Author
Listed:
- Yui Kanaoka
(Nagoya University)
- Takaharu Mori
(Tokyo University of Science)
- Wataru Nagaike
(Nagoya University)
- Seira Itaya
(Nara Institute of Science and Technology)
- Yuto Nonaka
(Nagoya University)
- Hidetaka Kohga
(Nara Institute of Science and Technology)
- Takamitsu Haruyama
(Nara Institute of Science and Technology)
- Yasunori Sugano
(Nara Institute of Science and Technology)
- Ryoji Miyazaki
(Nara Institute of Science and Technology)
- Muneyoshi Ichikawa
(Fudan University)
- Takayuki Uchihashi
(Nagoya University
National Institutes of Natural Science
Nagoya University)
- Tomoya Tsukazaki
(Nara Institute of Science and Technology)
Abstract
Protein translocation across cellular membranes is an essential and nano-scale dynamic process. In the bacterial cytoplasmic membrane, the core proteins in this process are a membrane protein complex, SecYEG, corresponding to the eukaryotic Sec61 complex, and a cytoplasmic protein, SecA ATPase. Despite more than three decades of extensive research on Sec proteins, from genetic experiments to cutting-edge single-molecule analyses, no study has visually demonstrated protein translocation. Here, we visualize the translocation, via one unit of a SecYEG-SecA-embedded nanodisc, of an unfolded substrate protein by high-speed atomic force microscopy (HS-AFM). Additionally, the uniform unidirectional distribution of nanodiscs on a mica substrate enables the HS-AFM image data analysis, revealing dynamic structural changes in the polypeptide-crosslinking domain of SecA between wide-open and closed states depending on nucleotides. The nanodisc-AFM approach will allow us to execute detailed analyses of Sec proteins as well as visualize nano-scale events of other membrane proteins.
Suggested Citation
Yui Kanaoka & Takaharu Mori & Wataru Nagaike & Seira Itaya & Yuto Nonaka & Hidetaka Kohga & Takamitsu Haruyama & Yasunori Sugano & Ryoji Miyazaki & Muneyoshi Ichikawa & Takayuki Uchihashi & Tomoya Tsu, 2025.
"AFM observation of protein translocation mediated by one unit of SecYEG-SecA complex,"
Nature Communications, Nature, vol. 16(1), pages 1-12, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-024-54875-x
DOI: 10.1038/s41467-024-54875-x
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