2021
DIAPH1 Variants in Non–East Asian Patients With Sporadic Moyamoya Disease
Kundishora AJ, Peters ST, Pinard A, Duran D, Panchagnula S, Barak T, Miyagishima DF, Dong W, Smith H, Ocken J, Dunbar A, Nelson-Williams C, Haider S, Walker RL, Li B, Zhao H, Thumkeo D, Marlier A, Duy PQ, Diab NS, Reeves BC, Robert SM, Sujijantarat N, Stratman AN, Chen YH, Zhao S, Roszko I, Lu Q, Zhang B, Mane S, Castaldi C, López-Giráldez F, Knight JR, Bamshad MJ, Nickerson DA, Geschwind DH, Chen SL, Storm PB, Diluna ML, Matouk CC, Orbach DB, Alper SL, Smith ER, Lifton RP, Gunel M, Milewicz DM, Jin SC, Kahle KT. DIAPH1 Variants in Non–East Asian Patients With Sporadic Moyamoya Disease. JAMA Neurology 2021, 78: 993-1003. PMID: 34125151, PMCID: PMC8204259, DOI: 10.1001/jamaneurol.2021.1681.Peer-Reviewed Original ResearchConceptsSporadic moyamoya diseaseMoyamoya diseaseValidation cohortDiscovery cohortIntracranial internal carotid arteryRisk genesBilateral moyamoya diseaseTransfusion-dependent thrombocytopeniaLarger validation cohortNon-East Asian patientsInternal carotid arteryAsian individualsCompound heterozygous variantsNon-East AsiansProgressive vasculopathyTransmitted variantsAsian patientsChildhood strokeMedical recordsCarotid arteryTherapeutic ramificationsMAIN OUTCOMEMouse brain tissuePatientsUS hospitals
2019
Loss of UGP2 in brain leads to a severe epileptic encephalopathy, emphasizing that bi-allelic isoform-specific start-loss mutations of essential genes can cause genetic diseases
Perenthaler E, Nikoncuk A, Yousefi S, Berdowski WM, Alsagob M, Capo I, van der Linde HC, van den Berg P, Jacobs EH, Putar D, Ghazvini M, Aronica E, van IJcken WFJ, de Valk WG, Medici-van den Herik E, van Slegtenhorst M, Brick L, Kozenko M, Kohler JN, Bernstein JA, Monaghan KG, Begtrup A, Torene R, Al Futaisi A, Al Murshedi F, Mani R, Al Azri F, Kamsteeg EJ, Mojarrad M, Eslahi A, Khazaei Z, Darmiyan FM, Doosti M, Karimiani EG, Vandrovcova J, Zafar F, Rana N, Kandaswamy KK, Hertecant J, Bauer P, AlMuhaizea MA, Salih MA, Aldosary M, Almass R, Al-Quait L, Qubbaj W, Coskun S, Alahmadi KO, Hamad MHA, Alwadaee S, Awartani K, Dababo AM, Almohanna F, Colak D, Dehghani M, Mehrjardi MYV, Gunel M, Ercan-Sencicek AG, Passi GR, Cheema HA, Efthymiou S, Houlden H, Bertoli-Avella AM, Brooks AS, Retterer K, Maroofian R, Kaya N, van Ham TJ, Barakat TS. Loss of UGP2 in brain leads to a severe epileptic encephalopathy, emphasizing that bi-allelic isoform-specific start-loss mutations of essential genes can cause genetic diseases. Acta Neuropathologica 2019, 139: 415-442. PMID: 31820119, PMCID: PMC7035241, DOI: 10.1007/s00401-019-02109-6.Peer-Reviewed Original ResearchConceptsUDP-glucose pyrophosphorylase genePluripotent stem cell differentiationGenetic diseasesUnfolded protein responseVisual disturbancesAltered glycogen metabolismPremature neuronal differentiationStem cell differentiationEpileptic encephalopathyUpregulated unfolded protein responseDevelopmental delayEssential genesEssential proteinsTherapy-resistant seizuresDifferentiation defectsMutant animalsStart codonMultiple lineagesProtein responseNeural stem cellsSevere epileptic encephalopathySimilar disease mechanismsSevere developmental delayShort isoformProtein absence
2018
MAB21L1 loss of function causes a syndromic neurodevelopmental disorder with distinctive cerebellar, ocular, craniofacial and genital features (COFG syndrome)
Rad A, Altunoglu U, Miller R, Maroofian R, James KN, Çağlayan AO, Najafi M, Stanley V, Boustany RM, Yeşil G, Sahebzamani A, Ercan-Sencicek G, Saeidi K, Wu K, Bauer P, Bakey Z, Gleeson JG, Hauser N, Gunel M, Kayserili H, Schmidts M. MAB21L1 loss of function causes a syndromic neurodevelopmental disorder with distinctive cerebellar, ocular, craniofacial and genital features (COFG syndrome). Journal Of Medical Genetics 2018, 56: 332. PMID: 30487245, PMCID: PMC6581149, DOI: 10.1136/jmedgenet-2018-105623.Peer-Reviewed Original ResearchMeSH KeywordsAbnormalities, MultipleBrainChildChild, PreschoolConsanguinityExome SequencingFaciesFemaleGenetic Association StudiesGenetic Predisposition to DiseaseHomeodomain ProteinsHomozygoteHumansInfantLoss of Function MutationMagnetic Resonance ImagingMaleModels, MolecularNeurodevelopmental DisordersPedigreePhenotypePolymorphism, Single NucleotideProtein ConformationSyndromeConceptsScrotal agenesisCerebellar hypoplasiaCharacteristic facial gestaltHomozygous truncating variantConsanguineous familyUnrelated consanguineous familiesOphthalmological anomaliesSyndromic neurodevelopmental disorderCardinal featuresCerebello-oculoCorneal dystrophyLabioscrotal foldsTruncating variantsFunction variantsFacial gestaltExome sequencingSyndromeSimilar phenotypic featuresGenetic causeFacial dysmorphismNeurodevelopmental disordersMissense variantsVariable microcephalyNeurodevelopmental syndromeAffected individualsLoss of Protocadherin‐12 Leads to Diencephalic‐Mesencephalic Junction Dysplasia Syndrome
Guemez‐Gamboa A, Çağlayan AO, Stanley V, Gregor A, Zaki M, Saleem SN, Musaev D, McEvoy‐Venneri J, Belandres D, Akizu N, Silhavy JL, Schroth J, Rosti RO, Copeland B, Lewis SM, Fang R, Issa MY, Per H, Gumus H, Bayram AK, Kumandas S, Akgumus GT, Erson‐Omay E, Yasuno K, Bilguvar K, Heimer G, Pillar N, Shomron N, Weissglas‐Volkov D, Porat Y, Einhorn Y, Gabriel S, Ben‐Zeev B, Gunel M, Gleeson JG. Loss of Protocadherin‐12 Leads to Diencephalic‐Mesencephalic Junction Dysplasia Syndrome. Annals Of Neurology 2018, 84: 638-647. PMID: 30178464, PMCID: PMC6510237, DOI: 10.1002/ana.25327.Peer-Reviewed Original ResearchConceptsBrainstem malformationDysplasia syndromeEndothelial cellsBiallelic mutationsAutosomal recessive malformationSuch pathogenic variantsCharacteristic clinical presentationPatient-derived induced pluripotent stem cellsWhite matter tractsAnn NeurolAppendicular spasticityBrain calcificationClinical presentationPoor outcomeAxial hypotoniaPsychomotor disabilityProgressive microcephalyTract defectsPathogenic variantsPhenotypic spectrumPatientsCraniofacial dysmorphismBrain imagingNeural precursorsProtein expression9p24 triplication in syndromic hydrocephalus with diffuse villous hyperplasia of the choroid plexus
Furey C, Antwi P, Duran D, Timberlake AT, Nelson-Williams C, Matouk CC, DiLuna ML, Günel M, Kahle KT. 9p24 triplication in syndromic hydrocephalus with diffuse villous hyperplasia of the choroid plexus. Molecular Case Studies 2018, 4: a003145. PMID: 29895553, PMCID: PMC6169828, DOI: 10.1101/mcs.a003145.Peer-Reviewed Original ResearchConceptsDiffuse villous hyperplasiaVillous hyperplasiaChoroid plexusSyndromic hydrocephalusCerebrospinal fluid homeostasisSurgical managementPathological featuresHigh prevalenceHydrocephalus treatmentHydrocephalusDVHCPFluid homeostasisCSF productionHyperplasiaPlexusChromosome 9pCritical genesHypersecretionPatientsPathogenesisPrevalenceDisease
2016
Impaired Amino Acid Transport at the Blood Brain Barrier Is a Cause of Autism Spectrum Disorder
Tărlungeanu DC, Deliu E, Dotter CP, Kara M, Janiesch PC, Scalise M, Galluccio M, Tesulov M, Morelli E, Sonmez FM, Bilguvar K, Ohgaki R, Kanai Y, Johansen A, Esharif S, Ben-Omran T, Topcu M, Schlessinger A, Indiveri C, Duncan KE, Caglayan AO, Gunel M, Gleeson JG, Novarino G. Impaired Amino Acid Transport at the Blood Brain Barrier Is a Cause of Autism Spectrum Disorder. Cell 2016, 167: 1481-1494.e18. PMID: 27912058, PMCID: PMC5554935, DOI: 10.1016/j.cell.2016.11.013.Peer-Reviewed Original ResearchConceptsBlood-brain barrierBrain barrierBrain amino acid profilesLarge neutral amino acid transporterAutism spectrum disorderAdult mutant miceBranched-chain amino acid (BCAA) catabolic pathwaySevere neurological abnormalitiesNeutral amino acid transporterIntracerebroventricular administrationNeurological syndromeNeurological abnormalitiesNeurological conditionsSpectrum disorderSLC7A5 geneMotor delayAmino acid transportAmino acid transportersMutant miceNormal levelsBrain functionHuman brain functionEndothelial cellsHomozygous mutationCauses of ASDBiallelic Mutations in TMTC3, Encoding a Transmembrane and TPR-Containing Protein, Lead to Cobblestone Lissencephaly
Jerber J, Zaki MS, Al-Aama JY, Rosti RO, Ben-Omran T, Dikoglu E, Silhavy JL, Caglar C, Musaev D, Albrecht B, Campbell KP, Willer T, Almuriekhi M, Çağlayan A, Vajsar J, Bilgüvar K, Ogur G, Jamra R, Günel M, Gleeson JG. Biallelic Mutations in TMTC3, Encoding a Transmembrane and TPR-Containing Protein, Lead to Cobblestone Lissencephaly. American Journal Of Human Genetics 2016, 99: 1181-1189. PMID: 27773428, PMCID: PMC5097947, DOI: 10.1016/j.ajhg.2016.09.007.Peer-Reviewed Original ResearchConceptsCongenital muscular dystrophyCobblestone lissencephalyOvermigration of neuronsBiallelic mutationsMuscular dystrophyTMTC3Affected individualsWalker-Warburg syndromeMembrane componentsSevere brain malformationsBasement membrane componentsFukuyama congenital muscular dystrophyMuscle creatine phosphokinaseEye defectsMutationsGenesRecessive formGenetic disordersGlial cellsMinimal eyeMuscle involvementCortical dysplasiaBrain malformationsEye anomaliesCreatine phosphokinaseACOX2 deficiency: A disorder of bile acid synthesis with transaminase elevation, liver fibrosis, ataxia, and cognitive impairment
Vilarinho S, Sari S, Mazzacuva F, Bilgüvar K, Esendagli-Yilmaz G, Jain D, Akyol G, Dalgiç B, Günel M, Clayton PT, Lifton RP. ACOX2 deficiency: A disorder of bile acid synthesis with transaminase elevation, liver fibrosis, ataxia, and cognitive impairment. Proceedings Of The National Academy Of Sciences Of The United States Of America 2016, 113: 11289-11293. PMID: 27647924, PMCID: PMC5056113, DOI: 10.1073/pnas.1613228113.Peer-Reviewed Original ResearchConceptsAcyl-CoA oxidase 2Liver fibrosisCognitive impairmentElevated transaminase levelsTreatable inborn errorsBile acid synthesisBile acid intermediatesBile acid biosynthesisTransaminase elevationTransaminase levelsMarked elevationMild ataxiaBile acidsPatient's liverOxidase 2Acyl-CoA oxidaseOld maleBranched chain acyl-CoA oxidaseInborn errorsExome sequencingPremature termination mutationsBranched-chain fatty acidsFibrosisAtaxiaLiver
2015
Inactivating mutations in MFSD2A, required for omega-3 fatty acid transport in brain, cause a lethal microcephaly syndrome
Guemez-Gamboa A, Nguyen LN, Yang H, Zaki MS, Kara M, Ben-Omran T, Akizu N, Rosti RO, Rosti B, Scott E, Schroth J, Copeland B, Vaux KK, Cazenave-Gassiot A, Quek DQ, Wong BH, Tan BC, Wenk MR, Gunel M, Gabriel S, Chi NC, Silver DL, Gleeson JG. Inactivating mutations in MFSD2A, required for omega-3 fatty acid transport in brain, cause a lethal microcephaly syndrome. Nature Genetics 2015, 47: 809-813. PMID: 26005868, PMCID: PMC4547531, DOI: 10.1038/ng.3311.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAnimalsBiological TransportBlood-Brain BarrierBrainCase-Control StudiesChildChild, PreschoolConsanguinityFatty Acids, Omega-3FemaleGenes, LethalGenetic Association StudiesHEK293 CellsHumansInfantMaleMice, KnockoutMicrocephalyMutation, MissenseSymportersSyndromeTumor Suppressor ProteinsZebrafishBiallelic mutations in SNX14 cause a syndromic form of cerebellar atrophy and lysosome-autophagosome dysfunction
Akizu N, Cantagrel V, Zaki MS, Al-Gazali L, Wang X, Rosti RO, Dikoglu E, Gelot AB, Rosti B, Vaux KK, Scott EM, Silhavy JL, Schroth J, Copeland B, Schaffer AE, Gordts PL, Esko JD, Buschman MD, Field SJ, Napolitano G, Abdel-Salam GM, Ozgul RK, Sagıroglu M, Azam M, Ismail S, Aglan M, Selim L, Mahmoud IG, Abdel-Hadi S, Badawy AE, Sadek AA, Mojahedi F, Kayserili H, Masri A, Bastaki L, Temtamy S, Müller U, Desguerre I, Casanova JL, Dursun A, Gunel M, Gabriel SB, de Lonlay P, Gleeson JG. Biallelic mutations in SNX14 cause a syndromic form of cerebellar atrophy and lysosome-autophagosome dysfunction. Nature Genetics 2015, 47: 528-534. PMID: 25848753, PMCID: PMC4414867, DOI: 10.1038/ng.3256.Peer-Reviewed Original Research
2014
Exceptional aggressiveness of cerebral cavernous malformation disease associated with PDCD10 mutations
Shenkar R, Shi C, Rebeiz T, Stockton RA, McDonald DA, Mikati AG, Zhang L, Austin C, Akers AL, Gallione CJ, Rorrer A, Gunel M, Min W, Marcondes de Souza J, Lee C, Marchuk DA, Awad IA. Exceptional aggressiveness of cerebral cavernous malformation disease associated with PDCD10 mutations. Genetics In Medicine 2014, 17: 188-196. PMID: 25122144, PMCID: PMC4329119, DOI: 10.1038/gim.2014.97.Peer-Reviewed Original ResearchMeSH Keywords1-(5-Isoquinolinesulfonyl)-2-MethylpiperazineAdolescentAdultAnimalsApoptosis Regulatory ProteinsCarrier ProteinsCells, CulturedCentral Nervous System NeoplasmsChildChild, PreschoolDisease Models, AnimalHemangioma, Cavernous, Central Nervous SystemHuman Umbilical Vein Endothelial CellsHumansInfantIntracellular Signaling Peptides and ProteinsKeratin-1Membrane ProteinsMiceMiddle AgedMutationProspective StudiesProto-Oncogene ProteinsRho-Associated KinasesStress FibersYoung AdultConceptsCerebral cavernous malformation diseaseRho-kinase activityLesion burdenExceptional aggressivenessCerebral cavernous malformation lesionsSporadic cerebral cavernous malformationBrain vascular permeabilityPreclinical therapeutic testingDesign of trialsPotential therapeutic targetCerebral cavernous malformationsClinical manifestationsBrain permeabilityEndothelial stress fibersSkin lesionsVascular permeabilityCavernous malformationsTherapeutic targetTherapeutic testingFrequent hemorrhagesKinase activityClinical phenotypeClinical counselingHeterozygous miceEndothelial cellsPaediatric hepatocellular carcinoma due to somatic CTNNB1 and NFE2L2 mutations in the setting of inherited bi-allelic ABCB11 mutations
Vilarinho S, Erson-Omay EZ, Harmanci AS, Morotti R, Carrion-Grant G, Baranoski J, Knisely AS, Ekong U, Emre S, Yasuno K, Bilguvar K, Günel M. Paediatric hepatocellular carcinoma due to somatic CTNNB1 and NFE2L2 mutations in the setting of inherited bi-allelic ABCB11 mutations. Journal Of Hepatology 2014, 61: 1178-1183. PMID: 25016225, DOI: 10.1016/j.jhep.2014.07.003.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceATP Binding Cassette Transporter, Subfamily B, Member 11ATP-Binding Cassette TransportersBase SequenceBeta CateninCarcinoma, HepatocellularCholestasis, IntrahepaticDNA, NeoplasmFemaleGerm-Line MutationHumansInfantLiver NeoplasmsMolecular Sequence DataMutationMutation, MissenseNF-E2-Related Factor 2Sequence Homology, Amino AcidConceptsBile salt export pumpWhole-exome sequencingHepatocellular carcinomaMonths of ageNFE2L2 mutationsABCB11 mutationsSomatic CTNNB1Background liver parenchymaPediatric hepatocellular carcinomaNew onsetSomatic driver mutationsBSEP expressionLiver parenchymaHCC tissuesHepatocellular carcinogenesisWES analysisExport pumpDriver mutationsCTNNB1 mutationsExome sequencingChild's diagnosisClonality analysisGermline DNAPossible genetic basisEarly childhoodHomozygous loss of DIAPH1 is a novel cause of microcephaly in humans
Ercan-Sencicek AG, Jambi S, Franjic D, Nishimura S, Li M, El-Fishawy P, Morgan TM, Sanders SJ, Bilguvar K, Suri M, Johnson MH, Gupta AR, Yuksel Z, Mane S, Grigorenko E, Picciotto M, Alberts AS, Gunel M, Šestan N, State MW. Homozygous loss of DIAPH1 is a novel cause of microcephaly in humans. European Journal Of Human Genetics 2014, 23: 165-172. PMID: 24781755, PMCID: PMC4297910, DOI: 10.1038/ejhg.2014.82.Peer-Reviewed Original ResearchConceptsCell divisionFamily-based linkage analysisLinkage analysisRho effector proteinsLinear actin filamentsMaintenance of polarityMitotic cell divisionHigh-throughput sequencingRare genetic variantsHuman neuronal precursor cellsParametric multipoint linkage analysisActivation of GTPNeuronal precursor cellsFormin familyMammalian DiaphanousEffector proteinsMultipoint linkage analysisSpindle formationActin filamentsNonsense alterationWhole-exome sequencingHuman pathologiesNeuroepithelial cellsGenetic variantsHomozygous loss
2011
The Essential Role of Centrosomal NDE1 in Human Cerebral Cortex Neurogenesis
Bakircioglu M, Carvalho OP, Khurshid M, Cox JJ, Tuysuz B, Barak T, Yilmaz S, Caglayan O, Dincer A, Nicholas AK, Quarrell O, Springell K, Karbani G, Malik S, Gannon C, Sheridan E, Crosier M, Lisgo SN, Lindsay S, Bilguvar K, Gergely F, Gunel M, Woods CG. The Essential Role of Centrosomal NDE1 in Human Cerebral Cortex Neurogenesis. American Journal Of Human Genetics 2011, 88: 523-535. PMID: 21529752, PMCID: PMC3146716, DOI: 10.1016/j.ajhg.2011.03.019.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell Cycle ProteinsCentrosomeCerebral CortexChild, PreschoolDNA Mutational AnalysisEpithelial CellsExonsFemaleGenetic LinkageHeLa CellsHomozygoteHumansInfantMaleMiceMicrocephalyMicrotubule-Associated ProteinsMutationNeural Stem CellsNeurogenesisNeuronsPhenotypePregnancyRNA, MessengerTransfectionConceptsCortical laminationPatient-derived cell linesDistinct homozygous mutationsProfound mental retardationCerebral cortexCerebral cortex neurogenesisMouse embryonic brainNeuron productionBrain scansPostmortem dataEmbryonic brainNeural precursorsHomozygous mutationNeuroepithelial cellsNeurogenesisPatient cellsMental retardationExtreme microcephalyAffected individualsEarly neurogenesisCell linesT mutationPakistani originBrainTurkish family