Evolutionary paths that link orthogonal pairs of binding proteins.

Ziv Avizemer, Carlos Martí-Gómez, Shlomo Yakir Hoch, David M McCandlish, Sarel J Fleishman
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Abstract

Some protein binding pairs exhibit extreme specificities that functionally insulate them from homologs. Such pairs evolve mostly by accumulating single-point mutations, and mutants are selected if their affinity exceeds the threshold required for function1-4. Thus, homologous and high-specificity binding pairs bring to light an evolutionary conundrum: how does a new specificity evolve while maintaining the required affinity in each intermediate5,6? Until now, a fully functional single-mutation path that connects two orthogonal pairs has only been described where the pairs were mutationally close thus enabling experimental enumeration of all intermediates2. We present an atomistic and graph-theoretical framework for discovering low molecular strain single-mutation paths that connect two extant pairs, enabling enumeration beyond experimental capability. We apply it to two orthogonal bacterial colicin endonuclease-immunity pairs separated by 17 interface mutations7. We were not able to find a strain-free and functional path in the sequence space defined by the two extant pairs. But including mutations that bridge amino acids that cannot be exchanged through single-nucleotide mutations led us to a strain-free 19-mutation trajectory that is completely viable in vivo. Our experiments show that the specificity switch is remarkably abrupt, resulting from only one radical mutation on each partner. Furthermore, each of the critical specificity-switch mutations increases fitness, demonstrating that functional divergence could be driven by positive Darwinian selection. These results reveal how even radical functional changes in an epistatic fitness landscape may evolve.

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连接正交结合蛋白对的进化路径。
一些蛋白质结合对表现出极端的特异性,使它们在功能上与同源物隔离。这样的配对主要通过积累单点突变来进化,如果它们的亲和力超过功能1-4所需的阈值,则选择突变体。因此,同源和高特异性结合对揭示了一个进化难题:一种新的特异性如何进化,同时在每个中间体中保持所需的亲和力5,6?到目前为止,只描述了连接两个正交对的全功能单一突变路径,其中这些对在突变上很接近,从而能够对所有中间体进行实验计数2。我们提出了一个原子论和图论框架,用于发现连接两个现存对的低分子菌株单突变路径,并将其应用于由17个界面突变分离的两个正交细菌肠绞痛核酸内切酶免疫对7。我们无法在由两个现存配对定义的序列空间中找到一条无应变和功能路径。通过包括桥接无法通过单核苷酸突变交换的氨基酸的突变,我们发现了一个在体内完全起作用的无菌株19突变轨迹。尽管突变轨迹很长,但特异性的转换非常突然,这是由每个伴侣上只有一个激进突变引起的。每一个关键的特异性转换突变都会增加适应度,这表明功能差异可能是由积极的达尔文选择驱动的。这些结果揭示了上位适应度景观中即使是根本的功能变化也可能如何演变。
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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