高等植物中SWI/SNF染色质重塑研究的新进展

染色质重塑是真核生物表观遗传调控的重要方式．通过对染色质物理结构的调节,染色质重塑在高等动植物干细胞的自我更新及分化、器官和个体发育以及肿瘤发生等多种生物学过程中发挥重要作用．近年来,高等动植物染色质重塑方面的研究已经成为表观遗传学研究领域的热点．本综述总结近年来有关高等动植物染色质重塑的重要研究报道,介绍了染色质重塑的结构机制、分析比较了高等动植物染色质重塑复合体的组成及其生物学功能的多样性,并着重综述了高等植物SWI/SNF染色质重塑复合体各组分在调控植物发育与逆境生长等方面的功能,以期为今后植物中染色质重塑的研究提供启示．     

Biochemical characterisation of the SWI/SNF family member HLTF

HLTF is highly similar in domain organisation to yeast Rad5. We identify PTIP and RPA70, both involved in DNA replication and DNA repair, as HLTF-interacting proteins although cells depleted of HLTF did not show defects in cellular responses to DNA damage. In vitro, HLTF has ATPase activity and E3 ubiquitin ligase activity with a range of E2 ubiquitin conjugating enzymes. HLTF expression is severely reduced in a range of cancer cells, and we suggest that the HLTF antibodies generated in this study could be used for cancer diagnostic purposes.     

Mutations in two non‐canonical Arabidopsis SWI2/SNF2 chromatin remodeling ATPases cause embryogenesis and stem cell maintenance defects

SWI2/SNF2 chromatin remodeling ATPases play important roles in plant and metazoan development. Whereas metazoans generally encode one or two SWI2/SNF2 ATPase genes, Arabidopsis encodes four such chromatin regulators: the well‐studied BRAHMA and SPLAYED ATPases, as well as two closely related non‐canonical SWI2/SNF2 ATPases, CHR12 and CHR23. No developmental role has as yet been described for CHR12 and CHR23. Here, we show that although strong single chr12 or chr23 mutants are morphologically indistinguishable from the wild type, chr12 chr23 double mutants cause embryonic lethality. The double mutant embryos fail to initiate root and shoot meristems, and display few and aberrant cell divisions. Weak double mutant embryos give rise to viable seedlings with dramatic defects in the maintenance of both the shoot and the root stem cell populations. Paradoxically, the stem cell defects are correlated with increased expression of the stem cell markers WUSCHEL and WOX5. During subsequent development, the meristem defects are partially overcome to allow for the formation of very small, bushy adult plants. Based on the observed morphological defects, we named the two chromatin remodelers MINUSCULE 1 and 2. Possible links between minu1 minu2 defects and defects in hormone signaling and replication‐coupled chromatin assembly are discussed.     

The SWI/SNF chromatin-remodeling gene AtCHR12 mediates temporary growth arrest in Arabidopsis thaliana upon perceiving environmental stress

One of the earliest responses of plants to environmental stress is establishing a temporary growth arrest that allows adaptation to adverse conditions. The response to abiotic stress requires the modulation of gene expression, which may be mediated by the alteration of chromatin structures. This alteration can be accomplished with the help of chromatin-remodeling enzymes, such as the various SWI/SNF classes of ATPases. Here, we investigate the role of the Arabidopsis SNF2/Brahma-type AtCHR12 chromatin-remodeling gene in plant growth and development in reaction to adverse environmental conditions. We show that the AtCHR12 chromatin-remodeling gene plays a vital role in mediating the temporary growth arrest of Arabidopsis that is induced upon perception of stress. Exposing an AtCHR12 overexpressing mutant to stress conditions leads to growth arrest of normally active primary buds, as well as to reduced growth of the primary stem. In contrast, the AtCHR12 knockout mutant shows less growth arrest than the wild-type when exposed to moderate stress. Without stress, mutant plants are indistinguishable from the wild-type, and the growth arrest response seems to depend on the severity of the stress applied. Modulation of AtCHR12 expression correlates with changes in expression of dormancy-associated genes. This is in agreement with the concept of AtCHR12 participation in priming the plants for the growth arrest response. Our data indicate that AtCHR12-associated growth arrest differs from DELLA-mediated growth restraint. This establishes AtCHR12 as a novel gene involved in the response repertoire of plants that permits flexible modulation of growth in adverse and/or otherwise limiting environments.     

Characterization of a human SWI2/SNF2 like protein hINO80: demonstration of catalytic and DNA binding activity

The proteins belonging to SWI2/SNF2 family of DNA dependent ATPases are important members of the chromatin remodeling complexes that are implicated in epigenetic control of gene expression. We have identified a human gene with a putative DNA binding domain, which belongs to the INO80 subfamily of SWI2/SNF2 proteins. Here we report the cloning, expression, and functional activity of the domains from hINO80 gene both in terms of the DNA dependent ATPase as well as DNA binding activity. A differential expression of the various domains within this gene is detected in human tissues while a ubiquitous expression is detected in mice. The intranuclear localization is demonstrated using antibodies directed against the DBINO domain of hINO80.     

A cooperative activation loop among SWI/SNF, γ‐H2AX and H3 acetylation for DNA double‐strand break repair

Although recent studies highlight the importance of histone modifications and ATP‐dependent chromatin remodelling in DNA double‐strand break (DSB) repair, how these mechanisms cooperate has remained largely unexplored. Here, we show that the SWI/SNF chromatin remodelling complex, earlier known to facilitate the phosphorylation of histone H2AX at Ser‐139 (S139ph) after DNA damage, binds to γ‐H2AX (the phosphorylated form of H2AX)‐containing nucleosomes in S139ph‐dependent manner. Unexpectedly, BRG1, the catalytic subunit of SWI/SNF, binds to γ‐H2AX nucleosomes by interacting with acetylated H3, not with S139ph itself, through its bromodomain. Blocking the BRG1 interaction with γ‐H2AX nucleosomes either by deletion or overexpression of the BRG1 bromodomain leads to defect of S139ph and DSB repair. H3 acetylation is required for the binding of BRG1 to γ‐H2AX nucleosomes. S139ph stimulates the H3 acetylation on γ‐H2AX nucleosomes, and the histone acetyltransferase Gcn5 is responsible for this novel crosstalk. The H3 acetylation on γ‐H2AX nucleosomes is induced by DNA damage. These results collectively suggest that SWI/SNF, γ‐H2AX and H3 acetylation cooperatively act in a feedback activation loop to facilitate DSB repair.     

NSD1 mediates antagonism between SWI/SNF and polycomb complexes and is required for transcriptional activation upon EZH2 inhibition

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