Functional tuning of a salvaged green fluorescent protein variant with a new sequence space by directed evolution.

Sung-Hun Nam, Ki-Hoon Oh, Geun-Joong Kim, Hak-Sung Kim
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引用次数: 12

Abstract

We previously reported a method, designated functional salvage screen (FSS), to generate protein lineages with new sequence spaces through the functional or structural salvage of a defective protein by employing green fluorescent protein (GFP) as a model protein. Here, in an attempt to mimic a step in the natural evolution process of proteins, the functionally salvaged mutant GFP-I5 with new sequence space, but showing low fluorescence intensity and stability, was selected and fine-tuned by directed evolution. During a course of functional tuning, GFP-I5 was found to evolve rapidly, recovering the spectral traits to those of the parent GFPuv. The mutant 3E4 from the third round of directed evolution possessed four substitutions; three (F64L, E111V and K166Q) were at the original GFP gene and the other (K8N) at the inserted segment. The fluorescence intensity of 3E4 was approximately 28-fold stronger than GFP-I5, and other spectral properties were retained. Biochemical and biophysical investigations suggested that the fine-tuning by directed evolution led the salvaged variant GFP-I5 to a functionally favorable structure, resulting in recovery of stability and fluorescence. Site-directed mutagenesis of the mutated amino acid residues in both GFPuv and GFP-I5 revealed that each amino acid residue has a different effect on the fluorescence intensity, which implies that 3E4 adopted a new evolutionary path with respect to fluorescence characteristics compared with the parent GFPuv. Directed evolution in conjunction with FSS is expected to be used for generating protein lineages with new fitness landscapes.

利用定向进化对一种回收的具有新序列空间的绿色荧光蛋白变体进行功能调整。
我们之前报道了一种方法,称为功能挽救筛选(FSS),通过使用绿色荧光蛋白(GFP)作为模型蛋白,通过功能或结构挽救缺陷蛋白来产生具有新序列空间的蛋白质谱系。在这里,为了模仿蛋白质自然进化过程中的一个步骤,选择了具有新序列空间但荧光强度和稳定性较低的功能挽救突变体GFP-I5,并通过定向进化进行微调。在功能调整过程中,发现GFP-I5进化迅速,恢复到母体GFPuv的光谱特征。来自第三轮定向进化的突变体3E4具有4个替换;三个(F64L, E111V和K166Q)位于原始GFP基因上,另一个(K8N)位于插入片段上。3E4的荧光强度比GFP-I5强约28倍,并保留了其他光谱性质。生物化学和生物物理研究表明,定向进化的微调使回收的变体GFP-I5具有良好的功能结构,从而恢复了稳定性和荧光性。对突变的氨基酸残基GFPuv和GFP-I5进行定点突变,发现每个氨基酸残基对荧光强度的影响不同,这表明3E4在荧光特性方面与亲本GFPuv相比采用了新的进化路径。定向进化与FSS相结合有望用于产生具有新适应度景观的蛋白质谱系。
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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