2021
The genetic structure of the Turkish population reveals high levels of variation and admixture
Kars ME, Başak AN, Onat OE, Bilguvar K, Choi J, Itan Y, Çağlar C, Palvadeau R, Casanova JL, Cooper DN, Stenson PD, Yavuz A, Buluş H, Günel M, Friedman JM, Özçelik T. The genetic structure of the Turkish population reveals high levels of variation and admixture. Proceedings Of The National Academy Of Sciences Of The United States Of America 2021, 118: e2026076118. PMID: 34426522, PMCID: PMC8433500, DOI: 10.1073/pnas.2026076118.Peer-Reviewed Original ResearchConceptsGenetic structureTR populationGenome-wide association studiesRuns of homozygosityGenomes Project populationsHigh inbreeding coefficientsDisease gene discoveryHigh-quality haplotypesPotential medical relevanceGene discoveryExtensive admixturePhenotypic consequencesWhole genomeGenetic basisInbreeding coefficientSpecific genesRare rangeGenome variantsAssociation studiesGenetic relationshipsFunctional consequencesWhole exomeSpecific phenotypesGenotype imputationMedical relevance
2020
Alternative genomic diagnoses for individuals with a clinical diagnosis of Dubowitz syndrome
Dyment DA, O'Donnell‐Luria A, Agrawal PB, Akdemir Z, Aleck KA, Antaki D, Al Sharhan H, Au P, Aydin H, Beggs AH, Bilguvar K, Boerwinkle E, Brand H, Brownstein CA, Buyske S, Chodirker B, Choi J, Chudley AE, Clericuzio CL, Cox GF, Curry C, de Boer E, de Vries B, Dunn K, Dutmer CM, England EM, Fahrner JA, Geckinli BB, Genetti CA, Gezdirici A, Gibson WT, Gleeson JG, Greenberg CR, Hall A, Hamosh A, Hartley T, Jhangiani SN, Karaca E, Kernohan K, Lauzon JL, Lewis MES, Lowry RB, López‐Giráldez F, Matise TC, McEvoy‐Venneri J, McInnes B, Mhanni A, Minaur S, Moilanen J, Nguyen A, Nowaczyk MJM, Posey JE, Õunap K, Pehlivan D, Pajusalu S, Penney LS, Poterba T, Prontera P, Doriqui MJR, Sawyer SL, Sobreira N, Stanley V, Torun D, Wargowski D, Witmer PD, Wong I, Xing J, Zaki MS, Zhang Y, Consortium C, Genomics C, Boycott KM, Bamshad MJ, Nickerson DA, Blue EE, Innes AM. Alternative genomic diagnoses for individuals with a clinical diagnosis of Dubowitz syndrome. American Journal Of Medical Genetics Part A 2020, 185: 119-133. PMID: 33098347, PMCID: PMC8197629, DOI: 10.1002/ajmg.a.61926.Peer-Reviewed Original ResearchConceptsGenome sequencingExtensive locus heterogeneityCopy number variationsGenomic analysisMolecular diagnosisSingle geneDe novo variantsNext-generation sequencingDisease genesWide sequencingGenesGenomic diagnosisLocus heterogeneityNovo variantsSequencingPhenotypeAdditional familiesBiallelic variantsHDAC8FamilyVariant filteringDistinctive facial appearanceClinical phenotypeVariantsUncertain significanceMutations disrupting neuritogenesis genes confer risk for cerebral palsy
Jin SC, Lewis SA, Bakhtiari S, Zeng X, Sierant MC, Shetty S, Nordlie SM, Elie A, Corbett MA, Norton BY, van Eyk CL, Haider S, Guida BS, Magee H, Liu J, Pastore S, Vincent JB, Brunstrom-Hernandez J, Papavasileiou A, Fahey MC, Berry JG, Harper K, Zhou C, Zhang J, Li B, Zhao H, Heim J, Webber DL, Frank MSB, Xia L, Xu Y, Zhu D, Zhang B, Sheth AH, Knight JR, Castaldi C, Tikhonova IR, López-Giráldez F, Keren B, Whalen S, Buratti J, Doummar D, Cho M, Retterer K, Millan F, Wang Y, Waugh JL, Rodan L, Cohen JS, Fatemi A, Lin AE, Phillips JP, Feyma T, MacLennan SC, Vaughan S, Crompton KE, Reid SM, Reddihough DS, Shang Q, Gao C, Novak I, Badawi N, Wilson YA, McIntyre SJ, Mane SM, Wang X, Amor DJ, Zarnescu DC, Lu Q, Xing Q, Zhu C, Bilguvar K, Padilla-Lopez S, Lifton RP, Gecz J, MacLennan AH, Kruer MC. Mutations disrupting neuritogenesis genes confer risk for cerebral palsy. Nature Genetics 2020, 52: 1046-1056. PMID: 32989326, PMCID: PMC9148538, DOI: 10.1038/s41588-020-0695-1.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBeta CateninCerebral PalsyCyclin DCytoskeletonDrosophilaExomeExome SequencingExtracellular MatrixF-Box ProteinsFemaleFocal AdhesionsGenetic Predisposition to DiseaseGenome, HumanHumansMaleMutationNeuritesRhoB GTP-Binding ProteinRisk FactorsSequence Analysis, DNASignal TransductionTubulinTumor Suppressor ProteinsConceptsDamaging de novo mutationsCerebral palsyDe novo mutationsCerebral palsy casesRisk genesDamaging de novoNovo mutationsWhole-exome sequencingPalsy casesNeuromotor functionD levelsMonogenic etiologyCyclin D levelsNeuronal connectivityPalsyGene confer riskConfer riskRecessive variantsNeurodevelopmental disorder genesReverse genetic screenDisorder genesParent-offspring triosGenome-wide significanceGenomic factorsCytoskeleton pathway
2018
Biallelic loss of human CTNNA2, encoding αN-catenin, leads to ARP2/3 complex overactivity and disordered cortical neuronal migration
Schaffer AE, Breuss MW, Caglayan AO, Al-Sanaa N, Al-Abdulwahed HY, Kaymakçalan H, Yılmaz C, Zaki MS, Rosti RO, Copeland B, Baek ST, Musaev D, Scott EC, Ben-Omran T, Kariminejad A, Kayserili H, Mojahedi F, Kara M, Cai N, Silhavy JL, Elsharif S, Fenercioglu E, Barshop BA, Kara B, Wang R, Stanley V, James KN, Nachnani R, Kalur A, Megahed H, Incecik F, Danda S, Alanay Y, Faqeih E, Melikishvili G, Mansour L, Miller I, Sukhudyan B, Chelly J, Dobyns WB, Bilguvar K, Jamra RA, Gunel M, Gleeson JG. Biallelic loss of human CTNNA2, encoding αN-catenin, leads to ARP2/3 complex overactivity and disordered cortical neuronal migration. Nature Genetics 2018, 50: 1093-1101. PMID: 30013181, PMCID: PMC6072555, DOI: 10.1038/s41588-018-0166-0.Peer-Reviewed Original ResearchConceptsNeuronal migrationHuman cerebral cortexCortical neuronal migrationΒ-catenin signalingCerebral cortexPotential disease mechanismsDevelopmental brain defectsBiallelic truncating mutationsNeuronal phenotypeBiallelic lossBrain defectsBiallelic mutationsTruncating mutationsDisease mechanismsΒ-cateninPachygyriaRecessive formNeurite stabilityNeuronsFamily membersCTNNA2OveractivityPatients
2017
Longitudinal 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
2009
The syndrome of pachygyria, mental retardation, and arachnoid cysts maps to 11p15
Bilguvar K, Ozturk AK, Bayrakli F, Guzel A, DiLuna ML, Bayri Y, Tatli M, Tekes S, Arlier Z, Yasuno K, Mason CE, Lifton RP, State MW, Gunel M. The syndrome of pachygyria, mental retardation, and arachnoid cysts maps to 11p15. American Journal Of Medical Genetics Part A 2009, 149A: 2569-2572. PMID: 19876906, DOI: 10.1002/ajmg.a.33063.Peer-Reviewed Original ResearchAbnormalities, MultipleArachnoid CystsBlood Specimen CollectionChromosome MappingChromosomes, Human, Pair 11DNADNA Copy Number VariationsFamilyFemaleGenome, HumanGenome-Wide Association StudyGenotypeHomozygoteHumansIntellectual DisabilityLissencephalyLod ScoreMalePedigreePhenotypePolymorphism, Single NucleotideSyndrome