基于物理全局优化和知识引导片段打包的蛋白质结构预测

2005 IEEE Computational Systems Bioinformatics Conference - Workshops (CSBW'05) Pub Date : 2005-08-08 DOI:10.1109/CSBW.2005.115

Jinhui Ding, E. Eskow, N. Max, S. Crivelli

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引用次数: 2

摘要

我们描述了一种预测新折叠蛋白三级结构的新方法。我们的两阶段方法结合了基于知识的碎片打包和基于物理的能量函数的最小化。该方法是在优化的所有阶段使用基于全原子物理的能量函数的少数尝试之一。来自已知蛋白质的信息被用来指导在巨大的构象空间中的搜索。我们在CASP6中测试了这种方法，并对其中一个新折叠靶标- - -螺旋蛋白t238进行了最好的预测。在CASP6之后，我们进行了一系列的实验来测试和改进我们的方法，我们发现我们的方法在α -螺旋蛋白上表现良好。

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Protein structure prediction using physical-based global optimization and knowledge-guided fragment packing

We describe a new method to predict the tertiary structure of new-fold proteins. Our two-phase approach combines the knowledge-based fragment-packing with the minimization of a physics-based energy function. The method is one of the few attempts to use an all-atom physics-based energy function throughout all stages of the optimization. Information from the known proteins is utilized to guide the search through the vast conformational space. We tested this method in CASP6 and it produced the best prediction on one of the new-fold targets-T238, alpha-helical protein. After CASP6, we carried out a series of experiments to test and improve our method and we found that our method performed well on alpha-helical proteins.

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2005 IEEE Computational Systems Bioinformatics Conference - Workshops (CSBW'05)

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