Abstract
Bacillus subtilis is widely used in agriculture and industrial biotechnology; however, cell autolysis significantly decreases its yield in liquid cultures. Numerous factors mediate the lysis of B. subtilis, such as cannibalism factors, prophages, and peptidoglycan (PG) hydrolases. The aim of this work was to use molecular genetic techniques to develop a new strategy to prevent cell lysis and enhance biomass as well as the production of recombinant proteins. Five genes or genetic elements representing three different functional categories were studied as follows: lytC encoding PG hydrolases, the prophage genes xpf and yqxG-yqxH-cwlA (yGlA), and skfA and sdpC that encode cannibalism factors. Cell lysis was reduced and biomass was enhanced by deleting individually skfA, sdpC, xpf, and lytC. We constructed the multiple deletion mutant LM2531 (skfA sdpC lytC xpf) and found that after 4 h of culture, its biomass yield was significantly increased compared with that of prototypical B. subtilis 168 (wild-type) strain and that 15% and 92% of the cells were lysed in cultures of LM2531 and wild-type, respectively. Moreover, two expression vectors were constructed for producing recombinant proteins (β-galactosidase and nattokinase) under the control of the P43 promoter. Cultures of LM2531 and wild-type transformants produced 13741 U/ml and 7991 U/ml of intracellular β-galactosidase, respectively (1.72-fold increase). Further, the level of secreted nattokinase produced by strain LM2531 increased by 2.6-fold compared with wild-type (5226 IU/ml vs. 2028 IU/ml, respectively). Our novel, systematic multigene deletion approach designed to inhibit cell lysis significantly increased the biomass yield and the production of recombinant proteins by B. subtili s. These findings show promise for guiding efforts to manipulate the genomes of other B. subtilis strains that are used for industrial purposes.
Highlights
Bacillus subtilis is widely used in agriculture and industrial biotechnology; cell autolysis significantly decreases its yield in liquid cultures
Analysis of biomass of B. subtilis strains harboring mutations in individual genes encoding proteins involved in cell lysis To test the influence of targeted mutation of genes involved in cell lysis on the biomass of batch cultures of B. subtilis, we generated the deletion mutants LM1, LM2, LM3, LM4, and LM5, respectively (Additional file 1: Table S1, Appendix S1)
Consistent with published data [35], the transition of wild-type from exponential growth to stationary phase occurred between 6 to 7 h, after which the optical density measured at 600 nm (OD600) decreased, indicating autolysis (Figure 1a)
Summary
Bacillus subtilis is widely used in agriculture and industrial biotechnology; cell autolysis significantly decreases its yield in liquid cultures. The aim of this work was to use molecular genetic techniques to develop a new strategy to prevent cell lysis and enhance biomass as well as the production of recombinant proteins. Cell lysis occurs in liquid cultures of B. subtilis, which may significantly decrease the total biomass and reduce the fermentation yields. The first category includes genes encoding products that play roles in cannibalism during sporulation. Spo0A regulates the skf and sdp operons. A small peptide encoded by skfA, the first gene of the skf operon, acts as an antibiotic that kills siblings. Cells that do not express spo0A are killed, and their contents provide nutrients that feed their siblings and delay sporulation of the entire bacterial population. In cells that express Spo0A, the sdp operon produces the signaling protein SdpC that increases the killing effect [13,14,15]
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