生物分子的压力-温度相图

László Smeller
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引用次数: 358

摘要

综述了各种生物分子的压力-温度相图。特别注意的是蛋白质的椭圆相图。描述这张图的现象学热力学理论在一个统一的图像中解释了热、冷和压变性。讨论了这一理论的局限性和可能的发展。指出当考虑分子间相互作用时,可以得到一个更复杂的图。在这种情况下,由于分子间相互作用,亚稳态出现在压力-温度(p-T)图上。对其他生物聚合物的压力-温度相图也进行了讨论。核酸的螺旋-线圈转变和脂质双层的凝胶-液晶转变的p-T图是非椭圆形的,而淀粉糊化和某些合成聚合物的相分离的p-T图则与蛋白质的p-T图相似,呈椭圆形。最后,细菌失活的p-T图显示为椭圆形。从基础科学的角度来看,这一事实表明,失活的关键因素应该是蛋白质类型,从实际应用的角度来看,这是生物系统压力处理的理论基础。
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Pressure–temperature phase diagrams of biomolecules

The pressure–temperature phase diagram of various biomolecules is reviewed. Special attention is focused on the elliptic phase diagram of proteins. The phenomenological thermodynamic theory describing this diagram explains the heat, cold and pressure denaturations in a unified picture. The limitations and possible developments of this theory are discussed as well. It is pointed out that a more complex diagram can be obtained when the intermolecular interactions are also taken into account. In this case metastable states appear on the pressure–temperature (pT) diagram due to intermolecular interactions. Pressure–temperature phase diagrams of other biopolymers are also discussed. While the pT diagrams of helix–coil transition of nucleic acids and of gel–liquid crystal transition of lipid bilayers are non-elliptical, those of gelatinization of starch and of phase separation of some synthetic polymers show an elliptic profile, similar to that of proteins. Finally, the pT diagram of bacterial inactivation is shown to be elliptic. From the point of view of basic science, this fact shows that the key factor of inactivation should be the protein type, and from the viewpoint of practical applications, it serves as the theoretical basis of pressure treatment of biosystems.

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