Your search keyword '"Malformations of Cortical Development, Group II genetics"' showing total 37 results

1. Threshold of somatic mosaicism leading to brain dysfunction with focal epilepsy.

Author

Kim J, Park SM, Koh HY, Ko A, Kang HC, Chang WS, Kim DS, and Lee JH

Subjects

Animals, Mice, Humans, Male, Female, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II physiopathology, Brain physiopathology, Brain metabolism, Mutation, Child, Neurons metabolism, Mice, Transgenic, Electroencephalography, Disease Models, Animal, Epilepsy, Malformations of Cortical Development, Group I, Mosaicism, Epilepsies, Partial genetics, Epilepsies, Partial physiopathology, TOR Serine-Threonine Kinases genetics, TOR Serine-Threonine Kinases metabolism

Abstract

Somatic mosaicism in a fraction of brain cells causes neurodevelopmental disorders, including childhood intractable epilepsy. However, the threshold for somatic mosaicism leading to brain dysfunction is unknown. In this study, we induced various mosaic burdens in focal cortical dysplasia type II (FCD II) mice, featuring mTOR somatic mosaicism and spontaneous behavioural seizures. The mosaic burdens ranged from approximately 1000 to 40 000 neurons expressing the mTOR mutant in the somatosensory or medial prefrontal cortex. Surprisingly, approximately 8000-9000 neurons expressing the MTOR mutant, extrapolated to constitute 0.08%-0.09% of total cells or roughly 0.04% of variant allele frequency in the mouse hemicortex, were sufficient to trigger epileptic seizures. The mutational burden was correlated with seizure frequency and onset, with a higher tendency for electrographic inter-ictal spikes and beta- and gamma-frequency oscillations in FCD II mice exceeding the threshold. Moreover, mutation-negative FCD II patients in deep sequencing of their bulky brain tissues revealed somatic mosaicism of the mTOR pathway genes as low as 0.07% in resected brain tissues through ultra-deep targeted sequencing (up to 20 million reads). Thus, our study suggests that extremely low levels of somatic mosaicism can contribute to brain dysfunction., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

2. X-linked neuronal migration disorders: Gender differences and insights for genetic screening.

Author

Edey J, Soleimani-Nouri P, Dawson-Kavanagh A, Imran Azeem MS, and Episkopou V

Subjects

Female, Humans, Sex Factors, Genetic Testing, Mutation, Fragile X Mental Retardation Protein genetics, Cullin Proteins genetics, Epilepsy genetics, Malformations of Cortical Development, Group II complications, Malformations of Cortical Development, Group II genetics

Abstract

Cortical development depends on neuronal migration of both excitatory and inhibitory interneurons. Neuronal migration disorders (NMDs) are conditions characterised by anatomical cortical defects leading to varying degrees of neurocognitive impairment, developmental delay and seizures. Refractory epilepsy affects 15 million people worldwide, and it is thought that cortical developmental disorders are responsible for 25% of childhood cases. However, little is known about the epidemiology of these disorders, nor are their aetiologies fully understood, though many are associated with sporadic genetic mutations. In this review, we aim to highlight X-linked NMDs including lissencephaly, periventricular nodular heterotopia and polymicrogyria because of their mostly familial inheritance pattern. We focus on the most prominent genes responsible: including DCX, ARX, FLNA, FMR1, L1CAM, SRPX2, DDX3X, NSHDL, CUL4B and OFD1, outlining what is known about their prevalence among NMDs, and the underlying pathophysiology. X-linked disorders are important to recognise clinically, as females often have milder phenotypes. Consequently, there is a greater chance they survive to reproductive age and risk passing the mutations down. Effective genetic screening is important to prevent and treat these conditions, and for this, we need to know gene mutations and have a clear understanding of the function of the genes involved. This review summarises the knowledge base and provides clear direction for future work by both scientists and clinicians alike., (© 2023 The Authors. International Journal of Developmental Neuroscience published by John Wiley & Sons Ltd on behalf of International Society for Developmental Neuroscience.)

Published

2023

3. Neurodevelopmental malformations of the cerebellum and neocortex in the Shank3 and Cntnap2 mouse models of autism.

Author

Otazu GH, Li Y, Lodato Z, Elnasher A, Keever KM, Li Y, and Ramos RL

Subjects

Animals, Cerebellum abnormalities, Cerebellum pathology, Female, Heterozygote, Humans, Male, Malformations of Cortical Development, Group II pathology, Mice, Mice, Inbred C57BL genetics, Mice, Knockout, Neocortex abnormalities, Neocortex pathology, Autistic Disorder genetics, Disease Models, Animal, Malformations of Cortical Development, Group II genetics, Membrane Proteins genetics, Microfilament Proteins genetics, Nerve Tissue Proteins genetics

Abstract

There are many mouse models of autism with broad use in neuroscience research. Genetic background can be a major contributor to the phenotype observed in any mouse model of disease, including genetic models of autism. C57BL/6 mice display spontaneous glio-neuronal heterotopia in the cerebellar vermis and neocortex which may also exist in mouse models of autism created on this background. In the present report, we document the presence of cerebellar and neocortical heterotopia in heterozygous and KO Shank3 and Cntnap2 mice which are due to the C57BL/6 genotype and discuss the role these malformations may play in research using these genetic models of autism., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

4. A deletion in Eml1 leads to bilateral subcortical heterotopia in the tish rat.

Author

Grosenbaugh DK, Joshi S, Fitzgerald MP, Lee KS, Wagley PK, Koeppel AF, Turner SD, McConnell MJ, and Goodkin HP

Subjects

Animals, Cerebral Cortex, Disease Models, Animal, Electroencephalography, Epilepsy genetics, Female, Male, Rats, Seizures genetics, Classical Lissencephalies and Subcortical Band Heterotopias genetics, Malformations of Cortical Development, Group II genetics, Microtubule-Associated Proteins genetics

Abstract

Children with malformations of cortical development (MCD) are at risk for epilepsy, developmental delays, behavioral disorders, and intellectual disabilities. For a subset of these children, antiseizure medications or epilepsy surgery may result in seizure freedom. However, there are limited options for treating or curing the other conditions, and epilepsy surgery is not an option in all cases of pharmacoresistant epilepsy. Understanding the genetic and neurobiological mechanisms underlying MCD is a necessary step in elucidating novel therapeutic targets. The tish (telencephalic internal structural heterotopia) rat is a unique model of MCD with spontaneous seizures, but the underlying genetic mutation(s) have remained unknown. DNA and RNA-sequencing revealed that a deletion encompassing a previously unannotated first exon markedly diminished Eml1 transcript and protein abundance in the tish brain. Developmental electrographic characterization of the tish rat revealed early-onset of spontaneous spike-wave discharge (SWD) bursts beginning at postnatal day (P) 17. A dihybrid cross demonstrated that the mutant Eml1 allele segregates with the observed dysplastic cortex and the early-onset SWD bursts in monogenic autosomal recessive frequencies. Our data link the development of the bilateral, heterotopic dysplastic cortex of the tish rat to a deletion in Eml1., (Copyright © 2020. Published by Elsevier Inc.)

Published

2020

5. Inborn errors of metabolism leading to neuronal migration defects.

Author

Schiller S, Rosewich H, Grünewald S, and Gärtner J

Subjects

Cerebral Cortex pathology, Humans, Magnetic Resonance Imaging, Malformations of Cortical Development, Group II classification, Mutation, Neurons physiology, Cerebral Cortex abnormalities, Cerebral Cortex growth & development, Malformations of Cortical Development, Group II genetics, Metabolism, Inborn Errors genetics

Abstract

The development and organisation of the human brain start in the embryonic stage and is a highly complex orchestrated process. It depends on series of cellular mechanisms that are precisely regulated by multiple proteins, signalling pathways and non-protein-coding genes. A crucial process during cerebral cortex development is the migration of nascent neuronal cells to their appropriate positions and their associated differentiation into layer-specific neurons. Neuronal migration defects (NMD) comprise a heterogeneous group of neurodevelopmental disorders including monogenetic disorders and residual syndromes due to damaging factors during prenatal development like infections, maternal diabetes mellitus or phenylketonuria, trauma, and drug use. Multifactorial causes are also possible. Classification into lissencephaly, polymicrogyria, schizencephaly, and neuronal heterotopia is based on the visible morphologic cortex anomalies. Characteristic clinical features of NMDs are severe psychomotor developmental delay, severe intellectual disability, intractable epilepsy, and dysmorphisms. Neurometabolic disorders only form a small subgroup within the large group of NMDs. The prototypes are peroxisomal biogenesis disorders, peroxisomal ß-oxidation defects and congenital disorders of O-glycosylation. The rapid evolution of biotechnology has resulted in an ongoing identification of metabolic and non-metabolic disease genes for NMDs. Nevertheless, we are far away from understanding the specific role of cortical genes and metabolites on spatial and temporal regulation of human cortex development and associated malformations. This limited understanding of the pathogenesis hinders the attempt for therapeutic approaches. In this article, we provide an overview of the most important cortical malformations and potential underlying neurometabolic disorders., (© 2019 SSIEM.)

Published

2020

6. EML1-associated brain overgrowth syndrome with ribbon-like heterotopia.

Author

Oegema R, McGillivray G, Leventer R, Le Moing AG, Bahi-Buisson N, Barnicoat A, Mandelstam S, Francis D, Francis F, Mancini GMS, Savelberg S, van Haaften G, Mankad K, and Lequin MH

Subjects

Humans, Malformations of Cortical Development, Group II genetics, Mutation, Missense, Sequence Deletion, Brain pathology, Microtubule-Associated Proteins genetics

Abstract

EML1 encodes the protein Echinoderm microtubule-associated protein-like 1 or EMAP-1 that binds to the microtubule complex. Mutations in this gene resulting in complex brain malformations have only recently been published with limited clinical descriptions. We provide further clinical and imaging details on three previously published families, and describe two novel unrelated individuals with a homozygous partial EML1 deletion and a homozygous missense variant c.760G>A, p.(Val254Met), respectively. From review of the clinical and imaging data of eight individuals from five families with biallelic EML1 variants, a very consistent imaging phenotype emerges. The clinical syndrome is characterized by mainly neurological features including severe developmental delay, drug-resistant seizures and visual impairment. On brain imaging there is megalencephaly with a characteristic ribbon-like subcortical heterotopia combined with partial or complete callosal agenesis and an overlying polymicrogyria-like cortical malformation. Several of its features can be recognized on prenatal imaging especially the abnormaly formed lateral ventricles, hydrocephalus (in half of the cases) and suspicion of a neuronal migration disorder. In conclusion, biallelic EML1 disease-causing variants cause a highly specific pattern of congenital brain malformations, severe developmental delay, seizures and visual impairment., (© 2019 The Authors. American Journal of Medical Genetics Part C: Seminars in Medical Genetics published by Wiley Periodicals, Inc.)

Published

2019

7. Germline and somatic mutations in cortical malformations: Molecular defects in Argentinean patients with neuronal migration disorders.

Author

González-Morón D, Vishnopolska S, Consalvo D, Medina N, Marti M, Córdoba M, Vazquez-Dusefante C, Claverie S, Rodríguez-Quiroga SA, Vega P, Silva W, Kochen S, and Kauffman MA

Subjects

Cohort Studies, DNA Copy Number Variations, Female, Genotype, Humans, Male, Malformations of Cortical Development, Group II diagnosis, Phenotype, Young Adult, Germ-Line Mutation, Malformations of Cortical Development, Group II genetics

Abstract

Neuronal migration disorders are a clinically and genetically heterogeneous group of malformations of cortical development, frequently responsible for severe disability. Despite the increasing knowledge of the molecular mechanisms underlying this group of diseases, their genetic diagnosis remains unattainable in a high proportion of cases. Here, we present the results of 38 patients with lissencephaly, periventricular heterotopia and subcortical band heterotopia from Argentina. We performed Sanger and Next Generation Sequencing (NGS) of DCX, FLNA and ARX and searched for copy number variations by MLPA in PAFAH1B1, DCX, POMT1, and POMGNT1. Additionally, somatic mosaicism at 5% or higher was investigated by means of targeted high coverage NGS of DCX, ARX, and PAFAH1B1. Our approach had a diagnostic yield of 36%. Pathogenic or likely pathogenic variants were identified in 14 patients, including 10 germline (five novel) and 4 somatic mutations in FLNA, DCX, ARX and PAFAH1B1 genes. This study represents the largest series of patients comprehensively characterized in our population. Our findings reinforce the importance of somatic mutations in the pathophysiology and diagnosis of neuronal migration disorders and contribute to expand their phenotype-genotype correlations.

Published

2017

8. Pathologic Active mTOR Mutation in Brain Malformation with Intractable Epilepsy Leads to Cell-Autonomous Migration Delay.

Author

Hanai S, Sukigara S, Dai H, Owa T, Horike SI, Otsuki T, Saito T, Nakagawa E, Ikegaya N, Kaido T, Sato N, Takahashi A, Sugai K, Saito Y, Sasaki M, Hoshino M, Goto YI, Koizumi S, and Itoh M

Subjects

Animals, Cells, Cultured, Drug Resistant Epilepsy surgery, Electroencephalography, Female, Hemimegalencephaly surgery, Humans, Infant, Malformations of Cortical Development, Group II surgery, Mice, Positron Emission Tomography Computed Tomography, TOR Serine-Threonine Kinases metabolism, Transfection, Up-Regulation, Drug Resistant Epilepsy genetics, Hemimegalencephaly genetics, Malformations of Cortical Development, Group II genetics, TOR Serine-Threonine Kinases genetics

Abstract

The activation of phosphatidylinositol 3-kinase-AKTs-mammalian target of rapamycin cell signaling pathway leads to cell overgrowth and abnormal migration and results in various types of cortical malformations, such as hemimegalencephaly (HME), focal cortical dysplasia, and tuberous sclerosis complex. However, the pathomechanism underlying abnormal cell migration remains unknown. With the use of fetal mouse brain, we performed causative gene analysis of the resected brain tissues from a patient with HME and investigated the pathogenesis. We obtained a novel somatic mutation of the MTOR gene, having approximately 11% and 7% mutation frequency in the resected brain tissues. Moreover, we revealed that the MTOR mutation resulted in hyperphosphorylation of its downstream molecules, S6 and 4E-binding protein 1, and delayed cell migration on the radial glial fiber and did not affect other cells. We suspect cell-autonomous migration arrest on the radial glial foot by the active MTOR mutation and offer potential explanations for why this may lead to cortical malformations such as HME., (Copyright © 2017 American Society for Investigative Pathology. Published by Elsevier Inc. All rights reserved.)

Published

2017

9. Divergence and inheritance of neocortical heterotopia in inbred and genetically-engineered mice.

Author

Toia AR, Cuoco JA, Esposito AW, Ahsan J, Joshi A, Herron BJ, Torres G, Bolivar VJ, and Ramos RL

Subjects

Animals, Homozygote, Malformations of Cortical Development, Group II pathology, Mice, Inbred C57BL, Mice, Inbred Strains, Mice, Transgenic, Penetrance, Species Specificity, Malformations of Cortical Development, Group II genetics, Neocortex abnormalities

Abstract

Cortical function emerges from the intrinsic properties of neocortical neurons and their synaptic connections within and across lamina. Neurodevelopmental disorders affecting migration and lamination of the neocortex result in cognitive delay/disability and epilepsy. Molecular layer heterotopia (MLH), a dysplasia characterized by over-migration of neurons into layer I, are associated with cognitive deficits and neuronal hyperexcitability in humans and mice. The breadth of different inbred mouse strains that exhibit MLH and inheritance patterns of heterotopia remain unknown. A neuroanatomical survey of numerous different inbred mouse strains, 2 first filial generation (F1) hybrids, and one consomic strain (C57BL/6J-Chr 1 A/J /NaJ) revealed MLH only in C57BL/6 mice and the consomic strain. Heterotopia were observed in numerous genetically-engineered mouse lines on a congenic C57BL/6 background. These data indicate that heterotopia formation is a weakly penetrant trait requiring homozygosity of one or more C57BL/6 alleles outside of chromosome 1. These data are relevant toward understanding neocortical development and disorders affecting neocortical lamination., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published

2017

10. Somatic Mutations in the MTOR gene cause focal cortical dysplasia type IIb.

Author

Nakashima M, Saitsu H, Takei N, Tohyama J, Kato M, Kitaura H, Shiina M, Shirozu H, Masuda H, Watanabe K, Ohba C, Tsurusaki Y, Miyake N, Zheng Y, Sato T, Takebayashi H, Ogata K, Kameyama S, Kakita A, and Matsumoto N

Subjects

Adolescent, Adult, Child, Female, HEK293 Cells, Humans, Male, Malformations of Cortical Development diagnosis, Malformations of Cortical Development genetics, Malformations of Cortical Development, Group II diagnosis, Brain pathology, Malformations of Cortical Development, Group II genetics, Mutation genetics, TOR Serine-Threonine Kinases genetics

Abstract

Objective: Focal cortical dysplasia (FCD) type IIb is a cortical malformation characterized by cortical architectural abnormalities, dysmorphic neurons, and balloon cells. It has been suggested that FCDs are caused by somatic mutations in cells in the developing brain. Here, we explore the possible involvement of somatic mutations in FCD type IIb., Methods: We collected a total of 24 blood-brain paired samples with FCD, including 13 individuals with FCD type IIb, 5 with type IIa, and 6 with type I. We performed whole-exome sequencing using paired samples from 9 of the FCD type IIb subjects. Somatic MTOR mutations were identified and further investigated using all 24 paired samples by deep sequencing of the entire gene's coding region. Somatic MTOR mutations were confirmed by droplet digital polymerase chain reaction. The effect of MTOR mutations on mammalian target of rapamycin (mTOR) kinase signaling was evaluated by immunohistochemistry and Western blotting analyses of brain samples and by in vitro transfection experiments., Results: We identified four lesion-specific somatic MTOR mutations in 6 of 13 (46%) individuals with FCD type IIb showing mutant allele rates of 1.11% to 9.31%. Functional analyses showed that phosphorylation of ribosomal protein S6 in FCD type IIb brain tissues with MTOR mutations was clearly elevated, compared to control samples. Transfection of any of the four MTOR mutants into HEK293T cells led to elevated phosphorylation of 4EBP, the direct target of mTOR kinase., Interpretation: We found low-prevalence somatic mutations in MTOR in FCD type IIb, indicating that activating somatic mutations in MTOR cause FCD type IIb., (© 2015 American Neurological Association.)

Published

2015

11. Case report: Neuronal migration disorder associated with chromosome 15q13.3 duplication in a boy with autism and seizures.

Author

Beal JC

Subjects

Autistic Disorder complications, Child, Preschool, Humans, Male, Malformations of Cortical Development, Group II complications, Seizures complications, Autistic Disorder genetics, Chromosome Duplication genetics, Chromosomes, Human, Pair 15 genetics, Malformations of Cortical Development, Group II genetics, Seizures genetics

Abstract

Neuronal migration disorders are a group of disorders that cause structural brain abnormalities and varying degrees of neurocognitive impairment, resulting from abnormal neuronal migration during brain development. There are several mutations that have been associated with these disorders. Here the case of a 4-year-old autistic boy is presented, who was found to have evidence of a neuronal migration disorder on magnetic resonance imaging (MRI) during a workup for seizures. Genetic testing did not reveal any of the gene mutations known to be associated with neuronal migration disorders but did reveal a microduplication at chromosome 15q13.3, a locus that has been previously associated with autism, cognitive impairment, and seizures. Although the concurrent presence of the genetic and structural abnormalities does not necessarily imply causality, the simultaneous independent occurrence of both conditions is certainly unusual. It is possible that there may be an association between this duplication syndrome and aberrant neuronal migration., (© The Author(s) 2013.)

Published

2014

12. Periventricular heterotopia in 6q terminal deletion syndrome: role of the C6orf70 gene.

Author

Conti V, Carabalona A, Pallesi-Pocachard E, Parrini E, Leventer RJ, Buhler E, McGillivray G, Michel FJ, Striano P, Mei D, Watrin F, Lise S, Pagnamenta AT, Taylor JC, Kini U, Clayton-Smith J, Novara F, Zuffardi O, Dobyns WB, Scheffer IE, Robertson SP, Berkovic SF, Represa A, Keays DA, Cardoso C, and Guerrini R

Subjects

Abnormalities, Multiple pathology, Abnormalities, Multiple physiopathology, Adolescent, Adult, Animals, Brain pathology, Brain physiopathology, Child, Chromosome Deletion, Chromosomes, Human, Pair 6 genetics, Cohort Studies, Developmental Disabilities genetics, Epilepsy genetics, Exome genetics, Female, Haploinsufficiency genetics, Humans, Infant, Magnetic Resonance Imaging, Male, Malformations of Cortical Development, Group II pathology, Malformations of Cortical Development, Group II physiopathology, Mutation genetics, Periventricular Nodular Heterotopia pathology, Periventricular Nodular Heterotopia physiopathology, Rats, Rats, Wistar, Syndrome, Abnormalities, Multiple genetics, Brain abnormalities, Malformations of Cortical Development, Group II genetics, Periventricular Nodular Heterotopia genetics

Abstract

Periventricular nodular heterotopia is caused by defective neuronal migration that results in heterotopic neuronal nodules lining the lateral ventricles. Mutations in filamin A (FLNA) or ADP-ribosylation factor guanine nucleotide-exchange factor 2 (ARFGEF2) cause periventricular nodular heterotopia, but most patients with this malformation do not have a known aetiology. Using comparative genomic hybridization, we identified 12 patients with developmental brain abnormalities, variably combining periventricular nodular heterotopia, corpus callosum dysgenesis, colpocephaly, cerebellar hypoplasia and polymicrogyria, harbouring a common 1.2 Mb minimal critical deletion in 6q27. These anatomic features were mainly associated with epilepsy, ataxia and cognitive impairment. Using whole exome sequencing in 14 patients with isolated periventricular nodular heterotopia but no copy number variants, we identified one patient with periventricular nodular heterotopia, developmental delay and epilepsy and a de novo missense mutation in the chromosome 6 open reading frame 70 (C6orf70) gene, mapping in the minimal critical deleted region. Using immunohistochemistry and western blots, we demonstrated that in human cell lines, C6orf70 shows primarily a cytoplasmic vesicular puncta-like distribution and that the mutation affects its stability and subcellular distribution. We also performed in utero silencing of C6orf70 and of Phf10 and Dll1, the two additional genes mapping in the 6q27 minimal critical deleted region that are expressed in human and rodent brain. Silencing of C6orf70 in the developing rat neocortex produced periventricular nodular heterotopia that was rescued by concomitant expression of wild-type human C6orf70 protein. Silencing of the contiguous Phf10 or Dll1 genes only produced slightly delayed migration but not periventricular nodular heterotopia. The complex brain phenotype observed in the 6q terminal deletion syndrome likely results from the combined haploinsufficiency of contiguous genes mapping to a small 1.2 Mb region. Our data suggest that, of the genes within this minimal critical region, C6orf70 plays a major role in the control of neuronal migration and its haploinsufficiency or mutation causes periventricular nodular heterotopia.

Published

2013

13. Embryonic disruption of the candidate dyslexia susceptibility gene homolog Kiaa0319-like results in neuronal migration disorders.

Author

Platt MP, Adler WT, Mehlhorn AJ, Johnson GC, Wright KA, Choi RT, Tsang WH, Poon MW, Yeung SY, Waye MM, Galaburda AM, and Rosen GD

Subjects

Animals, Animals, Newborn, Disease Susceptibility, Electroporation, Humans, Neurogenesis genetics, Nuclear Proteins genetics, RNA, Small Interfering, Rats, Rats, Transgenic, Receptors, Cell Surface, Transfection, Cerebral Cortex growth & development, Dyslexia genetics, Gene Expression Regulation, Developmental, Malformations of Cortical Development, Group II genetics, Neural Stem Cells metabolism, Nuclear Proteins metabolism

Abstract

Developmental dyslexia, the most common childhood learning disorder, is highly heritable, and recent studies have identified KIAA0319-Like (KIAA0319L) as a candidate dyslexia susceptibility gene at the 1p36-34 (DYX8) locus. In this experiment, we investigated the anatomical effects of knocking down this gene during rat corticogenesis. Cortical progenitor cells were transfected using in utero electroporation on embryonic day (E) 15.5 with plasmids encoding either: (1) Kiaa0319l small hairpin RNA (shRNA), (2) an expression construct for human KIAA0319L, (3) Kiaa0319l shRNA+KIAA0319L expression construct (rescue), or (4) controls (scrambled Kiaa0319l shRNA or empty expression vector). Mothers were injected with 5-bromo-2-deoxyuridine (BrdU) at either E13.5, E15.5, or E17.5. Disruption of Kiaa0319l function (by knockdown, overexpression, or rescue) resulted in the formation of large nodular periventricular heterotopia in approximately 25% of the rats, which can be seen as early as postnatal day 1. Only a small subset of heterotopic neurons had been transfected, indicating non-cell autonomous effects of the transfection. Most heterotopic neurons were generated in mid- to late-gestation, and laminar markers suggest that they were destined for upper cortical laminae. Finally, we found that transfected neurons in the cerebral cortex were located in their expected laminae. These results indicate that KIAA0319L is the fourth of four candidate dyslexia susceptibility genes that is involved in neuronal migration, which supports the association of abnormal neuronal migration with developmental dyslexia., (Copyright © 2013 IBRO. Published by Elsevier Ltd. All rights reserved.)

Published

2013

14. A behavioral evaluation of sex differences in a mouse model of severe neuronal migration disorder.

Author

Truong DT, Bonet A, Rendall AR, Rosen GD, and Fitch RH

Subjects

Animals, Disease Models, Animal, Feedback, Sensory, Female, Male, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Maze Learning, Mice, Mice, Transgenic, Nervous System Malformations genetics, Phenotype, Severity of Illness Index, Sex Factors, Social Behavior, Behavior, Animal, Malformations of Cortical Development, Group II diagnosis

Abstract

Disruption of neuronal migration in humans is associated with a wide range of behavioral and cognitive outcomes including severe intellectual disability, language impairment, and social dysfunction. Furthermore, malformations of cortical development have been observed in a number of neurodevelopmental disorders (e.g. autism and dyslexia), where boys are much more commonly diagnosed than girls (estimates around 4 to 1). The use of rodent models provides an excellent means to examine how sex may modulate behavioral outcomes in the presence of comparable abnormal neuroanatomical presentations. Initially characterized by Rosen et al. 2012, the BXD29- Tlr4(lps-2J) /J mouse mutant exhibits a highly penetrant neuroanatomical phenotype that consists of bilateral midline subcortical nodular heterotopia with partial callosal agenesis. In the current study, we confirm our initial findings of a severe impairment in rapid auditory processing in affected male mice. We also report that BXD29- Tlr4(lps-2J) /J (mutant) female mice show no sparing of rapid auditory processing, and in fact show deficits similar to mutant males. Interestingly, female BXD29- Tlr4(lps-2J) /J mice do display superiority in Morris water maze performance as compared to wild type females, an affect not seen in mutant males. Finally, we report new evidence that BXD29- Tlr4(lps-2J) /J mice, in general, show evidence of hyper-social behaviors. In closing, the use of the BXD29- Tlr4(lps-2J) /J strain of mice - with its strong behavioral and neuroanatomical phenotype - may be highly useful in characterizing sex independent versus dependent mechanisms that interact with neural reorganization, as well as clinically relevant abnormal behavior resulting from aberrant neuronal migration.

Published

2013

15. Molecular layer heterotopia of the cerebellar vermis in mutant and transgenic mouse models on a C57BL/6 background.

Author

Ramos RL, Van Dine SE, George E, Patel D, Hoplight BJ, Leheste JR, Richfield EK, and Torres G

Subjects

Animals, Cerebellum pathology, Female, Male, Malformations of Cortical Development, Group II pathology, Mice, Mice, Inbred C57BL, Mice, Mutant Strains, Mice, Transgenic, Cerebellum abnormalities, Malformations of Cortical Development, Group II genetics

Abstract

C57BL/6 mice exhibit spontaneous cerebellar malformations consisting of heterotopic neurons and glia in the molecular layer of the vermis (Tanaka and Marunouchi, 2005; Mangaru et al., 2013). Malformations are only found between folia VIII and IX and are indicative of deficits of neuronal migration during cerebellar development. In the present report we test the prediction that mutant and transgenic mouse models on a C57BL/6 background will also exhibit these same cerebellar malformations. Consistent with our hypothesis, we found that 2 spontaneous mutant models of Parkinson's disease on a C57BL/6 background had cerebellar malformations. In addition, we found that numerous transgenic mouse lines on a full or partial C57BL/6 background including eGFP-, YFP- and Cre-transgenic mice also exhibited heterotopia. These data suggest that histological analyses be performed in studies of cerebellar function or development when using C57BL/6 or other mice on this background in order for correct interpretation of research results., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

16. Expanding the spectrum of TUBA1A-related cortical dysgenesis to Polymicrogyria.

Author

Poirier K, Saillour Y, Fourniol F, Francis F, Souville I, Valence S, Desguerre I, Marie Lepage J, Boddaert N, Line Jacquemont M, Beldjord C, Chelly J, and Bahi-Buisson N

Subjects

Amino Acid Sequence, Child, Child, Preschool, Female, Humans, Infant, Male, Malformations of Cortical Development diagnosis, Malformations of Cortical Development, Group II diagnosis, Molecular Sequence Data, Mutation, Missense, Pedigree, Protein Structure, Tertiary, Tubulin chemistry, Tubulin metabolism, Malformations of Cortical Development genetics, Malformations of Cortical Development, Group II genetics, Tubulin genetics

Abstract

De novo mutations in the TUBA1A gene are responsible for a wide spectrum of neuronal migration disorders, ranging from lissencephaly to perisylvian pachygyria. Recently, one family with polymicrogyria (PMG) and mutation in TUBA1A was reported. Hence, the purpose of our study was to determine the frequency of TUBA1A mutations in patients with PMG and better define clinical and imaging characteristics for TUBA1A-related PMG. We collected 95 sporadic patients with non-syndromic bilateral PMG, including 54 with perisylvian PMG and 30 PMG with additional brain abnormalities. Mutation analysis of the TUBA1A gene was performed by sequencing of PCR fragments corresponding to TUBA1A-coding sequences. Three de novo missense TUBA1A mutations were identified in three unrelated patients with PMG representing 3.1% of PMG and 10% of PMGs with complex cerebral malformations. These patients had bilateral perisylvian asymmetrical PMG with dysmorphic basal ganglia cerebellar vermian dysplasia and pontine hypoplasia. These mutations (p.Tyr161His; p.Val235Leu; p.Arg390Cys) appear distributed throughout the primary structure of the alpha-tubulin polypeptide, but their localization within the tertiary structure suggests that PMG-related mutations are likely to impact microtubule dynamics, stability and/or local interactions with partner proteins. These findings broaden the phenotypic spectrum associated with TUBA1A mutations to PMG and further emphasize that additional brain abnormalities, that is, dysmorphic basal ganglia, hypoplastic pons and cerebellar dysplasia are key features for the diagnosis of TUBA1A-related PMG.

Published

2013

17. Cytoskeleton in action: lissencephaly, a neuronal migration disorder.

Author

Moon HM and Wynshaw-Boris A

Subjects

Animals, Cell Movement, Cerebral Cortex metabolism, Cerebral Cortex pathology, Cytoskeleton genetics, Cytoskeleton metabolism, Doublecortin Protein, Humans, Lissencephaly genetics, Lissencephaly pathology, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II metabolism, Mice, Microtubule-Associated Proteins genetics, Microtubule-Associated Proteins metabolism, Nervous System Malformations genetics, Neurons pathology, Reelin Protein, Cytoskeleton pathology, Lissencephaly metabolism, Malformations of Cortical Development, Group II pathology, Nervous System Malformations pathology, Neurons metabolism

Abstract

During neocortical development, the extensive migratory movements of neurons from their place of birth to their final location are essential for the coordinated wiring of synaptic circuits and proper neurological function. Failure or delay in neuronal migration causes severe abnormalities in cortical layering, which consequently results in human lissencephaly ('smooth brain'), a neuronal migration disorder. The brains of lissencephaly patients have less-convoluted gyri in the cerebral cortex with impaired cortical lamination of neurons. Since microtubule (MT) and actin-associated proteins play important functions in regulating the dynamics of MT and actin cytoskeletons during neuronal migration, genetic mutations or deletions of crucial genes involved in cytoskeletal processes lead to lissencephaly in human and neuronal migration defects in mouse. During neuronal migration, MT organization and transport are controlled by platelet-activating factor acetylhydrolase isoform 1b regulatory subunit 1 (PAFAH1B1, formerly known as LIS1, Lissencephaly-1), doublecortin (DCX), YWHAE, and tubulin. Actin stress fibers are modulated by PAFAH1B1 (LIS1), DCX, RELN, and VLDLR (very low-density lipoprotein receptor)/LRP8 (low-density lipoprotein-related receptor 8, formerly known as APOER2). There are several important levels of crosstalk between these two cytoskeletal systems to establish accurate cortical patterning in development. The recent understanding of the protein networks that govern neuronal migration by regulating cytoskeletal dynamics, from human and mouse genetics as well as molecular and cellular analyses, provides new insights on neuronal migration disorders and may help us devise novel therapeutic strategies for such brain malformations.

Published

2013

18. Agenesis of the corpus callosum and gray matter heterotopia in three patients with constitutional mismatch repair deficiency syndrome.

Author

Baas AF, Gabbett M, Rimac M, Kansikas M, Raphael M, Nievelstein RA, Nicholls W, Offerhaus J, Bodmer D, Wernstedt A, Krabichler B, Strasser U, Nyström M, Zschocke J, Robertson SP, van Haelst MM, and Wimmer K

Subjects

Adaptor Proteins, Signal Transducing genetics, Adenosine Triphosphatases genetics, Agenesis of Corpus Callosum pathology, Child, Child, Preschool, Contractile Proteins genetics, DNA Repair Enzymes genetics, DNA Repair-Deficiency Disorders etiology, DNA-Binding Proteins genetics, Female, Filamins, Glioblastoma diagnosis, Glioblastoma genetics, Glioblastoma therapy, Humans, Male, Malformations of Cortical Development, Group II genetics, Microfilament Proteins genetics, Microsatellite Instability, Mismatch Repair Endonuclease PMS2, MutL Protein Homolog 1, Mutation, Nuclear Proteins genetics, Parotid Neoplasms diagnosis, Parotid Neoplasms genetics, Parotid Neoplasms therapy, Pregnancy, Syndrome, Agenesis of Corpus Callosum genetics, DNA Repair-Deficiency Disorders genetics, Glioblastoma complications, Malformations of Cortical Development, Group II pathology, Parotid Neoplasms complications

Abstract

Constitutional mismatch repair deficiency (CMMR-D) syndrome is a rare inherited childhood cancer predisposition caused by biallelic germline mutations in one of the four mismatch repair (MMR)-genes, MLH1, MSH2, MSH6 or PMS2. Owing to a wide tumor spectrum, the lack of specific clinical features and the overlap with other cancer predisposing syndromes, diagnosis of CMMR-D is often delayed in pediatric cancer patients. Here, we report of three new CMMR-D patients all of whom developed more than one malignancy. The common finding in these three patients is agenesis of the corpus callosum (ACC). Gray matter heterotopia is present in two patients. One of the 57 previously reported CMMR-D patients with brain tumors (therefore all likely had cerebral imaging) also had ACC. With the present report the prevalence of cerebral malformations is at least 4/60 (6.6%). This number is well above the population birth prevalence of 0.09-0.36 live births with these cerebral malformations, suggesting that ACC and heterotopia are features of CMMR-D. Therefore, the presence of cerebral malformations in pediatric cancer patients should alert to the possible diagnosis of CMMR-D. ACC and gray matter heterotopia are the first congenital malformations described to occur at higher frequency in CMMR-D patients than in the general population. Further systematic evaluations of CMMR-D patients are needed to identify possible other malformations associated with this syndrome.

Published

2013

19. Van Maldergem syndrome: further characterisation and evidence for neuronal migration abnormalities and autosomal recessive inheritance.

Author

Mansour S, Swinkels M, Terhal PA, Wilson LC, Rich P, Van Maldergem L, Zwijnenburg PJ, Hall CM, Robertson SP, and Newbury-Ecob R

Subjects

Abnormalities, Multiple genetics, Abnormalities, Multiple pathology, Child, Child, Preschool, Consanguinity, Craniofacial Abnormalities genetics, Craniofacial Abnormalities pathology, Diagnosis, Differential, Female, Foot Deformities, Congenital genetics, Foot Deformities, Congenital pathology, Hand Deformities, Congenital genetics, Hand Deformities, Congenital pathology, Humans, Intellectual Disability genetics, Intellectual Disability pathology, Joint Instability genetics, Joint Instability pathology, Karyotype, Male, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Pedigree, Abnormalities, Multiple diagnosis, Craniofacial Abnormalities diagnosis, Foot Deformities, Congenital diagnosis, Genes, Recessive, Hand Deformities, Congenital diagnosis, Intellectual Disability diagnosis, Joint Instability diagnosis, Malformations of Cortical Development, Group II diagnosis

Abstract

We present six patients from five unrelated families with a condition originally described by Van Maldergem et al and provide follow-up studies of the original patient. The phenotype comprises a distinctive facial appearance that includes blepharophimosis, maxillary hypoplasia, telecanthus, microtia and atresia of the external auditory meatus, intellectual disability, digital contractures and skeletal anomalies together with subependymal and subcortical neuronal heterotopia. Affected patients typically have neonatal hypotonia, chronic feeding difficulties and respiratory problems. In our cohort, we have observed one instance of sibling recurrence and parental consanguinity in three of the families, indicating that autosomal recessive inheritance is likely.

Published

2012

20. Array-based characterization of an interstitial de-novo deletion of chromosome 4q in a patient with a neuronal migration defect and hypocalcemia plus a literature review.

Author

Moreno-García M, Sánchez Del Pozo J, Cruz-Rojo J, Fernández-Martínez FJ, and Perez-Nanclares Leal G

Subjects

Cerebellum diagnostic imaging, Cerebellum pathology, Chromosome Mapping, Comparative Genomic Hybridization, Epilepsy diagnosis, Female, Genome, Human, Humans, Infant, Infant, Newborn, Malformations of Cortical Development, Group II diagnosis, Malformations of Cortical Development, Group II pathology, Mucins genetics, Salivary Proteins and Peptides genetics, Ultrasonography, Chromosome Deletion, Chromosomes, Human, Pair 4 genetics, Hypocalcemia genetics, Malformations of Cortical Development, Group II genetics

Published

2012

21. What disorders of cortical development tell us about the cortex: one plus one does not always make two.

Author

Manzini MC and Walsh CA

Subjects

Cell Movement genetics, Cell Movement physiology, Cell Proliferation, Humans, Malformations of Cortical Development, Group II genetics, Microtubules genetics, Neurogenesis physiology, Walker-Warburg Syndrome genetics, Centrosome physiology, Cerebral Cortex abnormalities, Cerebral Cortex growth & development, Microtubules physiology, Neurogenesis genetics, Neurons physiology

Abstract

The unique size and complexity of the human cerebral cortex are achieved via a long and precisely regulated developmental process controlling neurogenesis, neuronal migration and differentiation. Traditionally, disorders of cortical development have been classified on the basis of the most obvious defects in one of these developmental steps. However, the more we learn about the cellular biological roles of genes that are essential for cortical development, the more we realize that these functions map onto molecular processes, but not so cleanly onto anatomical processes. Essential genes might be involved in both proliferation and migration as well as differentiation, reflecting roles for underlying molecular mechanisms in different phases of development and causing a stunning variety of cortical defects., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

22. Annual Research Review: Development of the cerebral cortex: implications for neurodevelopmental disorders.

Author

Rubenstein JL

Subjects

Affective Symptoms genetics, Affective Symptoms pathology, Animals, Autistic Disorder genetics, Autistic Disorder pathology, Axons pathology, Axons physiology, Body Patterning genetics, Body Patterning physiology, Brain Mapping, Cerebral Cortex pathology, Child, Cognition Disorders genetics, Cognition Disorders pathology, Female, Fibroblast Growth Factors genetics, Homeodomain Proteins genetics, Humans, Infant, Newborn, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Malformations of Cortical Development, Group II physiopathology, Mice, Nerve Net pathology, Nerve Net physiopathology, Neural Inhibition genetics, Neural Inhibition physiology, Neuronal Plasticity genetics, Neuronal Plasticity physiology, Neurons pathology, Neurons physiology, Pregnancy, Signal Transduction genetics, Transcription Factors genetics, gamma-Aminobutyric Acid physiology, Affective Symptoms physiopathology, Autistic Disorder physiopathology, Cerebral Cortex physiopathology, Cognition Disorders physiopathology

Abstract

The cerebral cortex has a central role in cognitive and emotional processing. As such, understanding the mechanisms that govern its development and function will be central to understanding the bases of severe neuropsychiatric disorders, particularly those that first appear in childhood. In this review, I highlight recent progress in elucidating genetic, molecular and cellular mechanisms that control cortical development. I discuss basic aspects of cortical developmental anatomy, and mechanisms that regulate cortical size and area formation, with an emphasis on the roles of fibroblast growth factor (Fgf) signaling and specific transcription factors. I then examine how specific types of cortical excitatory projection neurons are generated, and how their axons grow along stereotyped pathways to their targets. Next, I address how cortical inhibitory (GABAergic) neurons are generated, and point out the role of these cells in controlling cortical plasticity and critical periods. The paper concludes with an examination of four possible developmental mechanisms that could contribute to some forms of neurodevelopmental disorders, such as autism., (© 2010 The Author. Journal of Child Psychology and Psychiatry. © 2010 Association for Child and Adolescent Mental Health.)

Published

2011

23. Sonographic diagnosis of cerebral malformations. Part 3: agenesis of the corpus callosum - migration disorders.

Author

Deeg KH

Subjects

Aicardi Syndrome genetics, Brain pathology, Cerebral Cortex diagnostic imaging, Cerebral Cortex pathology, Cerebral Ventricles diagnostic imaging, Cerebral Ventricles pathology, Chromosome Aberrations, Corpus Callosum diagnostic imaging, Corpus Callosum pathology, Diagnosis, Differential, Female, Humans, Infant, Infant, Newborn, Lissencephaly genetics, Magnetic Resonance Imaging, Malformations of Cortical Development diagnostic imaging, Malformations of Cortical Development pathology, Malformations of Cortical Development, Group II genetics, Nervous System Malformations diagnostic imaging, Nervous System Malformations genetics, Pregnancy, Syndrome, Aicardi Syndrome diagnostic imaging, Echoencephalography, Lissencephaly diagnostic imaging, Malformations of Cortical Development, Group II diagnostic imaging

Published

2011

24. Neuronal migration disorders in microcephalic osteodysplastic primordial dwarfism type I/III.

Author

Juric-Sekhar G, Kapur RP, Glass IA, Murray ML, Parnell SE, and Hevner RF

Subjects

Brain metabolism, Calbindin 2, Calbindins, Dwarfism complications, Dwarfism diagnostic imaging, Dwarfism genetics, Dwarfism pathology, Female, Fetal Growth Retardation diagnostic imaging, Fetal Growth Retardation genetics, Fetal Growth Retardation pathology, Genetic Testing methods, Glial Fibrillary Acidic Protein metabolism, Humans, Infant, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Malformations of Cortical Development, Group II radiotherapy, Microcephaly complications, Microcephaly diagnostic imaging, Microcephaly genetics, Microcephaly pathology, Microtubule-Associated Proteins metabolism, Neurofilament Proteins metabolism, Neurologic Examination, Osteochondrodysplasias complications, Osteochondrodysplasias diagnostic imaging, Osteochondrodysplasias genetics, Osteochondrodysplasias pathology, Radiography, S100 Calcium Binding Protein G metabolism, Brain pathology, Malformations of Cortical Development, Group II etiology

Abstract

Microcephalic osteodysplastic primordial dwarfism (MOPD) is a rare microlissencephaly syndrome, with at least two distinct phenotypic and genetic types. MOPD type II is caused by pericentrin mutations, while types I and III appear to represent a distinct entity (MOPD I/III) with variably penetrant phenotypes and unknown genetic basis. The neuropathology of MOPD I/III is little understood, especially in comparison to other forms of lissencephaly. Here, we report postmortem brain findings in an 11-month-old female infant with MOPD I/III. The cerebral cortex was diffusely pachygyric, with a right parietal porencephalic lesion. Histologically, the cortex was abnormally thick and disorganized. Distinct malformations were observed in different cerebral lobes, as characterized using layer-specific neuronal markers. Frontal cortex was severely disorganized and coated with extensive leptomeningeal glioneuronal heterotopia. Temporal cortex had a relatively normal 6-layered pattern, despite cortical thickening. Occipital cortex was variably affected. The corpus callosum was extremely hypoplastic. Brainstem and cerebellar malformations were also present, as well as old necrotic foci. Findings in this case suggest that the cortical malformation in MOPD I/III is distinct from other forms of pachygyria-lissencephaly.

Published

2011

25. Molecular genetics of neuronal migration disorders.

Author

Liu JS

Subjects

1-Alkyl-2-acetylglycerophosphocholine Esterase genetics, Animals, Cell Adhesion Molecules, Neuronal genetics, Cell Movement physiology, Cerebral Cortex abnormalities, Cerebral Cortex cytology, Cerebral Cortex embryology, Cerebral Cortex growth & development, Contractile Proteins genetics, Doublecortin Domain Proteins, Doublecortin Protein, Extracellular Matrix Proteins genetics, Filamins, Guanine Nucleotide Exchange Factors genetics, Homeodomain Proteins genetics, Humans, Malformations of Cortical Development, Group II pathology, Microfilament Proteins genetics, Microtubule-Associated Proteins genetics, Microtubules metabolism, Mutation, Nerve Tissue Proteins genetics, Neural Stem Cells cytology, Neural Stem Cells physiology, Neurons cytology, Neurons physiology, Neuropeptides genetics, Receptors, LDL genetics, Reelin Protein, Serine Endopeptidases genetics, Syndrome, Transcription Factors genetics, Tubulin genetics, Tubulin metabolism, Malformations of Cortical Development, Group II genetics, Molecular Biology

Abstract

Cortical malformations associated with defects in neuronal migration result in severe developmental consequences including intractable epilepsy and intellectual disability. Genetic causes of migration defects have been identified with the advent and widespread use of high-resolution MRI and genetic techniques. Thus, the full phenotypic range of these genetic disorders is becoming apparent. Genes that cause lissencephaly, pachygyria, subcortical band heterotopia, and periventricular nodular heterotopias have been defined. Many of these genes are involved in cytoskeletal regulation including the function of microtubules (LIS1, TUBA1A,TUBB3, and DCX) and of actin (FilaminA). Thus, the molecular pathways regulating neuronal migration including the cytoskeletal pathways appear to be defined by human mutation syndromes. Basic science, including cell biology and animal models of these disorders, has informed our understanding of the pathogenesis of neuronal migration disorders and further progress depends on the continued integration of the clinical and basic sciences.

Published

2011

26. Mutations in the neuronal ß-tubulin subunit TUBB3 result in malformation of cortical development and neuronal migration defects.

Author

Poirier K, Saillour Y, Bahi-Buisson N, Jaglin XH, Fallet-Bianco C, Nabbout R, Castelnau-Ptakhine L, Roubertie A, Attie-Bitach T, Desguerre I, Genevieve D, Barnerias C, Keren B, Lebrun N, Boddaert N, Encha-Razavi F, and Chelly J

Subjects

Cell Differentiation genetics, Humans, Microtubules genetics, Microtubules metabolism, Mutation, Missense, Neurogenesis, Phenotype, Tubulin metabolism, Cell Movement genetics, Cerebral Cortex abnormalities, Malformations of Cortical Development genetics, Malformations of Cortical Development, Group II genetics, Mutation, Neurons metabolism, Tubulin genetics

Abstract

Mutations in the TUBB3 gene, encoding β-tubulin isotype III, were recently shown to be associated with various neurological syndromes which all have in common the ocular motility disorder, congenital fibrosis of the extraocular muscle type 3 (CFEOM3). Surprisingly and in contrast to previously described TUBA1A and TUBB2B phenotypes, no evidence of dysfunctional neuronal migration and cortical organization was reported. In our study, we report the discovery of six novel missense mutations in the TUBB3 gene, including one fetal case and one homozygous variation, in nine patients that all share cortical disorganization, axonal abnormalities associated with pontocerebellar hypoplasia, but with no ocular motility defects, CFEOM3. These new findings demonstrate that the spectrum of TUBB3-related phenotype is broader than previously described and includes malformations of cortical development (MCD) associated with neuronal migration and differentiation defects, axonal guidance and tract organization impairment. Complementary functional studies revealed that the mutated βIII-tubulin causing the MCD phenotype results in a reduction of heterodimer formation, yet produce correctly formed microtubules (MTs) in mammalian cells. Further to this, we investigated the properties of the MT network in patients' fibroblasts and revealed that MCD mutations can alter the resistance of MTs to depolymerization. Interestingly, this finding contrasts with the increased MT stability observed in the case of CFEOM3-related mutations. These results led us to hypothesize that either MT dynamics or their interactions with various MT-interacting proteins could be differently affected by TUBB3 variations, thus resulting in distinct alteration of downstream processes and therefore explaining the phenotypic diversity of the TUBB3-related spectrum.

Published

2010

27. [Developmental malformations of the cerebral cortex].

Author

Reiss-Zimmermann M, Weber D, Sorge I, Merkenschlager A, and Hirsch W

Subjects

Cerebral Cortex pathology, Child, Child, Preschool, Choristoma classification, Choristoma diagnosis, Choristoma genetics, Epilepsy classification, Epilepsy diagnosis, Epilepsy genetics, Female, Humans, Infant, Infant, Newborn, Lissencephaly classification, Lissencephaly diagnosis, Lissencephaly genetics, Malformations of Cortical Development classification, Malformations of Cortical Development genetics, Malformations of Cortical Development, Group II classification, Malformations of Cortical Development, Group II diagnosis, Malformations of Cortical Development, Group II genetics, Pregnancy, Prenatal Diagnosis, Prognosis, Sensitivity and Specificity, Magnetic Resonance Imaging, Malformations of Cortical Development diagnosis

Abstract

Migration disorders (MD) are increasingly recognized as an important cause of epilepsy and developmental delay. Up to 25 % of children with refractory epilepsy have a cortical malformation. MD encompass a wide spectrum with underlying genetic etiologies and clinical manifestations. Research regarding the delineation of the genetic and molecular basis of these disorders has provided greater insight into the pathogenesis of not only the malformation but also the process involved in normal cortical development. Diagnosis of MD is important since patients who fail three antiepileptic medications are less likely to have their seizures controlled with additional trials of medications and therefore epilepsy surgery should be considered. Recent improvements in neuroimaging have resulted in a significant increase in the recognition of MD. Findings can be subdivided in disorders due to abnormal neurogenesis, neuronal migration, neuronal migration arrest and neuronal organization resulting in different malformations like microcephaly, lissencephaly, schizencephaly and heterotopia. The examination protocol should include T 1-w and T 2-w sequences in adequate slice orientation. T 1-w turbo-inversion recovery sequences (TIR) can be helpful to diagnose heterotopia. Contrast agent is needed only to exclude other differential diagnoses., (Georg Thieme Verlag KG Stuttgart New York.)

Published

2010

28. Neuronal migration disorders.

Author

Guerrini R and Parrini E

Subjects

Cell Movement genetics, Humans, Magnetic Resonance Imaging, Mutation, Neurons physiology, Reelin Protein, Cerebral Cortex abnormalities, Malformations of Cortical Development, Group II genetics

Abstract

Lissencephaly-pachygyria-severe band heterotopia are diffuse neuronal migration disorders (NMDs) causing severe, global neurological impairment. Abnormalities of the LIS1, DCX, ARX, TUBA1A and RELN genes have been associated with these malformations. NMDs only affecting subsets of neurons, such as mild subcortical band heterotopia and periventricular heterotopia, cause neurological and cognitive impairment that vary from severe to mild deficits. They have been associated with abnormalities of the DCX, FLN1A, and ARFGEF2 genes. Polymicrogyria results from abnormal late cortical organization and is inconstantly associated with abnormal neuronal migration. Localized polymicrogyria has been associated with anatomo-specific deficits, including disorders of language and higher cognition. Polymicrogyria is genetically heterogeneous and only in a small minority of patients a definite genetic cause has been identified. Mutations of the GPR56 and SRPX2 genes have been related to isolated polymicrogyria. Focal migration abnormalities associated with abnormal cell types, such as focal cortical dysplasia, are highly epileptogenic and variably influence the functioning of the affected cortex. The functional consequences of abnormal neuronal migration are still poorly understood. Conservation of function in the malformed cortex, its atypical representation, and relocation outside the malformed area are all possible. Localization of function based on anatomic landmarks may not be reliable., (Copyright 2009 Elsevier Inc. All rights reserved.)

Published

2010

29. Molecular genetics of attention-deficit/hyperactivity disorder: an overview.

Author

Banaschewski T, Becker K, Scherag S, Franke B, and Coghill D

Subjects

Adolescent, Cell Division genetics, Child, Genome-Wide Association Study, Humans, Malformations of Cortical Development, Group II genetics, Neurotransmitter Agents genetics, Phenotype, Genetic Markers genetics, Genetic Predisposition to Disease genetics

Abstract

As heritability is high in attention-deficit/hyperactivity disorder (ADHD), genetic factors must play a significant role in the development and course of this disorder. In recent years a large number of studies on different candidate genes for ADHD have been published, most have focused on genes involved in the dopaminergic neurotransmission system, such as DRD4, DRD5, DAT1/SLC6A3, DBH, DDC. Genes associated with the noradrenergic (such as NET1/SLC6A2, ADRA2A, ADRA2C) and serotonergic systems (such as 5-HTT/SLC6A4, HTR1B, HTR2A, TPH2) have also received considerable interest. Additional candidate genes related to neurotransmission and neuronal plasticity that have been studied less intensively include SNAP25, CHRNA4, NMDA, BDNF, NGF, NTF3, NTF4/5, GDNF. This review article provides an overview of these candidate gene studies, and summarizes findings from recently published genome-wide association studies (GWAS). GWAS is a relatively new tool that enables the identification of new ADHD genes in a hypothesis-free manner. Although these latter studies could be improved and need to be replicated they are starting to implicate processes like neuronal migration and cell adhesion and cell division as potentially important in the aetiology of ADHD and have suggested several new directions for future ADHD genetics studies.

Published

2010

30. New trends in neuronal migration disorders.

Author

Verrotti A, Spalice A, Ursitti F, Papetti L, Mariani R, Castronovo A, Mastrangelo M, and Iannetti P

Subjects

Brain pathology, Brain physiopathology, Epilepsy complications, Epilepsy genetics, Epilepsy pathology, Genetic Predisposition to Disease, Humans, Magnetic Resonance Imaging, Malformations of Cortical Development complications, Malformations of Cortical Development genetics, Malformations of Cortical Development pathology, Malformations of Cortical Development, Group II complications, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Pediatrics

Abstract

Neuronal migration disorders are an heterogeneous group of disorders of nervous system development and they are considered to be one of the most significant causes of neurological and developmental disabilities and epileptic seizures in childhood. In the last ten years, molecular biologic and genetic investigations have widely increased our knowledge about the regulation of neuronal migration during development. One of the most frequent disorders is lissencephaly. It is characterized by a paucity of normal gyri and sulci resulting in a "smooth brain". There are two pathologic subtypes: classical and cobblestone. Classical lissencephaly is caused by an arrest of neuronal migration whereas cobblestone lissencephaly caused by overmigration. Heterotopia is another important neuronal migration disorder. It is characterized by a cluster of disorganized neurons in abnormal locations and it is divided into three main groups: periventricular nodular heterotopia, subcortical heterotopia and marginal glioneural heterotopia. Polymicrogyria develops at the final stages of neuronal migration, in the earliest phases of cortical organization; bilateral frontoparietal form is characterized by bilateral, symmetric polymicrogyria in the frontoparietal regions. Bilateral perisylvian polymicrogyria causes a clinical syndrome which manifests itself in the form of mild mental retardation, epilepsy and pseudobulbar palsy. Schizencephaly is another important neuronal migration disorder whose clinical characteristics are extremely variable. This review reports the main clinical and pathophysiological aspects of these disorders paying particular attention to the recent advances in molecular genetics., (Copyright 2009 European Paediatric Neurology Society. Published by Elsevier Ltd. All rights reserved.)

Published

2010

31. Neuronal migration disorders: clinical, neuroradiologic and genetics aspects.

Author

Spalice A, Parisi P, Nicita F, Pizzardi G, Del Balzo F, and Iannetti P

Subjects

Animals, Genes, Developmental, Humans, Magnetic Resonance Imaging, Malformations of Cortical Development, Group II diagnosis, Malformations of Cortical Development, Group II physiopathology, Reelin Protein, Malformations of Cortical Development, Group II genetics

Abstract

Unlabelled: Disorders of neuronal migration are a heterogeneous group of disorders of nervous system development. One of the most frequent disorders is lissencephaly, characterized by a paucity of normal gyri and sulci resulting in a 'smooth brain'. There are two pathologic subtypes: classical and cobblestone. Six different genes could be responsible for this entity (LIS1, DCX, TUBA1A, VLDLR, ARX, RELN), although co-delection of YWHAE gene with LIS1 could result in Miller-Dieker Syndrome. Heterotopia is defined as a cluster of normal neurons in abnormal locations, and divided into three main groups: periventricular nodular heterotopia, subcortical heterotopia and marginal glioneural heterotopia. Genetically, heterotopia is related to Filamin A (FLNA) or ADP-ribosylation factor guanine exchange factor 2 (ARFGEF2) genes mutations. Polymicrogyria is described as an augmentation of small circonvolutions separated by shallow enlarged sulci; bilateral frontoparietal form is characterized by bilateral, symmetric polymicrogyria in the frontoparietal regions. Bilateral perisylvian polymicrogyria results in a clinical syndrome manifested by mild mental retardation, epilepsy and pseudobulbar palsy. Gene mutations linked to this disorder are SRPX2, PAX6, TBR2, KIAA1279, RAB3GAP1 and COL18A1. Schizencephaly, consisting in a cleft of cerebral hemisphere connecting extra-axial subaracnoid spaces and ventricles, is another important disorder of neuronal migration whose clinical characteristics are extremely variable. EMX2 gene could be implicated in its genesis. Focal cortical dysplasia is characterized by three different types of altered cortical laminations, and represents one of most severe cause of epilepsy in children. TSC1 gene could play a role in its etiology., Conclusion: This review reports the main clinical, genetical and neuroradiological aspects of these disorders. It is hoped that accumulating data of the development mechanisms underlying the expanded network formation in the brain will lead to the development of therapeutic options for neuronal migration disorders.

Published

2009

32. Dcx reexpression reduces subcortical band heterotopia and seizure threshold in an animal model of neuronal migration disorder.

Author

Manent JB, Wang Y, Chang Y, Paramasivam M, and LoTurco JJ

Subjects

Animals, Animals, Genetically Modified, Cell Movement genetics, Classical Lissencephalies and Subcortical Band Heterotopias pathology, Classical Lissencephalies and Subcortical Band Heterotopias therapy, Classical Lissencephalies and Subcortical Band Heterotopias veterinary, Doublecortin Domain Proteins, Doublecortin Protein, Female, Gene Knockdown Techniques, Genetic Predisposition to Disease, Genetic Therapy, Malformations of Cortical Development, Group II embryology, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II pathology, Malformations of Cortical Development, Group II veterinary, Microtubule-Associated Proteins antagonists & inhibitors, Microtubule-Associated Proteins physiology, Models, Biological, Neurons pathology, Neurons physiology, Neuropeptides antagonists & inhibitors, Neuropeptides physiology, Pregnancy, RNA Interference physiology, Rats, Seizures pathology, Seizures therapy, Severity of Illness Index, Classical Lissencephalies and Subcortical Band Heterotopias genetics, Disease Models, Animal, Microtubule-Associated Proteins genetics, Neuropeptides genetics, Seizures genetics

Abstract

Disorders of neuronal migration can lead to malformations of the cerebral neocortex that greatly increase the risk of seizures. It remains untested whether malformations caused by disorders in neuronal migration can be reduced by reactivating cellular migration and whether such repair can decrease seizure risk. Here we show, in a rat model of subcortical band heterotopia (SBH) generated by in utero RNA interference of the Dcx gene, that aberrantly positioned neurons can be stimulated to migrate by reexpressing Dcx after birth. Restarting migration in this way both reduces neocortical malformations and restores neuronal patterning. We further find that the capacity to reduce SBH continues into early postnatal development. Moreover, intervention after birth reduces the convulsant-induced seizure threshold to a level similar to that in malformation-free controls. These results suggest that disorders of neuronal migration may be eventually treatable by reengaging developmental programs both to reduce the size of cortical malformations and to reduce seizure risk.

Published

2009

33. Moving neurons back into place.

Author

Kerjan G and Gleeson JG

Subjects

Animals, Cell Movement physiology, Doublecortin Domain Proteins, Epilepsy etiology, Epilepsy genetics, Epilepsy therapy, Fetal Development physiology, Genes, Developmental physiology, Genetic Therapy, Intellectual Disability etiology, Intellectual Disability genetics, Intellectual Disability therapy, Malformations of Cortical Development, Group II complications, Mice, Microtubule-Associated Proteins genetics, Microtubule-Associated Proteins physiology, Models, Biological, Neurons pathology, Neuropeptides genetics, Neuropeptides physiology, Rats, Cell Movement genetics, Fetal Development genetics, Malformations of Cortical Development, Group II genetics, Malformations of Cortical Development, Group II therapy, Neurons physiology

Published

2009

34. Postnatal analysis of the effect of embryonic knockdown and overexpression of candidate dyslexia susceptibility gene homolog Dcdc2 in the rat.

Author

Burbridge TJ, Wang Y, Volz AJ, Peschansky VJ, Lisann L, Galaburda AM, Lo Turco JJ, and Rosen GD

Subjects

Animals, Cerebral Cortex metabolism, Cerebral Cortex physiopathology, Choristoma genetics, Choristoma metabolism, Choristoma physiopathology, Doublecortin Protein, Down-Regulation genetics, Dyslexia metabolism, Dyslexia physiopathology, Gene Expression Regulation, Developmental genetics, Gene Targeting, Hippocampus abnormalities, Hippocampus metabolism, Hippocampus physiopathology, Humans, Malformations of Cortical Development, Group II metabolism, Malformations of Cortical Development, Group II physiopathology, Microtubule-Associated Proteins biosynthesis, Microtubule-Associated Proteins deficiency, Pyramidal Cells metabolism, Pyramidal Cells pathology, RNA Interference, Rats, Rats, Wistar, Transfection, Cell Movement genetics, Cerebral Cortex abnormalities, Dyslexia genetics, Genetic Predisposition to Disease genetics, Malformations of Cortical Development, Group II genetics, Microtubule-Associated Proteins genetics

Abstract

Embryonic knockdown of candidate dyslexia susceptibility gene (CDSG) homologs in cerebral cortical progenitor cells in the rat results in acute disturbances of neocortical migration. In the current report we investigated the effects of embryonic knockdown and overexpression of the homolog of DCDC2, one of the CDSGs, on the postnatal organization of the cerebral cortex. Using a within-litter design, we transfected cells in rat embryo neocortical ventricular zone around embryonic day (E) 15 with either 1) small hairpin RNA (shRNA) vectors targeting Dcdc2, 2) a DCDC2 overexpression construct, 3) Dcdc2 shRNA along with DCDC2 overexpression construct, 4) an overexpression construct composed of the C terminal domain of DCDC2, or 5) an overexpression construct composed of the DCX terminal domain of DCDC2. RNAi of Dcdc2 resulted in pockets of heterotopic neurons in the periventricular region. Approximately 25% of the transfected brains had hippocampal pyramidal cell migration anomalies. Dcdc2 shRNA-transfected neurons migrated in a bimodal pattern, with approximately 7% of the neurons migrating a short distance from the ventricular zone, and another 30% migrating past their expected lamina. Rats transfected with Dcdc2 shRNA along with the DCDC2 overexpression construct rescued the periventricular heterotopia phenotype, but did not affect the percentage of transfected neurons that migrate past their expected laminar location. There were no malformations associated with any of the overexpression constructs, nor was there a significant laminar disruption of migration. These results support the claim that knockdown of Dcdc2 expression results in neuronal migration disorders similar to those seen in the brains of dyslexics.

Published

2008

35. Sudden death in a patient with mosaic ring X Turner syndrome and a neuronal migration disorder.

Author

Longman C, MacKenzie J, Rankin R, McEntagart M, Johnson R, Al-Hilaly N, and Atkinson P

Subjects

Female, Hippocampus pathology, Humans, Infant, Karyotyping, Malformations of Cortical Development, Group II genetics, Turner Syndrome genetics, Chromosomes, Human, X, Death, Sudden, Malformations of Cortical Development, Group II physiopathology, Mosaicism, Ring Chromosomes, Turner Syndrome physiopathology

Published

2008

36. Genetic mechanisms underlying abnormal neuronal migration in classical lissencephaly.

Author

Kerjan G and Gleeson JG

Subjects

1-Alkyl-2-acetylglycerophosphocholine Esterase genetics, Animals, Cerebral Cortex abnormalities, Cerebral Cortex embryology, Cytoskeletal Proteins genetics, Disease Models, Animal, Doublecortin Domain Proteins, Doublecortin Protein, Evolution, Molecular, Humans, Lissencephaly pathology, Mice, Microtubule-Associated Proteins genetics, Models, Biological, Mutation, Neurons pathology, Neuropeptides genetics, Cell Movement, Lissencephaly embryology, Lissencephaly genetics, Malformations of Cortical Development, Group II genetics, Neurons physiology

Abstract

Classical lissencephaly is a human developmental brain disorder characterized by a paucity of cortical gyration and thickening of the cortical gray matter, leading to severe epilepsy and mental retardation. Loss-of-function mutations in the microtubule-associated protein encoding genes, PAFAH1B1 (encoding the protein LIS1), DCX and TUBA1A have been implicated in the pathogenesis of the condition. Animal models are required to understand the basis of this disease, which is a challenge, given that mice normally have a smooth cortex. Recent advances toward this goal have come from stepwise reduction in gene function, deletion of redundant genes and acute gene inactivation using short hairpin RNA (shRNA). These approaches have implicated genes that regulate the microtubule cytoskeleton during neuronal division, migration and maturation.

Published

2007

37. Dyslexia--a molecular disorder of neuronal migration: the 2004 Norman Geschwind Memorial Lecture.

Author

Galaburda AM

Subjects

Animals, Auditory Perception genetics, Brain pathology, Dominance, Cerebral physiology, Dyslexia diagnosis, Dyslexia pathology, Female, Humans, Male, Malformations of Cortical Development, Group II diagnosis, Malformations of Cortical Development, Group II pathology, Models, Genetic, Neuronal Plasticity genetics, Rats, Sex Factors, Dyslexia genetics, Malformations of Cortical Development, Group II genetics

Abstract

For 25 years now, there has been a serious attempt to get at the fundamental cause(s) of dyslexia in our laboratory. A great deal of research has been carried out on the psychological and brain underpinnings of the linguistic dysfunctions seen in dyslexia, but attempts to get at its cause have been limited. Initially, observations were made on the brains of persons with dyslexia who had died and their brains donated for research. These observations were modeled in animal models in order to better understand the full extent of anatomical and developmental brain characteristics. More recently, models have begun to employ genetic manipulations in order to close the gap between genes, brain, and behavior. In this article based on a lecture given in memory of Dr. Norman Geschwind to the International Dyslexia Association assembly in Philadelphia in 2004, I outline the history of the research leading up to the most recent findings. These findings consist of experiments using methods that interfere with the function of DNA, using as constructs genes that have been implicated in dyslexia, which cause developmental problems of neuronal migration in rats, secondary brain changes in response to the migration problems, and abnormal processing of sounds.

Published

2005