动态代谢工程：开发响应性细胞工厂的新策略。

Dynamic metabolic engineering: New strategies for developing responsive cell factories.

作者信息

Brockman Irene M, Prather Kristala L J

机构信息

Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA.

出版信息

Biotechnol J. 2015 Sep;10(9):1360-9. doi: 10.1002/biot.201400422. Epub 2015 Apr 13.

DOI:10.1002/biot.201400422

PMID:25868062

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4629492/

Abstract

Metabolic engineering strategies have enabled improvements in yield and titer for a variety of valuable small molecules produced naturally in microorganisms, as well as those produced via heterologous pathways. Typically, the approaches have been focused on up- and downregulation of genes to redistribute steady-state pathway fluxes, but more recently a number of groups have developed strategies for dynamic regulation, which allows rebalancing of fluxes according to changing conditions in the cell or the fermentation medium. This review highlights some of the recently published work related to dynamic metabolic engineering strategies and explores how advances in high-throughput screening and synthetic biology can support development of new dynamic systems. Dynamic gene expression profiles allow trade-offs between growth and production to be better managed and can help avoid build-up of undesired intermediates. The implementation is more complex relative to static control, but advances in screening techniques and DNA synthesis will continue to drive innovation in this field.

摘要

代谢工程策略已使微生物天然产生的以及通过异源途径产生的各种有价值的小分子的产量和滴度得到提高。通常，这些方法侧重于基因的上调和下调，以重新分配稳态途径通量，但最近一些研究团队已经开发出动态调控策略，这种策略可根据细胞内或发酵培养基中不断变化的条件对通量进行重新平衡。本综述重点介绍了一些最近发表的与动态代谢工程策略相关的研究工作，并探讨了高通量筛选和合成生物学的进展如何支持新动态系统的开发。动态基因表达谱有助于更好地管理生长与生产之间的权衡，并有助于避免不需要的中间体的积累。相对于静态控制，其实施更为复杂，但筛选技术和DNA合成的进展将继续推动该领域的创新。

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