PKD2 孔道螺旋中的 ADPKD 变体会导致门结构崩溃和不同形式的通道功能障碍。

Orhi Esarte Palomero, Paul G DeCaen
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摘要

PKD2 是瞬态受体电位(TRP)离子通道亚基聚胞素亚族的成员,该亚基在初级纤毛细胞器膜中起交通和功能作用。数百万人携带 PKD2 的致病基因变异,这种变异会导致一种名为常染色体显性多囊肾病(ADPKD)的危及生命的疾病。虽然 ADPKD 是一种常见的单基因遗传疾病,但目前还没有药物可以治愈,也没有针对潜在通道失调的治疗方法。此外,大多数致病变体的结构和机理影响尚未定性。利用直接纤毛电生理学、低温电子显微镜(cryo-EM)和超分辨率成像技术,我们发现了位于 PKD2s 孔道螺旋 1 的三个种系错义变异导致的通道失调的机理差异。变体 C632R 降低了蛋白质的热稳定性,导致通道组装受损,并取消了初级纤毛运输。相比之下,变体 F629S 和 R638C 保留了原生纤毛运输,但表现出门控缺陷。这些变体的低温电子显微镜结构(2.7-3.2 埃)显示,关键的孔螺旋相互作用丧失,并导致通道内门的异构崩溃。研究结果表明,ADPKD导致的这些突变如何对PKD2的功能产生不同程度的影响,尽管它们的结构非常接近。这些意想不到的发现强调了对多囊卵巢蛋白变体进行机理表征的必要性,这可能会指导 ADPKD 治疗药物的合理药物开发。
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ADPKD variants in the PKD2 pore helix cause structural collapse of the gate and distinct forms of channel dysfunction.
PKD2 is a member of the polycystin subfamily of transient receptor potential (TRP) ion channel subunits which traffic and function in primary cilia organelle membranes. Millions of individuals carry pathogenic genetic variants in PKD2 that cause a life-threatening condition called autosomal dominant polycystic kidney disease (ADPKD). Although ADPKD is a common monogenetic disorder, there is no drug cure or available therapeutics which address the underlying channel dysregulation. Furthermore, the structural and mechanistic impact of most disease-causing variants are uncharacterized. Using direct cilia electrophysiology, cryogenic electron microscopy (cryo-EM), and super resolution imaging, we have discovered mechanistic differences in channel dysregulation caused by three germline missense variants located in PKD2s pore helix 1. Variant C632R reduces protein thermal stability, resulting in impaired channel assembly and abolishes primary cilia trafficking. In contrast, variants F629S and R638C retain native cilia trafficking, but exhibit gating defects. Resolved cryo-EM structures (2.7-3.2 Angstrom) of the variants indicate loss of critical pore helix interactions and precipitate allosteric collapse of the channels inner gate. Results demonstrate how ADPKD-causing these mutations have divergent and ranging impacts on PKD2 function, despite their shared structural proximity. These unexpected findings underscore the need for mechanistic characterization of polycystin variants, which may guide rational drug development of ADPKD therapeutics.
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