Conserved linker length in double dsRBD proteins from plants restricts interdomain motion

IF 2.624
Florencia C. Mascali , Roberta Crespo , Leandro C. Tabares , Rodolfo M. Rasia
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引用次数: 1

Abstract

Double stranded RNA binding domains (dsRBDs) are ubiquitous in all kingdoms of life. They can participate both in RNA and protein recognition and are usually present in multiple copies in multidomain proteins. We analyzed the linkers between dsRBDs in different proteins and found that sequences corresponding to plant proteins have a highly conserved linker length. In order to assess the importance of linker length in the conformational freedom of double dsRBD plant proteins, we introduced lanthanide binding tags (LBTs) in different positions of the dsRBD containing protein HYL1 from Arabidopsis thaliana. These constructs were used to obtain conformational restraints from Double electron–electron resonance (DEER) measurements on doubly labeled proteins and from paramagnetic relaxation enhancement (PRE) in single labeled samples. Fitting the experimental datasets to a computational model of the ensemble created by allowing freedom to the linker region we found that the domains tend to explore a particular region of the allowed conformational space. The high conservation in linker length suggests that this restricted conformational sampling is functional, possibly hindering HYL1-dsRBD2 from contacting the substrate dsRNA and allowing it to participate in protein-protein interactions.

Abstract Image

植物双dsRBD蛋白中保守的连接子长度限制了结构域间的运动
双链RNA结合域(dsrbd)在所有生命体中普遍存在。它们可以参与RNA和蛋白质的识别,通常存在于多结构域蛋白的多个拷贝中。我们分析了不同蛋白的dsrbd之间的连接子,发现与植物蛋白对应的序列具有高度保守的连接子长度。为了评估连接体长度对双dsRBD植物蛋白构象自由的重要性,我们在拟南芥中含有HYL1蛋白的dsRBD的不同位置引入镧系结合标签(lbt)。这些结构被用来从双标记蛋白质的双电子-电子共振(DEER)测量和单标记样品的顺磁弛豫增强(PRE)中获得构象约束。将实验数据集拟合到通过允许连接区域自由创建的集成的计算模型中,我们发现这些域倾向于探索允许的构象空间的特定区域。连接体长度的高度保守性表明,这种受限的构象取样是功能性的,可能阻碍了HYL1-dsRBD2接触底物dsRNA并允许其参与蛋白质-蛋白质相互作用。
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CiteScore
1.90
自引率
0.00%
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