Project description:Natural selection has shaped the gene regulatory networks that orchestrate the development of the neocortex, leading to diverse neocortical structure and function across mammals, but the molecular and cellular mechanisms driving phenotypic changes have proven difficult to characterize. Here, we develop a reproducible protocol to generate cortical organoids from mouse epiblast stem cells that enable in depth mechanistic studies of cortical developmental in vitro. Cortical organoids develop with similar kinetics to the mouse cortex in vivo, recapitulate the cellular diversity present in the embryonic neocortex, and undergo relatively rapid maturation compared to human organoids. We generated cortical organoids from F1 hybrid epiblast stem cell lines from crosses between standard laboratory mice (C57Bl/6J) and four wild-derived inbred mouse strains from distinct sub-species that span ~1 million years of evolutionary divergence. Using scRNA-seq and allele-specific expression analysis we identified hundreds of genes that exhibit differential cis-regulation during cortical neurogenesis. These experimental methods and cellular resources represent a powerful new platform for investigating gene regulatory mechanisms across evolutionary timescales.

Project description:Natural selection has shaped the gene regulatory networks that orchestrate the development of the neocortex, leading to diverse neocortical structure and function across mammals, but the molecular and cellular mechanisms driving phenotypic changes have proven difficult to characterize. Here, we develop a reproducible protocol to generate cortical organoids from mouse epiblast stem cells that enable in depth mechanistic studies of cortical developmental in vitro. Cortical organoids develop with similar kinetics to the mouse cortex in vivo, recapitulate the cellular diversity present in the embryonic neocortex, and undergo relatively rapid maturation compared to human organoids. We generated cortical organoids from F1 hybrid epiblast stem cell lines from crosses between standard laboratory mice (C57Bl/6J) and four wild-derived inbred mouse strains from distinct sub-species that span ~1 million years of evolutionary divergence. Using scRNA-seq and allele-specific expression analysis we identified hundreds of genes that exhibit differential cis-regulation during cortical neurogenesis. These experimental methods and cellular resources represent a powerful new platform for investigating gene regulatory mechanisms across evolutionary timescales.

Project description:Natural selection has shaped the gene regulatory networks that orchestrate the development of the neocortex, leading to diverse neocortical structure and function across mammals, but the molecular and cellular mechanisms driving phenotypic changes have proven difficult to characterize. Here, we develop a reproducible protocol to generate cortical organoids from mouse epiblast stem cells that enable in depth mechanistic studies of cortical developmental in vitro. Cortical organoids develop with similar kinetics to the mouse cortex in vivo, recapitulate the cellular diversity present in the embryonic neocortex, and undergo relatively rapid maturation compared to human organoids. We generated cortical organoids from F1 hybrid epiblast stem cell lines from crosses between standard laboratory mice (C57Bl/6J) and four wild-derived inbred mouse strains from distinct sub-species that span ~1 million years of evolutionary divergence. Using scRNA-seq and allele-specific expression analysis we identified hundreds of genes that exhibit differential cis-regulation during cortical neurogenesis. These experimental methods and cellular resources represent a powerful new platform for investigating gene regulatory mechanisms across evolutionary timescales.

Project description:Changes to the human genome have driven the evolution of human features including a larger neocortex and enhanced cognition. Human Accelerated Regions (HARs) are highly-conserved loci containing human-specific variants, which can be transcriptional enhancers during neurodevelopment. However, the neurodevelopmental functions of HARs and their mechanism of gene regulation are still largely unknown. Here, we show that the HAR1984 promotes neural progenitor cell identity and neurogenesis by influencing species-specific transcription and chromatin interactions. Humanized HAR1984 knock-in of chimpanzee cortical organoids increased intermediate progenitors and neurons, whereas chimpanzee HAR1984 knock-in in human cortical organoids produced the opposite phenotype. Moreover, humanized HAR1984 knock-in mouse brains showed increased progenitor proliferation and neuron number, resulting in a thicker cortex with cortical folding. Hi-C data revealed a chromatin loop of HAR1984 with its target genes, ETV5 and TRA2B, present in human fetal brains, but reduced in chimpanzee, macaque or mouse neural cells. We show that human-specific mutations in HAR1984 promote chromatin looping and that human-specific ETV5 binding auto-regulates enhancer activity. This work demonstrates new molecular mechanisms underlying human-specific neurodevelopment, linking HARs to chromatin architecture, cortical cell identity and evolutionary expansion of human brains.

Project description:Changes to the human genome have driven the evolution of human features including a larger neocortex and enhanced cognition. Human Accelerated Regions (HARs) are highly-conserved loci containing human-specific variants, which can be transcriptional enhancers during neurodevelopment. However, the neurodevelopmental functions of HARs and their mechanism of gene regulation are still largely unknown. Here, we show that the HAR1984 promotes neural progenitor cell identity and neurogenesis by influencing species-specific transcription and chromatin interactions. Humanized HAR1984 knock-in of chimpanzee cortical organoids increased intermediate progenitors and neurons, whereas chimpanzee HAR1984 knock-in in human cortical organoids produced the opposite phenotype. Moreover, humanized HAR1984 knock-in mouse brains showed increased progenitor proliferation and neuron number, resulting in a thicker cortex with cortical folding. Hi-C data revealed a chromatin loop of HAR1984 with its target genes, ETV5 and TRA2B, present in human fetal brains, but reduced in chimpanzee, macaque or mouse neural cells. We show that human-specific mutations in HAR1984 promote chromatin looping and that human-specific ETV5 binding auto-regulates enhancer activity. This work demonstrates new molecular mechanisms underlying human-specific neurodevelopment, linking HARs to chromatin architecture, cortical cell identity and evolutionary expansion of human brains.

Project description:Fate determination of neural stem cells is crucial for cerebral cortex development and is closely linked to neurodevelopmental disorders when gene expression networks are disrupted. The transcriptional corepressor chromodomain Y-like (CDYL) is widely expressed across diverse cell populations within the human embryonic cortex, though its precise role in this complex developmental process remains unclear. Here, we show that CDYL is critical for human cortical neurogenesis. CDYL deficiency leads to a substantial increase in gamma-aminobutyric acid (GABA)-ergic neurons in human cortical organoids, instead of the expected generation of typical cortical neurons. Subsequently, neuronatin (NNAT) is identified as a significant target of CDYL in this process, and its abnormal expression obviously influences the proliferation and fate commitment of cortical neural stem cells (NSCs) within human cortical organoids. Cross-species comparisons of CDYL targets unravel a distinct developmental trajectory between human cortical organoids and mouse cortex at an analogous stage. Collectively, our data provide insight into the evolutionary roles of CDYL in human cortex development, emphasizing the critical function of CDYL in maintaining the fate of human cortical NSCs.

Project description:The molecular basis for cortical expansion during evolution remains largely unknown. Here, we report that fibroblast growth factor (FGF)-extracellular signal-regulated kinase (ERK) signaling promotes the self-renewal and expansion of cortical radial glial (RG) cells. Furthermore, FGF-ERK signaling induces bone morphogenic protein 7 (Bmp7) expression in cortical RG cells, which increases the length of the neurogenic period. We demonstrate that ERK signaling and Sonic Hedgehog (SHH) signaling mutually inhibit each other in cortical RG cells. We provide evidence that ERK signaling is elevated in cortical RG cells during development and evolution. We propose that the expansion of the mammalian cortex, notably in human, is driven by the ERK-BMP7-GLI3R signaling pathway in cortical RG cells, which participates in a positive feedback loop through antagonizing SHH signaling. We also propose that the relatively short cortical neurogenic period in mice is partly due to mouse cortical RG cells receiving higher SHH signaling that antagonizes ERK signaling.

Project description:In the developing mouse brain, PRDM16 exhibits robust expression in radial glia (RG) progenitors, serving as one of the conserved core RG genes shared between humans and mice. Much is known regarding the functions of PRDM16 in the developing mouse brain, yet its roles in the developing human brain are less explored. Our study was motivated by detecting a patient with a de novo nonsense mutation in PRDM16 exhibiting lissencephaly and microcephaly features. We introduced the mutation in human stem cells in both homozygous and heterozygous manner and generated human cortical organoids. The organoids differed in cell cycle parameters, and RNA-seq demonstrated changes in cell adhesion and WNT-signaling, which were confirmed by immunostaining. We further generated ChIP-seq data from human fetuses and compared the results to ChIP-seq data previously obtained from mice and differentially expressed genes in humans and mice (REFS he and baizabal papers). The top detected motif matched LHX2, so we compared our data with recently acquired LHX2 ChIP-seq data from the mouse. Our studies show highly conserved genes and pathways suggesting that PRDM16 and LHX2 complex and collaborate in the developing mouse and human brains. The multifaceted nature of PRDM16 and its intricate involvement in transcriptional regulation and various developmental processes highlight its importance in understanding neurodevelopmental mechanisms.

Project description:Human cortical neurogenesis involves conserved and specialized developmental processes during a restricted window of prenatal development. Radial glia (RG) neural stem cells shape cortical cell diversity by giving rise to excitatory neurons, oligodendrocytes, and astrocytes, as well as olfactory bulb interneurons (INs) and a recently characterized population of cortical INs. Complex genetic programs orchestrated by transcription factor (TF) circuits govern the balance between self-renewal and differentiation, and between different cell fates. Despite progress in measuring gene regulatory network activity during human cortical development, functional studies are required to evaluate the roles of TFs and effector genes in human RG lineage progression. Here we establish a human primary culture system that allows sensitive discrimination of cell fate dynamics and apply single cell clustered regularly interspaced short palindromic repeats interference (CRISPRi) screening to examine the transcriptional and cell fate consequences of 44 TFs active during cortical neurogenesis. We identified multiple TFs, with novel roles in cortical neurogenesis, including ZNF219, previously uncharacterized, that represses neural differentiation and NR2E1 and ARX that have opposing roles in regulating RG lineage plasticity and progression across developmental stages. We also uncovered convergent effector genes downstream of multiple TFs enriched in neurodevelopmental and neuropsychiatric disorders and observed conserved mechanisms of RG lineage plasticity across primates. We further uncovered a postmitotic role for ARX in safeguarding IN subtype specification through repressing LMO1. Our study provides a framework for dissecting regulatory networks driving cell fate consequences during human neurogenesis.

Project description:Natural selection has shaped the gene regulatory networks that orchestrate the development of the neocortex, leading to diverse neocortical structure and function across mammals, but the molecular and cellular mechanisms driving phenotypic changes have proven difficult to characterize. Here, we develop a reproducible protocol to generate neocortical organoids from mouse epiblast stem cells (EpiSCs) that gives rise to diverse cortical cell types, including distinct classes of excitatory neurons (pre-plate, deep-layer, and upper-layer) and glia (oligodendrocyte precursor cells, myelinating oligodendrocytes, astrocytes, ependymal cells). Cortical organoids develop with similar kinetics to the mouse cortex in vivo and begin to exhibit features of maturation in glia and neuronal cell types relatively rapidly compared to human brain organoids. Using this new protocol, we generated cortical organoids from F1 hybrid EpiSCs derived from crosses between standard laboratory mice (C57BL/6J) and four wild-derived mouse strains from distinct sub-species spanning ∼1M years of evolutionary divergence. This allowed us to comprehensively map cis-acting transcriptional regulatory variation across developing cortical cell types using scRNA-seq. We identify hundreds of genes that exhibit dynamic allelic imbalances during cortical neurogenesis, providing the first insight into the developmental mechanisms underpinning changes in cortical structure and function between mouse strains. These experimental methods and cellular resources represent a powerful new platform for investigating mechanisms of gene regulation in the developing cerebral cortex.