‐ Two Alternative Mechanisms Regulate the Onset of Chaperone‐mediated Assembly of the Proteasomal ATPases

Soyeon Park, Asrafun Nahar
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Abstract

The proteasome holoenzyme is a molecular machine that degrades most proteins in eukaryotes. In the holoenzyme, its heterohexameric ATPase injects protein substrates into the proteolytic core particle, where degradation occurs. The heterohexameric ATPase, referred to as ‘Rpt ring’, assembles through six ATPase subunits (Rpt1‐Rpt6) individually binding to specific chaperones (Rpn14, Nas6, Nas2 and Hsm3). Here, our findings suggest that the onset of Rpt ring assembly can be regulated by two alternative mechanisms. Excess Rpt subunits relative to their chaperones are sequestered into multiple puncta specifically during early‐stage Rpt ring assembly. Sequestration occurs during stressed conditions, for example heat, which transcriptionally induce Rpt subunits. When the free Rpt pool is limited experimentally, Rpt subunits are competent for proteasome assembly even without their cognate chaperones. These data suggest that sequestration may regulate amounts of individual Rpt subunits relative to their chaperones, allowing for proper onset of Rpt ring assembly. Indeed, Rpt subunits in the puncta can later resume their assembly into the proteasome. Intriguingly, when proteasome assembly resumes in stressed cells or is ongoing in unstressed cells, excess Rpt subunits are recognized by an alternative mechanism—degradation by the proteasome holoenzyme itself. Rpt subunits undergo proteasome assembly until the holoenzyme complex is generated at a sufficient level. The fully‐formed holoenzyme can then degrade any remaining excess Rpt subunits, thereby regulating its own Rpt ring assembly. These two alternative mechanisms, degradation and sequestration of Rpt subunits, may help control the onset of chaperone‐mediated Rpt ring assembly, thereby promoting proper proteasome holoenzyme formation.
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- 两种可供选择的机制调节蛋白酶体 ATP 酶伴侣介导的组装过程
蛋白酶体全酶是真核生物中降解大多数蛋白质的分子机器。在蛋白酶体全酶中,其异六聚体 ATP 酶将蛋白质底物注入蛋白水解核心颗粒,并在那里进行降解。异六聚体 ATP 酶被称为 "Rpt 环",它通过六个 ATP 酶亚基(Rpt1-Rpt6)与特定的伴侣蛋白(Rpn14、Nas6、Nas2 和 Hsm3)单独结合而形成。在这里,我们的研究结果表明,Rpt 环组装的开始可由两种不同的机制调节。在 Rpt 环组装的早期阶段,相对于其伴侣蛋白的过量 Rpt 亚基会被特异性地封存到多个点中。在受压条件下(例如热),Rpt 亚基会转录诱导,从而发生螯合。当自由 Rpt 池受到实验限制时,即使没有同源伴侣,Rpt 亚基也能进行蛋白酶体组装。这些数据表明,螯合作用可能会调节单个 Rpt 亚基相对于其伴侣蛋白的数量,从而使 Rpt 环组装正常开始。事实上,点状区中的 Rpt 亚基随后可以重新组装到蛋白酶体中。耐人寻味的是,当蛋白酶体在受压细胞中重新组装或在未受压细胞中继续组装时,多余的Rpt亚基会被另一种机制识别--蛋白酶体全酶本身的降解。Rpt 亚基会进行蛋白酶体组装,直到全酶复合物达到足够的水平。然后,完全形成的全酶可以降解剩余的多余 Rpt 亚基,从而调节自身 Rpt 环的组装。Rpt亚基的降解和螯合这两种替代机制可能有助于控制伴侣介导的Rpt环组装的开始,从而促进蛋白酶体全酶的正常形成。
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