Single-nucleus multi-omics analyses reveal cellular and molecular innovations in the anterior cingulate cortex during primate evolution
Yuan J, Dong K, Wu H, Zeng X, Liu X, Liu Y, Dai J, Yin J, Chen Y, Guo Y, Luo W, Liu N, Sun Y, Zhang S, Su B. Single-nucleus multi-omics analyses reveal cellular and molecular innovations in the anterior cingulate cortex during primate evolution. Cell Genomics 2024, 4: 100703. PMID: 39631404, DOI: 10.1016/j.xgen.2024.100703.Peer-Reviewed Original ResearchConceptsChromatin accessibilitySingle-nucleusGene expressionTranscription factor bindingPatterns of gene expressionSingle-nucleus resolutionCell lineage originACC gene expressionPrimate evolutionMulti-omics analysisAnterior cingulate cortexFactor bindingEvolutionary roleFunctional innovationSequence changesMolecular innovationsVon Economo neuronsMolecular regulationMarker genesPublished mouse dataCell typesChromatinMolecular identityHuman originCingulate cortexComparative single-cell multiome identifies evolutionary changes in neural progenitor cells during primate brain development
Liu Y, Luo X, Sun Y, Chen K, Hu T, You B, Xu J, Zhang F, Cheng Q, Meng X, Yan T, Li X, Qi X, He X, Guo X, Li C, Su B. Comparative single-cell multiome identifies evolutionary changes in neural progenitor cells during primate brain development. Developmental Cell 2024 PMID: 39481377, DOI: 10.1016/j.devcel.2024.10.005.Peer-Reviewed Original ResearchEvolutionary changesDistal regulatory elementsGene regulatory mechanismsExtracellular matrixSingle-cell multiomicsProgenitor cellsTranscriptional divergenceEvolutionary divergenceChromatin regionsChromatin accessibilityNeural progenitorsRegulatory elementsSequence changesTranscriptional rewiringGenetic mechanismsMouse prefrontal cortexRegulatory mechanismsPrefrontal cortexHuman neural progenitorsHuman-specific featuresUpper-layer neuronsNeural progenitor cellsChromatinCellular propertiesProgenitor proliferation
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