College of Life Sciences, Sichuan Key Laboratory of Molecular Biology and Biotechnology, Key Laboratory of Bio-Resources and Eco-Environment, Ministry of Education, Sichuan University, Chengdu, 610064, Sichuan, People's Republic of China.
Curr Microbiol. 2020 Nov;77(11):3612-3622. doi: 10.1007/s00284-020-02154-5. Epub 2020 Aug 4.
Bacillus pumilus BA06 has great potential for the production of alkaline proteases. To improve the protease yield, classical mutagenesis to combine the physical and chemical mutagens was performed to obtain a protease hyper-productive mutant SCU11. The full genome sequences of BA06 and SCU11 strains were assembled through DNA sequencing using the PacBio sequencing platform. By comparative genomics analysis, 147 SNPs and 15 InDels were found between these two genomes, which lead to alternation of coding sequence in 15 genes. Noticeable, the gene (kinA) encoding sporulation kinase A is interrupted by introducing a stop codon in its coding region in BA06. Interestedly, this gene is reversely corrected in SCU11. Furthermore, comparative transcriptome analysis revealed that kinA and two positive regulatory genes (DegU and Spo0A) were upregulated in transcription in SCU11. In terms of the transcriptional data, upregulation of a phosphorylation cascade starting with KinA may enhance Spo0A phosphorylation, and thus activate expression of the gene aprE (encoding major extracellular protease) through repression of AbrB (a repressor of aprE) and activation of SinI, an antagonist of SinR (a repressor of aprE). In addition, the other genes involved in various metabolic pathways, especially of membrane transport and sporulation, were altered in transcription between these two strains. Conclusively, our transcriptome data suggested that upregulation degU and spo0A, as well as kinA, may at least partially contribute to the high production of alkaline protease in SCU11.
短小芽孢杆菌 BA06 具有生产碱性蛋白酶的巨大潜力。为了提高蛋白酶的产量,采用经典的诱变方法,结合物理和化学诱变剂,获得了一种产蛋白酶能力超高效的突变株 SCU11。通过 PacBio 测序平台进行 DNA 测序,对 BA06 和 SCU11 菌株的全基因组序列进行了组装。通过比较基因组学分析,在这两个基因组之间发现了 147 个 SNPs 和 15 个 InDels,导致 15 个基因的编码序列发生改变。值得注意的是,编码孢子形成激酶 A 的基因(kinA)在其编码区被引入一个终止密码子而中断。有趣的是,这个基因在 SCU11 中被反向纠正。此外,比较转录组分析显示,kinA 和两个正调控基因(DegU 和 Spo0A)在 SCU11 中转录上调。就转录数据而言,从 KinA 开始的磷酸化级联的上调可能增强 Spo0A 的磷酸化,从而通过抑制 AbrB(aprE 的阻遏物)和激活 SinI(aprE 的阻遏物 SinR 的拮抗剂)来激活 aprE 基因的表达。此外,这两个菌株之间的转录发生了各种代谢途径的其他基因的改变,特别是膜转运和孢子形成。总之,我们的转录组数据表明,degU 和 spo0A 的上调,以及 kinA 的上调,可能至少部分导致了 SCU11 中碱性蛋白酶的高产。
