Project description:Stem cells have the unique ability to self-renew and differentiate into specialized cell types. Among the many factors influencing cell fate, epigenetic mechanisms, like histones, play a crucial role in regulating genomic programs like gene transcription and DNA replication, which are integral to a cell’s identity. However, the transcriptional, chromatin, and DNA replication timing profiles of stem cells within in vivo tissues remain poorly understood. The Drosophila testis serves as an excellent in vivo model for studying stem cells, as it contains two stem cell populations: the germline stem cells (GSC) and somatic cyst stem cells (CySC). Despite this, a comprehensive understanding of genome regulation in these cell types has been limited by the small number of stem cells and heterogeneity of the testis. In this study, we developed cell-specific genomic techniques to analyze the transcriptome, histone modification patterns, and replication timing profiles of GSCs and CySCs. Our single cell RNA-sequencing validated previous cell-biological and genetic studies on the role of intercellular communication between GSCs and CySCs while revealing high expression of chromatin regulators in GSCs. To characterize chromatin landscapes, we developed a cell-specific chromatin profiling assay to map H3K4me3, H3K27me3, and H3K9me3. These posttranslational modifications define euchromatic, facultative heterochromatic, and constitutive heterochromatic domains, respectively. Finally, we determined the cell-specific replication timing profiles of GSCs and CySCs, integrating our in vivo datasets with published in vitro data. Our results reveal that the replication program of GSCs is distinct from somatic lineages and that these differences align with variations in chromatin patterns. Collectively, our integrated genomic datasets build a framework for understanding genome-wide regulatory differences in two in vivo stem cell populations, demonstrating the power of combining transcriptomic, chromatin, and replication datasets to uncover cell-specific features of genome regulation.

Project description:Extensive changes in replication timing occur during early mouse development, but their biological significance remains uncertain. To identify evolutionarily conserved features of replication timing and their relationships to epigenetic properties in humans, we profiled replication timing genome-wide in four human embryonic stem cell (hESC) lines, hESC-derived neural precursor cells (NPCs), lymphoblastoid cells, and two independently derived human induced pluripotent stem cell lines (hiPSCs). Results confirm the conservation of coordinately replicated megabase-sized units of chromosomes (replication domains) with stable cell type specific molecular boundaries that consolidate into larger replication domains during differentiation. Replication timing changes encompassed units of 400-800 kb and were coordinated with changes in transcription similar to mouse. Moreover, significant cell-type specific conservation of replication timing profiles was observed across regions of conserved synteny, despite significant species variation in the alignment of replication timing to isochore GC/LINE-1 content. Replication profiling also revealed a closer genome-wide epigenetic alignment of hESCs to mouse epiblast-derived stem cells (mEpiSCs) than to mouse ESCs. Finally, we identify a signature of chromatin modifications marking the boundaries of early replicating domains and a remarkably strong link between spatial proximity of chromatin as measured by Hi-C analysis and replication timing. Together, our results reveal evolutionarily conserved elements of the replication program in mammalian early development, demonstrate the power of replication profiling to identify important epigenetic distinctions between closely related stem cell populations (e.g. ESCs vs. EpiSCs), and strengthen the hypothesis that replication domains are structural and functional units of 3D chromosomal architecture. 8 cell types, with a total of 13 individual replicates (i.e. 5 in duplicates, 3 in single replicates)

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Cell type- and chromosome-specific chromatin landscapes and DNA replication programs of Drosophila testis stem cells [scRNA-seq]

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