2022
Loss of IRF2BPL impairs neuronal maintenance through excess Wnt signaling
Marcogliese P, Dutta D, Ray S, Dang N, Zuo Z, Wang Y, Lu D, Fazal F, Ravenscroft T, Chung H, Kanca O, Wan J, Douine E, Network U, Pena L, Yamamoto S, Nelson S, Might M, Meyer K, Yeo N, Bellen H. Loss of IRF2BPL impairs neuronal maintenance through excess Wnt signaling. Science Advances 2022, 8: eabl5613. PMID: 35044823, PMCID: PMC8769555, DOI: 10.1126/sciadv.abl5613.Peer-Reviewed Original ResearchConceptsAxonal lossPatient-derived astrocytesChildhood-onset neurodegenerative disordersNeuronal depletionNeural dysfunctionNeuronal expressionNeurological defectsPharmacological inhibitionNeurodegenerative disordersNeuronal maintenanceNeurological phenotypeWnt antagonistsDownstream signalingIRF2BPLBinding proteinInhibitionWntSignalingWnt transcriptionAstrocytesDysfunctionAntagonistBrain
2018
IRF2BPL Is Associated with Neurological Phenotypes
Marcogliese P, Shashi V, Spillmann R, Stong N, Rosenfeld J, Koenig M, Martínez-Agosto J, Herzog M, Chen A, Dickson P, Lin H, Vera M, Salamon N, Graham J, Ortiz D, Infante E, Steyaert W, Dermaut B, Poppe B, Chung H, Zuo Z, Lee P, Kanca O, Xia F, Yang Y, Smith E, Jasien J, Kansagra S, Spiridigliozzi G, El-Dairi M, Lark R, Riley K, Koeberl D, Golden-Grant K, Diseases P, Callens S, Coucke P, Dermaut B, Hemelsoet D, Poppe B, Steyaert W, Terryn W, Van Coster R, Network U, Adams D, Alejandro M, Allard P, Azamian M, Bacino C, Balasubramanyam A, Barseghyan H, Batzli G, Beggs A, Behnam B, Bican A, Bick D, Birch C, Bonner D, Boone B, Bostwick B, Briere L, Brown D, Brush M, Burke E, Burrage L, Chen S, Clark G, Coakley T, Cogan J, Cooper C, Cope H, Craigen W, D’Souza P, Davids M, Dayal J, Dell’Angelica E, Dhar S, Dillon A, Dipple K, Donnell-Fink L, Dorrani N, Dorset D, Douine E, Draper D, Eckstein D, Emrick L, Eng C, Eskin A, Esteves C, Estwick T, Ferreira C, Fogel B, Friedman N, Gahl W, Glanton E, Godfrey R, Goldstein D, Gould S, Gourdine J, Groden C, Gropman A, Haendel M, Hamid R, Hanchard N, Handley L, Herzog M, Holm I, Hom J, Howerton E, Huang Y, Jacob H, Jain M, Jiang Y, Johnston J, Jones A, Kohane I, Krasnewich D, Krieg E, Krier J, Lalani S, Lau C, Lazar J, Lee B, Lee H, Levy S, Lewis R, Lincoln S, Lipson A, Loo S, Loscalzo J, Maas R, Macnamara E, MacRae C, Maduro V, Majcherska M, Malicdan M, Mamounas L, Manolio T, Markello T, Marom R, Martínez-Agosto J, Marwaha S, May T, McConkie-Rosell A, McCormack C, McCray A, Might M, Moretti P, Morimoto M, Mulvihill J, Murphy J, Muzny D, Nehrebecky M, Nelson S, Newberry J, Newman J, Nicholas S, Novacic D, Orange J, Pallais J, Palmer C, Papp J, Parker N, Pena L, Phillips J, Posey J, Postlethwait J, Potocki L, Pusey B, Reuter C, Robertson A, Rodan L, Rosenfeld J, Sampson J, Samson S, Schoch K, Schroeder M, Scott D, Sharma P, Shashi V, Signer R, Silverman E, Sinsheimer J, Smith K, Spillmann R, Splinter K, Stoler J, Stong N, Sullivan J, Sweetser D, Tifft C, Toro C, Tran A, Urv T, Valivullah Z, Vilain E, Vogel T, Wahl C, Walley N, Walsh C, Ward P, Waters K, Westerfield M, Wise A, Wolfe L, Worthey E, Yamamoto S, Yang Y, Yu G, Zastrow D, Zheng A, Yamamoto S, Wangler M, Mirzaa G, Hemelsoet D, Lee B, Nelson S, Goldstein D, Bellen H, Pena L. IRF2BPL Is Associated with Neurological Phenotypes. American Journal Of Human Genetics 2018, 103: 245-260. PMID: 30057031, PMCID: PMC6081494, DOI: 10.1016/j.ajhg.2018.07.006.Peer-Reviewed Original ResearchMissense variantsRange of phenotypesNeurological phenotypeProper neuronal functionNonsense variantPopulation genomicsModel organismsTranscriptional regulatorsFunction allelesPartial knockdownEctopic expressionRNA interferenceNonsense allelesBiological functionsMendelian diseasesDamaging heterozygous variantsGenesIRF2BPLNeuronal functionPhenotypeAdditional individualsComplete lossNervous systemMild phenotypeAlleles
2017
Clinically severe CACNA1A alleles affect synaptic function and neurodegeneration differentially
Luo X, Rosenfeld J, Yamamoto S, Harel T, Zuo Z, Hall M, Wierenga K, Pastore M, Bartholomew D, Delgado M, Rotenberg J, Lewis R, Emrick L, Bacino C, Eldomery M, Coban Akdemir Z, Xia F, Yang Y, Lalani S, Lotze T, Lupski J, Lee B, Bellen H, Wangler M, . Clinically severe CACNA1A alleles affect synaptic function and neurodegeneration differentially. PLOS Genetics 2017, 13: e1006905. PMID: 28742085, PMCID: PMC5557584, DOI: 10.1371/journal.pgen.1006905.Peer-Reviewed Original ResearchMeSH KeywordsAllelesAnimalsAnimals, Genetically ModifiedCalcium ChannelsCerebellar AtaxiaChildChild, PreschoolDrosophila melanogasterFemaleGenome-Wide Association StudyGenome, HumanHumansMaleMicroscopy, Electron, TransmissionMutation, MissenseNeurodegenerative DiseasesNeuroimagingPhenotypePoint MutationConceptsNeurodegenerative phenotypeGenomic rescue constructsS4 transmembrane segmentRescue constructTransmembrane segmentsFunction phenotypesLoss of functionMissense allelesFunction allelesWild typeGlobal developmental delayToxic gainMutant clonesDominant mutationsDevelopmental delayPoint mutationsDrosophilaFunctional impactPhenotypeQ-type voltage-dependent Ca2Early-onset developmental delayNeurological phenotypeAllelesSynaptic functionNovel variants
This site is protected by hCaptcha and its Privacy Policy and Terms of Service apply