Featured Publications
Whole-exome sequencing identifies recessive WDR62 mutations in severe brain malformations
Bilgüvar K, Öztürk A, Louvi A, Kwan KY, Choi M, Tatlı B, Yalnızoğlu D, Tüysüz B, Çağlayan A, Gökben S, Kaymakçalan H, Barak T, Bakırcıoğlu M, Yasuno K, Ho W, Sanders S, Zhu Y, Yılmaz S, Dinçer A, Johnson MH, Bronen RA, Koçer N, Per H, Mane S, Pamir MN, Yalçınkaya C, Kumandaş S, Topçu M, Özmen M, Šestan N, Lifton RP, State MW, Günel M. Whole-exome sequencing identifies recessive WDR62 mutations in severe brain malformations. Nature 2010, 467: 207-210. PMID: 20729831, PMCID: PMC3129007, DOI: 10.1038/nature09327.Peer-Reviewed Original ResearchConceptsAbnormal cortical developmentWD repeat domain 62 (WDR62) geneSevere brain malformationsWhole-exome sequencingBrain abnormalitiesBrain malformationsCortical developmentMolecular pathogenesisCerebellar hypoplasiaWDR62 mutationsEmbryonic neurogenesisDiagnostic classificationMicrocephaly genesSmall family sizeGenetic heterogeneityWide spectrumRecessive mutationsPachygyriaPathogenesisHypoplasiaNeocortexNeurogenesisAbnormalitiesMalformationsMutationsGenomic Analysis of Non-NF2 Meningiomas Reveals Mutations in TRAF7, KLF4, AKT1, and SMO
Clark VE, Erson-Omay EZ, Serin A, Yin J, Cotney J, Özduman K, Avşar T, Li J, Murray PB, Henegariu O, Yilmaz S, Günel JM, Carrión-Grant G, Yılmaz B, Grady C, Tanrıkulu B, Bakırcıoğlu M, Kaymakçalan H, Caglayan AO, Sencar L, Ceyhun E, Atik AF, Bayri Y, Bai H, Kolb LE, Hebert RM, Omay SB, Mishra-Gorur K, Choi M, Overton JD, Holland EC, Mane S, State MW, Bilgüvar K, Baehring JM, Gutin PH, Piepmeier JM, Vortmeyer A, Brennan CW, Pamir MN, Kılıç T, Lifton RP, Noonan JP, Yasuno K, Günel M. Genomic Analysis of Non-NF2 Meningiomas Reveals Mutations in TRAF7, KLF4, AKT1, and SMO. Science 2013, 339: 1077-1080. PMID: 23348505, PMCID: PMC4808587, DOI: 10.1126/science.1233009.Peer-Reviewed Original ResearchMeSH KeywordsAdultAgedAged, 80 and overBrain NeoplasmsChromosomes, Human, Pair 22DNA Mutational AnalysisFemaleGenes, Neurofibromatosis 2Genomic InstabilityGenomicsHumansKruppel-Like Factor 4Kruppel-Like Transcription FactorsMaleMeningeal NeoplasmsMeningiomaMiddle AgedMutationNeoplasm GradingProto-Oncogene Proteins c-aktReceptors, G-Protein-CoupledSmoothened ReceptorTumor Necrosis Factor Receptor-Associated Peptides and ProteinsSomatic POLE mutations cause an ultramutated giant cell high-grade glioma subtype with better prognosis
Erson-Omay EZ, Çağlayan AO, Schultz N, Weinhold N, Omay SB, Özduman K, Köksal Y, Li J, Serin Harmancı A, Clark V, Carrión-Grant G, Baranoski J, Çağlar C, Barak T, Coşkun S, Baran B, Köse D, Sun J, Bakırcıoğlu M, Moliterno Günel J, Pamir MN, Mishra-Gorur K, Bilguvar K, Yasuno K, Vortmeyer A, Huttner AJ, Sander C, Günel M. Somatic POLE mutations cause an ultramutated giant cell high-grade glioma subtype with better prognosis. Neuro-Oncology 2015, 17: 1356-1364. PMID: 25740784, PMCID: PMC4578578, DOI: 10.1093/neuonc/nov027.Peer-Reviewed Original ResearchConceptsHigh-grade gliomasSomatic POLE mutationsPOLE mutationsMalignant high-grade gliomasLonger progression-free survivalProgression-free survivalSomatic mutationsOverall survivalPediatric patientsBetter prognosisClinical featuresImproved prognosisClinical behaviorImmune cellsBizarre cellsAggressive formGlioblastoma multiformeDisease pathophysiologyMolecular subgroupsHomozygous germline mutationGermline mutationsPrognosisGlioma subtypesComprehensive genomic analysisDistinct subgroupsRecurrent somatic mutations in POLR2A define a distinct subset of meningiomas
Clark VE, Harmancı AS, Bai H, Youngblood MW, Lee TI, Baranoski JF, Ercan-Sencicek AG, Abraham BJ, Weintraub AS, Hnisz D, Simon M, Krischek B, Erson-Omay EZ, Henegariu O, Carrión-Grant G, Mishra-Gorur K, Durán D, Goldmann JE, Schramm J, Goldbrunner R, Piepmeier JM, Vortmeyer AO, Günel JM, Bilgüvar K, Yasuno K, Young RA, Günel M. Recurrent somatic mutations in POLR2A define a distinct subset of meningiomas. Nature Genetics 2016, 48: 1253-1259. PMID: 27548314, PMCID: PMC5114141, DOI: 10.1038/ng.3651.Peer-Reviewed Original ResearchCatalytic DomainChromosomes, Human, Pair 22Cohort StudiesDNA Mutational AnalysisEnhancer Elements, GeneticExomeGene Expression Regulation, NeoplasticGenotypeHumansKruppel-Like Factor 4Kruppel-Like Transcription FactorsMeningeal NeoplasmsMeningiomaMutationNeurofibromin 2RNA Polymerase IITumor Necrosis Factor Receptor-Associated Peptides and Proteins
2017
AAV-mediated direct in vivo CRISPR screen identifies functional suppressors in glioblastoma
Chow RD, Guzman CD, Wang G, Schmidt F, Youngblood MW, Ye L, Errami Y, Dong MB, Martinez MA, Zhang S, Renauer P, Bilguvar K, Gunel M, Sharp PA, Zhang F, Platt RJ, Chen S. AAV-mediated direct in vivo CRISPR screen identifies functional suppressors in glioblastoma. Nature Neuroscience 2017, 20: 1329-1341. PMID: 28805815, PMCID: PMC5614841, DOI: 10.1038/nn.4620.Peer-Reviewed Original ResearchUse of telomerase promoter mutations to mark specific molecular subsets with reciprocal clinical behavior in IDH mutant and IDH wild-type diffuse gliomas.
Akyerli CB, Yüksel Ş, Can Ö, Erson-Omay EZ, Oktay Y, Coşgun E, Ülgen E, Erdemgil Y, Sav A, von Deimling A, Günel M, Yakıcıer MC, Pamir MN, Özduman K. Use of telomerase promoter mutations to mark specific molecular subsets with reciprocal clinical behavior in IDH mutant and IDH wild-type diffuse gliomas. Journal Of Neurosurgery 2017, 128: 1102-1114. PMID: 28621624, DOI: 10.3171/2016.11.jns16973.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAdultAge FactorsAgedAged, 80 and overBrain NeoplasmsCohort StudiesDNA Mutational AnalysisFemaleGenetic MarkersGliomaHumansIsocitrate DehydrogenaseKaplan-Meier EstimateKi-67 AntigenMaleMiddle AgedMutationPromoter Regions, GeneticSurvival AnalysisTelomeraseTreatment OutcomeYoung AdultConceptsMolecular subsetsIDH-wt gliomasIDH wild-type diffuse gliomasDiffuse gliomasIDH-mut gliomasClinical behaviorTERTp-mutHigh Ki-67 labeling indexKi-67 labeling indexDouble-negative subsetObjective Recent studiesClinical tumor behaviorDifferent tumor biologySpecific molecular subsetsTERT promoter mutationsEpidermal growth factor receptorTensin homolog (PTEN) mutationsTelomerase promoter mutationsCumulative followGrowth factor receptorSurgical cohortMalignant degenerationClinical parametersHistopathological diagnosisCombined statusLongitudinal analysis of treatment-induced genomic alterations in gliomas
Erson-Omay EZ, Henegariu O, Omay SB, Harmancı AS, Youngblood MW, Mishra-Gorur K, Li J, Özduman K, Carrión-Grant G, Clark VE, Çağlar C, Bakırcıoğlu M, Pamir MN, Tabar V, Vortmeyer AO, Bilguvar K, Yasuno K, DeAngelis LM, Baehring JM, Moliterno J, Günel M. Longitudinal analysis of treatment-induced genomic alterations in gliomas. Genome Medicine 2017, 9: 12. PMID: 28153049, PMCID: PMC5290635, DOI: 10.1186/s13073-017-0401-9.Peer-Reviewed Original ResearchMeSH KeywordsAntineoplastic AgentsChromosome AberrationsCombined Modality TherapyDisease ProgressionDNA Mismatch RepairDNA Mutational AnalysisDNA, NeoplasmExomeFemaleGeneral SurgeryGenome, HumanGenomicsGlioblastomaHumansImmunotherapyLongitudinal StudiesMiddle AgedMutationNeoplasm Recurrence, LocalPrecision MedicineRadiotherapyTreatment OutcomeConceptsWhole-exome sequencingMismatch repair deficiencyImmune checkpoint inhibitionMalignant brain tumorsMolecular changesLongitudinal analysisMedian survivalCheckpoint inhibitionSubsequent recurrenceMaximal resectionStandard treatmentBackgroundGlioblastoma multiformeBrain tumorsTumor-normal pairsFavorable responsePrimary GBMIndividual tumorsConclusionsOur studyPrecision therapyPersonalized treatmentGenomic profilingRepair deficiencyGenomic alterationsGenomic profilesTherapy
2014
Autosomal recessive spastic tetraplegia caused by AP4M1 and AP4B1 gene mutation: Expansion of the facial and neuroimaging features
Tüysüz B, Bilguvar K, Koçer N, Yalçınkaya C, Çağlayan O, Gül E, Şahin S, Çomu S, Günel M. Autosomal recessive spastic tetraplegia caused by AP4M1 and AP4B1 gene mutation: Expansion of the facial and neuroimaging features. American Journal Of Medical Genetics Part A 2014, 164: 1677-1685. PMID: 24700674, DOI: 10.1002/ajmg.a.36514.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentBasic Helix-Loop-Helix Leucine Zipper Transcription FactorsBrainChildDNA Mutational AnalysisDNA-Binding ProteinsFaciesFemaleGenes, RecessiveGenetic Association StudiesHomozygoteHumansMagnetic Resonance ImagingMaleMutationNeuroimagingPedigreePhenotypeQuadriplegiaRNA-Binding ProteinsSiblingsConceptsAdaptor protein complex 4Tetraplegic cerebral palsySevere intellectual disabilitySpastic tetraplegiaCerebral palsySpastic tetraplegic cerebral palsyIntellectual disabilityStereotypic laughterCranial imaging findingsWhite matter volumeWhole-exome sequencingNovel homozygous mutationAsymmetrical ventriculomegalyCranial MRIImaging findingsClinical findingsNeuroimaging featuresBrain abnormalitiesCommon findingCorpus callosumAutosomal recessive phenotypePairs of siblingsPatientsSimilar facial featuresMatter volume
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
2008
Novel NTRK1 mutations cause hereditary sensory and autonomic neuropathy type IV: demonstration of a founder mutation in the Turkish population
Tüysüz B, Bayrakli F, DiLuna ML, Bilguvar K, Bayri Y, Yalcinkaya C, Bursali A, Ozdamar E, Korkmaz B, Mason CE, Ozturk AK, Lifton RP, State MW, Gunel M. Novel NTRK1 mutations cause hereditary sensory and autonomic neuropathy type IV: demonstration of a founder mutation in the Turkish population. Neurogenetics 2008, 9: 119-125. PMID: 18322713, DOI: 10.1007/s10048-008-0121-9.Peer-Reviewed Original ResearchConceptsNeurotrophic tyrosine kinase receptor type 1Autonomic neuropathy type IVHSAN IVHereditary sensoryNTRK1 geneTurkish populationFounder mutationType IVReceptor type 1Nerve growth factorSplice site mutationAutosomal recessive disorderCongenital insensitivityNovel frameshift mutationSame splice site mutationNTRK1 mutationsNoxious stimuliType 1Motor developmentSweat glandsGrowth factorNovel nonsense mutationRecessive disorderSpectrum of mutationsAnhidrosis
2005
Mutations in Apoptosis-related Gene, PDCD10, Cause Cerebral Cavernous Malformation 3
Guclu B, Ozturk AK, Pricola KL, Bilguvar K, Shin D, O’Roak B, Gunel M. Mutations in Apoptosis-related Gene, PDCD10, Cause Cerebral Cavernous Malformation 3. Neurosurgery 2005, 57: 1008-1013. PMID: 16284570, DOI: 10.1227/01.neu.0000180811.56157.e1.Peer-Reviewed Original ResearchCerebral Venous Malformations Have Distinct Genetic Origin From Cerebral Cavernous Malformations
Guclu B, Ozturk AK, Pricola KL, Seker A, Ozek M, Gunel M. Cerebral Venous Malformations Have Distinct Genetic Origin From Cerebral Cavernous Malformations. Stroke 2005, 36: 2479-2480. PMID: 16239636, DOI: 10.1161/01.str.0000183616.99139.d3.Peer-Reviewed Original ResearchMeSH KeywordsApoptosis Regulatory ProteinsBlood VesselsCarrier ProteinsChildDNA Mutational AnalysisExonsFamily HealthFemaleFrameshift MutationGene Expression RegulationHumansIntracranial Arteriovenous MalformationsKRIT1 ProteinMaleMembrane ProteinsMicrotubule-Associated ProteinsModels, GeneticMutationPedigreeProto-Oncogene ProteinsConceptsMutational analysisCerebral cavernous malformationsDistinct genetic originsCCM genesCerebral venous malformationSuch mutationsCausative genesUnique familyFrameshift mutationGenesGenetic originCCM1 geneCommon originMutationsFamilyVenous malformationsPathogenetic mechanismsCavernous malformationsMembersDistinct biologyPDCD10BiologyExon 19KRIT1Different pathogenetic mechanismsSequence Variants in SLITRK1 Are Associated with Tourette's Syndrome
Abelson JF, Kwan KY, O'Roak BJ, Baek DY, Stillman AA, Morgan TM, Mathews CA, Pauls DL, Rašin M, Gunel M, Davis NR, Ercan-Sencicek AG, Guez DH, Spertus JA, Leckman JF, Dure LS, Kurlan R, Singer HS, Gilbert DL, Farhi A, Louvi A, Lifton RP, Šestan N, State MW. Sequence Variants in SLITRK1 Are Associated with Tourette's Syndrome. Science 2005, 310: 317-320. PMID: 16224024, DOI: 10.1126/science.1116502.Peer-Reviewed Original ResearchMeSH Keywords3' Untranslated RegionsAdolescentAnimalsAttention Deficit Disorder with HyperactivityBrainChildChild, PreschoolChromosome InversionChromosome MappingChromosomes, Human, Pair 13DNADNA Mutational AnalysisFemaleFrameshift MutationHumansIn Situ Hybridization, FluorescenceMaleMembrane ProteinsMiceMutationNerve Tissue ProteinsPedigreeSequence Analysis, DNATourette SyndromeConceptsSequence variantsTourette syndromeChromosomal inversionsFrameshift mutantsCandidate genesExpression patternsControl chromosomesPrimary neuronal culturesFrameshift mutationSLITRK1Independent occurrenceMotor ticsDevelopmental neuropsychiatric disordersChronic vocalNeuronal culturesIdentical variantsUnrelated probandsBrain regionsNeuropsychiatric disordersSyndrome
2003
Mutational analysis of 206 families with cavernous malformations.
Laurans MS, DiLuna ML, Shin D, Niazi F, Voorhees JR, Nelson-Williams C, Johnson EW, Siegel AM, Steinberg GK, Berg MJ, Scott RM, Tedeschi G, Enevoldson TP, Anson J, Rouleau GA, Ogilvy C, Awad IA, Lifton RP, Gunel M. Mutational analysis of 206 families with cavernous malformations. Journal Of Neurosurgery 2003, 99: 38-43. PMID: 12854741, DOI: 10.3171/jns.2003.99.1.0038.Peer-Reviewed Original Research
1996
Genetic Heterogeneity of Inherited Cerebral Cavernous Malformation
Günel M, Awad I, Finberg K, Steinberg G, Craig H, Cepeda O, Nelson-Williams C, Lifton R. Genetic Heterogeneity of Inherited Cerebral Cavernous Malformation. Neurosurgery 1996, 38: 1265-1271. DOI: 10.1227/00006123-199606000-00059.Peer-Reviewed Original ResearchConceptsGenetic analysisCauses of CCMsCerebral cavernous malformationsHuman chromosome 7Second geneIndependent inheritanceMutant geneChromosome 7Genetic markersGenesLong armGenetic heterogeneityMutationsCavernous malformationsInheritanceFamilyAutosomal dominant transmissionClinical featuresGenetic testingDominant transmissionKindredsMarkersNon-Hispanic familiesMalformationsDisordersGenetic heterogeneity of inherited cerebral cavernous malformation.
Günel M, Awad I, Finberg K, Steinberg G, Craig H, Cepeda O, Carol N, Lifton R. Genetic heterogeneity of inherited cerebral cavernous malformation. Neurosurgery 1996, 38: 1265-71. PMID: 8727164, DOI: 10.1097/00006123-199606000-00059.Peer-Reviewed Original ResearchConceptsGenetic analysisCauses of CCMsCerebral cavernous malformationsHuman chromosome 7Second geneIndependent inheritanceMutant geneChromosome 7Genetic markersGenesLong armGenetic heterogeneityMutationsCavernous malformationsInheritanceFamilyAutosomal dominant transmissionClinical featuresGenetic testingDominant transmissionKindredsMarkersNon-Hispanic familiesMalformationsDisorders