9IVK
cryo-EM structure of a tmFAP
9IVK の概要
| エントリーDOI | 10.2210/pdb9ivk/pdb |
| 関連するPDBエントリー | 8W6E 8W6F |
| EMDBエントリー | 60929 |
| 分子名称 | HBC599 membrane protein binder, Heavy chain, Fab fragment, Light Chain, Fab fragment, ... (4 entities in total) |
| 機能のキーワード | de novo protein design; transmembrane protein; ligand binding; fluorogenic; membrane; fluorescent protein., membrane protein/immune system, membrane protein-immune system complex |
| 由来する生物種 | artificial sequences 詳細 |
| タンパク質・核酸の鎖数 | 3 |
| 化学式量合計 | 81072.12 |
| 構造登録者 | |
| 主引用文献 | Zhu, J.,Liang, M.,Sun, K.,Wei, Y.,Guo, R.,Zhang, L.,Shi, J.,Ma, D.,Hu, Q.,Huang, G.,Lu, P. De novo design of transmembrane fluorescence-activating proteins. Nature, 640:249-257, 2025 Cited by PubMed Abstract: The recognition of ligands by transmembrane proteins is essential for the exchange of materials, energy and information across biological membranes. Progress has been made in the de novo design of transmembrane proteins, as well as in designing water-soluble proteins to bind small molecules, but de novo design of transmembrane proteins that tightly and specifically bind to small molecules remains an outstanding challenge. Here we present the accurate design of ligand-binding transmembrane proteins by integrating deep learning and energy-based methods. We designed pre-organized ligand-binding pockets in high-quality four-helix backbones for a fluorogenic ligand, and generated a transmembrane span using gradient-guided hallucination. The designer transmembrane proteins specifically activated fluorescence of the target fluorophore with mid-nanomolar affinity, exhibiting higher brightness and quantum yield compared to those of enhanced green fluorescent protein. These proteins were highly active in the membrane fraction of live bacterial and eukaryotic cells following expression. The crystal and cryogenic electron microscopy structures of the designer protein-ligand complexes were very close to the structures of the design models. We showed that the interactions between ligands and transmembrane proteins within the membrane can be accurately designed. Our work paves the way for the creation of new functional transmembrane proteins, with a wide range of applications including imaging, ligand sensing and membrane transport. PubMed: 39972138DOI: 10.1038/s41586-025-08598-8 主引用文献が同じPDBエントリー |
| 実験手法 | ELECTRON MICROSCOPY (2.74 Å) |
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