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MADS 结构域转录因子介导短距离 DNA 环化,这对拟南芥靶基因的表达至关重要。

MADS domain transcription factors mediate short-range DNA looping that is essential for target gene expression in Arabidopsis.

机构信息

Dipartimento di BioScienze, Università degli Studi di Milano, 20133 Milan, Italy.

出版信息

Plant Cell. 2013 Jul;25(7):2560-72. doi: 10.1105/tpc.112.108688. Epub 2013 Jul 11.

DOI:10.1105/tpc.112.108688
PMID:23847151
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3753383/
Abstract

MADS domain transcription factors are key regulators of eukaryotic development. In plants, the homeotic MIKC MADS factors that regulate floral organ identity have been studied in great detail. Based on genetic and protein-protein interaction studies, a floral quartet model was proposed that describes how these MADS domain proteins assemble into higher order complexes to regulate their target genes. However, despite the attractiveness of this model and its general acceptance in the literature, solid in vivo proof has never been provided. To gain deeper insight into the mechanisms of transcriptional regulation by MADS domain factors, we studied how SEEDSTICK (STK) and SEPALLATA3 (SEP3) directly regulate the expression of the reproductive meristem gene family transcription factor-encoding gene VERDANDI (VDD). Our data show that STK-SEP3 dimers can induce loop formation in the VDD promoter by binding to two nearby CC(A/T)6GG (CArG) boxes and that this is essential for promoter activity. Our in vivo data show that the size and position of this loop, determined by the choice of CArG element usage, is essential for correct expression. Our studies provide solid in vivo evidence for the floral quartet model.

摘要

MADS 结构域转录因子是真核生物发育的关键调节剂。在植物中,调控花器官身份的同源异型 MIKC MADS 因子已被深入研究。基于遗传和蛋白质-蛋白质相互作用研究,提出了花四分体模型,描述了这些 MADS 结构域蛋白如何组装成更高阶的复合物来调节其靶基因。然而,尽管该模型具有吸引力,并且在文献中得到了普遍认可,但从未提供过确凿的体内证据。为了更深入地了解 MADS 结构域因子对转录调控的机制,我们研究了 SEEDSTICK(STK)和 SEPALLATA3(SEP3)如何直接调节生殖分生组织基因家族转录因子编码基因 VERDANDI(VDD)的表达。我们的数据表明,STK-SEP3 二聚体可以通过结合两个附近的 CC(A/T)6GG(CArG)盒在 VDD 启动子上诱导环形成,这对于启动子活性是必需的。我们的体内数据表明,由 CArG 元件使用决定的环的大小和位置对于正确的表达是必需的。我们的研究为花四分体模型提供了确凿的体内证据。

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