嗜热蛋白中埋藏型和网络型盐桥（BNSB）的稳定性

Stability of buried and networked salt-bridges (BNSB)in thermophilic proteins.

作者信息

Bandyopadhyay Amal Kumar, Islam Rifat Nawaz Ul, Mitra Debanjan, Banerjee Sahini, Goswami Arunava

机构信息

Department of Biotechnology, University of Burdwan, Burdwan, West Bengal,India.

Department of Zoology, University of Burdwan,Burdwan, West Bengal,India.

出版信息

Bioinformation. 2019 Feb 3;15(1):61-67. doi: 10.6026/97320630015061. eCollection 2019.

DOI:10.6026/97320630015061

PMID:31360001

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6651030/

Abstract

Thermophilic proteins function at high temperature, unlike mesophilic proteins. Thermo-stability of these proteins is due to the unique buried and networked salt-bridge (BNSB). However, it is known that the desolvation cost of BNSB is too high compared to other favorable energy terms. Nonetheless, it is known that stability is provided generally by hydrophobic isosteres without the need for BNSB. We show in this analysis that the BNSB is the optimal evolutionary design of salt-bridge to offset desolvation cost efficiently. Hence, thermophilic proteins with a high level of BNSB provide thermo-stability.

摘要

与嗜温蛋白不同，嗜热蛋白在高温下发挥作用。这些蛋白的热稳定性归因于独特的埋藏式网络盐桥（BNSB）。然而，已知与其他有利的能量项相比，BNSB的去溶剂化成本过高。尽管如此，已知通常由疏水等排体提供稳定性，而无需BNSB。我们在本分析中表明，BNSB是盐桥的最佳进化设计，可有效抵消去溶剂化成本。因此，具有高水平BNSB的嗜热蛋白提供热稳定性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fe94/6651030/0599751aecff/97320630015061F1.jpg

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嗜热蛋白中埋藏型和网络型盐桥（BNSB）的稳定性

Stability of buried and networked salt-bridges (BNSB)in thermophilic proteins.

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