电子在生物分子中的流动:空穴跳跃能否保护蛋白质免受氧化损伤?
Electron flow through biological molecules: does hole hopping protect proteins from oxidative damage?
作者信息
Winkler Jay R, Gray Harry B
机构信息
Beckman Institute,California Institute of Technology,Pasadena,CA 91125,USA.
出版信息
Q Rev Biophys. 2015 Nov;48(4):411-20. doi: 10.1017/S0033583515000062.
Abstract
Biological electron transfers often occur between metal-containing cofactors that are separated by very large molecular distances. Employing photosensitizer-modified iron and copper proteins, we have shown that single-step electron tunneling can occur on nanosecond to microsecond timescales at distances between 15 and 20 Å. We also have shown that charge transport can occur over even longer distances by hole hopping (multistep tunneling) through intervening tyrosines and tryptophans. In this perspective, we advance the hypothesis that such hole hopping through Tyr/Trp chains could protect oxygenase, dioxygenase, and peroxidase enzymes from oxidative damage. In support of this view, by examining the structures of P450 (CYP102A) and 2OG-Fe (TauD) enzymes, we have identified candidate Tyr/Trp chains that could transfer holes from uncoupled high-potential intermediates to reductants in contact with protein surface sites.
摘要
生物电子转移通常发生在含金属的辅因子之间,这些辅因子被非常大的分子距离隔开。利用光敏剂修饰的铁蛋白和铜蛋白,我们已经表明,单步电子隧穿可以在纳秒到微秒的时间尺度上,在15到20埃的距离内发生。我们还表明,电荷传输可以通过中间的酪氨酸和色氨酸进行空穴跳跃(多步隧穿),从而在更长的距离上发生。从这个角度出发,我们提出这样一个假设:通过酪氨酸/色氨酸链进行的这种空穴跳跃可以保护加氧酶、双加氧酶和过氧化物酶免受氧化损伤。为了支持这一观点,通过研究细胞色素P450(CYP102A)和2-氧代戊二酸-铁(TauD)酶的结构,我们已经确定了候选的酪氨酸/色氨酸链,这些链可以将空穴从未偶联的高电位中间体转移到与蛋白质表面位点接触的还原剂上。
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