Modern Approaches to the Genome Editing of Antibiotic Biosynthetic Clusters in Actinomycetes.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
J A Buyuklyan, Yu V Zakalyukina, I A Osterman, M V Biryukov
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Abstract

Representatives of the phylum Actinomycetota are one of the main sources of secondary metabolites, including antibiotics of various classes. Modern studies using high-throughput sequencing techniques enable the detection of dozens of potential antibiotic biosynthetic genome clusters in many actinomycetes; however, under laboratory conditions, production of secondary metabolites amounts to less than 5% of the total coding potential of producer strains. However, many of these antibiotics have already been described. There is a continuous "rediscovery" of known antibiotics, and new molecules become almost invisible against the general background. The established approaches aimed at increasing the production of novel antibiotics include: selection of optimal cultivation conditions by modifying the composition of nutrient media; co-cultivation methods; microfluidics, and the use of various transcription factors to activate silent genes. Unfortunately, these tools are non-universal for various actinomycete strains, stochastic in nature, and therefore do not always lead to success. The use of genetic engineering technologies is much more efficient, because they allow for a directed and controlled change in the production of target metabolites. One example of such technologies is mutagenesis-based genome editing of antibiotic biosynthetic clusters. This targeted approach allows one to alter gene expression, suppressing the production of previously characterized molecules, and thereby promoting the synthesis of other unknown antibiotic variants. In addition, mutagenesis techniques can be successfully applied both to new producer strains and to the genes of known isolates to identify new compounds.

放线菌抗生素生物合成簇基因组编辑的现代方法。
放线菌门的代表是次级代谢产物的主要来源之一,包括各类抗生素。使用高通量测序技术的现代研究能够在许多放线菌中检测到数十个潜在的抗生素生物合成基因组簇;然而,在实验室条件下,次级代谢产物的产生量不到生产菌株总编码潜力的5%。然而,这些抗生素中的许多已经被描述过了。已知抗生素不断被“重新发现”,新分子在大背景下几乎看不见。旨在增加新型抗生素产量的既定方法包括:通过改变营养培养基的组成来选择最佳培养条件;共育方式;微流体以及使用各种转录因子来激活沉默基因。不幸的是,这些工具对各种放线菌菌株来说是不通用的,本质上是随机的,因此并不总是成功的。基因工程技术的使用要有效得多,因为它们可以直接和可控地改变目标代谢产物的产生。这类技术的一个例子是基于诱变的抗生素生物合成簇的基因组编辑。这种靶向方法可以改变基因表达,抑制先前表征的分子的产生,从而促进其他未知抗生素变体的合成。此外,诱变技术可以成功地应用于新的生产菌株和已知分离株的基因,以鉴定新的化合物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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