Rand R P
Department of Biological Sciences, Brock University, St Catharines, Ontario L2S 3A1, Canada.
Philos Trans R Soc Lond B Biol Sci. 2004 Aug 29;359(1448):1277-84; discussion 1284-5. doi: 10.1098/rstb.2004.1504.
Life began in a bath of water and has never escaped it. Cellular function has forced the evolution of many mechanisms ensuring that cellular water concentration has never changed significantly. To free oneself of any conceptual distinction among all small molecules, solutes and solvents, means that experiments to probe water's specific role in molecular function can be designed like any classical chemical reaction. Such an 'osmotic stress' strategy will be described in general and for an enzyme, hexokinase. Water behaves like a reactant that competes with glucose in binding to hexokinase, and modulates its conformational change and activity. This 'osmotic stress' strategy, now applied to many very different systems, shows that water plays a significant role, energetically, in most macromolecular reactions. It can be required to fill obligatory space, it dominates nearest non-specific interactions between large surfaces, it can be a reactant modulating conformational change; all this in addition to its more commonly perceived static role as an integral part of stereospecific intramolecular structure.
生命始于水中,并从未脱离过水。细胞功能促使多种机制不断进化,以确保细胞内水的浓度从未发生显著变化。消除所有小分子、溶质和溶剂之间的概念区分,意味着可以像设计任何经典化学反应一样,设计探究水在分子功能中特定作用的实验。本文将概述这种“渗透应激”策略,并以己糖激酶这种酶为例进行说明。水的行为类似于一种反应物,它与葡萄糖竞争结合己糖激酶,并调节其构象变化和活性。这种“渗透应激”策略目前已应用于许多截然不同的系统,表明水在大多数大分子反应中在能量方面发挥着重要作用。它可能需要填充必要的空间,主导大表面之间最邻近的非特异性相互作用,它可以是调节构象变化的反应物;除了其更常被视为立体特异性分子内结构不可或缺的静态组成部分之外,水还具有所有这些作用。