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

Project description:Our laboratory identified robust recurrent DNA double-strand break (DSB) cluster (“RDC”) genes in mouse neural stem/progenitor cells (NSPCs) by applying the high-throughput, genome-wide, translocation sequencing (HTGTS) method. Genomic alterations of most of the identified RDC-genes have been associated with psychiatric disorders such as autism and schizophrenia and several are altered in brain cancer. The most robust mouse RDCs are all in genes that tend to be very long, actively transcribed and were enhanced after mild inhibition of replication stress. The common transcription and replication characteristics we observe in RDC-genes suggest that frequent RDC DSBs might be generated by collision between transcription and replication processes. However, the underlying mechanism of RDC formation is still unknown. To elucidate mechanisms that generate and resolve DSBs in these cells, we established an in vitro system of induced neural progenitor cells derived from embryonic stem cells. HTGTS bait-DSBs introduced by CRISPR/Cas9 on three mouse chromosomes identified only 5 RDC-genes in embryonic stem cells and 27 RDC-genes in the neural progenitor cells differentiated from them. All RDC-genes identified in induced neural progenitor cells belonged to the group of genes identified in primary neural and progenitor cells. These results indicate that our in vitro differentiation system is both effective and robust in terms of recapitulating our previous findings and facilitating mechanistic studies.

Project description:Our laboratory identified robust recurrent DNA double-strand break (DSB) cluster (“RDC”) genes in mouse neural stem/progenitor cells (NSPCs) by applying the high-throughput, genome-wide, translocation sequencing (HTGTS) method. Genomic alterations of most of the identified RDC-genes have been associated with psychiatric disorders such as autism and schizophrenia and several are altered in brain cancer. The most robust mouse RDCs are all in genes that tend to be very long, actively transcribed and were enhanced after mild inhibition of replication stress. The common transcription and replication characteristics we observe in RDC-genes suggest that frequent RDC DSBs might be generated by collision between transcription and replication processes. However, the underlying mechanism of RDC formation is still unknown. To elucidate mechanisms that generate and resolve DSBs in these cells, we established an in vitro system of induced neural progenitor cells derived from embryonic stem cells. HTGTS bait-DSBs introduced by CRISPR/Cas9 on three mouse chromosomes identified only 5 RDC-genes in embryonic stem cells and 27 RDC-genes in the neural progenitor cells differentiated from them. All RDC-genes identified in induced neural progenitor cells belonged to the group of genes identified in primary neural and progenitor cells. These results indicate that our in vitro differentiation system is both effective and robust in terms of recapitulating our previous findings and facilitating mechanistic studies.

Project description:Induction of Recurrent Break Cluster Genes in Neural Progenitor Cells Differentiated from Embryonic Stem Cells In Culture

Project description:Induction of Recurrent Break Cluster Genes in Neural Progenitor Cells Differentiated from Embryonic Stem Cells In Culture [HTGTS-Seq]

Project description:Induction of Recurrent Break Cluster Genes in Neural Progenitor Cells Differentiated from Embryonic Stem Cells In Culture [GRO-seq]

Project description:Repair of DNA double-strand breaks (DSBs) by non-homologous end joining is critical for neural development, and brain cells frequently contain somatic genomic variations that might involve DSB intermediates. We now use an unbiased, high-throughput approach to identify genomic regions harboring recurrent DSBs in primary neural stem/progenitor cells (NSPCs). We identify 27 recurrent DSB clusters (RDCs), and remarkably, all occur within gene bodies. Most of these NSPC RDCs were detected only upon mild, aphidicolin-induced replication stress, providing a nucleotide-resolution view of replication-associated genomic fragile sites. The vast majority of RDCs occur in long, transcribed, and late-replicating genes. Moreover, almost 90% of identified RDC-containing genes are involved in synapse function and/or neural cell adhesion, with a substantial fraction also implicated in tumor suppression and/or mental disorders. Our characterization of NSPC RDCs reveals a basis of gene fragility and suggests potential impacts of DNA breaks on neurodevelopment and neural functions.

Project description:Repair of DNA double-strand breaks (DSBs) by non-homologous end-joining is critical for neural development, and brain cells frequently contain somatic genomic variations that might involve DSB intermediates. We now use an unbiased, high-throughput approach to identify genomic regions harboring recurrent DSBs in primary neural stem/progenitor cells (NSPCs). We identify 27 recurrent DSB clusters (RDCs) and, remarkably, all occur within gene bodies. Most of these NSPC RDCs were detected only upon mild, aphidicolin-induced replication stress, providing a nucleotide-resolution view of replication-associated genomic fragile sites. The vast majority of RDCs occur in long, transcribed, and late-replicating genes. Moreover, almost 90% of identified RDC-containing genes are involved in synapse function and/or neural cell adhesion, with a substantial fraction also implicated in tumor suppression and/or mental disorders. Our characterization of NSPC RDCs reveals a basis of gene fragility and suggests potential impacts of DNA breaks on neurodevelopment and neural functions. We performed high-throughput, genome-wide, translocation sequencing (HTGTS) and GRO-seq in primary mouse neural stem/progenitor cells of the indicated genotypes.

Project description:Repair of DNA double-strand breaks (DSBs) by non-homologous end-joining is critical for neural development, and brain cells frequently contain somatic genomic variations that might involve DSB intermediates. We now use an unbiased, high-throughput approach to identify genomic regions harboring recurrent DSBs in primary neural stem/progenitor cells (NSPCs). We identify 27 recurrent DSB clusters (RDCs) and, remarkably, all occur within gene bodies. Most of these NSPC RDCs were detected only upon mild, aphidicolin-induced replication stress, providing a nucleotide-resolution view of replication-associated genomic fragile sites. The vast majority of RDCs occur in long, transcribed, and late-replicating genes. Moreover, almost 90% of identified RDC-containing genes are involved in synapse function and/or neural cell adhesion, with a substantial fraction also implicated in tumor suppression and/or mental disorders. Our characterization of NSPC RDCs reveals a basis of gene fragility and suggests potential impacts of DNA breaks on neurodevelopment and neural functions.

Project description:BackgroundDepletion of oocytes leads to ovarian aging-associated infertility, endocrine disruption and related diseases. Excitingly, unlimited oocytes can be generated by differentiation of primordial germ cell like cells (PGCLCs) from pluripotent stem cells. Nevertheless, development of oocytes and follicles from PGCLCs relies on developmentally matched gonadal somatic cells, only available from E12.5 embryos in mice. It is therefore imperative to achieve an in vitro source of E12.5 gonadal somatic cells.MethodsWe explored to identify small molecules, which can induce female embryonic stem cells (ESCs) into gonadal somatic cell like cells.ResultsUsing RNA-sequencing, we identified signaling pathways highly upregulated in E12.5_gonadal somatic cells (E12.5_GSCs). Through searching for the activators of these pathways, we identified small-molecule compounds Vitamin C (Vc) and AM580 in combination (V580) for inducing differentiation of female embryonic stem cells (ESCs) into E12.5_GSC-like cells (E12.5_GSCLCs). After V580 treatment for 6 days and sorted by a surface marker CD63, the cell population yielded a transcriptome profile similar to that of E12.5_GSCs, which promoted meiosis progression and folliculogenesis of primordial germ cells. This approach will contribute to the study of germ cell and follicle development and oocyte production and have implications in potentially treating female infertility.ConclusionESCs can be induced into embryonic gonadal somatic cell like cells by small molecules.