ATP Regeneration from Pyruvate in the PURE System

Surendra Yadav, Alexander J. P. Perkins, Sahan B. W. Liyanagedera, Anthony Bougas, Nadanai Laohakunakorn
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Abstract

The 'Protein synthesis Using Recombinant Elements' ('PURE') system is a minimal biochemical system capable of carrying out cell-free protein synthesis using defined enzymatic components. This study extends PURE by integrating an ATP regeneration system based on pyruvate oxidase, acetate kinase, and catalase. The new pathway generates acetyl phosphate from pyruvate, phosphate, and oxygen, which is used to rephosphorylate ATP in situ. Successful ATP regeneration requires a high initial concentration of ~10 mM phosphate buffer, which surprisingly does not affect the protein synthesis activity of PURE. The pathway can function independently or in combination with the existing creatine-based system in PURE; the combined system produces up to 233 ug/ml of mCherry, an enhancement of 78% compared to using the creatine system alone. The results are reproducible across multiple batches of homemade PURE, and importantly also generalise to commercial systems such as PURExpress from New England Biolabs. These results demonstrate a rational bottom-up approach to engineering PURE, paving the way for applications in cell-free synthetic biology and synthetic cell construction.
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纯净系统中丙酮酸的 ATP 再生
利用重组元件合成蛋白质"("PURE")系统是一个最小的生化系统,能够利用确定的酶元件进行无细胞蛋白质合成。本研究通过整合基于丙酮酸氧化酶、乙酸激酶和过氧化氢酶的 ATP 再生系统对 PURE 进行了扩展。新途径从丙酮酸、磷酸盐和氧气中生成磷酸乙酰,用于原位再磷酸化 ATP。ATP 的成功再生需要约 10 mM 磷酸盐缓冲液的高初始浓度,但令人惊讶的是,这并不影响 PURE 的蛋白质合成活性。该途径可独立运行,也可与 PURE 中现有的肌酸系统结合使用;结合使用的系统可产生高达 233 微克/毫升的 mCherry,与单独使用肌酸系统相比提高了 78%。这些结果在多个批次的自制 PURE 中都具有可重复性,更重要的是,它们也适用于新英格兰生物实验室(New England Biolabs)的 PURExpress 等商业系统。这些结果展示了一种合理的自下而上的 PURE 工程方法,为无细胞合成生物学和合成细胞构建的应用铺平了道路。
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