Ramos Kristine Rose M, Valdehuesa Kris Niño G, Liu Huaiwei, Nisola Grace M, Lee Won-Keun, Chung Wook-Jin
Department of Energy and Biotechnology (DEB), Energy and Environment Fusion Technology Center (E2FTC), Myongji University, 116 Myongji-ro, Cheoin-gu, Yongin-si, Gyeonggi-do, 449-728, Republic of Korea.
Bioprocess Biosyst Eng. 2014 Dec;37(12):2505-13. doi: 10.1007/s00449-014-1228-z. Epub 2014 Jun 14.
An engineered Escherichia coli strain was developed for enhanced isoprene production using D-galactose as substrate. Isoprene is a valuable compound that can be biosynthetically produced from pyruvate and glyceraldehyde-3-phosphate (G3P) through the methylerythritol phosphate pathway (MEP). The Leloir and De Ley-Doudoroff (DD) pathways are known existing routes in E. coli that can supply the MEP precursors from D-galactose. The DD pathway was selected as it is capable of supplying equimolar amounts of pyruvate and G3P simultaneously. To exclusively direct D-galactose toward the DD pathway, an E. coli ΔgalK strain with blocked Leloir pathway was used as the host. To obtain a fully functional DD pathway, a dehydrogenase encoding gene (gld) was recruited from Pseudomonas syringae to catalyze D-galactose conversion to D-galactonate. Overexpressions of endogenous genes known as MEP bottlenecks, and a heterologous gene, were conducted to enhance and enable isoprene production, respectively. Growth test confirmed a functional DD pathway concomitant with equimolar generation of pyruvate and G3P, in contrast to the wild-type strain where G3P was limiting. Finally, the engineered strain with combined DD-MEP pathway exhibited the highest isoprene production. This suggests that the equimolar pyruvate and G3P pools resulted in a more efficient carbon flux toward isoprene production. This strategy provides a new platform for developing improved isoprenoid producing strains through the combined DD-MEP pathway.
构建了一种工程化大肠杆菌菌株,用于以D-半乳糖为底物提高异戊二烯产量。异戊二烯是一种有价值的化合物,可通过甲基赤藓糖醇磷酸途径(MEP)由丙酮酸和3-磷酸甘油醛(G3P)生物合成产生。Leloir途径和De Ley-Doudoroff(DD)途径是大肠杆菌中已知的现有途径,可从D-半乳糖供应MEP前体。选择DD途径是因为它能够同时供应等摩尔量的丙酮酸和G3P。为了将D-半乳糖专门导向DD途径,使用Leloir途径受阻的大肠杆菌ΔgalK菌株作为宿主。为了获得功能完整的DD途径,从丁香假单胞菌中引入了一个编码脱氢酶的基因(gld),以催化D-半乳糖转化为D-半乳糖酸。分别过表达已知为MEP瓶颈的内源基因和一个异源基因,以增强和实现异戊二烯的产生。生长测试证实了功能完整的DD途径伴随着丙酮酸和G3P的等摩尔生成,这与野生型菌株中G3P受限的情况形成对比。最后,具有组合DD-MEP途径的工程菌株表现出最高的异戊二烯产量。这表明等摩尔的丙酮酸和G3P库导致了更有效的碳通量向异戊二烯生产方向流动。该策略为通过组合DD-MEP途径开发改良的类异戊二烯生产菌株提供了一个新平台。
