2021
Severe multisystem pathology, metabolic acidosis, mitochondrial dysfunction, and early death associated with an X-linked AIFM1 variant
Moss T, May M, Flanagan-Steet H, Caylor R, Jiang YH, McDonald M, Friez M, McConkie-Rosell A, Steet R. Severe multisystem pathology, metabolic acidosis, mitochondrial dysfunction, and early death associated with an X-linked AIFM1 variant. Molecular Case Studies 2021, 7: a006081. PMID: 34117073, PMCID: PMC8208043, DOI: 10.1101/mcs.a006081.Peer-Reviewed Original ResearchConceptsMitochondrial flavin adenine dinucleotideCaspase-independent typeRespiratory complex assemblyFunctional studiesApoptosis inducer staurosporineGalactose-containing mediumNicotinamide adenine dinucleotide (phosphate) oxidoreductaseApoptotic stimuliSteady-state levelsComplex assemblyGene productsReactive oxygen speciesMitochondrial deficiencyTissue-specific effectsNuclear condensationFlavin adenine dinucleotideReduced abundanceMitochondrial complexesComplex IPyruvate dehydrogenaseMitochondrial dysfunctionPatient cellsExome sequencingOxygen speciesElevated sensitivity
2019
De Novo Missense Variants in FBXW11 Cause Diverse Developmental Phenotypes Including Brain, Eye, and Digit Anomalies
Holt RJ, Young RM, Crespo B, Ceroni F, Curry CJ, Bellacchio E, Bax DA, Ciolfi A, Simon M, Fagerberg CR, van Binsbergen E, De Luca A, Memo L, Dobyns WB, Mohammed AA, Clokie SJH, Seco C, Jiang YH, Sørensen KP, Andersen H, Sullivan J, Powis Z, Chassevent A, Smith-Hicks C, Petrovski S, Antoniadi T, Shashi V, Gelb BD, Wilson SW, Gerrelli D, Tartaglia M, Chassaing N, Calvas P, Ragge NK. De Novo Missense Variants in FBXW11 Cause Diverse Developmental Phenotypes Including Brain, Eye, and Digit Anomalies. American Journal Of Human Genetics 2019, 105: 640-657. PMID: 31402090, PMCID: PMC6731360, DOI: 10.1016/j.ajhg.2019.07.005.Peer-Reviewed Original ResearchConceptsF-box (SCF) ubiquitin ligase complexF-box proteinsMultiple developmental processesPectoral fin developmentSubstrate-binding domainUbiquitin ligase complexGli transcription factorsHuman developmental disordersSecond-generation sequencingDe novo missense variantsWhole-genome sequencingSkp1-CullinDevelopmental phenotypesLigase complexFin developmentResidue clustersTranscription factorsProteasomal degradationEye developmentNovo missense variantsDevelopmental processesFBXW11Genome sequencingEmbryonic tissuesUnderdeveloped eyes
2018
PAK2 Haploinsufficiency Results in Synaptic Cytoskeleton Impairment and Autism-Related Behavior
Wang Y, Zeng C, Li J, Zhou Z, Ju X, Xia S, Li Y, Liu A, Teng H, Zhang K, Shi L, Bi C, Xie W, He X, Jia Z, Jiang Y, Cai T, Wu J, Xia K, Sun Z. PAK2 Haploinsufficiency Results in Synaptic Cytoskeleton Impairment and Autism-Related Behavior. Cell Reports 2018, 24: 2029-2041. PMID: 30134165, DOI: 10.1016/j.celrep.2018.07.061.Peer-Reviewed Original Research
2017
The importance of managing the patient and not the gene: expanded phenotype of GLE1-associated arthrogryposis
Tan Q, McConkie-Rosell A, Juusola J, Gustafson KE, Pizoli CE, Buckley AF, Jiang YH. The importance of managing the patient and not the gene: expanded phenotype of GLE1-associated arthrogryposis. Molecular Case Studies 2017, 3: a002063. PMID: 28729373, PMCID: PMC5701308, DOI: 10.1101/mcs.a002063.Peer-Reviewed Original ResearchConceptsAnterior horn cell diseaseCell diseasePathogenic variantsMotor neuron diseaseBiallelic missense mutationsSpinal muscular atrophyWhole-exome sequencingMotor weaknessRespiratory supportRespiratory difficultyNeuron diseaseMotor phenotypePerinatal periodPrenatal symptomsContracture syndromeMuscle biopsySevere formFetal akinesiaMuscular atrophyDiseaseMRNA exportLethal arthrogryposisTranslation initiationPerinatal lethalityArthrogryposis
2013
Deficiency of Asparagine Synthetase Causes Congenital Microcephaly and a Progressive Form of Encephalopathy
Ruzzo EK, Capo-Chichi JM, Ben-Zeev B, Chitayat D, Mao H, Pappas AL, Hitomi Y, Lu YF, Yao X, Hamdan FF, Pelak K, Reznik-Wolf H, Bar-Joseph I, Oz-Levi D, Lev D, Lerman-Sagie T, Leshinsky-Silver E, Anikster Y, Ben-Asher E, Olender T, Colleaux L, Décarie JC, Blaser S, Banwell B, Joshi RB, He XP, Patry L, Silver RJ, Dobrzeniecka S, Islam MS, Hasnat A, Samuels ME, Aryal DK, Rodriguiz RM, Jiang YH, Wetsel WC, McNamara JO, Rouleau GA, Silver DL, Lancet D, Pras E, Mitchell GA, Michaud JL, Goldstein DB. Deficiency of Asparagine Synthetase Causes Congenital Microcephaly and a Progressive Form of Encephalopathy. Neuron 2013, 80: 429-441. PMID: 24139043, PMCID: PMC3820368, DOI: 10.1016/j.neuron.2013.08.013.Peer-Reviewed Original ResearchConceptsCongenital microcephalyProgressive cerebral atrophyStructural brain abnormalitiesCerebral atrophyNeuronal damageEnhanced excitabilityIntractable seizuresAsparagine depletionNeurological impairmentBrain abnormalitiesCortical thicknessLoss of functionASNS deficiencyProgressive formMutant micePatient phenotypesIntellectual disabilityASNS geneMicrocephalyMissense mutationsBrainDeficiencyAspartate/MutationsRecessive mutations
2012
Mutations of ANK3 identified by exome sequencing are associated with autism susceptibility
Bi C, Wu J, Jiang T, Liu Q, Cai W, Yu P, Cai T, Zhao M, Jiang Y, Sun ZS. Mutations of ANK3 identified by exome sequencing are associated with autism susceptibility. Human Mutation 2012, 33: 1635-1638. PMID: 22865819, DOI: 10.1002/humu.22174.Peer-Reviewed Original ResearchConceptsExtensive bioinformatics analysisNext-generation sequencing technologiesExtreme genetic heterogeneityStrong genetic etiologyGene discoveryWhole-exome sequencesDifferent missense mutationsBioinformatics analysisSequencing technologiesAutism susceptibilityMissense mutationsANK3Genetic heterogeneityMutationsNovo mutationsExome sequencingMolecular pathophysiologyGenetic causeGenetic etiologyASD susceptibilitySynaptic functionNovel mutationsNeurodevelopmental disordersGenesSequencing
2010
Pseudometabolic presentation of dystrophinopathy due to a missense mutation
Veerapandiyan A, Shashi V, Jiang Y, Gallentine W, Schoch K, Smith E. Pseudometabolic presentation of dystrophinopathy due to a missense mutation. Muscle & Nerve 2010, 42: 975-979. PMID: 21104870, PMCID: PMC5506871, DOI: 10.1002/mus.21823.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentChildDystrophinExerciseHumansMaleMuscle, SkeletalMuscular DiseasesMutation, MissenseMyoglobinuriaConceptsMuscle stiffnessNormal neurological examinationRetrospective chart reviewIdentical point mutationMissense mutationsWestern blot analysisExertional myalgiaChart reviewNeurological examinationClinical findingsExercise intoleranceRecurrent rhabdomyolysisMetabolic myopathyClinical reportsDMD geneUnrelated boysInaccurate diagnosisMyalgiaRhabdomyolysisFurther studiesBlot analysisSpecific mutationsExon 15Amino acid substitutionsBoys