沉默蛋白NeP1引起的DNA弯曲受到甲状腺激素受体(TR)和视黄酸X受体(RXR)的调节。
DNA bending by the silencer protein NeP1 is modulated by TR and RXR.
作者信息
Arnold R, Burcin M, Kaiser B, Muller M, Renkawitz R
机构信息
Genetisches Institut, Justus-Liebig-Universität, Giessen, Germany.
出版信息
Nucleic Acids Res. 1996 Jul 15;24(14):2640-7. doi: 10.1093/nar/24.14.2640.
Abstract
NeP1 binds to the F1 silencer element of the chicken lysozyme gene and, in the presence of TR, v-ERBA or RAR, synergistically represses transcriptional activity. This repression involves a silencing mechanism acting independently of the relative promoter position. Here we show that NeP1 alone can induce a significant directed bend on DNA. The chicken homologue of human NeP1, CTCF, shows identical binding and bending properties. In contrast, the isolated DNA binding domain of CTCF efficiently binds DNA, but fails to confer bending. Similarly, the TR-RXR hetero- or homodimer, binding adjacent to NeP1 at the F2 sequence, do not show significant DNA bending. The binding of the T3 ligand to TR changes neither the magnitude nor the direction of the NeP1 induced bend. However, when all factors are bound simultaneously as a quaternary complex, the TR-RXR heterodimer changes the location of the bend center, the flexure angle and the bending direction.
摘要
NeP1与鸡溶菌酶基因的F1沉默元件结合,并且在甲状腺激素受体(TR)、v-ERBA或视黄酸受体(RAR)存在的情况下,协同抑制转录活性。这种抑制涉及一种独立于相对启动子位置起作用的沉默机制。在此我们表明,单独的NeP1就能在DNA上诱导显著的定向弯曲。人类NeP1的鸡同源物CTCF表现出相同的结合和弯曲特性。相比之下,CTCF的分离的DNA结合结构域能有效地结合DNA,但无法产生弯曲。同样,在F2序列处与NeP1相邻结合的TR-RXR异源或同源二聚体,也不会表现出显著的DNA弯曲。T3配体与TR的结合既不改变NeP1诱导弯曲的幅度,也不改变其方向。然而,当所有因子作为四聚体复合物同时结合时,TR-RXR异源二聚体会改变弯曲中心的位置、弯曲角度和弯曲方向。
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