Aoto Takahiro, Saitoh Noriko, Sakamoto Yasuo, Watanabe Sugiko, Nakao Mitsuyoshi
Department of Regeneration Medicine, Institute of Molecular Embryology and Genetics, Kumamoto University, 2-2-1 Honjo, Kumamoto 860-0811, Japan.
J Biol Chem. 2008 Jul 4;283(27):18905-15. doi: 10.1074/jbc.M709322200. Epub 2008 May 2.
Polycomb group (PcG) proteins form two distinct complexes, PRC1 and PRC2, to regulate developmental target genes by maintaining the epigenetic state in cells. PRC2 methylates histone H3 at lysine 27 (H3K27), and PRC1 then recognizes methyl-H3K27 to form repressive chromatin. However, it remains unknown how PcG proteins maintain stable and plastic chromatin during cell division. Here we report that PcG-associated chromatin is reproduced in the G(1) phase in post-mitotic cells and is required for subsequent S phase progression. In dividing cells, H3K27 trimethylation (H3K27Me(3)) marked mitotic chromosome arms where PRC2 (Suz12 and Ezh2) co-existed, whereas PRC1 (Bmi1 and Pc2) appeared in distinct foci in the pericentromeric regions. As each PRC complex was increasingly assembled from mitosis to G(1) phase, PRC1 formed H3K27Me(3)-based chromatin intensively during middle and late G(1) phase; this chromatin was highly resistant to in situ nuclease treatment. Thus, the transition from mitosis to G(1) phase is crucial for PcG-mediated chromatin inheritance. Knockdown of Suz12 markedly reduced the amount of H3K27Me(3) on mitotic chromosomes, and as a consequence, PRC1 foci were not fully transmitted to post-mitotic daughter cells. S phase progression was markedly delayed in these Suz12-knockdown cells. The fact that PcG-associated chromatin is reproduced during post-mitotic G(1) phase suggests the possibility that PcG proteins enable their target chromatin to be remodeled in response to stimuli in the G(1) phase.
多梳蛋白家族(PcG)形成两种不同的复合物,即PRC1和PRC2,通过维持细胞中的表观遗传状态来调控发育靶基因。PRC2使组蛋白H3的赖氨酸27位点(H3K27)发生甲基化,然后PRC1识别甲基化的H3K27以形成抑制性染色质。然而,目前尚不清楚PcG蛋白如何在细胞分裂过程中维持稳定且具有可塑性的染色质。在此我们报告,与PcG相关的染色质在有丝分裂后细胞的G1期得以重现,并且是随后S期进展所必需的。在分裂细胞中,H3K27三甲基化(H3K27Me3)标记了有丝分裂染色体臂,PRC2(Suz12和Ezh2)共存于此,而PRC1(Bmi1和Pc2)则出现在着丝粒周围区域的不同位点。随着每个PRC复合物从有丝分裂期到G1期逐渐组装,PRC1在G1期中期和后期强烈形成基于H3K27Me3的染色质;这种染色质对原位核酸酶处理具有高度抗性。因此,从有丝分裂期到G1期的转变对于PcG介导的染色质遗传至关重要。敲低Suz12会显著减少有丝分裂染色体上H3K27Me3的量,结果,PRC1位点无法完全传递给有丝分裂后的子细胞。在这些Suz12敲低的细胞中,S期进展明显延迟。与PcG相关的染色质在有丝分裂后G1期得以重现这一事实表明,PcG蛋白有可能使其靶染色质在G1期响应刺激而发生重塑。
