Design and construction of light-regulated gene transcription and protein translation systems in yeast P. Pastoris.

Siyu Zhang, Jiazhen Zhang, Ru Lin, Chaoyu Lu, Bohao Fang, Jiacheng Shi, Tianyi Jiang, Mian Zhou
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Abstract

Introduction: P. pastoris is a common host for effective biosynthesis of heterologous proteins as well as small molecules. Accurate regulation of gene transcription and protein synthesis is necessary to coordinate synthetic gene circuits and optimize cellular energy distribution. Traditional methanol or other inducible promoters, natural or engineered, have defects in either fermentation safety or expression capacity. The utilization of chemical inducers typically adds complexity to the product purification process, but there is no other well-controlled protein synthesis system than promoters yet.

Objective: The study aimed to address the aforementioned challenges by constructing light-regulated gene transcription and protein translation systems with excellent expression capacity and light sensitivity.

Methods: Trans-acting factors were designed by linking the N. crassa blue-light sensor WC-1 with the activation domain of endogenous transcription factors. Light inducible or repressive promoters were then constructed through chimeric design of cis-elements (light-responsive elements, LREs) and endogenous promoters. Various configurations of trans-acting factor/LRE pairs, along with different LRE positions and copy numbers were tested for optimal promoter performance. In addition to transcription, a light-repressive translation system was constructed through the "rare codon brake" design. Rare codons were deliberately utilized to serve as brakes during protein synthesis, which were switched on and off through the light-regulated changes in the expression of the corresponding pLRE-tRNA.

Results: As demonstrated with GFP, the light-inducible promoter 4pLRE-cPAOX1 was 70 % stronger than the constitutive promoter PGAP, with L/D ratio = 77. The light-repressive promoter PGAP-pLRE was strictly suppressed by light, with expression capacity comparable with PGAP in darkness. As for the light-repressive translation system, the "triple brake" design successfully eliminated leakage and achieved light repression on protein synthesis without any impact on mRNA expression.

Conclusion: The newly designed light-regulated transcription and translation systems offer innovative tools that optimize the application of P. pastoris in biotechnology and synthetic biology.

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帕斯托瑞斯酵母中光调控基因转录和蛋白质翻译系统的设计与构建。
简介:牧杆菌是有效生物合成异源蛋白和小分子的常见宿主。基因转录和蛋白质合成的精确调控是协调合成基因回路和优化细胞能量分配所必需的。传统的甲醇或其他天然或人工合成的诱导型启动子在发酵安全性或表达能力方面都存在缺陷。使用化学诱导剂通常会增加产品纯化过程的复杂性,但除了启动子之外,还没有其他控制良好的蛋白质合成系统:本研究旨在通过构建具有出色表达能力和光敏感性的光调节基因转录和蛋白质翻译系统来应对上述挑战:方法:通过将 N. crassa 的蓝光传感器 WC-1 与内源转录因子的激活结构域连接,设计出转录因子。然后通过顺式元件(光响应元件,LREs)和内源启动子的嵌合设计构建了光诱导或抑制启动子。对各种反式作用因子/LRE 对的配置以及不同的 LRE 位置和拷贝数进行了测试,以获得最佳启动子性能。除转录外,还通过 "稀有密码子制动 "设计构建了光抑制翻译系统。特意利用稀有密码子作为蛋白质合成过程中的制动器,通过光调节相应 pLRE-tRNA 的表达变化来开关制动器:结果:正如 GFP 所显示的,光诱导启动子 4pLRE-cPAOX1 比组成型启动子 PGAP 强 70%,长径比 = 77。光抑制型启动子 PGAP-pLRE 受到光的严格抑制,其表达能力与黑暗条件下的 PGAP 相当。至于光抑制翻译系统,"三重制动 "设计成功消除了泄漏,实现了光抑制蛋白质合成,而不影响 mRNA 的表达:结论:新设计的光调节转录和翻译系统提供了创新工具,优化了 P. pastoris 在生物技术和合成生物学中的应用。
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