2024
Exploring molecular and cellular mechanisms and phenotypic characteristics of NAGLU Arg234Gly and Asp312Asn variants
Kaymakcalan Celebiler H, Barak T, Rai D, Kaya I, Erbilgin S, Cikili Uytun M, Oztop D, Gumus H, Per H, Ceylaner S, Bozkurt I, Kontaridis M, Bilguvar K, Akhun N, Kilincaslan A, Caglayan A, Erson-Omay E, Gunel M, Ercan-Sencicek A. Exploring molecular and cellular mechanisms and phenotypic characteristics of NAGLU Arg234Gly and Asp312Asn variants. Molecular Syndromology 2024, 1-15. DOI: 10.1159/000542367.Peer-Reviewed Original ResearchWhole-exome sequencingStandard Sanger sequencingMucopolysaccharidosis type IIIBExome sequencingProgressive neurodegenerative disorderConsanguineous familySanger sequencingNAGLU genePhenotypic characteristicsMagnetic resonance imagingEnzymatic assayNeurodegenerative disordersAffected individualsLoss of activityNeurodegenerative symptomsAutosomal recessive lysosomal disorderCellular mechanismsVariantsLysosomal disorderEnzymeNormal MRI findingsSequenceMPS IIIBMRI findingsType IIIB
2023
Toward Precision Oncology in Glioblastoma with a Personalized Cancer Genome Reporting Tool and Genetic Changes Identified by Whole Exome Sequencing
Erdogan O, Özkaya Ş, Erzik C, Bilguvar K, Arga K, Bayraklı F. Toward Precision Oncology in Glioblastoma with a Personalized Cancer Genome Reporting Tool and Genetic Changes Identified by Whole Exome Sequencing. OMICS A Journal Of Integrative Biology 2023, 27: 426-433. PMID: 37669106, DOI: 10.1089/omi.2023.0117.Peer-Reviewed Original ResearchConceptsTreatment optionsWhole-exome sequencingPrecision/personalized medicineExome sequencingLimited treatment optionsGenetic alterationsPersonalized medicinePotential therapeutic targetAggressive brain tumorTumor tissue samplesPoor prognosisGBM patientsTargetable pathwaysBrain tumorsTherapeutic targetLarger studyMolecular findingsNeurosurgical oncologyGenomic profilingPatientsPersonalized therapyMolecular profilingAkt/GlioblastomaPrecision oncology169 Exome Sequencing Implicates Endothelial Ras Signaling Network in Vein of Galen Aneurysmal Malformation
Mekbib K, Zhao S, Nelson-Williams C, Prendergast A, Zeng X, Rolle M, Shohfi J, Smith H, Ocken J, Moyer Q, Piwowarczyk P, Allington G, Dong W, van der Ent M, Chen D, Li B, Duran D, Mane S, Walcott B, Stapleton C, Aagaard-Kienitz B, Rodesch G, Jackson E, Smith E, Orbach D, Berenstein A, Bilguvar K, Zhao H, Erson-Omay Z, King P, Huttner A, Lifton R, Boggon T, Nicoli S, Jin S, Kahle K. 169 Exome Sequencing Implicates Endothelial Ras Signaling Network in Vein of Galen Aneurysmal Malformation. Neurosurgery 2023, 69: 22-22. DOI: 10.1227/neu.0000000000002375_169.Peer-Reviewed Original ResearchPathway analysisP120 Ras-GAPExome sequencingSevere vascular defectsGalen aneurysmal malformationReceptor tyrosine kinase activityTyrosine kinase activityDamaging de novoMutant embryosRas-GAPSignaling networksGenetic regulationRas activationAneurysmal malformationZebrafish modelDe novo mutationsKinase activityDisease genesAxon guidanceGenetic samplesWhole-exome sequencingHigh-output heart failureFunctional studiesCollected specimensSequencing
2022
Biallelic frameshift variants in PHLDB1 cause mild-type osteogenesis imperfecta with regressive spondylometaphyseal changes
Tuysuz B, Alkaya D, Geyik F, Alaylıoğlu M, Kasap B, Kurugoğlu S, Akman Y, Vural M, Bilguvar K. Biallelic frameshift variants in PHLDB1 cause mild-type osteogenesis imperfecta with regressive spondylometaphyseal changes. Journal Of Medical Genetics 2022, 60: 819-826. PMID: 36543534, DOI: 10.1136/jmg-2022-108763.Peer-Reviewed Original ResearchConceptsOsteogenesis imperfectaWestern blot analysisPathogenic variantsFrameshift variantSkin fibroblast samplesExpression levelsInsulin-dependent Akt phosphorylationBlot analysisAutosomal recessive osteogenesis imperfectaWhole-exome sequencingMRNA expression levelsType 1 collagenBisphosphonate treatmentRecurrent fracturesClinical evaluationRecessive osteogenesis imperfectaCommon findingReal-time PCRMRNA expressionVertebral changesHeterogeneous groupAkt phosphorylationLong bonesBloodSkin fibroblastsSevere Phenotype in Patients with X-linked Hydrocephalus Caused by a Missense Mutation in L1CAM
Tuysuz B, Department of Pediatric Genetics I, Sencicek A, Ozer E, Goc N, Yalcinkaya C, Bilguvar K, Department of Neurosurgery P, Department of Neurology I. Severe Phenotype in Patients with X-linked Hydrocephalus Caused by a Missense Mutation in L1CAM. Turkish Archives Of Pediatrics 2022, 57: 521-525. PMID: 35950747, PMCID: PMC9524456, DOI: 10.5152/turkarchpediatr.2022.22070.Peer-Reviewed Original ResearchWhole-exome sequencingL1 syndromeSevere phenotypeMissense mutationsHemizygous missense mutationClinical characteristicsDifferential diagnosisIndex patientsPatientsCarrier mothersPathogenic missense mutationsMale childrenL1CAM mutationsPathogenic variantsMild formHydrocephalusSpeech delaySyndromeExon 18Truncating mutationsGenetic etiologyIntellectual disabilityL1CAML1CAM geneFamily membersMutation spectrum of congenital heart disease in a consanguineous Turkish population
Dong W, Kaymakcalan H, Jin SC, Diab NS, Tanıdır C, Yalcin ASY, Ercan‐Sencicek A, Mane S, Gunel M, Lifton RP, Bilguvar K, Brueckner M. Mutation spectrum of congenital heart disease in a consanguineous Turkish population. Molecular Genetics & Genomic Medicine 2022, 10: e1944. PMID: 35481623, PMCID: PMC9184665, DOI: 10.1002/mgg3.1944.Peer-Reviewed Original ResearchConceptsWhole-exome sequencingLaterality defectsUnique genetic architectureCongenital heart diseaseConsanguineous familyGenetic architectureCausal genesCHD genesGenome analysisHomozygous variantGenetic landscapeGenetic lesionsGenomic alterationsHeart diseaseConsanguineous populationFunction variantsRecessive variantsCHD probandsGenesType of CHDMutation spectrumStructural congenital heart diseaseVariantsCHD subjectsAdditional patientsFurther delineation of familial polycystic ovary syndrome (PCOS) via whole‐exome sequencing: PCOS‐related rare FBN3 and FN1 gene variants are identified
Karakaya C, Çil AP, Bilguvar K, Çakir T, Karalok MH, Karabacak RO, Caglayan AO. Further delineation of familial polycystic ovary syndrome (PCOS) via whole‐exome sequencing: PCOS‐related rare FBN3 and FN1 gene variants are identified. Journal Of Obstetrics And Gynaecology Research 2022, 48: 1202-1211. PMID: 35141985, PMCID: PMC9050819, DOI: 10.1111/jog.15187.Peer-Reviewed Original ResearchConceptsPolycystic ovary syndromeWhole-exome sequencingFurther functional studiesMissense variantsNew drug targetsGerm-line DNAWhole-exome sequencing dataThree-dimensional structurePolycystic ovary syndrome patientsFunctional predictionChemogenomic analysisCandidate proteinsSequencing dataBiological pathwaysDrug targetsFunctional studiesCandidate variantsSequencingPCOS familiesRotterdam criteriaOvary syndromeFBN3Syndrome patientsPathwayPCOS probands
2021
PPIL4 is essential for brain angiogenesis and implicated in intracranial aneurysms in humans
Barak T, Ristori E, Ercan-Sencicek AG, Miyagishima DF, Nelson-Williams C, Dong W, Jin SC, Prendergast A, Armero W, Henegariu O, Erson-Omay EZ, Harmancı AS, Guy M, Gültekin B, Kilic D, Rai DK, Goc N, Aguilera SM, Gülez B, Altinok S, Ozcan K, Yarman Y, Coskun S, Sempou E, Deniz E, Hintzen J, Cox A, Fomchenko E, Jung SW, Ozturk AK, Louvi A, Bilgüvar K, Connolly ES, Khokha MK, Kahle KT, Yasuno K, Lifton RP, Mishra-Gorur K, Nicoli S, Günel M. PPIL4 is essential for brain angiogenesis and implicated in intracranial aneurysms in humans. Nature Medicine 2021, 27: 2165-2175. PMID: 34887573, PMCID: PMC8768030, DOI: 10.1038/s41591-021-01572-7.Peer-Reviewed Original ResearchConceptsGenome-wide association studiesPeptidyl-prolyl cis-transPathogenesis of IAContribution of variantsCommon genetic variantsVertebrate modelDeleterious mutationsWnt activatorAssociation studiesWhole-exome sequencingSignificant enrichmentGenetic variantsWntAngiogenesis regulatorsMutationsGene mutationsBrain angiogenesisIntracranial aneurysm ruptureJMJD6AngiogenesisCerebrovascular morphologyCerebrovascular integrityIntracerebral hemorrhageAneurysm ruptureVariantsGenetic Defects in DNAH2 Underlie Male Infertility With Multiple Morphological Abnormalities of the Sperm Flagella in Humans and Mice
Hwang JY, Nawaz S, Choi J, Wang H, Hussain S, Nawaz M, Lopez-Giraldez F, Jeong K, Dong W, Oh JN, Bilguvar K, Mane S, Lee CK, Bystroff C, Lifton RP, Ahmad W, Chung JJ. Genetic Defects in DNAH2 Underlie Male Infertility With Multiple Morphological Abnormalities of the Sperm Flagella in Humans and Mice. Frontiers In Cell And Developmental Biology 2021, 9: 662903. PMID: 33968937, PMCID: PMC8103034, DOI: 10.3389/fcell.2021.662903.Peer-Reviewed Original ResearchMultiple morphological abnormalitiesMale infertility casesMorphological abnormalitiesWhole-exome sequencingIrregular flagellaInfertility casesSperm flagella formationMMAF phenotypeSevere formMale infertilityAsthenozoospermic patientsMutant miceNon-synonymous variantsAbnormalitiesRecessive variantsCellular mechanismsGenetic factorsMMAFGenetic defectsPatientsMiceHeavy chain domainSperm morphologyAsthenozoospermiaSperm motility
2020
Mutations and Copy Number Alterations in IDH Wild-Type Glioblastomas Are Shaped by Different Oncogenic Mechanisms
Ülgen E, Karacan S, Gerlevik U, Can Ö, Bilguvar K, Oktay Y, Akyerli C, Yüksel Ş, Danyeli A, Tihan T, Sezerman OU, Yakıcıer MC, Pamir MN, Özduman K. Mutations and Copy Number Alterations in IDH Wild-Type Glioblastomas Are Shaped by Different Oncogenic Mechanisms. Biomedicines 2020, 8: 574. PMID: 33297360, PMCID: PMC7762325, DOI: 10.3390/biomedicines8120574.Peer-Reviewed Original ResearchUnderlying oncogenic mechanismsOncogenic mechanismsNumber alterationsDifferent oncogenic mechanismsDiffuse midline gliomaMismatch repair deficiencySingle nucleotide variationsWhole-exome sequencingIDH wild-type glioblastomaWild-type glioblastomaPrimary tumorMolecular subsetsBlood samplesMidline gliomaAdult diffuse gliomasHeterogenous groupWt glioblastomaCopy number alterationsGliomasRecurrenceExome sequencingDiffuse gliomasRepair deficiencyAlteration frequencyGenomic alterationsExome sequencing implicates genetic disruption of prenatal neuro-gliogenesis in sporadic congenital hydrocephalus
Jin SC, Dong W, Kundishora AJ, Panchagnula S, Moreno-De-Luca A, Furey CG, Allocco AA, Walker RL, Nelson-Williams C, Smith H, Dunbar A, Conine S, Lu Q, Zeng X, Sierant MC, Knight JR, Sullivan W, Duy PQ, DeSpenza T, Reeves BC, Karimy JK, Marlier A, Castaldi C, Tikhonova IR, Li B, Peña HP, Broach JR, Kabachelor EM, Ssenyonga P, Hehnly C, Ge L, Keren B, Timberlake AT, Goto J, Mangano FT, Johnston JM, Butler WE, Warf BC, Smith ER, Schiff SJ, Limbrick DD, Heuer G, Jackson EM, Iskandar BJ, Mane S, Haider S, Guclu B, Bayri Y, Sahin Y, Duncan CC, Apuzzo MLJ, DiLuna ML, Hoffman EJ, Sestan N, Ment LR, Alper SL, Bilguvar K, Geschwind DH, Günel M, Lifton RP, Kahle KT. Exome sequencing implicates genetic disruption of prenatal neuro-gliogenesis in sporadic congenital hydrocephalus. Nature Medicine 2020, 26: 1754-1765. PMID: 33077954, PMCID: PMC7871900, DOI: 10.1038/s41591-020-1090-2.Peer-Reviewed Original ResearchConceptsCongenital hydrocephalusPoor neurodevelopmental outcomesPost-surgical patientsCerebrospinal fluid accumulationNeural stem cell biologyGenetic disruptionWhole-exome sequencingPrimary pathomechanismEarly brain developmentNeurodevelopmental outcomesHigh morbidityCSF diversionMutation burdenFluid accumulationBrain ventriclesCH casesBrain developmentDe novo mutationsPatientsExome sequencingCSF dynamicsDisease mechanismsHydrocephalusNovo mutationsCell typesMutations 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
2019
Whole-exome sequencing of cervical carcinomas identifies activating ERBB2 and PIK3CA mutations as targets for combination therapy
Zammataro L, Lopez S, Bellone S, Pettinella F, Bonazzoli E, Perrone E, Zhao S, Menderes G, Altwerger G, Han C, Zeybek B, Bianchi A, Manzano A, Manara P, Cocco E, Buza N, Hui P, Wong S, Ravaggi A, Bignotti E, Romani C, Todeschini P, Zanotti L, Odicino F, Pecorelli S, Donzelli C, Ardighieri L, Angioli R, Raspagliesi F, Scambia G, Choi J, Dong W, Bilguvar K, Alexandrov LB, Silasi DA, Huang GS, Ratner E, Azodi M, Schwartz PE, Pirazzoli V, Stiegler AL, Boggon TJ, Lifton RP, Schlessinger J, Santin AD. Whole-exome sequencing of cervical carcinomas identifies activating ERBB2 and PIK3CA mutations as targets for combination therapy. Proceedings Of The National Academy Of Sciences Of The United States Of America 2019, 116: 22730-22736. PMID: 31624127, PMCID: PMC6842590, DOI: 10.1073/pnas.1911385116.Peer-Reviewed Original ResearchConceptsPI3K/AKT/mTOR pathwaySquamous cell carcinomaWhole-exome sequencingAKT/mTOR pathwayPrimary cervical cancer cell linesPIK3CA inhibitorsRecurrent cervical cancer patientsMTOR pathwayCombination of copanlisibCervical cancer patientsPI3K/Akt/mTORCervical cancer xenograftsRegression of tumorsCervical cancer cell linesCervical tumor cell linesSingle nucleotide variantsWild-type tumorsRecurrent somatic missense mutationsAkt/mTORCell linesPan-HERCancer cell linesTypes 16/18Cervical cancerCancer patientsIdentification of a dominant MYH11 causal variant in chronic intestinal pseudo‐obstruction: Results of whole‐exome sequencing
Dong W, Baldwin C, Choi J, Milunsky JM, Zhang J, Bilguvar K, Lifton RP, Milunsky A. Identification of a dominant MYH11 causal variant in chronic intestinal pseudo‐obstruction: Results of whole‐exome sequencing. Clinical Genetics 2019, 96: 473-477. PMID: 31389005, DOI: 10.1111/cge.13617.Peer-Reviewed Original ResearchConceptsChronic Intestinal Pseudo-ObstructionSmooth muscle actin geneMuscle actin geneAdditional genetic evidenceGene burden analysisIntestinal Pseudo-ObstructionRare gastrointestinal disorderSmooth muscle contractionActin geneMyosin genesAdditional genesGenetic evidenceCausal variantsWhole-exome sequencingFamily membersCIPO patientsPseudo-ObstructionGenetic linkageGastrointestinal disordersDominant mutationsGenesUnaffected family membersGastrointestinal tractRare mutationsMuscle contraction
2018
Genotype–phenotype investigation of 35 patients from 11 unrelated families with camptodactyly–arthropathy–coxa vara–pericarditis (CACP) syndrome
Yilmaz S, Alkaya D, Kasapçopur Ö, Barut K, Akdemir ES, Celen C, Youngblood MW, Yasuno K, Bilguvar K, Günel M, Tüysüz B. Genotype–phenotype investigation of 35 patients from 11 unrelated families with camptodactyly–arthropathy–coxa vara–pericarditis (CACP) syndrome. Molecular Genetics & Genomic Medicine 2018, 6: 230-248. PMID: 29397575, PMCID: PMC5902402, DOI: 10.1002/mgg3.364.Peer-Reviewed Original ResearchConceptsCoxa vara-pericarditis (CACP) syndromeCoxa varaCommon childhood rheumatic diseaseIncreased pain levelSevere hip involvementChildhood rheumatic diseasesJuvenile idiopathic arthritisDevelopmental coxa varaRare autosomal recessive conditionYears of ageUnrelated familiesWhole-exome sequencingAutosomal recessive conditionHip involvementIdiopathic arthritisMost patientsPain levelsRadiological findingsPleural effusionJoint involvementNoninflammatory arthropathyRheumatic diseasesNovel genomic alterationsFirst symptomsCACP syndrome
2017
GABBR2 mutations determine phenotype in rett syndrome and epileptic encephalopathy
Yoo Y, Jung J, Lee Y, Lee Y, Cho H, Na E, Hong J, Kim E, Lee JS, Lee JS, Hong C, Park S, Wie J, Miller K, Shur N, Clow C, Ebel RS, DeBrosse SD, Henderson LB, Willaert R, Castaldi C, Tikhonova I, Bilgüvar K, Mane S, Kim KJ, Hwang YS, Lee S, So I, Lim BC, Choi H, Seong JY, Shin YB, Jung H, Chae J, Choi M. GABBR2 mutations determine phenotype in rett syndrome and epileptic encephalopathy. Annals Of Neurology 2017, 82: 466-478. PMID: 28856709, DOI: 10.1002/ana.25032.Peer-Reviewed Original ResearchConceptsRett syndromeGenetic factorsAppropriate medical interventionΓ-aminobutyric acid signalingDistinct diagnostic criteriaDevastating neurodevelopmental disorderWhole-exome sequencingAnn NeurolClinical featuresEE patientsEpileptic encephalopathyDe novo variantsNovel genetic factorsDiagnostic criteriaAnimal modelsMedical interventionsAccurate diagnosisReceptor activityReceptor functionSpecific molecular mechanismsPatientsRTT-like patientsNeurodevelopmental disordersNovo variantsMECP2 mutationsALPK3 gene mutation in a patient with congenital cardiomyopathy and dysmorphic features
Çağlayan AO, Sezer RG, Kaymakçalan H, Ulgen E, Yavuz T, Baranoski JF, Bozaykut A, Harmanci AS, Yalcin Y, Youngblood MW, Yasuno K, Bilgüvar K, Gunel M. ALPK3 gene mutation in a patient with congenital cardiomyopathy and dysmorphic features. Molecular Case Studies 2017, 3: a001859. PMID: 28630369, PMCID: PMC5593152, DOI: 10.1101/mcs.a001859.Peer-Reviewed Original ResearchConceptsNovel homozygous frameshift mutationWk of gestationHomozygous pathogenic variantNovel disease-causing genesPhenotypic featuresHomozygous frameshift mutationWhole-exome sequencingHeterozygous family membersUnrelated consanguineous familiesEchocardiographic examinationDisease groupPrimary cardiomyopathyMale infantHypertrophic cardiomyopathyRoutine diagnostic toolCardiac diseaseCardiac abnormalitiesMale fetusesCardiomyopathyPathogenic variantsGenetic testingDysmorphic featuresGene mutationsPast historyDisease-causing genesLongitudinal 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
2016
Mutational landscape of uterine and ovarian carcinosarcomas implicates histone genes in epithelial–mesenchymal transition
Zhao S, Bellone S, Lopez S, Thakral D, Schwab C, English DP, Black J, Cocco E, Choi J, Zammataro L, Predolini F, Bonazzoli E, Bi M, Buza N, Hui P, Wong S, Abu-Khalaf M, Ravaggi A, Bignotti E, Bandiera E, Romani C, Todeschini P, Tassi R, Zanotti L, Odicino F, Pecorelli S, Donzelli C, Ardighieri L, Facchetti F, Falchetti M, Silasi DA, Ratner E, Azodi M, Schwartz PE, Mane S, Angioli R, Terranova C, Quick CM, Edraki B, Bilgüvar K, Lee M, Choi M, Stiegler AL, Boggon TJ, Schlessinger J, Lifton RP, Santin AD. Mutational landscape of uterine and ovarian carcinosarcomas implicates histone genes in epithelial–mesenchymal transition. Proceedings Of The National Academy Of Sciences Of The United States Of America 2016, 113: 12238-12243. PMID: 27791010, PMCID: PMC5087050, DOI: 10.1073/pnas.1614120113.Peer-Reviewed Original ResearchMeSH KeywordsAgedAged, 80 and overCarcinosarcomaClass I Phosphatidylinositol 3-KinasesDNA-Binding ProteinsEpithelial-Mesenchymal TransitionFemaleGene Expression Regulation, NeoplasticHistonesHumansMiddle AgedMutationOvarian NeoplasmsPTEN PhosphohydrolaseTelomeraseTumor Suppressor Protein p53Uterine NeoplasmsConceptsEpithelial-mesenchymal transitionWhole-exome sequencingHistone gene clusterMutational landscapeStable transgenic expressionExcess of mutationsMultiregion whole-exome sequencingHistone genesEvolutionary historyPhylogenetic relationshipsGene clusterHistone H2AChromosome segmentsSeparate lineagesCancer genesGenetic landscapeUterine serous carcinoma cell linesTransgenic expressionGenesCarcinoma cell linesGene TP53Frequent amplificationFrequent deletionsChromosome 6pInvasive propertiesFamilial occurrence of brain arteriovenous malformation: a novel ACVRL1 mutation detected by whole exome sequencing.
Yılmaz B, Toktaş ZO, Akakın A, Işık S, Bilguvar K, Kılıç T, Günel M. Familial occurrence of brain arteriovenous malformation: a novel ACVRL1 mutation detected by whole exome sequencing. Journal Of Neurosurgery 2016, 126: 1879-1883. PMID: 27611203, DOI: 10.3171/2016.6.jns16665.Peer-Reviewed Original ResearchConceptsBrain arteriovenous malformationsHereditary hemorrhagic telangiectasiaWhole-exome sequencingArteriovenous malformationsExome sequencingWhole-exome sequencing analysisSpinal arteriovenous malformationsDiagnostic classification schemesExome sequencing analysisComprehensive genomic characterizationConclusion Study resultsCranial MRIDirect Sanger sequencingHemorrhagic telangiectasiaBlood samplesFamilial occurrenceHeterozygous mutationsACVRL1 mutationsPatientsThree SiblingsFourth siblingVariant segregationSanger sequencingMalformationsSiblings