蓝氏贾第鞭毛虫蛋白酶体盖的二元蛋白相互作用组图谱揭示了 GlRpn11 的额外蛋白酶体功能

Ankita Das, Atrayee Ray, Nibedita Ray Chaudhuri, Soumyajit Mukherjee, Shubhra Ghosh Dastidar, Alok Ghosh, Sandipan Ganguly, Kuladip Jana, Srimonti Sarkar
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The Rpn11-Rpn8 dimer provides a platform for lid assembly and their interaction involves the insertion of a methionine residue of Rpn11 into a hydrophobic pocket of Rpn8. Molecular modeling indicates that GlRpn8s pocket is wider, reconciling the experimental observation of its weak interaction with GlRpn11. This weaker interaction may have evolved to support extra proteasomal functions of GlRpn11, which localizes to multiple subcellular regions where other proteasome subunits have not been detected. One such location is the mitosome. Functional complementation in yeast shows that GlRpn11 can influence mitochondrial function and distribution. This, together with its mitosomal localization, indicates that GlRpn11 functions at the mitosome. Thus, this parasites proteasome lid has a simpler subunit architecture and structural attributes that may support dual functionalities for GlRpn11. 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引用次数: 0

摘要

蓝氏贾第鞭毛虫不编码Rpn12和Sem1,而这两种蛋白质对蛋白酶体盖的组装至关重要。为了了解贾第虫蛋白酶体盖亚基之间的相互作用是如何变化的,以弥补它们的缺失,我们使用酵母双杂交试验生成了贾第虫蛋白酶体盖亚基的二元蛋白质相互作用图谱。贾第虫蛋白酶体盖子内的大多数相互作用比酿酒酵母盖子内的相互作用更强。这可能弥补了 Rpn12 和 Sem1 的缺失。与酵母的 Rpn11-Rpn8 之间的强相互作用相比,GlRpn11 和 GlRpn8 之间的相互作用较弱,这是一个明显的例外。Rpn11-Rpn8 二聚体为盖子的组装提供了一个平台,它们之间的相互作用涉及 Rpn11 的一个蛋氨酸残基插入 Rpn8 的一个疏水口袋。分子建模表明,GlRpn8 的口袋更宽,这与实验观察到的它与 GlRpn11 的微弱相互作用相吻合。这种较弱的相互作用可能是为了支持 GlRpn11 的额外蛋白酶体功能而演变而来的,GlRpn11 定位在多个亚细胞区域,而在这些区域尚未检测到其他蛋白酶体亚基。其中一个位置就是有丝分裂体。酵母中的功能互补显示,GlRpn11 可以影响线粒体的功能和分布。这与其有丝分裂体定位一起表明,GlRpn11 在有丝分裂体中发挥作用。因此,这种寄生虫蛋白酶体盖具有更简单的亚基结构和结构属性,可能支持 GlRpn11 的双重功能。这种寄生虫特异性蛋白酶体特征可为控制贾第虫的传播提供新的途径。
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The binary protein interactome mapping of the Giardia lamblia proteasome lid reveals extra proteasomal functions of GlRpn11
Giardia lamblia does not encode Rpn12 and Sem1, two proteins crucial for assembling the proteasome lid. To understand how the interactions between the giardial proteasome lid subunits may have changed to compensate for their absence, we used the yeast two-hybrid assay to generate a binary protein interaction map of the Giardia lid subunits. Most interactions within the Giardia proteasome lid are stronger than those within the Saccharomyces cerevisiae lid. These may compensate for the absence of Rpn12 and Sem1. A notable exception was the weaker interaction between GlRpn11 and GlRpn8, compared to the strong interaction between Rpn11-Rpn8 of yeast. The Rpn11-Rpn8 dimer provides a platform for lid assembly and their interaction involves the insertion of a methionine residue of Rpn11 into a hydrophobic pocket of Rpn8. Molecular modeling indicates that GlRpn8s pocket is wider, reconciling the experimental observation of its weak interaction with GlRpn11. This weaker interaction may have evolved to support extra proteasomal functions of GlRpn11, which localizes to multiple subcellular regions where other proteasome subunits have not been detected. One such location is the mitosome. Functional complementation in yeast shows that GlRpn11 can influence mitochondrial function and distribution. This, together with its mitosomal localization, indicates that GlRpn11 functions at the mitosome. Thus, this parasites proteasome lid has a simpler subunit architecture and structural attributes that may support dual functionalities for GlRpn11. Such parasite-specific proteasome features could provide new avenues for controlling the transmission of Giardia.
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