探索压力下的超嗜热蛋白:理论方面和实验结果

Enrico Mombelli , Erlet Shehi , Paola Fusi , Paolo Tortora
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引用次数: 32

摘要

来自超嗜热微生物的蛋白质通常能够承受接近沸点甚至高于沸点的温度。通常,这些蛋白质也具有很强的压稳性,尽管也有例外报道。这一观察结果具有理论意义,因为了解压力和温度对蛋白质稳定性的影响对于建立蛋白质热力学稳定性的综合模型同样重要。然而,证明耐热性和耐压性之间的相关性的结构特征却知之甚少。实际上,大多数报道都没有超出现象层面。只有在来自solfataricus的小蛋白Sso7d的情况下,野生型和一些突变型的特征表明,这两种特性在很大程度上是由分子疏水性核心中发现的芳香残基网络决定的。然而,目前的知识还不能确定这一发现可以推广到什么程度。从生物技术的角度来看,超嗜热酶似乎比中温酶更适合于高压下的生物过程。事实上,由于它们对压力和温度的耐受性更高,它们可以在更广泛的工作条件下用于调节活性和特异性。此外,它们往往因压力增加而被激活,尽管迄今还不能确定这在多大程度上是一种共同特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exploring hyperthermophilic proteins under pressure: theoretical aspects and experimental findings

Proteins from hyperthermophilic microorganisms are generally capable of withstanding temperatures close to, or even higher than the boiling point. As a rule, these proteins are strongly piezostable as well, although exceptions have been also reported. This observation has a theoretical relevance, as the understanding of the effects of pressure and temperature on protein stability is equally important to develop a comprehensive model for their thermodynamic stability. Nevertheless, the structural features justifying the correlation between heat resistance and pressure resistance are poorly understood. Actually, most reports do not exceed the phenomenological level. Only in the case of the small protein Sso7d from Sulfolobus solfataricus, characterisation of wild-type and some mutants showed that both properties are largely accounted for by a network of aromatic residues found in the hydrophobic core of the molecule. Current knowledge, however, does not allow to establish to what extent this finding may be generalised. In a biotechnological perspective, hyperthermophilic enzymes seem to be more suitable for bioprocesses at high pressure with respect to their mesophilic counterparts. Indeed, thanks to their higher resistance towards pressure and temperature, they may be exploited in a much broader range of working conditions for tuning activity and specificity. Furthermore, they are often activated by increasing pressure, although it cannot be established, to date, to what extent this is a common feature.

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