State Key Laboratory of Microbial Resources, Institute of Microbiology, Chinese Academy of Sciences, Beijing, People's Republic of China.
College of Life Science, University of Chinese Academy of Sciences, Beijing, People's Republic of China.
Microbiol Spectr. 2022 Dec 21;10(6):e0214922. doi: 10.1128/spectrum.02149-22. Epub 2022 Oct 20.
Although the use of multiple replication origins for chromosome replication has been widely characterized in haloarchaea, whether it is possible to manipulate the chromosome copy number by their genetic engineering is not known, and how it would affect the cell functioning is poorly understood. Here, we demonstrate that deletion of the three active chromosomal origins in Haloferax mediterranei remarkably reduces its DNA amounts and ploidy numbers. Consequently, the mutant strain H. mediterranei Δ123 is more sensitive to UV and mitomycin C. Surprisingly, the cell size increases by 21.2%, and poly(3-hydroxybutyrate--3-hydroxyvalerate) (PHBV) production in shake flask culture enhances from 7.23 to 8.11 g/L in ΔEPSΔ123, although there is also a decrease in cell growth. In this mutant, the chromosomal copy number decreases, whereas the -encoding pHM300 megaplasmid copy number increases. Moreover, our transcriptome analysis reveals that the genes involved in primary metabolisms are significantly downregulated in ΔEPSΔ123, whereas those responsible for starch utilization and precursor supplying for PHBV monomers are upregulated. This indicates that more energy and carbon flux is redirected from primary metabolism to PHBV synthesis, thereby enhancing its PHBV accumulation. These findings may therefore provide a rational design to enhance PHBV synthesis by simply tuning the replication origins to modulate the chromosome/megaplasmid copy number ratio and subsequently influence cellular metabolism and physiological functions. The haloarchaeon Haloferax mediterranei is a potential producer of PHBV (100% biodegradable plastic) from inexpensive carbon sources. We previously reported that H. mediterranei possessed three active chromosomal origins and, when these origins were deleted, a dormant origin was activated to initiate the replication of chromosome. In this context, in the present study, we first found a close connection between replication initiation and PHBV accumulation. We describe the potential industrial advantages of the strain H. mediterranei ΔEPSΔ123, which includes the enlargement of cell volume by 21.2% and enhancement of PHBV production by 11.2%. We further reveal the possible mechanism that contributes to the greater PHBV production in the ΔEPSΔ123 strain. Overall, we provide here a conceptual advance in the field of synthetic biology by modulating chromosome replication to improve the production of bio-based chemicals.
虽然在盐杆菌中已经广泛研究了使用多个复制起点进行染色体复制的情况,但尚不清楚是否可以通过遗传工程来操纵染色体拷贝数,以及这将如何影响细胞功能也知之甚少。在这里,我们证明了删除嗜盐古菌地中海盐杆菌中的三个活性染色体起点会显著降低其 DNA 含量和倍性数量。因此,突变株 H. mediterranei Δ123 对 UV 和丝裂霉素 C 更为敏感。令人惊讶的是,细胞大小增加了 21.2%,并且在摇瓶培养中聚(3-羟基丁酸酯-3-羟基戊酸酯)(PHBV)的产量从 ΔEPSΔ123 的 7.23 增加到 8.11 g/L,尽管细胞生长也有所下降。在这个突变体中,染色体拷贝数减少,而编码 pHM300 大片段的拷贝数增加。此外,我们的转录组分析表明,ΔEPSΔ123 中与初级代谢相关的基因显著下调,而负责淀粉利用和 PHBV 单体前体供应的基因上调。这表明更多的能量和碳通量从初级代谢重新定向到 PHBV 合成,从而增强其 PHBV 积累。这些发现可能为通过简单地调整复制起点来调节染色体/大片段拷贝数比,从而影响细胞代谢和生理功能,从而提供一种合理的设计来增强 PHBV 合成提供了依据。盐杆菌地中海盐杆菌是一种从廉价碳源生产 PHBV(100%可生物降解塑料)的潜在生产者。我们之前报道过,H. mediterranei 拥有三个活跃的染色体起点,当这些起点被删除时,一个休眠的起点被激活以启动染色体的复制。在这种情况下,在本研究中,我们首先发现复制起始与 PHBV 积累之间存在密切联系。我们描述了菌株 H. mediterranei ΔEPSΔ123 的潜在工业优势,包括细胞体积增加 21.2%和 PHBV 产量提高 11.2%。我们进一步揭示了导致 ΔEPSΔ123 菌株中 PHBV 产量更高的可能机制。总的来说,我们通过调节染色体复制来提高生物基化学品的产量,为合成生物学领域提供了一个概念上的进展。
