Project description:Heterochromatin stability is crucial for progenitor proliferation during early neurogenesis. It relays on the maintenance of local hubs of H3K9me. However, the current understanding of the processes involved in the formation of efficient localized levels of H3K9me remains limited. To address this intriguing question, we used a neural stem cell (NSC) to analyze the function of the H3K9me2 demethylase PHF2, which is crucial for progenitor proliferation. Through mass spectroscopy and genome-wide assays, we uncovered that PHF2 interacts with heterochromatin components and it is enriched at pericentromeric heterochromatin (PcH) boundaries. This binding is essential for maintaining silenced the satellite repeats thereby preventing DNA damage and genome instability. Depletion of PHF2 led to increased transcription of heterochromatic repeats, accompanied by a decrease in H3K9me3 levels and alterations in PcH organization. Further analysis revealed that PHF2's PHD and catalytic domains are crucial for maintaining PcH stability and preventing unscheduled repeat transcription, thereby safeguarding genome integrity. These results highlight the multifaceted nature of PHF2's functions in maintaining heterochromatin stability and regulating gene expression during neural development. Altogether, our study unravels the intricate relationship between heterochromatin stability and progenitor proliferation during mammalian neurogenesis, shedding light on its potential as a therapeutic target for neurodevelopmental disorders

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

Project description:Heterochromatin stability is crucial for progenitor proliferation during development. It relays on the maintenance of local hubs of H3K9me. However, the mechanisms underlying the establishment of competent local levels of H3K9me remain poorly understood. To address this intriguing question, we used a neural stem cell (NSC) model to analyze the significance of the H3K9me2 demethylase PHF2, which is crucial for progenitor proliferation. Through mass spectroscopy and genome-wide assays, we uncovered that PHF2 interacts with heterochromatin components and it is enriched at pericentromeric heterochromatin (PcH) boundaries. This binding is essential for maintaining silenced the satellite repeats and to prevent DNA damage and genome instability. To do that, PHF2 balances H3K9me3 levels at these boundaries to ensure high H3K9me3 levels at satellite repeats. Mechanistically, we discover that while its catalytic and PHD domains are indispensable, the intrinsically disordered region within PHF2 is dispensable for stabilizing PcH. Altogether, our study sheds light on the intricate relationship between heterochromatin stability and progenitor proliferation during mammalian neurogenesis.

Project description:Heterochromatin stability is crucial for progenitor proliferation during development. It relays on the maintenance of local hubs of H3K9me. However, the mechanisms underlying the establishment of competent local levels of H3K9me remain poorly understood. To address this intriguing question, we used a neural stem cell (NSC) model to analyze the significance of the H3K9me2 demethylase PHF2, which is crucial for progenitor proliferation. Through mass spectroscopy and genome-wide assays, we uncovered that PHF2 interacts with heterochromatin components and it is enriched at pericentromeric heterochromatin (PcH) boundaries. This binding is essential for maintaining silenced the satellite repeats and to prevent DNA damage and genome instability. To do that, PHF2 balances H3K9me3 levels at these boundaries to ensure high H3K9me3 levels at satellite repeats. Mechanistically, we discover that while its catalytic and PHD domains are indispensable, the intrinsically disordered region within PHF2 is dispensable for stabilizing PcH. Altogether, our study sheds light on the intricate relationship between heterochromatin stability and progenitor proliferation during mammalian neurogenesis.

Project description:PHF2 maintains neural progenitor genome stability by preserving pericentric heterochromatin integrity

Project description:PHF2 maintains neural progenitor genome stability by preserving pericentric heterochromatin integrity (ChIP-Seq)

Project description:PHF2 maintains neural progenitor genome stability by preserving pericentric heterochromatin integrity (ATAC-Seq)

Project description:We report the genomic characterization of H2AZ binding at E13 brain. ChIP experiment was performed with antibody against H2AZ. we generated genome-wide characterization of H2AZ occupancy and find that H2AZ was prone to bind the promoter and the intergenic regions. The genomic localization of H2AZ might reveal its essential role during early neurogenesis. Gene ontology (GO) analysis, revealing that these genes occupied by H2AZ play roles in the cellular metabolic process, DNA replication, cell cycle, and neuron development and so on. Detailed investigation of the binding profiles show that direct binding of NkX2-4 by H2AZ. This study provides a framework for the epigenetic regulation of H2AZ in embryonic neurogenesis.

Project description:Purpose:To gain a deeper insight into how H2AZ regulates embryonic neurogenesis, RNA-sequencing (RNA-seq) was performed to analyze the genome-wide changes by H2AZ deletion at E12. Methods: Total RNA was extracted from E12 telencephalic tissue of H2AZcKO and H2AZfl/fl mice. Then total RNA was quality controlled and quantified using an Agilent 2100 Bioanalyzer. After converting to cDNA and building library, high-throughput sequencing was performed using the Illumina HiSeq 2500 platform in Annoroad Genomics. Results: Approximately approximately one thousand transcripts showed differential expression between the H2AZfl/fl and H2AZcKO brain, with a fold change ≥1.5 and p value <0.05. Gene ontology (GO) analysis showed that the down-regulated genes were enriched in the terms related to transcription and cortex development, such as regulation of transcription, cerebellar cortex formation, forebrain development, and cerebellum development. Up-regulated genes showed a significant enrichment of terms involved in negative regulation of cell differentiation, neuron migration, and cognition. These results reflected the importance of H2AZ in cortical development. Conclusions: We conclude that RNA-seq based transcriptome characterization would provide a framework for understanding how a disruption in the H2AZ gene may contribute to cortical development.

Project description:Since the highly conserved exosome complex mediates the degradation and processing of multiple classes of RNAs, it almost certainly controls diverse biological processes. How this post-transcriptional RNA-regulatory machine impacts cell fate decisions and differentiation is poorly understood. Previously, we demonstrated that exosome complex subunits confer an erythroid maturation barricade, and the erythroid transcription factor GATA-1 dismantles the barricade by transcriptionally repressing the cognate genes. While dissecting requirements for the maturation barricade in Mus musculus, we discovered that the exosome complex is a vital determinant of a developmental signaling transition that dictates proliferation/amplification versus differentiation. Exosome complex integrity in erythroid precursor cells ensures Kit receptor tyrosine kinase expression and stem cell factor/Kit signaling, while preventing responsiveness to erythropoietin-instigated signals that promote differentiation. Functioning as a gatekeeper of this developmental signaling transition, the exosome complex controls the massive production of erythroid cells that ensures organismal survival in homeostatic and stress contexts.