A Study on How Conformation Entropy of Attached Macromolecules Drives Polymeric Collapse and Protein Folding

IF 1.8 4区 工程技术 Q3 POLYMER SCIENCE
Ionel Popa
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Abstract

The conformation of macromolecules attached to a surface is influenced by both their excluded volume and steric forces. Here, self-avoiding random walk simulations are used to evaluate the occurrence of various conformations as a function of the number of monomeric units to estimate the effect of conformational entropy of a tethered chain. Then, a more realistic scenario is assessed, which can more accurately reproduce the shape of a tethered macromolecule. The simulations presented here confirm that it is more likely for a polymer to undergo a collapse conformation rather than a stretched one, as a collapse conformation can be realized in more different ways. Also, they confirm the “mushroom” shape of polymers close to a surface. From this simple approach, the conformation entropy of a model 100-unit polymer close to a surface is estimated to contribute with over 129 k B T ${{k}_{\mathrm{B}}}T$ toward its collapse. This conformation entropy is higher than that of typical hydrogen bonds and even barriers that keep proteins folded. As such, entropic collapse of macromolecules plays an important role in realizing the mushroom shape of attached polymers and can be the driving force in protein folding, while the polypeptide chain emerges from the ribosome.

关于附着大分子的构象熵如何驱动聚合物坍缩和蛋白质折叠的研究
附着在表面上的大分子的构象受其外排体积和立体力的影响。在这里,我利用自避让随机游走模拟来评估各种构象的出现与单体单元数量的函数关系,从而估计系链构象熵的影响。然后,评估了一种更现实的情况,它能更准确地再现系链大分子的形状。本文介绍的模拟证实,聚合物更有可能发生塌缩构象,而不是拉伸构象,因为塌缩构象可以通过更多不同的方式实现。此外,模拟还证实了聚合物接近表面时的 "蘑菇 "形状。通过这种简单的方法,我们可以估算出构象熵随分子大小的变化情况。这些结果预测,对于接近表面的 100 单位模型聚合物,构象熵对其坍缩的贡献超过 129 kBT${{k}_B}T$。这一构象熵高于典型的氢键,甚至高于保持蛋白质折叠的屏障。因此,当多肽链从核糖体中出现时,大分子的熵塌缩在实现附着聚合物的蘑菇形状方面起着重要作用,并可能成为蛋白质折叠的驱动力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Macromolecular Theory and Simulations
Macromolecular Theory and Simulations 工程技术-高分子科学
CiteScore
3.00
自引率
14.30%
发文量
45
审稿时长
2 months
期刊介绍: Macromolecular Theory and Simulations is the only high-quality polymer science journal dedicated exclusively to theory and simulations, covering all aspects from macromolecular theory to advanced computer simulation techniques.
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