided satisfactory molecular explanations. Known genes most frequently implicated by polymicrogyria-associated variants in this cohort were PIK3R2, TUBB2B, COL4A1, and SCN3A. Six candidate novel polymicrogyria genes were identified or confirmed: de novo missense variants in PANX1, QRICH1, and SCN2A and compound heterozygous variants in TMEM161B, KIF26A, and MAN2C1, each with consistent genotype-phenotype relationships in multiple families.
CONCLUSIONS AND RELEVANCE
This study's findings reveal a higher than previously recognized rate of identifiable genetic causes, specifically of channelopathies, in individuals with polymicrogyria and support the utility of exome sequencing for families affected with polymicrogyria.
Topics: Humans; Polymicrogyria; Exome Sequencing; Retrospective Studies; Mutation, Missense; Siblings; Nerve Tissue Proteins; Connexins
PubMed: 37486637
DOI: 10.1001/jamaneurol.2023.2363 -
European Journal of Medical Genetics Apr 2020We present the case of a male infant with bilateral perisylvian polymicrogyria associated with a de novo duplication of chromosome region 17p13.3p13.2. To our knowledge,... (Review)
Review
We present the case of a male infant with bilateral perisylvian polymicrogyria associated with a de novo duplication of chromosome region 17p13.3p13.2. To our knowledge, this is the first report of polymicrogyria associated with the 17p13.3 contiguous gene duplication syndrome. Testing for known monogenic causes of polymicrogyria was negative and there was no clinical evidence of an acquired prenatal cause. Given the critical, dose-sensitive role that the 17p13.3 region plays in brain development, we suggest that the chromosome duplication is the most likely explanation for the polymicrogyria. Clinical and functional studies have demonstrated deleterious effects of increased LIS1 expression on the developing brain and the contribution of YWHAE to the brain phenotype of the 17p13 duplication syndrome. There is also evidence that CRK, the other candidate gene in this region, via interaction with LIS1, plays a critical role in cortical development. In addition to LIS1, YWHAE and CRK, our patient's chromosome duplication involves at least 100 other genes, less than half of which are annotated at the time of writing. It is expected that the ongoing use of chromosome microarray and next-generation sequencing to investigate the genetic causes of brain malformations will continue to extend our understanding of the 17p13 region and of the contributions of the genes in this region to cortical development.
Topics: Chromosome Duplication; Chromosomes, Human, Pair 17; Humans; Infant; Male; Phenotype; Polymicrogyria
PubMed: 31585183
DOI: 10.1016/j.ejmg.2019.103774 -
Brain & Development Feb 2022Polymicrogyria is a malformation of cortical development with overfolding of the cerebral cortex and abnormal cortical layering. Polymicrogyria constitutes a...
BACK GROUND
Polymicrogyria is a malformation of cortical development with overfolding of the cerebral cortex and abnormal cortical layering. Polymicrogyria constitutes a heterogenous collection of neuroimaging features, neuropathological findings, and clinical associations, and is due to multiple underlying etiologies. In the last few years, some glutamate and sodium channelopathies have been associated with cortical brain malformations such as polymicrogyria. The potassium calcium-activated channel subfamily M alpha 1 (KCNMA1) gene encodes each of the four alpha-subunits that make up the large conductance calcium and voltage-activated potassium channel "Big K+". KCNMA1-related channelopathies are associated with various neurological abnormalities, including epilepsy, ataxia, paroxysmal dyskinesias, developmental delay and cognitive disorders.
CASE REPORT
We report the observation of a patient who presented since the age of two months with drug-resistant epilepsy with severe developmental delay initially related to bilateral asymmetric frontal polymicrogyria. Later, exome sequencing revealed a de novo heterozygous variation in the KCNMA1 gene (c.112delG) considered pathogenic.
CONCLUSION
This first case of polymicrogyria associated with KCNMA1-related channelopathy may expand the phenotypic spectrum of KCNMA1-related channelopathies and enrich the recently identified group of developmental channelopathies with polymicrogyria.
Topics: Channelopathies; Developmental Disabilities; Drug Resistant Epilepsy; Humans; Infant; Large-Conductance Calcium-Activated Potassium Channel alpha Subunits; Polymicrogyria
PubMed: 34674900
DOI: 10.1016/j.braindev.2021.09.009 -
Acta Neuropathologica Communications Jul 2014Polymicrogyria (PMG) is a complex cortical malformation which has so far defied any mechanistic or genetic explanation. Adopting a broad definition of an abnormally... (Review)
Review
Polymicrogyria (PMG) is a complex cortical malformation which has so far defied any mechanistic or genetic explanation. Adopting a broad definition of an abnormally folded or festooned cerebral cortical neuronal ribbon, this review addresses the literature on PMG and the mechanisms of its development, as derived from the neuropathological study of many cases of human PMG, a large proportion in fetal life. This reveals the several processes which appear to be involved in the early stages of formation of polymicrogyric cortex. The most consistent feature of developing PMG is disruption of the brain surface with pial defects, over-migration of cells, thickening and reduplication of the pial collagen layers and increased leptomeningeal vascularity. Evidence from animal models is consistent with our observations and supports the notion that disturbance in the formation of the leptomeninges or loss of their normal signalling functions are potent contributors to cortical malformation. Other mechanisms which may lead to PMG include premature folding of the neuronal band, abnormal fusion of adjacent gyri and laminar necrosis of the developing cortex. The observation of PMG in association with other and better understood forms of brain malformation, such as cobblestone cortex, suggests mechanistic pathways for some forms of PMG. The role of altered physical properties of the thickened leptomeninges in exerting mechanical constraints on the developing cortex is also considered.
Topics: Cerebral Cortex; Female; Fetus; Humans; Male; Polymicrogyria
PubMed: 25047116
DOI: 10.1186/s40478-014-0080-3 -
Epileptic Disorders : International... Oct 2018Polymicrogyria (PMG) is one of the most common malformations of cortical development (MCDs), with epilepsy affecting most patients. PMG-related drug-resistant epilepsy... (Review)
Review
Polymicrogyria (PMG) is one of the most common malformations of cortical development (MCDs), with epilepsy affecting most patients. PMG-related drug-resistant epilepsy patients can be considered for epilepsy surgery in well-selected cases. In this context, a comprehensive presurgical evaluation, often including stereo-electroencephalography (SEEG), is warranted to accurately delineate the epileptogenic zone. The heterogeneity of intrinsic epileptogenicity in PMG, together with the additional or predominant involvement of remote cortical areas, calls for a different strategy in PMG compared to other MCDs, namely one that is not predominantly MRI- but rather SEEG-oriented. Favourable results in terms of seizure freedom and antiepileptic drug cessation are feasible in a large proportion of patients with unilateral PMG. PMG extent should not deter from exploring the possibility of epilepsy surgery. On the other hand, patients with hemispheric PMG can be excellent hemispherotomy candidates, particularly when presenting with contralateral hemiparesis. Recent findings support the early consideration of surgery in PMG-related drug-resistant epilepsy.
Topics: Drug Resistant Epilepsy; Electroencephalography; Humans; Polymicrogyria; Stereotaxic Techniques
PubMed: 30378553
DOI: 10.1684/epd.2018.1004 -
Brain Communications 2023Polymicrogyria is estimated to be one of the most common brain malformations, accounting for ∼16% of malformations of cortical development. However, the prevalence and...
Polymicrogyria is estimated to be one of the most common brain malformations, accounting for ∼16% of malformations of cortical development. However, the prevalence and incidence of polymicrogyria is unknown. Our aim was to estimate the prevalence, incidence rate, neuroimaging diversity, aetiology, and clinical phenotype of polymicrogyria in a population-based paediatric cohort. We performed a systematic search of MRI scans at neuroradiology department databases in Stockholm using the keyword polymicrogyria. The study population included all children living in the Stockholm region born from January 2004 to June 2021 with polymicrogyria. Information on the number of children living in the region during 2004-21 was collected from records from Statistics Sweden, whereas the number of births for each year during the study period was collected from the Swedish Medical Birth Register. All MRI scans were re-evaluated, and malformations were classified by a senior paediatric neuroradiologist. The prevalence and yearly incidence were estimated. Clinical data were collected from medical records. A total of 109 patients with polymicrogyria were included in the study. The overall polymicrogyria prevalence in Stockholm was 2.3 per 10 000 children, and the overall estimated yearly incidence between 2004 and 2020 was 1.9 per 10 000 person-years. The most common polymicrogyria distribution was in the frontal lobe (71%), followed by the parietal lobe (37%). Polymicrogyria in the peri-sylvian region was observed in 53%. Genetic testing was performed in 90 patients revealing pathogenic variants in 32%. Additionally, 12% had variants of uncertain significance. Five patients had a confirmed congenital infection, and in six individuals, the cause of polymicrogyria was assumed to be vascular. Epilepsy was diagnosed in 54%. Seizure onset during the first year of life was observed in 44%. The most common seizure types were focal seizures with impaired awareness, followed by epileptic spasms. Thirty-three of 59 patients with epilepsy (56%) were treated with more than two anti-seizure medications, indicating that pharmacoresistant epilepsy is common in polymicrogyria patients. Neurodevelopmental symptoms were observed in 94% of the individuals. This is the first population-based study on polymicrogyria prevalence and incidence. Confirmed genetic aetiology was present in one-third of individuals with polymicrogyria. Epilepsy was common in this patient group, and the majority had pharmacoresistant epilepsy. These findings increase our knowledge about polymicrogyria and will help in counselling patients and their families.
PubMed: 37614989
DOI: 10.1093/braincomms/fcad213 -
Annals of Indian Academy of Neurology 2022Polymicrogyria (PMG) is a relatively common complex malformation with cortical development, characterized by an exorbitant number of abnormally tiny gyri separated by...
Polymicrogyria (PMG) is a relatively common complex malformation with cortical development, characterized by an exorbitant number of abnormally tiny gyri separated by shallow sulci. It is a neuronal migration disorder. Familial cases of PMG and the manifestation of PMG in patients with chromosomal aberrations and mutations indicate their important role of genetics in this disorder. The highly stereotyped and well-conserved nature of the cortical folding pattern in humans is suggestive of the genetic regulation of the process. The chromosomal abnormalities observed in PMG include deletions, duplications, chromosomal rearrangements, and aneuploidies. Two of the most common deletions in PMG are 22q11.2 deletion and 1p36 deletion. Further, mutations in several genes such as , and are known to be associated with PMG. Intriguingly, these genes are responsible only for a small number of cases of PMG. The protein products of these genes are implicated in diverse molecular and cellular functions. Taken together, PMG could be the result of the disruption of several biological pathways. Different modes of Mendelian inheritance and non-Mendelian inheritance are seen in PMG. We have suggested a gene panel that can be used for the detection of malformations of cortical development.
PubMed: 36211152
DOI: 10.4103/aian.aian_97_22 -
American Journal of Medical Genetics.... Jun 2014Polymicrogyria (PMG) is one of the most common malformations of cortical development. It is characterized by overfolding of the cerebral cortex and abnormal cortical... (Review)
Review
Polymicrogyria (PMG) is one of the most common malformations of cortical development. It is characterized by overfolding of the cerebral cortex and abnormal cortical layering. It is a highly heterogeneous malformation with variable clinical and imaging features, pathological findings, and etiologies. It may occur as an isolated cortical malformation, or in association with other malformations within the brain or body as part of a multiple congenital anomaly syndrome. Polymicrogyria shows variable topographic patterns with the bilateral perisylvian pattern being most common. Schizencephaly is a subtype of PMG in which the overfolded cortex lines full-thickness clefts connecting the subarachnoid space with the cerebral ventricles. Both genetic and non-genetic causes of PMG have been identified. Non-genetic causes include congenital cytomegalovirus infection and in utero ischemia. Genetic causes include metabolic conditions such as peroxisomal disorders and the 22q11.2 and 1p36 continguous gene deletion syndromes. Mutations in over 30 genes have been found in association with PMG, especially mutations in the tubulin family of genes. Mutations in the (PI3K)-AKT pathway have been found in association PMG and megalencephaly. Despite recent genetic advances, the mechanisms by which polymicrogyric cortex forms and causes of the majority of cases remain unknown, making diagnostic and prenatal testing and genetic counseling challenging. This review summarizes the clinical, imaging, pathologic, and etiologic features of PMG, highlighting recent genetic advances.
Topics: Animals; Cerebral Cortex; Chromosome Aberrations; Genetic Heterogeneity; Humans; Magnetic Resonance Imaging; Mutation; Neuroimaging; Polymicrogyria
PubMed: 24888723
DOI: 10.1002/ajmg.c.31399