Copper-Induced In Vivo Gene Amplification in Budding Yeast.

Q2 Agricultural and Biological Sciences 生物设计研究(英文) Pub Date : 2024-03-28 eCollection Date: 2024-01-01 DOI:10.34133/bdr.0030
Junyi Wang, Jingya Song, Cong Fan, Jiahao Duan, Kaiyuan He, Jifeng Yuan
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Abstract

In the biotechnological industry, multicopy gene integration represents an effective strategy to maintain a high-level production of recombinant proteins and to assemble multigene biochemical pathways. In this study, we developed copper-induced in vivo gene amplification in budding yeast for multicopy gene expressions. To make copper as an effective selection pressure, we first constructed a copper-sensitive yeast strain by deleting the CUP1 gene encoding a small metallothionein-like protein for copper resistance. Subsequently, the reporter gene fused with a proline-glutamate-serine-threonine-destabilized CUP1 was integrated at the δ sites of retrotransposon (Ty) elements to counter the copper toxicity at 100 μM Cu2+. We further demonstrated the feasibility of modulating chromosomal rearrangements for increased protein expression under higher copper concentrations. In addition, we also demonstrated a simplified design of integrating the expression cassette at the CUP1 locus to achieve tandem duplication under high concentrations of copper. Taken together, we envision that this method of copper-induced in vivo gene amplification would serve as a robust and useful method for protein overproduction and metabolic engineering applications in budding yeast.

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铜诱导芽殖酵母体内基因扩增。
在生物技术产业中,多拷贝基因整合是维持高水平重组蛋白生产和组合多基因生化途径的有效策略。在这项研究中,我们在芽殖酵母中开发了铜诱导的体内基因扩增技术,以实现多拷贝基因的表达。为使铜成为有效的选择压力,我们首先通过删除编码铜抗性金属硫蛋白样小蛋白的 CUP1 基因构建了铜敏感酵母菌株。随后,我们在逆转录转座子(Ty)元件的δ位点整合了与脯氨酸-谷氨酸-丝氨酸-苏氨酸稳定的 CUP1 融合的报告基因,以对抗 100 μM Cu2+ 的铜毒性。我们进一步证明了在铜浓度较高的情况下通过调节染色体重排来增加蛋白质表达的可行性。此外,我们还展示了在 CUP1 基因座上整合表达盒的简化设计,从而在高浓度铜条件下实现串联复制。总之,我们设想这种铜诱导体内基因扩增的方法将成为一种稳健而有用的方法,可用于芽殖酵母中蛋白质的过度生产和代谢工程应用。
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CiteScore
3.90
自引率
0.00%
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审稿时长
12 weeks
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