Takahiro Asanuma scite author profile

In most eukaryotes, constitutive heterochromatin, defined by histone H3 lysine 9 methylation (H3K9me), is enriched on repetitive DNA, such as pericentromeric repeats and transposons. Furthermore, repetitive transgenes also induce heterochromatin formation in diverse model organisms. However, the mechanisms that promote heterochromatin formation at repetitive DNA elements are still not clear. Here, using fission yeast, we show that tandemly repeated mRNA genes promote RNA interference (RNAi)-mediated heterochromatin formation in cooperation with an antisilencing factor, Epe1. Although the presence of tandemly repeated genes itself does not cause heterochromatin formation, once complementary small RNAs are artificially supplied intrans, the RNAi machinery assembled on the repeated genes starts producing cognate small RNAs incisto autonomously maintain heterochromatin at these sites. This “repeat-induced RNAi” depends on the copy number of repeated genes and Epe1, which is known to remove H3K9me and derepress the transcription of genes underlying heterochromatin. Analogous to repeated genes, the DNA sequence underlying constitutive heterochromatin encodes widespread transcription start sites (TSSs), from which Epe1 activates ncRNA transcription to promote RNAi-mediated heterochromatin formation. Our results suggest that when repetitive transcription units underlie heterochromatin, Epe1 generates sufficient transcripts for the activation of RNAi without disruption of heterochromatin.

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Two secured FACT recruitment mechanisms are essential for heterochromatin maintenance

Takahata

Chida

Ohnuma

et al. 2021

Cell Reports

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FACT (facilitate chromatin transcription) is involved in heterochromatic silencing, but its mechanisms and function remain unclear. We reveal that the Spt16 recruitment mechanism operates in two distinct ways in heterochromatin. First, Pob3 mediates Spt16 recruitment onto the heterochromatin through its Spt16 dimerization and tandem PH domains. Without Pob3, Spt16 recruitment is partially reduced, exhibiting a silencing defect and impaired H2A/H2B organization. Second, heterochromatin protein 1 (HP1)/Swi6 mediates Spt16 recruitment onto the heterochromatin by physical interaction of the Swi6 chromo-shadow domain (CSD) and Spt16 peptidase-like domains. Several CSD mutants are tested for Spt16 binding activity, and the charged loop connecting b1 and b2 is critical for Spt16 binding and heterochromatic silencing. Loss of these pathways causes a severe defect in H3K9 methylation and HP1/Swi6 localization in the pericentromeric region, exhibiting transcriptional silencing defects and disordered heterochromatin. Our findings suggest that FACT and HP1/Swi6 work intimately to regulate heterochromatin organization.

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Sfh1, an essential component of the RSC chromatin remodeling complex, maintains genome integrity in fission yeast

et al. 2018

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Abp1 is a fission yeast CENP-B homologue that contributes to centromere function, silencing at pericentromeric heterochromatin and silencing of retrotransposons. We identified the sfh1 gene, encoding a core subunit of the fission yeast chromatin remodeling complex RSC as an Abp1-interacting protein. Because sfh1 is essential for growth, we isolated temperature-sensitive sfh1 mutants. These mutants showed defects in centromere functions, reflected by sensitivity to an inhibitor of spindle formation and minichromosome instability. Sfh1 localized at both kinetochore and pericentromeric heterochromatin regions. Although sfh1 mutations had minor effect on silencing at these regions, they decreased the levels of cohesin on centromeric heterochromatin. Sfh1 also localized at a retrotransposon, Tf2, in a partly Abp1-dependent manner, and assisted in silencing of Tf2 by Abp1 probably in the same pathway as a histone chaperon, HIRA, which is also known to involve in Tf2 repression. Furthermore, sfh1 mutants were sensitive to several DNA-damaging treatments (HU, MMS, UV and X-ray). Increase in spontaneous foci of Rad22, a recombination Mediator protein Rad52 homologue, in sfh1 mutant suggests that RSC functions in homologous recombination repair of double-stranded break downstream of the Rad22 recruitment. These results indicate that RSC plays multiple roles in the maintenance of genome integrity.

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Tandemly repeated genes promote RNAi-mediated heterochromatin formation via an anti-silencing factor Epe1 in fission yeast

Asanuma

Inagaki

Kakutani

et al. 2022

Preprint

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Introductory paragraphIn most eukaryotes, constitutive heterochromatin defined by H3K9me2/me3 is enriched on repetitive DNA, such as the satellite repeats of pericentromeres1. Furthermore, repetitive transgenes often cause the formation of silent heterochromatin in diverse model organisms2. Although these facts suggest that the repetition itself promotes heterochromatin formation, the mechanism by which this occurs is still unclear3–7. Here, using Schizosaccharomyces pombe, we show that tandemly repeated reporter genes promote RNA interference (RNAi)-mediated heterochromatin formation in cooperation with an anti-silencing factor. The repeated gene itself does not cause heterochromatin formation; however, once the RNAi recognizes it via artificial small RNAs, the repeated gene starts producing cognate small RNAs to autonomously maintain heterochromatin. This depends on the number of repeats and an anti-silencing factor Epe1, which removes H3K9me and derepresses transcription of genes underlying heterochromatin. Our results suggest that an anti-silencing factor generates sufficient transcripts for the activation of RNAi when repetitive DNA underlies silent heterochromatin.

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