Project description:Using reduced representation bisulfite sequencing (RRBS), we have compared the methylomes of neuronal and non-neuronal cells from three female human and three chimpanzee cortices (Brodmann area 10). Differentially methylated regions (DMRs) with genome-wide significance were enriched in specific chromosomal regions. Intraspecific methylation differences between neuronal and non-neuronal cells were approximately three times more abundant than interspecific methylation differences between human and chimpanzee cell types. The vast majority (>90%) of human intraspecific DMRs (including DMRs with retrotransposons) were hypomethylated in neurons, compared to glia. Intraspecific DMRs were enriched in genes that have been associated with different neuropsychiatric disorders. Interspecific DMRs were enriched in genes showing human-specific brain histone modifications. Methylation differences between human and chimpanzee non-neuronal cells (N=666) were much more frequent than neuronal interspecific DMRs (N=96). More than 95% of interspecific non-neuronal DMRs were hypermethylated in humans.

Project description:Cell type and species-specific methylation patterns in neuronal and non-neuronal cells of human and chimpanzee cortex

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Project description:Understanding the evolutionary mechanisms underlying expansion and reorganization of the human brain is essential to comprehend the emergence of the cognitive abilities typical of our species. Comparative analyses of neuronal phenotypes in closely related species (Homo sapiens; human, Pan troglodytes; chimpanzees and Pan paniscus; bonobos) can shed light onto neuronal changes occurring during evolution, the timing of their appearance and the role of evolutionary mechanisms favoring a particular type of cortical organization in humans. The availability of post-mortem brains of endangered primates is limited and often does not represent important species-specific developmental hallmarks. We used induced pluripotent stem cell (iPSC) technology to model neural progenitor cell migration in Homo and Pan and early development of cortical pyramidal neurons in humans and chimpanzees after following cells grafted in vivo. We present results suggesting differential migration patterns in human neural progenitor cells compared to those of chimpanzees and bonobos in vitro and in vivo. Additionally, we reveal morphometric and functional differences that are suggestive of heterochronic changes in developing human neurons compared to chimpanzees. This report provides a comprehensive analysis of comparative neural development in closely related hominids. The strategy proposed here lays the groundwork for further comparative analysis between human and non-human primates and opens new avenues for understanding the differences in the neural underpinnings of cognition and neurological disease susceptibility between species.

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