N-terminal LysSN-His-tag improves the production of intracellular recombinant protein in Bacillus subtilis.

Choosing fusion tags to enhance the recombinant protein levels in the cytoplasm of Bacillus subtilis has been limited. Our previous study demonstrated that His-tag at the N-terminus could increase the expression levels of the low-expression gene egfp, while significantly reducing the high-expression genes gfp+ and bgaB in the cytoplasm of B. subtilis. In this study, we aimed to prove the potential of a fusion tag, the combination of the N-terminal domain of B. subtilis lysyl tRNA synthetase (LysSN) and His-tag with varying numbers of histidine (6xHis, 8xHis, 10xHis) by investigating their effects on the expression levels of egfp, gfp+ and bgaB in B. subtilis. For the low-expression gene, LysSN-xHis-tag could enhance the fluorescent intensity of EGFP 23.5 times higher than EGFP without a fusion tag, and 1.5 times higher than that fused with only His-tag. For high-expression genes, the expression level of BgaB and GFP+ was 2.9 and 12.5 times higher than that of His-tag, respectively. The number of histidines in LysSN-xHis-tag did not influence the expression levels of the high-expression genes but affected the expression levels of the low-expression gene.

Potent IPTG-inducible integrative expression vectors for production of recombinant proteins in Bacillus subtilis.

The IPTG-inducible promoter family, Pgrac, allows high protein expression levels in an inducible manner. In this study, we constructed IPTG-inducible expression vectors containing strong Pgrac promoters that allow integration of the transgene at either the amyE or lacA locus or both loci in Bacillus subtilis. Our novel integrative expression vectors based on Pgrac promoters could control the repression of protein production in the absence and the induction in the presence of an inducer, IPTG. The ß-galactosidase (BgaB) protein levels were 9.0%, 15% and 30% of the total cellular protein in the B. subtilis strains carrying single cassettes with the Pgrac01, Pgrac100 or Pgrac212 promoters, respectively. The maximal induction ratio of Pgrac01-bgaB was 35.5 while that of Pgrac100-bgaB was 7.5 and that of Pgrac212-bgaB was 9. The inducible expression of GFP and BgaB protein was stably maintained for 24 h, with the highest yield of GFP being 24% of cell total protein while the maximum amount of BgaB was found to be 38%. A dual integration of two copies of the gfp+ gene into the B. subtilis genome at the lacA and amyE loci resulted in a yield of about 40% of total cellular protein and a 1.74-fold increase in GFP compared with single-integrated strains containing the same Pgrac212 promoter. The capability of protein production from low to high levels of these inducible integrative systems is useful for fundamental and applied research in B. subtilis.

Preparation of Bacillus subtilis cell samples and generation of an SDS-PAGE.

Bacillus subtilis is a critical host for producing recombinant proteins. However, the SDS-PAGE process, including the sample preparation steps, varies among B. subtilis-related studies, making it impossible to compare findings. Hence, this paper provides a simple guide to culture and collect B. subtilis cells through an OD600 measurement and a protocol for SDS-PAGE. These techniques were applied to check the expression of a BgaB, a reporter protein and LukF-PV, a potential vaccine candidate against S. aureus, in the cytoplasm of B. subtilis under the control of a strong promoter, Pgrac212. This protocol could be helpful for scientists in preparing samples and generating an SDS-PAGE experiment, as well as favoring the unification of research about protein expression in B. subtilis.

Influence of N-terminal His-tags on the production of recombinant proteins in the cytoplasm of Bacillus subtilis.

The influence of fusion tags to produce recombinant proteins in the cytoplasm of Bacillus subtilis is not well-studied as in E. coli. This study aimed to investigate the influence of His-tags with different codons on the protein production levels of the high expression gene (gfp+) and low expression gene (egfp) in the cytoplasm of B. subtilis cells. We used three different N-terminal His-tags, M-6xHis, MRGS-8xHis and MEA-8xHis, to investigate their effects on the production levels of GFP variants under the control of the Pgrac212 in B. subtilis. The fusions of His-tags with GFP+ caused a reduction compared to the construct without His-tag. When three His-tags fused with egfp, the EGFP production levels were significantly increased up to 3.5-, 12-, and 15-fold. This study suggested that His-tag at the N-terminus could enhance the protein production for the low expression gene and reduce that of the high expression gene in B. subtilis.

A Protocol to Enhance Soluble Protein Expression in the Cytoplasm of Bacillus subtilis.

Bacillus subtilis is a generally regarded as safe (GRAS) microorganism, which has been used for industrial production of recombinant enzymes. Many inducible and inducer-free expression vectors have been developed for intracellular production; some of those demonstrated the capability for protein expression up to 42% of total cellular proteins. In this chapter, we introduce the method to enhance the expression of soluble protein in B. subtilis. It includes the construction of vectors, the transformation of a plasmid into B. subtilis, and checking the expression of the protein.

Integrative expression vectors with Pgrac promoters for inducer-free overproduction of recombinant proteins in Bacillus subtilis.

Inducer-free integrative vectors are often used to create B. subtilis strains for industrial purposes, but employing strong promoters to produce high levels of recombinant proteins in B. subtilis results in high leaky expression that can hamper cloning in Escherichia coli. To overcome the problem, we used strong IPTG-inducible Pgrac promoters harboring lac operators to construct inducer-free integrative vectors able to integrate into the B. subtilis genome at either the lacA or the amyE locus, or both and examined their ability to repress the ß-galactosidase (bgaB) gene in E. coli and to overexpress BgaB in B. subtilis. The Pgrac01 vectors could repress bgaB expression about 24-fold in E. coli to low background levels. The integrated Pgrac01-bgaB constructs exhibited inducer-free expression and produced 8% of total cellular proteins, only 1.25 or 1.75 times less compared with their cognates as plasmids. The stronger promoters, Pgrac100-bgaB and Pgrac212-bgaB yielded 20.9 % and 42 % of total intracellular proteins after 12 h of incubation, respectively. Incorporation of the Pgrac212-bgaB into both amyE and lacA loci resulted in BgaB expression up to 53.4 %. In conclusion, integrative vectors containing the Pgrac promoter family have great potential for inducer-free overproduction of recombinant proteins in B. subtilis.

Development of inducer-free expression plasmids based on IPTG-inducible promoters for Bacillus subtilis.

BACKGROUND: Besides Escherichia coli, Bacillus subtilis is an important bacterial species for the production of recombinant proteins. Recombinant genes are inserted into shuttle expression vectors which replicate in both E. coli and in B. subtilis. The ligation products are first transformed into E. coli cells, analyzed for correct insertions, and the correct recombinant plasmids are then transformed into B. subtilis. A major problem using E. coli cells can be the strong basal level of expression of the recombinant protein which may interfere with the stability of the cells. To minimize this problem, we developed strong expression vectors being repressed in E. coli and inducer-free in B. subtilis. RESULTS: In general, induction of IPTG-inducible expression vectors is determined by the regulatory lacI gene encoding the LacI repressor in combination with the lacO operator on the promoter. To investigate the inducer-free properties of the vectors, we constructed inducer-free expression plasmids by removing the lacI gene and characterized their properties. First, we examined the ability to repress a reporter gene in E. coli, which is a prominent property facilitating the construction of the expression vectors carrying a target gene. The ß-galactosidase (bgaB gene) basal levels expressed from Pgrac01-bgaB could be repressed at least twice in the E. coli cloning strain. Second, the inducer-free production of BgaB from four different plasmids with the Pgrac01 promoter in B. subtilis was investigated. As expected, BgaB expression levels of inducer-free constructs are at least 37 times higher than that of the inducible constructs in the absence of IPTG, and comparable to those in the presence of the inducer. Third, using efficient IPTG-inducible expression vectors containing the strong promoter Pgrac100, we could convert them into inducer-free expression plasmids. The BgaB production levels from the inducer-free plasmid in the absence of the inducer were at least 4.5 times higher than that of the inducible vector using the same promoter. Finally, we used gfp as a reporter gene in combination with the two promoters Pgrac01 and Pgrac100 to test the new vector types. The GFP expression levels could be repressed at least 1.5 times for the Pgrac01-gfp+ inducer-free construct in E. coli. The inducer-free constructs Pgrac01-gfp+ and Pgrac100-gfp+ allowed GFP expression at high levels from 23 × 104 to 32 × 104 RFU units and 9-13% of total intracellular proteins. We could reconfirm the two major advantages of the new inducer-free expression plasmids: (1) Strong repression of the target gene expression in the E. coli cloning strain, and (2) production of the target protein at high levels in B. subtilis in the absence of the inducer. CONCLUSIONS: We propose a general strategy to generate inducer-free expression vector by using IPTG-inducible vectors, and more specifically we developed inducer-free expression plasmids using IPTG-inducible promoters in the absence of the LacI repressor. These plasmids could be an excellent choice for high-level production of recombinant proteins in B. subtilis without the addition of inducer and at the same time maintaining a low basal level of the recombinant proteins in E. coli. The repression of the recombinant gene expression would facilitate cloning of genes that potentially inhibit the growth of E. coli cloning strains. The inducer-free expression plasmids will be extended versions of the current available IPTG-inducible expression vectors for B. subtilis, in which all these vectors use the same cognate promoters. These inducer-free and previously developed IPTG-inducible expression plasmids will be a useful cassette to study gene expression at a small scale up to a larger scale up for the production of recombinant proteins.

A Generic Protocol for Intracellular Expression of Recombinant Proteins in Bacillus subtilis.

Bacillus subtilis (B. subtilis) is a potential and attractive host for the production of recombinant proteins. Different expression systems for B. subtilis have been developed recently, and various target proteins have been recombinantly synthesized and purified using this host. In this chapter, we introduce a generic protocol to express a recombinant protein in B. subtilis. It includes protocols for (1) using our typical expression vector (plasmid pHT254) to introduce a target gene, (2) transformation of the target vector into B. subtilis, and (3) evaluation of the actual expression of a recombinant protein.