在蛋白质设计中耦合主链灵活性与氨基酸序列选择
Coupling backbone flexibility and amino acid sequence selection in protein design.
作者信息
Su A, Mayo S L
机构信息
Division of Physics, Mathematics and Astronomy, California Institute of Technology, Pasadena 91125, USA.
出版信息
Protein Sci. 1997 Aug;6(8):1701-7. doi: 10.1002/pro.5560060810.
Abstract
Using a protein design algorithm that considers side-chain packing quantitatively, the effect of explicit backbone motion on the selection of amino acids in protein design was assessed in the core of the streptococcal protein G beta 1 domain (G beta 1). Concerted backbone motion was introduced by varying G beta 1's supersecondary structure parameter values. The stability and structural flexibility of seven of the redesigned proteins were determined experimentally and showed that core variants containing as many as 6 of 10 possible mutations retain native-like properties. This result demonstrates that backbone flexibility can be combined explicitly with amino acid side-chain selection and that the selection algorithm is sufficiently robust to tolerate perturbations as large as 15% of G beta 1's native supersecondary structure parameter values.
摘要
利用一种能定量考虑侧链堆积的蛋白质设计算法,在链球菌蛋白G β1结构域(G β1)的核心区域评估了明确的主链运动对蛋白质设计中氨基酸选择的影响。通过改变G β1的超二级结构参数值来引入协同的主链运动。对7种重新设计的蛋白质的稳定性和结构灵活性进行了实验测定,结果表明,在10种可能的突变中,多达6种突变的核心变体保留了类似天然的特性。这一结果表明,主链灵活性可以与氨基酸侧链选择明确结合,并且该选择算法具有足够的鲁棒性,能够容忍高达G β1天然超二级结构参数值15%的扰动。
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