2022
Quantifying concordant genetic effects of de novo mutations on multiple disorders
Guo H, Hou L, Shi Y, Jin SC, Zeng X, Li B, Lifton R, Brueckner M, Zhao H, Lu Q. Quantifying concordant genetic effects of de novo mutations on multiple disorders. ELife 2022, 11: e75551. PMID: 35666111, PMCID: PMC9217133, DOI: 10.7554/elife.75551.Peer-Reviewed Original Research
2021
Molecular Genetics and Complex Inheritance of Congenital Heart Disease
Diab NS, Barish S, Dong W, Zhao S, Allington G, Yu X, Kahle KT, Brueckner M, Jin SC. Molecular Genetics and Complex Inheritance of Congenital Heart Disease. Genes 2021, 12: 1020. PMID: 34209044, PMCID: PMC8307500, DOI: 10.3390/genes12071020.Peer-Reviewed Original ResearchConceptsHigh-throughput genomic technologiesHigh-throughput sequencingGenetic architectureCHD familyGenetic variationSophisticated analysis strategiesCilia genesComplex inheritancePathway genesDe novo mutationsGenomic technologiesCauses of CHDMolecular geneticsBiological pathwaysMolecular diagnosisNumber variationsVEGF pathway genesGenesChromatinMutationsNovo mutationsGenetic etiologyTransmitted mutationsGenetic explanationSequencing
2020
De novo damaging variants associated with congenital heart diseases contribute to the connectome
Ji W, Ferdman D, Copel J, Scheinost D, Shabanova V, Brueckner M, Khokha MK, Ment LR. De novo damaging variants associated with congenital heart diseases contribute to the connectome. Scientific Reports 2020, 10: 7046. PMID: 32341405, PMCID: PMC7184603, DOI: 10.1038/s41598-020-63928-2.Peer-Reviewed Original ResearchMeSH KeywordsConnectomeDNA HelicasesDNA-Binding ProteinsExomeFemaleHeart Defects, CongenitalHistone-Lysine N-MethyltransferaseHomeodomain ProteinsHumansMaleMi-2 Nucleosome Remodeling and Deacetylase ComplexMutationMutation, MissenseMyeloid-Lymphoid Leukemia ProteinNerve Tissue ProteinsProtein Tyrosine Phosphatase, Non-Receptor Type 11Receptor, Notch1ConceptsDe novo variantsNDD genesCardiac patterningDe novo damaging variantsDamaging de novo variantsCHD genesDamaging variantsGenesProtein truncatingGenetic originNovo variantsGene mutationsPatterningRecent studiesDendritic developmentVariantsMutationsNeurogenesisSynaptogenesisBonferroni correction
2015
De novo mutations in congenital heart disease with neurodevelopmental and other congenital anomalies
Homsy J, Zaidi S, Shen Y, Ware JS, Samocha KE, Karczewski KJ, DePalma SR, McKean D, Wakimoto H, Gorham J, Jin SC, Deanfield J, Giardini A, Porter GA, Kim R, Bilguvar K, López-Giráldez F, Tikhonova I, Mane S, Romano-Adesman A, Qi H, Vardarajan B, Ma L, Daly M, Roberts AE, Russell MW, Mital S, Newburger JW, Gaynor JW, Breitbart RE, Iossifov I, Ronemus M, Sanders SJ, Kaltman JR, Seidman JG, Brueckner M, Gelb BD, Goldmuntz E, Lifton RP, Seidman CE, Chung WK. De novo mutations in congenital heart disease with neurodevelopmental and other congenital anomalies. Science 2015, 350: 1262-1266. PMID: 26785492, PMCID: PMC4890146, DOI: 10.1126/science.aac9396.Peer-Reviewed Original ResearchConceptsCongenital anomaliesNeurodevelopmental disabilitiesCongenital heart disease patientsDe novo mutationsExtracardiac congenital anomaliesImproved prognostic assessmentEarly therapeutic interventionHeart disease patientsCongenital heart diseaseNovo mutationsCHD patientsDisease patientsHeart diseasePrognostic assessmentCHD casesTherapeutic interventionsPatientsExome sequencingCHDParent-offspring triosMultiple mutationsGenetic contributionMutationsChromatin modificationsTranscriptional regulation
2013
De novo mutations in histone-modifying genes in congenital heart disease
Zaidi S, Choi M, Wakimoto H, Ma L, Jiang J, Overton JD, Romano-Adesman A, Bjornson RD, Breitbart RE, Brown KK, Carriero NJ, Cheung YH, Deanfield J, DePalma S, Fakhro KA, Glessner J, Hakonarson H, Italia MJ, Kaltman JR, Kaski J, Kim R, Kline JK, Lee T, Leipzig J, Lopez A, Mane SM, Mitchell LE, Newburger JW, Parfenov M, Pe’er I, Porter G, Roberts AE, Sachidanandam R, Sanders SJ, Seiden HS, State MW, Subramanian S, Tikhonova IR, Wang W, Warburton D, White PS, Williams IA, Zhao H, Seidman JG, Brueckner M, Chung WK, Gelb BD, Goldmuntz E, Seidman CE, Lifton RP. De novo mutations in histone-modifying genes in congenital heart disease. Nature 2013, 498: 220-223. PMID: 23665959, PMCID: PMC3706629, DOI: 10.1038/nature12141.Peer-Reviewed Original Research
2001
Cilia propel the embryo in the right direction
Brueckner M. Cilia propel the embryo in the right direction. American Journal Of Medical Genetics 2001, 101: 339-344. PMID: 11471157, DOI: 10.1002/1096-8628(20010715)101:4<339::aid-ajmg1442>3.0.co;2-p.Peer-Reviewed Original Research
2000
Of mice and men: Dissecting the genetic pathway that controls left‐right asymmetry in mice and humans
Schneider H, Brueckner M. Of mice and men: Dissecting the genetic pathway that controls left‐right asymmetry in mice and humans. American Journal Of Medical Genetics 2000, 97: 258-270. PMID: 11376437, DOI: 10.1002/1096-8628(200024)97:4<258::aid-ajmg1276>3.0.co;2-8.Peer-Reviewed Original ResearchMeSH KeywordsAbnormalities, MultipleAnimalsBody PatterningCiliaDyneinsEctodermEmbryonic and Fetal DevelopmentEndodermFetal ProteinsGastrulaGene Expression Regulation, DevelopmentalGenesGenes, HomeoboxGenes, LethalHomeodomain ProteinsHumansKinesinsMiceMice, Mutant StrainsMutationNotochordPhenotypeSpecies SpecificityTranscription FactorsConceptsLeft-right asymmetrySpontaneous mouse mutationGenetic pathwaysHuman homologueMouse mutationNode monociliaHuman mutationsHuman phenotypesFinal phenotypeOrchestrated mannerPathways resultsMouse phenotypeGenesLaterality determinationMutationsPhenotypeModel systemDifferent stepsMonociliaHomologuesCombination of analysisMicePathwayHuman developmentInitial asymmetry
1998
Handed asymmetry in the mouse: Understanding how things go right (or left) by studying how they go wrong
Supp D, Brueckner M, Potter S. Handed asymmetry in the mouse: Understanding how things go right (or left) by studying how they go wrong. Seminars In Cell And Developmental Biology 1998, 9: 77-87. PMID: 9572117, DOI: 10.1006/scdb.1997.0186.Peer-Reviewed Original ResearchConceptsSevere morphological defectsAnalysis of genesAsymmetric expression patternLeft/right axisRight patterningGenetic pathwaysMouse mutationExpression patternsMorphological defectsDevelopmental asymmetryVertebratesImportance of regulationMutant micePattern formationRight axisGenesMutationsRegulationPathwayPatterningMiceDisruption
1992
Duplication/deficiency mapping of situs inversus viscerum (iv), a gene that determines left-right asymmetry in the mouse
McGrath J, Horwich A, Brueckner M. Duplication/deficiency mapping of situs inversus viscerum (iv), a gene that determines left-right asymmetry in the mouse. Genomics 1992, 14: 643-648. PMID: 1427890, DOI: 10.1016/s0888-7543(05)80163-6.Peer-Reviewed Original ResearchConceptsDistal mouse chromosome 12Distal chromosome 12Mouse chromosome 12Deficiency mappingChromosome 12Trisomic progenyLeft-right body axisGenetic map locationDerivative chromosomesLeft-right asymmetryDuplication analysisTelomeric regionsMap locationChromosomal regionsGene complexChromosome 5Recessive mutationsBody axisGenetic linkageNormal copyProximal regionProgenyChromosomesMutationsReciprocal translocation