Tamogami Jun, Kikukawa Takashi, Miyauchi Seiji, Muneyuki Eiro, Kamo Naoki
Graduate School of Pharmaceutical Sciences, Hokkaido University, Sapporo, Japan.
Photochem Photobiol. 2009 Mar-Apr;85(2):578-89. doi: 10.1111/j.1751-1097.2008.00520.x. Epub 2009 Jan 19.
An electrochemical cell was previously reported in which bacteriorhodopsin (BR, purple membrane) was adsorbed on the surface of a transparent SnO(2) electrode, and illumination resulted in potential or current changes (Koyama et al., Science 265:762-765, 1994; Robertson and Lukashev, Biophys. J. 68:1507-1517, 1995; Koyama et al., Photochem. Photobiol. 68:400-406, 1998). In this paper, we concluded that pH changes caused by proton transfer by the deposited BR or proteorhodopsin (PR) films lead to the flash-induced potential change in the SnO(2) electrode. Thus, the signals originate from BR and PR acting as light-driven proton pumps. This conclusion was drawn from the following observations. (1) The relation between the potential of a bare electrode and pH is linear for a wide pH range. (2) The flash-induced potential changes decrease with an increase in the buffer concentration. (3) The action spectrum of PR agrees well with the absorption spectrum. (4) The present electrode can monitor the pH change in the time range from 10 ms to several hundred milliseconds, as deduced by comparing the SnO(2) signal with the signals of pH-sensitive dyes. Using this electrode system, flash-induced proton transfer by BR was measured for a wide pH range from 2 to 10. From these data, we reconfirmed various pK(a) values reported previously, indicating that the present method can give the correct pK(a) values. This is the first report to estimate these pK(a) values directly from the proton transfer. We then applied this method to flash-induced proton transfer of PR. We observed proton uptake followed by release for the pH range from 4 to 9.5, and in other pH ranges, proton release followed by uptake was observed.
先前报道过一种电化学电池,其中细菌视紫红质(BR,紫膜)吸附在透明的SnO₂电极表面,光照会导致电位或电流变化(小山等人,《科学》265:762 - 765,1994年;罗伯逊和卢卡舍夫,《生物物理杂志》68:1507 - 1517,1995年;小山等人,《光化学与光生物学》68:400 - 406,1998年)。在本文中,我们得出结论,沉积的BR或视紫质(PR)膜通过质子转移引起的pH变化导致了SnO₂电极中闪光诱导的电位变化。因此,信号源自作为光驱动质子泵的BR和PR。这个结论是基于以下观察得出的。(1)在很宽的pH范围内,裸电极的电位与pH之间的关系是线性的。(2)闪光诱导的电位变化随着缓冲液浓度的增加而减小。(3)PR的作用光谱与吸收光谱吻合良好。(4)通过将SnO₂信号与pH敏感染料的信号进行比较推断,当前电极可以在10毫秒到几百毫秒的时间范围内监测pH变化。使用这个电极系统,在2到10的宽pH范围内测量了BR的闪光诱导质子转移。根据这些数据,我们再次证实了先前报道的各种pKₐ值,表明本方法可以给出正确的pKₐ值。这是首次直接从质子转移估算这些pKₐ值的报告。然后我们将此方法应用于PR的闪光诱导质子转移。我们观察到在4到9.5的pH范围内先质子摄取后释放,而在其他pH范围内观察到先质子释放后摄取。
