Gulati Ashutosh, Ahn Do-Hwan, Suades Albert, Hult Yurie, Wolf Gernot, Iwata So, Superti-Furga Giulio, Nomura Norimichi, Drew David
Department of Biochemistry and Biophysics, Science for Life Laboratory, Stockholm University, Stockholm, Sweden.
CeMM Research Center for Molecular Medicine of the Austrian Academy of Sciences, Vienna, Austria.
Nature. 2025 May 21. doi: 10.1038/s41586-025-09069-w.
ATP generated in the mitochondria is exported by an ADP/ATP carrier of the SLC25 family. The endoplasmic reticulum (ER) cannot synthesize ATP but must import cytoplasmic ATP to energize protein folding, quality control and trafficking. It was recently proposed that a member of the nucleotide sugar transporter family, termed SLC35B1 (also known as AXER), is not a nucleotide sugar transporter but a long-sought-after ER importer of ATP. Here we report that human SLC35B1 does not bind nucleotide sugars but indeed executes strict ATP/ADP exchange with uptake kinetics consistent with the import of ATP into crude ER microsomes. A CRISPR-Cas9 cell-line knockout demonstrated that SLC35B1 clusters with the most essential SLC transporters for cell growth, consistent with its proposed physiological function. We have further determined seven cryogenic electron microscopy structures of human SLC35B1 in complex with an Fv fragment and either bound to an ATP analogue or ADP in all major conformations of the transport cycle. We observed that nucleotides were vertically repositioned up to approximately 6.5 Å during translocation while retaining key interactions with a flexible substrate-binding site. We conclude that SLC35B1 operates by a stepwise ATP translocation mechanism, which is a previously undescribed model for substrate translocation by an SLC transporter.
线粒体中产生的三磷酸腺苷(ATP)通过溶质载体家族25(SLC25)的一种ADP/ATP载体输出。内质网(ER)不能合成ATP,但必须输入细胞质ATP以促进蛋白质折叠、质量控制和运输。最近有研究提出,核苷酸糖转运蛋白家族的一个成员,称为SLC35B1(也称为AXER),并非核苷酸糖转运蛋白,而是长期以来寻找的内质网ATP输入蛋白。在此我们报告,人类SLC35B1不结合核苷酸糖,但确实执行严格的ATP/ADP交换,其摄取动力学与ATP向内质网粗微粒体的输入一致。一种CRISPR-Cas9细胞系敲除实验表明,SLC35B1与细胞生长最关键的SLC转运蛋白聚集在一起,与其推测的生理功能相符。我们进一步确定了人类SLC35B1与一个Fv片段结合,并在转运循环的所有主要构象中与ATP类似物或ADP结合的七个低温电子显微镜结构。我们观察到,在转运过程中核苷酸垂直重新定位高达约6.5埃,同时与一个灵活的底物结合位点保持关键相互作用。我们得出结论,SLC35B1通过逐步ATP转运机制发挥作用,这是一种以前未描述的SLC转运蛋白底物转运模型。
