合作型甘氨酸核糖开关感应结构域识别配体的结构见解。
Structural insights into ligand recognition by a sensing domain of the cooperative glycine riboswitch.
机构信息
Structural Biology Program, Memorial Sloan-Kettering Cancer Center, New York, NY 10065, USA.
出版信息
Mol Cell. 2010 Dec 10;40(5):774-86. doi: 10.1016/j.molcel.2010.11.026.
Abstract
Glycine riboswitches regulate gene expression by feedback modulation in response to cooperative binding to glycine. Here, we report on crystal structures of the second glycine-sensing domain from the Vibrio cholerae riboswitch in the ligand-bound and unbound states. This domain adopts a three-helical fold that centers on a three-way junction and accommodates glycine within a bulge-containing binding pocket above the junction. Glycine recognition is facilitated by a pair of bound Mg(2+) cations and governed by specific interactions and shape complementarity with the pocket. A conserved adenine extrudes from the binding pocket and intercalates into the junction implying that glycine binding in the context of the complete riboswitch could impact on gene expression by stabilizing the riboswitch junction and regulatory P1 helix. Analysis of riboswitch interactions in the crystal and footprinting experiments indicates that adjacent glycine-sensing modules of the riboswitch could form specific interdomain interactions, thereby potentially contributing to the cooperative response.
摘要
甘氨酰基核糖开关通过协同结合甘氨酸来反馈调节基因表达。在这里,我们报道了霍乱弧菌核糖开关的第二个甘氨酸感应结构域在配体结合和非结合状态下的晶体结构。该结构域采用三螺旋折叠结构,以三链结为中心,在结上方的凸起结合口袋中容纳甘氨酸。甘氨酸的识别由一对结合的 Mg(2+)阳离子辅助,并由口袋中的特异性相互作用和形状互补来调控。一个保守的腺嘌呤从结合口袋中伸出并插入结中,这意味着在完整的核糖开关中,甘氨酸结合可能通过稳定核糖开关结和调节 P1 螺旋来影响基因表达。晶体中核糖开关相互作用的分析和足迹实验表明,核糖开关的相邻甘氨酰基感应模块可以形成特定的域间相互作用,从而可能有助于协同反应。
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