Project description:Genome-wide association studies (GWAS) have identified hundreds of loci associated with psychiatric diseases, yet there is a lack of understanding of disease pathophysiology. Common risk variants can shed light on the molecular mechanisms underlying these diseases; however, identifying specific causal variants remains challenging. An added complication is that most common risk variants are in non-coding regions. Their impact is likely to be restricted to particular cell types, developmental stages, or cell states. Here, we comprehensively mapped cis-regulatory elements in two defined populations of human excitatory and inhibitory neurons derived from pluripotent stem cells. 

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Genome-wide association studies (GWAS) have identified hundreds of loci associated with psychiatric diseases, yet there is a lack of understanding of disease pathophysiology. Common risk variants can shed light on the molecular mechanisms underlying these diseases; however, identifying specific causal variants remains challenging. An added complication is that most common risk variants are in non-coding regions. Their impact is likely to be restricted to particular cell types, developmental stages, or cell states. Here, we comprehensively mapped cis-regulatory elements in two defined populations of human excitatory and inhibitory neurons derived from pluripotent stem cells. 

Project description:Genome-wide association studies (GWAS) have identified hundreds of loci associated with psychiatric diseases, yet there is a lack of understanding of disease pathophysiology. Common risk variants can shed light on the molecular mechanisms underlying these diseases; however, identifying specific causal variants remains challenging. An added complication is that most common risk variants are in non-coding regions. Their impact is likely to be restricted to particular cell types, developmental stages, or cell states. Here, we comprehensively mapped cis-regulatory elements in two defined populations of human excitatory and inhibitory neurons derived from pluripotent stem cells. 

Project description:Mapping cis-regulatory elements in human excitatory and inhibitory neurons links psychiatric disease heritability and activity-regulated transcriptional programs

Project description:Mapping cis-regulatory elements in human excitatory and inhibitory neurons links psychiatric disease heritability and activity-regulated transcriptional programs

Project description:Mapping cis-regulatory elements in human excitatory and inhibitory neurons links psychiatric disease heritability and activity-regulated transcriptional programs [RNA-seq]

Project description:Mapping cis-regulatory elements in human excitatory and inhibitory neurons links psychiatric disease heritability and activity-regulated transcriptional programs [ATAC-seq]

Project description:The placenta is a temporary organ that provides the developing fetus with nutrients, oxygen, and protection in utero. Defects in its development, which may be caused by misregulated gene expression, can lead to devastating outcomes for the mother and fetus. In mouse, placental defects during midgestation commonly lead to embryonic lethality. However, the regulatory mechanisms controlling expression of genes during this period have not been thoroughly investigated. Therefore, we generated and analyzed ChIP-seq data for multiple histone modifications known to mark cis-regulatory regions. We annotated active and poised promoters and enhancers, as well as regions generally associated with repressed gene expression. We found that poised promoters were associated with neuronal development genes, while active promoters were largely associated with housekeeping genes. Active and poised enhancers were associated with placental development genes, though only active enhancers were associated with genes that have placenta-specific expression. Motif analysis within active enhancers identified a large network of transcription factors, including those that have not been previously studied in the placenta and are candidates for future studies. The data generated and genomic regions annotated provide researchers with a foundation for future studies, aimed at understanding how specific genes in the midgestation mouse placenta are regulated.

Project description:BackgroundPost-transcriptional gene regulation controls the amount of protein produced from an individual mRNA by altering rates of decay and translation. Many sequence elements that direct post-transcriptional regulation have been found; in mammals, most such elements are located within the 3' untranslated regions (3'UTRs). Comparative genomic studies demonstrate that mammalian 3'UTRs contain extensive conserved sequence tracts, yet only a small fraction corresponds to recognized elements, implying that many additional novel elements exist. Despite a variety of computational, molecular, and biochemical approaches, identifying functional 3'UTRs elements remains difficult.ResultsWe created a high-throughput cell-based screen that enables identification of functional post-transcriptional 3'UTR regulatory elements. Our system exploits integrated single-copy reporters, which are expressed and processed as endogenous genes. We screened many thousands of short random sequences for their regulatory potential. Control sequences with known effects were captured effectively using our approach, establishing that our methodology was robust. We found hundreds of functional sequences, which we validated in traditional reporter assays, including verifying their regulatory impact in native sequence contexts. Although 3'UTRs are typically considered repressive, most of the functional elements were activating, including ones that were preferentially conserved. Additionally, we adapted our screening approach to examine the effect of elements on RNA abundance, revealing that most elements act by altering mRNA stability.ConclusionsWe developed and used a high-throughput approach to discover hundreds of post-transcriptional cis-regulatory elements. These results imply that most human 3'UTRs contain many previously unrecognized cis-regulatory elements, many of which are activating, and that the post-transcriptional fate of an mRNA is largely due to the actions of many individual cis-regulatory elements within its 3'UTR.