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在粘细菌黄色粘球菌发育过程中,MrpC2 和 FruA 对 fmgD 进行组合调控。

Combinatorial regulation of fmgD by MrpC2 and FruA during Myxococcus xanthus development.

机构信息

Department of Biochemistry and Molecular Biology, Michigan State University, East Lansing, MI 48824, USA.

出版信息

J Bacteriol. 2011 Apr;193(7):1681-9. doi: 10.1128/JB.01541-10. Epub 2011 Jan 21.

Abstract

Upon starvation, a dense population of rod-shaped Myxococcus xanthus bacteria coordinate their movements to construct mounds in which some of the cells differentiate to spherical spores. During this process of fruiting body formation, short-range C-signaling between cells regulates their movements and the expression of genes important for sporulation. C-signaling activates FruA, a transcription factor that binds cooperatively with another transcription factor, MrpC2, upstream of the fmgA and fmgBC promoters, activating transcription. We have found that a third C-signal-dependent gene, herein named fmgD, is subject to combinatorial control by FruA and MrpC2. The two proteins appear to bind cooperatively upstream of the fmgD promoter and activate transcription. FruA binds proximal to the fmgD promoter, as in the fmgBC promoter region, whereas MrpC2 binds proximal to the fmgA promoter. A novel feature of the fmgD promoter region is the presence of a second MrpC2 binding site partially overlapping the promoter and therefore likely to mediate repression. The downstream MrpC2 site appears to overlap the FruA site, so the two transcription factors may compete for binding, which in both cases appears to be cooperative with MrpC2 at the upstream site. We propose that binding of MrpC2 to the downstream site represses fmgD transcription until C-signaling causes the concentration of active FruA to increase sufficiently to outcompete the downstream MrpC2 for cooperative binding with the upstream MrpC2. This would explain why fmgD transcription begins later during development and is more dependent on C-signaling than transcription of fmgA and fmgBC.

摘要

在饥饿状态下,密集的杆状粘细菌(Myxococcus xanthus)协调它们的运动,构建菌堆,其中一些细胞分化成球形孢子。在这个生殖体形成过程中,细胞间的短程 C 信号调节它们的运动和与孢子形成相关的基因表达。C 信号激活 FruA,这是一种转录因子,与另一种转录因子 MrpC2 合作结合在 fmgA 和 fmgBC 启动子的上游,激活转录。我们发现第三个依赖 C 信号的基因 fmgD,受到 FruA 和 MrpC2 的组合调控。这两种蛋白似乎在 fmgD 启动子的上游合作结合并激活转录。FruA 靠近 fmgD 启动子结合,就像在 fmgBC 启动子区域一样,而 MrpC2 靠近 fmgA 启动子结合。fmgD 启动子区域的一个新特征是存在第二个 MrpC2 结合位点,部分重叠启动子,因此可能介导抑制。下游 MrpC2 位点似乎与 FruA 位点重叠,因此这两个转录因子可能竞争结合,在这两种情况下,与上游 MrpC2 结合似乎都是合作的。我们提出,MrpC2 结合到下游位点抑制 fmgD 转录,直到 C 信号导致活性 FruA 浓度增加到足以与下游 MrpC2 竞争与上游 MrpC2 合作结合。这可以解释为什么 fmgD 转录在发育过程中开始得更晚,并且比转录 fmgA 和 fmgBC 更依赖于 C 信号。

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