Evolverator: An engineered in cellulo yeast system to drive rapid continuous evolution of proteins

bioRxiv - Synthetic Biology Pub Date : 2024-09-01 DOI:10.1101/2024.09.01.610536

Asli Azizoglu, Eline Y. Bijman, Joerg Stelling, Roger Brent

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Abstract

In vivo continuous directed evolution generates genetic diversity and selects a target phenotype to generate proteins with desired functionality. However, in current systems, the two processes do not operate simultaneously in the same cell, restricting applications such as evolution of eukaryotic protein-ligand binding. Here, we describe Evolverator Saccharomyces cerevisiae cells that combine inducible targeted mutagenesis with engineered gene circuits that link the emergence of a desired function to graded increases in cell proliferation. Poor ligand binding induces targeted mutagenesis and cells with mutations that improve ligand binding overtake the cell population. By combining strain development with mathematical modeling for systems and process design, we evolved ligand specificities of the human estrogen receptor and more effective variants of the bacterial lacI repressor. Previously undescribed mutations affected residues plausibly involved in ligand binding and residues that exert allosteric effects. Evolverator should aid generation of proteins that bind new targets for many applications.

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进化器：用于驱动蛋白质快速持续进化的细胞内酵母工程系统

体内持续定向进化产生遗传多样性，并选择目标表型，生成具有所需功能的蛋白质。然而，在目前的系统中，这两个过程不能在同一个细胞中同时进行，从而限制了真核生物蛋白质配体结合进化等应用。在这里，我们描述了进化者酿酒酵母细胞，它将诱导性定向诱变与工程基因回路相结合，将所需功能的出现与细胞增殖的分级增加联系起来。配体结合力差会诱导定向诱变，而突变细胞则会改善配体结合力，从而超越细胞群。通过将菌株开发与用于系统和流程设计的数学建模相结合，我们进化出了人类雌激素受体的配体特异性和细菌lacI抑制因子的更有效变体。以前没有描述过的突变影响了可能参与配体结合的残基和产生异构效应的残基。进化器将有助于产生能结合新靶点的蛋白质，从而应用于多种领域。

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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bioRxiv - Synthetic Biology

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