Project description:The human cerebral cortex underwent rapid enlargement and complexification during recent evolution. Hominid-specific (HS) genes arising from genomic duplications may be involved, but it remains unclear how much and which HS genes contribute to human brain development. Using tailored RNAseq profiling, we identify a repertoire of >60 HS genes that display robust and dynamic expression during human fetal corticogenesis. Among these, Notch2NL genes stood out as human-specific Notch2 paralogs that promotes cortical progenitor maintenance. Clonal analyses of human cortical progenitors revealed that Notch2NL promotes their expansion by increasing self-renewal, ultimately leading to higher clonal neuronal output. Notch2NL acts by direct activation of the Notch pathway, through cell-autonomous inhibition of Delta/Notch interactions. Our data identify a large repertoire of newly evolved genes linking human brain development and evolution, and indicate how human-specific Notch paralogs may have contributed to the expansion of the human brain.

Project description:The cerebral cortex underwent a rapid expansion and complexification during recent primate evolution, but the underlying developmental mechanisms remain essentially unknown. In order to uncover genetic networks underlying the development of the human cerebral cortex, we profiled the transcriptome of human fetal cortical domains containing language areas of Broca and Wernicke, as well as associative areas. We thus identified hundreds of genes displaying differential expression between the two areas or between distinct temporal stages. A subset of these genes was further validated by qRTPCR and in situ hybridization, revealing novel patterns of area and layer-specific expression throughout the developing cortex at midgestation, a critical period of cortical patterning. Computational genomic analyses revealed that the proportion of genes located close to evolutionarily accelerated regions was far more abundant among the genes differentially expressed between the two cortical areas examined, but not among those differentially expressed between different stages of development. In silico screening enabled to identify accelerated regions displaying increased turnover of change in transcription factor binding sites, which were enriched among those closer to genes differentially expressed between cortical areas. Overall our work points to the identification of cortical genes that display a unique combination of patterns of evolution and expression, which may constitute an important part of the genetic framework underlying human-specific neural traits and diseases. We determined gene expression patterns in cortical domains that contain areas thought to have undergone significant divergence during primate evolution, including language areas of Broca and Wernicke, as well as association areas of the frontal and parieto-temporal cortex in the right and left sides of human fetal brains at 17 and 19 gestional weeks.

Project description:Evolution of the mammalian brain encompassed a remarkable increase in size of cerebral cortex, including tangential and radial expansion, but the mechanisms underlying these key parameters are still largely unknown. Here, we identified the novel DNA associated protein TRNP1 as a regulator of cerebral cortical expansion in both these dimensions. Gain and loss of function experiments in the mouse cerebral cortex in vivo demonstrate that high Trnp1 levels promote neural stem cell self-renewal and tangential expansion, while lower levels promote radial expansion resulting in a potent increase in the generation of intermediate progenitors and outer radial glial cells resulting in folding of the otherwise smooth murine cerebral cortex. Remarkably, TRNP1 expression levels exhibit regional differences also in the cerebral cortex of human fetuses anticipating radial or tangential expansion respectively. Thus, the dynamic regulation of TRNP1 is critical to regulate tangential and radial expansion of the cerebral cortex in mammals. We performed gene expression microarray analysis on embryonic mouse cerebral cortex derived from Trnp1 knockdown and control animals.

Project description:Brain organoids (BO) enabled the investigation of human corticogenesis in-vitro with an increasing range of protocols achieving its remarkable recapitulation. However, we lack a resource gathering fetal cortex-specific gene co-expression patterns and their behavior in BO. We complement the current knowledge with a benchmarking of BO versus human corticogenesis, integrating: transcriptomes from in-house differentiated cortical BO (CBO), in-house processed human fetal brain samples, analysis of transcriptomes from different BO systems and of pre-natal cortical samples from the BrainSpan Atlas.

Project description:Evolution of the mammalian brain encompassed a remarkable increase in size of cerebral cortex, including tangential and radial expansion, but the mechanisms underlying these key parameters are still largely unknown. Here, we identified the novel DNA associated protein TRNP1 as a regulator of cerebral cortical expansion in both these dimensions. Gain and loss of function experiments in the mouse cerebral cortex in vivo demonstrate that high Trnp1 levels promote neural stem cell self-renewal and tangential expansion, while lower levels promote radial expansion resulting in a potent increase in the generation of intermediate progenitors and outer radial glial cells resulting in folding of the otherwise smooth murine cerebral cortex. Remarkably, TRNP1 expression levels exhibit regional differences also in the cerebral cortex of human fetuses anticipating radial or tangential expansion respectively. Thus, the dynamic regulation of TRNP1 is critical to regulate tangential and radial expansion of the cerebral cortex in mammals.

Project description:This study demonstrates cellular and molecular mechanisms regulating the generation and function of basal radial glia (bRG), a neural stem cell population that was shown to be enriched in the developing human brain and was involved in the formation of cortical expansion. Here, we studied the role of LGALS3BP, a secreted protein whose RNA expression is enriched in bRGs. Based on a combination of three model systems i) in vitro human cerebral organoids, ii) ex vivo embryonic human fetal tissue and iii) in vivo embryonic mouse cortex, and a wide variety of techniques including single-cell RNA-sequencing, proteomics, and immunostaining, we characterized the role of human LGALS3BP mutations.

Project description:Genetic changes causing brain size expansion in human evolution have remained elusive. Notch signaling is essential for radial glia stem cell proliferation and a determinant of neuronal number in the mammalian cortex. We find three paralogs of human-specific NOTCH2NL are highly expressed in radial glia. Functional analysis reveals different alleles of NOTCH2NL have varying potencies to enhance Notch signaling by interacting directly with NOTCH receptors. Consistent with a role in Notch signaling, NOTCH2NL ectopic expression delays differentiation of neuronal progenitors, while deletion accelerates differentiation. Furthermore, NOTCH2NL genes provide the breakpoints in typical cases of 1q21.1 distal deletion/duplication syndrome, where duplications are associated with macrocephaly and autism, and deletions with microcephaly and schizophrenia. Thus, the emergence of hominin-specific NOTCH2NL genes may have contributed to the rapid evolution of the larger hominin neocortex accompanied by loss of genomic stability at the 1q21.1 locus and a resulting recurrent neurodevelopmental disorder.

Project description:The cerebral cortex underwent a rapid expansion and complexification during recent primate evolution, but the underlying developmental mechanisms remain essentially unknown. In order to uncover genetic networks underlying the development of the human cerebral cortex, we profiled the transcriptome of human fetal cortical domains containing language areas of Broca and Wernicke, as well as associative areas. We thus identified hundreds of genes displaying differential expression between the two areas or between distinct temporal stages. A subset of these genes was further validated by qRTPCR and in situ hybridization, revealing novel patterns of area and layer-specific expression throughout the developing cortex at midgestation, a critical period of cortical patterning. Computational genomic analyses revealed that the proportion of genes located close to evolutionarily accelerated regions was far more abundant among the genes differentially expressed between the two cortical areas examined, but not among those differentially expressed between different stages of development. In silico screening enabled to identify accelerated regions displaying increased turnover of change in transcription factor binding sites, which were enriched among those closer to genes differentially expressed between cortical areas. Overall our work points to the identification of cortical genes that display a unique combination of patterns of evolution and expression, which may constitute an important part of the genetic framework underlying human-specific neural traits and diseases.

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:The expansion of the neocortex during mammalian brain evolution results primarily from an increase in neural progenitor cell divisions in its two principal germinal zones during development, the ventricular zone (VZ) and the subventricular zone (SVZ). Using mRNA sequencing, we analyzed the transcriptomes of fetal human and embryonic mouse VZ, SVZ and cortical plate (CP). We describe sets of genes that are up- or down-regulated in each germinal zone. These data suggest that cell adhesion and cell-extracellular matrix (ECM) interactions promote the proliferation and self-renewal of neural progenitors in the developing human neocortex. Notably, relevant ECM-associated genes include distinct sets of collagens, laminins, proteoglycans and integrins, along with specific sets of growth factors and morphogens. Our data establish a basis for identifying novel cell-type markers and open up avenues to unravel the molecular basis of neocortex expansion during evolution. Total RNA was isolated from the VZ, inner SVZ (ISVZ), outer SVZ (OSVZ) and CP of six 13-16 weeks post-conception (w.p.c.) human fetuses and from the VZ, SVZ and CP of five E14.5 mouse embryos using laser capture microdissection of Nissl-stained cryosections of dorsolateral telencephalon. Poly A+ RNA was used as template for the preparation of cDNA which were then subjected to single-end 76-bp RNA-Seq.