Project description:The assembly of repressive heterochromatin domains in eukaryotic genomes is crucial for silencing lineage-inappropriate genes and repetitive DNA elements. Paradoxically, transcription of repetitive elements within constitutive heterochromatin domains is required for RNA-based mechanisms, such as the RNAi pathway, to target heterochromatin assembly proteins. However, the mechanism by which heterochromatic repeat elements are transcribed has been unclear. Using fission yeast, we show that the conserved trimeric transcription factor (TF) PhpCNF-Y complex, which includes histone fold domain proteins, can infiltrate constitutive heterochromatin to transcribe repeat elements. PhpCNF-Y collaborates with a Zn-finger containing TF to bind heterochromatic repeat promoter regions with CCAAT boxes. Mutating either the TFs or the CCAAT binding site disrupts the transcription of heterochromatic repeats. Although repeat elements are transcribed from both strands, PhpCNF-Y-dependent transcripts originate from only one strand. These TF-driven transcripts contain cryptic introns that are processed via a mechanism requiring the spliceosome to generate small interfering RNAs (siRNAs) by the RNAi machinery. Our analyses show that siRNA production by this TF-mediated transcription pathway is critical for nucleation of heterochromatin at target repeat loci. This study reveals a mechanism by which heterochromatic repeats are transcribed, initiating their own silencing by triggering a primary cascade that produces siRNAs necessary for heterochromatin nucleation.

Project description:Many repetitive DNA elements are packaged in heterochromatin, but depend on occasional transcription to maintain long-term silencing. The factors that promote transcription of repeat elements in heterochromatin are largely unknown. Here, we show that DOT1L, a histone methyltransferase that modifies lysine 79 of histone H3 (H3K79), is required for transcription of major satellite repeats to maintain pericentromeric heterochromatin (PCH), and that this function is essential for preimplantation development. DOT1L is a transcriptional activator at single-copy genes but does not have a known role in repeat element transcription. We show that H3K79me3 is specifically enriched at repetitive elements, that loss of DOT1L compromises pericentromeric major satellite transcription, and that this function depends on interaction between DOT1L and the chromatin remodeler SMARCA5. DOT1L inhibition causes chromosome breaks and cell cycle defects, and leads to embryonic lethality. Together, our findings uncover a vital new role for DOT1L in transcriptional activation of heterochromatic repeats.

Project description:Heterochromatin regions of the genome are transcriptionally repressive in nature. However, constitutive heterochromatin, such as at centromeres and telomeres, coats regions harboring multiple repetitive DNA elements that are preferentially transcribed during S-phase by RNA polymerase II. RNAi machinery processes the transcripts to generate small RNAs (siRNAs) that are crucial for heterochromatin assembly. Despite significant mechanistic advances in the field, the contribution of transcription factor (TF) based mechanisms to repeat element transcription and siRNA production is unclear. Here, we discover that the conserved TF PhpCNF-Y, which contains a histone fold motif, collaborates with a Zn-finger domain-containing factor, Moc3, to access specific sites within the heterochromatin region, regardless of the presence of the repressive histone methylation mark. The cooperative function of the TFs is essential for gaining access to the heterochromatin region, where they bind to specific CCAAT motif sites within the heterochromatic repeat elements cenH and dh. Perturbation of heterochromatin has minimal effect on the binding of the TFs to these specific sites, and they remain bound even outside of the S-phase. We find that PhpCNF-Y and Moc3 mediate the transcription of the repeat elements originating from a bottom strand of cenH, which the spliceosome targets to generate siRNAs in a Swi6HP1-independent manner. This pathway for generating the initial transcripts is crucial for de novo heterochromatin assembly. Collectively, our study uncovers a fundamental transcription factor-based mechanism that gains access to the heterochromatin to enforce transcriptional silencing of repeat elements. Our findings provide significant insights into de novo heterochromatin assembly.

Project description:Heterochromatin regions of the genome are transcriptionally repressive in nature. However, constitutive heterochromatin, such as at centromeres and telomeres, coats regions harboring multiple repetitive DNA elements that are preferentially transcribed during S-phase by RNA polymerase II. RNAi machinery processes the transcripts to generate small RNAs (siRNAs) that are crucial for heterochromatin assembly. Despite significant mechanistic advances in the field, the contribution of transcription factor (TF) based mechanisms to repeat element transcription and siRNA production is unclear. Here, we discover that the conserved TF PhpCNF-Y, which contains a histone fold motif, collaborates with a Zn-finger domain-containing factor, Moc3, to access specific sites within the heterochromatin region, regardless of the presence of the repressive histone methylation mark. The cooperative function of the TFs is essential for gaining access to the heterochromatin region, where they bind to specific CCAAT motif sites within the heterochromatic repeat elements cenH and dh. Perturbation of heterochromatin has minimal effect on the binding of the TFs to these specific sites, and they remain bound even outside of the S-phase. We find that PhpCNF-Y and Moc3 mediate the transcription of the repeat elements originating from a bottom strand of cenH, which the spliceosome targets to generate siRNAs in a Swi6HP1-independent manner. This pathway for generating the initial transcripts is crucial for de novo heterochromatin assembly. Collectively, our study uncovers a fundamental transcription factor-based mechanism that gains access to the heterochromatin to enforce transcriptional silencing of repeat elements. Our findings provide significant insights into de novo heterochromatin assembly.

Project description:Heterochromatin regions of the genome are transcriptionally repressive in nature. However, constitutive heterochromatin, such as at centromeres and telomeres, coats regions harboring multiple repetitive DNA elements that are preferentially transcribed during S-phase by RNA polymerase II. RNAi machinery processes the transcripts to generate small RNAs (siRNAs) that are crucial for heterochromatin assembly. Despite significant mechanistic advances in the field, the contribution of transcription factor (TF) based mechanisms to repeat element transcription and siRNA production is unclear. Here, we discover that the conserved TF PhpCNF-Y, which contains a histone fold motif, collaborates with a Zn-finger domain-containing factor, Moc3, to access specific sites within the heterochromatin region, regardless of the presence of the repressive histone methylation mark. The cooperative function of the TFs is essential for gaining access to the heterochromatin region, where they bind to specific CCAAT motif sites within the heterochromatic repeat elements cenH and dh. Perturbation of heterochromatin has minimal effect on the binding of the TFs to these specific sites, and they remain bound even outside of the S-phase. We find that PhpCNF-Y and Moc3 mediate the transcription of the repeat elements originating from a bottom strand of cenH, which the spliceosome targets to generate siRNAs in a Swi6HP1-independent manner. This pathway for generating the initial transcripts is crucial for de novo heterochromatin assembly. Collectively, our study uncovers a fundamental transcription factor-based mechanism that gains access to the heterochromatin to enforce transcriptional silencing of repeat elements. Our findings provide significant insights into de novo heterochromatin assembly.

Project description:In S. pombe, transcripts derived from the pericentromeric dg and dh repeats promote heterochromatin formation via RNAi as well as an RNAi-independent mechanism involving the RNAPII-associated RNA-binding protein Seb1 and RNA processing activities. We show that Seb1 promotes long-lived RNAPII pauses at pericentromeric repeat regions and their presence correlates with the heterochromatin-triggering activities of the corresponding dg and dh DNA fragments. Globally increasing RNAPII stalling by other means induces the formation of novel large ectopic heterochromatin domains. Such ectopic heterochromatin occurs even in cells lacking RNAi. These results uncover Seb1-mediated polymerase stalling as a signal necessary for heterochromatin nucleation.

Project description:In S. pombe, transcripts derived from the pericentromeric dg and dh repeats promote heterochromatin formation via RNAi as well as an RNAi-independent mechanism involving the RNAPII-associated RNA-binding protein Seb1 and RNA processing activities. We show that Seb1 promotes long-lived RNAPII pauses at pericentromeric repeat regions and their presence correlates with the heterochromatin-triggering activities of the corresponding dg and dh DNA fragments. Globally increasing RNAPII stalling by other means induces the formation of novel large ectopic heterochromatin domains. Such ectopic heterochromatin occurs even in cells lacking RNAi. These results uncover Seb1-mediated polymerase stalling as a signal necessary for heterochromatin nucleation.

Project description:In S. pombe, transcripts derived from the pericentromeric dg and dh repeats promote heterochromatin formation via RNAi as well as an RNAi-independent mechanism involving the RNAPII-associated RNA-binding protein Seb1 and RNA processing activities. We show that Seb1 promotes long-lived RNAPII pauses at pericentromeric repeat regions and their presence correlates with the heterochromatin-triggering activities of the corresponding dg and dh DNA fragments. Globally increasing RNAPII stalling by other means induces the formation of novel large ectopic heterochromatin domains. Such ectopic heterochromatin occurs even in cells lacking RNAi. These results uncover Seb1-mediated polymerase stalling as a signal necessary for heterochromatin nucleation.

Project description:In S. pombe, transcripts derived from the pericentromeric dg and dh repeats promote heterochromatin formation via RNAi as well as an RNAi-independent mechanism involving the RNAPII-associated RNA-binding protein Seb1 and RNA processing activities. We show that Seb1 promotes long-lived RNAPII pauses at pericentromeric repeat regions and their presence correlates with the heterochromatin-triggering activities of the corresponding dg and dh DNA fragments. Globally increasing RNAPII stalling by other means induces the formation of novel large ectopic heterochromatin domains. Such ectopic heterochromatin occurs even in cells lacking RNAi. These results uncover Seb1-mediated polymerase stalling as a signal necessary for heterochromatin nucleation.

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