Molecular basis for the activation of outer dynein arms in cilia.

Nature structural & molecular biology Pub Date : 2025-09-29 DOI:10.1038/s41594-025-01680-9

Karim Housseini B Issa,Muyang Ren,Bradley Burnet,Hao Lu,Charlotte Melia,Kate Heesom,Anthony J Roberts,Sudipto Roy,Girish R Mali

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Abstract

Multiciliogenesis requires large-scale biosynthesis of motility-powering axonemal inner and outer dynein arm motors (IDAs and ODAs) before their intraflagellar transport (IFT) into cilia. ODAs are inhibited by the packaging chaperone Shulin during ciliogenesis in Tetrahymena thermophila. How Shulin is released for ODAs to become active inside cilia remains unclear. Here we uncover a molecular mechanism for ODA activation. We establish interactions between DNAAF9 (human Shulin) and mammalian ODA subunits, IFT proteins and the ciliary small guanosine triphosphatase (GTPase) ARL3 using proteomics and in vitro reconstitutions. Mutagenesis combined with biochemical and structural studies reveal that DNAAF9 and Shulin preferentially bind active Arl3-GTP highlighting a cross-species conservation of this interaction. GTP-loaded Arl3 can access, bind and displace Shulin from the packaged ODA-Shulin complex. We propose that, once the inhibited ODA complex enters growing cilia, Arl3-GTP displaces Shulin (DNAAF9) and sequesters it away from ODAs, promoting activation of their motility specifically inside cilia.

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纤毛外动力蛋白臂激活的分子基础。

多纤毛发生需要在鞭毛内运输（IFT）进入纤毛之前，进行大规模的运动动力轴突内和外动力臂马达（ida和oda）的生物合成。在嗜热四膜虫纤毛发生过程中，ODAs受到包装伴侣舒林的抑制。鞘林是如何被释放，使oda在纤毛内变得活跃的，目前尚不清楚。在这里，我们揭示了ODA激活的分子机制。我们利用蛋白质组学和体外重组技术建立了DNAAF9（人鞘蛋白）与哺乳动物ODA亚基、IFT蛋白和纤毛小鸟苷三磷酸酶（GTPase） ARL3之间的相互作用。诱变结合生化和结构研究表明，DNAAF9和Shulin优先结合活性ar13 - gtp，表明这种相互作用具有跨物种保守性。装载gtp的Arl3可以从包装好的oda - sholin复合物中获取、结合和置换sholin。我们认为，一旦被抑制的ODA复合物进入生长中的纤毛，ar13 - gtp取代Shulin （DNAAF9）并将其从ODA中隔离出来，促进它们在纤毛内的运动激活。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nature structural & molecular biology

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