Project description:Recent discussions of human brain evolution have largely focused on increased neuron numbers and changes in their connectivity and expression. However, it is increasingly appreciated that oligodendrocytes play important roles in cognitive function and disease. Whether both cell types follow distinctive evolutionary trajectories is not known. We examined the transcriptomes of neurons and oligodendrocytes in the frontal cortex of humans, chimpanzees, and rhesus macaques. We identified human-specific trajectories of gene expression in oligodendrocytes and show that oligodendrocytes have undergone accelerated gene expression evolution in the human lineage. The signature of acceleration is enriched for cell type-specific expression alterations in schizophrenia. These results underscore the importance of oligodendrocytes in human brain evolution.
Project description:Long noncoding RNA sequences evolve relatively rapidly, but it is unclear whether this is due to relaxed constraint or accelerated evolution. Here, we trace the recent evolutionary history of human lncRNAs, using genomes of multiple individuals from all great ape species to map fixed lineage-specific nucleotide variants. We find that the lower conservation of lncRNAs compared to protein coding genes partially arises from lncRNA’s more recent evolutionary origin. We identify more than one hundred lncRNAs that show some evidence of accelerated evolution in at least one primate species, including 17 in human. Several of these display transcriptional regulatory activity in an RNA-specific reporter assay. By experimentally reconstructing the ancestral lncRNA sequence, we find that this activity has been altered by human-specific nucleotide substitutions. Functional analysis of accelerated lncRNAs with specific expression in blood suggests lncRNAs have participated in adaptive regulatory changes in the immune system during recent human evolution. Together our results provide evidence that accelerated evolution of lncRNAs may have contributed, through regulatory changes, to human-specific phenotypes.
Project description:Genomic changes acquired in human evolution contribute to the unique abilities of human brain. However, characterizing the molecular underpinnings of human-specific traits is a multifaceted challenge due to the cellular heterogeneity of human brain and complex regulation of gene expression. Here, we performed single-nuclei RNA-sequencing (snRNA-seq) and single-nuclei ATAC-seq (snATAC-seq) in human, chimpanzee, and rhesus macaque brain tissue (brodmann area 23, posterior cingulate cortex). Human-specific changes were distinct among neuronal subtypes indicating that human brain evolution was accompanied by molecular alterations in finer cellular resolution. We also observed more human-specific alterations in epigenome compared to transcriptome. Interestingly, human-specific accessibility changes in neurons were not as concordant with gene expression changes in comparison to other species, partially explaining this discrepancy. These cis-regulatory elements were enriched for immediate early gene motifs, identifying accelerated evolution of activity regulated genes in humans. We also uncovered associations between human evolution and brain disease genes at the cell type level. Together, these results reveal multiple mechanisms for human brain evolution at cell type resolution and establish the first direct evidence for accelerated human-specificity of activity-dependent molecular changes.
Project description:Genomic changes acquired in human evolution contribute to the unique abilities of human brain. However, characterizing the molecular underpinnings of human-specific traits is a multifaceted challenge due to the cellular heterogeneity of human brain and complex regulation of gene expression. Here, we performed single-nuclei RNA-sequencing (snRNA-seq) and single-nuclei ATAC-seq (snATAC-seq) in human, chimpanzee, and rhesus macaque brain tissue (brodmann area 23, posterior cingulate cortex). Human-specific changes were distinct among neuronal subtypes indicating that human brain evolution was accompanied by molecular alterations in finer cellular resolution. We also observed more human-specific alterations in epigenome compared to transcriptome. Interestingly, human-specific accessibility changes in neurons were not as concordant with gene expression changes in comparison to other species, partially explaining this discrepancy. These cis-regulatory elements were enriched for immediate early gene motifs, identifying accelerated evolution of activity regulated genes in humans. We also uncovered associations between human evolution and brain disease genes at the cell type level. Together, these results reveal multiple mechanisms for human brain evolution at cell type resolution and establish the first direct evidence for accelerated human-specificity of activity-dependent molecular changes.
Project description:Sexually dimorphic traits are subject to diversifying selection. Also genes with a male biased gene expression are probably affected by sexual selection and have a high rate of protein evolution. We used SAGE to measure sex biased gene expression in Drosophila pseudoobscura. Consistent with previous results from D. melanogaster, a larger number of genes were male biased (402 genes) than female biased (138 genes). About 34% of the genes changed the sex related expression pattern between D. melanogaster and D. pseudoobscura. Combining gene expression with protein divergence between both species, we observed a striking difference in rate of evolution for genes with a male biased gene expression in one species only. Contrary to expectations, D. pseudoobscura genes in this category showed no accelerated rate of protein evolution, while D. melanogaster genes did. If sexual selection is driving molecular evolution of male biased genes, our data imply a radically different selection regime in D. pseudoobscura. Keywords: SAGE Male and female SAGE libraries of D. pseudoobscura were developed for analyzing the gene expression pattern.
Project description:Neurocognitive dysfunction is the leading cause of a reduced quality of life in patients with primary brain tumors. However, how the human brain responds to the tumor and its treatment remains largely unknown. Here we show that the brain of patients with glioblastoma shares features with Alzheimer’s disease and displays hallmarks of accelerated ageing, mitochondrial and neuronal dysfunction, and proteostasis deregulation, thus revealing new targets for managing cancer-related side effects.
Project description:miRNA-mediated gene expression silencing has previously been shown to be important for a variety of physiological and pathological processes. Here, we have explored the role of one bona fide human-specific miRNA (miR-941) in evolution of the human-specific expression and function. Using combination of high-throughput sequencing (GSE26545), miRNA transfection and large-scale PCR of various human populations, we have shown that emergence and rapid expansion of miR-941 might take place on the human evolutionary linage between six and one million years ago. Functionally, miR-941 could be associated with hedgehog and insulin signaling pathways, and thus might potentially play a role in evolution of human longevity. Human-specific effects of miR-941 regulation are detectable in human brain and affect genes involved in neurotransmitter signaling. Furthermore, emergence of miR-941 on the human evolutionary linage was accompanied by the accelerated loss of its binding sites. Taken together, these results strongly implicate the contribution of miR-941 in evolution of the human-specific phenotype. Cerebellum mRNA samples from 5 human, 5 chimpanzee and 1 rhesus macaque for Affymetrix Human Exon 1.0 ST Arrays were prepared following the standard GeneChip Whole Transcript (WT) Sense Target Labelling Assay.