Your search keyword '"Tomoya Kato"' showing total 2 results

1. Real-time identification of two substrate-binding intermediates for the light-driven sodium pump rhodopsin

Author

Makoto Demura, Takashi Kikukawa, Takashi Tsukamoto, and Tomoya Kato

Subjects

0301 basic medicine, Rhodopsin, KR2, Krokinobacter eikastus rhodopsin 2, Absorption spectroscopy, Light, membrane transport, bioenergetics, Biochemistry, retinal proteins, 03 medical and health sciences, EC, extracellular, Bacterial Proteins, sodium pump, photobiology, CP, cytoplasmic, Molecular Biology, NaR, Na+-pump rhodopsin, MSP, membrane scaffold protein, 030102 biochemistry & molecular biology, biology, Membrane transport protein, Chemistry, Bacteroidetes, SG, skewed Gaussian, Sodium, Substrate (chemistry), sodium transport, Cell Biology, Membrane transport, 030104 developmental biology, Membrane, Photobiology, transporter, biology.protein, Biophysics, Absorption (chemistry), Research Article

Abstract

Membrane transport proteins undergo critical conformational changes during substrate uptake and release, as the substrate-binding site is believed to switch its accessibility from one side of the membrane to the other. Thus, at least two substrate-binding intermediates should appear during the process, that is, after uptake and before the release of the substrate. However, this view has not been verified for most transporters because of the difficulty in detecting short-lived intermediates. Here, we report real-time identification of these intermediates for the light-driven outward current-generating Na+-pump rhodopsin. We triggered the transport cycle of Na+-pump rhodopsin using a short laser pulse, and subsequent formation and decay of various intermediates was detected by time-resolved measurements of absorption changes. We used this method to analyze transport reactions and elucidated the sequential formation of the Na+-binding intermediates O1 and O2. Both intermediates exhibited red-shifted absorption spectra and generated transient equilibria with short-wavelength intermediates. The equilibria commonly shifted toward O1 and O2 with increasing Na+ concentration, indicating that Na+ is bound to these intermediates. However, these equilibria were formed independently; O1 reached equilibrium with preceding intermediates, indicating Na+ uptake on the cytoplasmic side. In contrast, O2 reached equilibrium with subsequent intermediates, indicating Na+ release on the extracellular side. Thus, there is an irreversible switch in "accessibility" during the O1 to O2 transition, which could represent one of the key processes governing unidirectional Na+ transport.

Published

2021

2. Real-time identification of two substrate-binding intermediates for the light-driven sodium pump rhodopsin.

Author

Tomoya Kato, Takashi Tsukamoto, Makoto Demura, and Takashi Kikukawa

Subjects

*MEMBRANE transport proteins, *RHODOPSIN, *LASER pulses, *ABSORPTION spectra, *SODIUM compounds, *TIME-resolved measurements

Abstract

Membrane transport proteins undergo critical conformational changes during substrate uptake and release, as the substrate-binding site is believed to switch its accessibility from one side of the membrane to the other. Thus, at least two substrate-binding intermediates should appear during the process, that is, after uptake and before the release of the substrate. However, this view has not been verified for most transporters because of the difficulty in detecting short-lived intermediates. Here, we report real-time identification of these intermediates for the light-driven outward currentgenerating Na+-pump rhodopsin. We triggered the transport cycle of Na+-pump rhodopsin using a short laser pulse, and subsequent formation and decay of various intermediates was detected by time-resolved measurements of absorption changes. We used this method to analyze transport reactions and elucidated the sequential formation of the Na+-binding intermediates O1 and O2. Both intermediates exhibited redshifted absorption spectra and generated transient equilibria with short-wavelength intermediates. The equilibria commonly shifted toward O1 and O2 with increasing Na+ concentration, indicating that Na+ is bound to these intermediates. However, these equilibria were formed independently; O1 reached equilibrium with preceding intermediates, indicating Na+ uptake on the cytoplasmic side. In contrast, O2 reached equilibrium with subsequent intermediates, indicating Na+ release on the extracellular side. Thus, there is an irreversible switch in "accessibility" during the O1 to O2 transition, which could represent one of the key processes governing unidirectional Na+ transport. [ABSTRACT FROM AUTHOR]

Published

2021