2015
Using hiPSCs to model neuropsychiatric copy number variations (CNVs) has potential to reveal underlying disease mechanisms
Flaherty E, Brennand K. Using hiPSCs to model neuropsychiatric copy number variations (CNVs) has potential to reveal underlying disease mechanisms. Brain Research 2015, 1655: 283-293. PMID: 26581337, PMCID: PMC4865445, DOI: 10.1016/j.brainres.2015.11.009.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsCopy number variationsIsogenic hiPSC linesRare variantsFull genetic architectureGenome editing technologyPluripotent stem cellsStrong heritable componentPatient-derived humanGenetic architectureEditing technologyHeritable componentBehavioral defectsNumber variationsNew therapeutic targetsHiPSC linesGenetic backgroundStem cellsCommon variantsFunctional contributionDisease mechanismsSingle variantMouse modelHigh penetranceHiPSCsTherapeutic target
2013
Mosaic Copy Number Variation in Human Neurons
McConnell MJ, Lindberg MR, Brennand KJ, Piper JC, Voet T, Cowing-Zitron C, Shumilina S, Lasken RS, Vermeesch JR, Hall IM, Gage FH. Mosaic Copy Number Variation in Human Neurons. Science 2013, 342: 632-637. PMID: 24179226, PMCID: PMC3975283, DOI: 10.1126/science.1243472.Peer-Reviewed Original ResearchConceptsCopy number variationsHiPSC-derived neuronsSingle-cell genomic approachesNumber variationsDNA copy number variationsSingle-cell sequencingHuman neuronsLarge copy number variationsStem cell linesNeural progenitor cellsNovo copy-number variationsPluripotent stem cell lineAneuploid neuronsGenomic approachesDe novo copy-number variationsSubchromosomal copy number variationsAberrant genomesFrontal cortex neuronsLarge deletionsProgenitor cellsCell linesSubset of neuronsEuploid neuronsDeletionMultiple alterations