Effect of pps disruption and constitutive expression of srfA on surfactin productivity,spreading and antagonistic properties of Bacillus subtilis 168 derivatives

Aims: To analyse the effects of plipastatin operon disruption and constitutive expression of surfactin operon in Bacillus subtilis 168 on surfactin productivity, in vitro invasive growth and antagonism against fungi. Methods and Results: The srfA native promoter was replaced by the constitutive promoter P_repU in B. subtilis 168 after integration of a functional sfp gene. Moreover, the plipastatin synthesis was further disrupted in the B. subtilis 168 derivatives. In liquid media, an earlier and higher expression of P_repU, than that found with P_srfA, led to a specific surfactin production fivefold higher after 6 h of culture. On solid media, not only the invasive growth and the haemolytic activity but also the antifungal activity of the constitutive strains were improved when compared to the parental strain BBG111. As expected, the disruption of the plipastatin operon strongly reduced in vitro antifungal properties but, interestingly, enhanced specific surfactin production (1·47 g g^?1 of biomass), spreading behaviour and haemolytic activity of the strains. Conclusions: This work demonstrates for the first time the interdependency of surfactin and plipastatin regarding their biosynthesis as well as their influence on the biological activities of the producing strain. Significance and Impact of the Study: The constitutive overproduction of surfactin enhances the invasive growth and the in vitro antagonistic activity of the mutant strain. Both properties are known to play an important role in the biocontrol of plant diseases. Plipastatin operon disruption increases the surfactin productivity of mutant strains. These mutants are interesting for use in continuous bioprocesses for surfactin production or in bioremediation.     

A modular autoinduction device for control of gene expression in Bacillus subtilis

Intense synthesis of proteins and chemicals in engineered microbes impose metabolic burden, frequently leading to reduced growth and heterogeneous cell population. Thus, the correct balance between growth and production is important. Such balance can be engineered through dynamic control of pathways, but few broadly applicable tools are available to achieve this. We present an autonomous control of gene expression mediated by quorum sensing in Bacillus subtilis, able to self-monitor and induce expression without human supervision. Two variations of the induction module and seven of the response module were engineered generating a range of induction folds and strengths for gene expression control. Our strongest response promoter is 2.5 and 3.2 times stronger than the well-characterized promoters P_srfA and P_veg, respectively. We applied our strongest autoinduction device for the production of the vitamin B₂. This study presents a toolbox of autoinduction modules for B. subtilis that is modular and tunable.     

Identification and characterization of P GCW14 : a novel, strong constitutive promoter of Pichia pastoris

The available promoters in the Pichia pastoris expression platform are still limited. We selected and identified a novel strong constitutive promoter, P _GCW14 , and tested its promoter activity using enhanced green fluorescent protein (EGFP) as a reporter. Potential promoter regions of P _GCW14 were cloned upstream of the EGFP gene and promoter activity was analyzed by measuring fluorescence intensity. P _GCW14 exhibited significantly stronger promoter activity than the classic strong constitutive promoters P _TEF1 and P _GAP under various carbon sources, suggesting that P _GCW14 is a strong and constitutive promoter. Hence, P _GCW14 can be used as a promoter for high-level expression of heterologous proteins.     

Isolation and functional characterization of a novel rice constitutive promoter

Key message

A novel rice constitutive promoter (P _OsCon1 ) was isolated. The molecular mechanism of the promoter activity was investigated. P _OsCon1 could be used as an alternative constitutive promoter for crop transgenic engineering.

Abstract

Monocot constitutive promoter is an important resource for crop transgenic engineering. In this report, we isolated a novel promoter, Oscon1 promoter (P _OsCon1 ), from the 5′ upstream region of a constitutively expressed rice gene OsDHAR1. In P _OsCon1 ::GUS transgenic rice, we showed that P _OsCon1 had a broad expression spectrum in all tested tissues. The expression of the promoter was further analyzed in comparison with the previously characterized strong constitutive promoters. P _OsCon1 exhibited comparable activity to OsCc1, OsAct1 or ZmUbi promoters in most tissues, and more active than 35S promoter in roots, seeds, and calli. Further quantitative assays indicated that P _OsCon1 activity was not affected by developmental stages or by environmental factors. Further, 5′-deletions analysis indicated that the distinct regions might contribute to the strong expression of P _OsCon1 in different tissues. Overall, our results suggest that P _OsCon1 is a novel constitutive promoter, which could potentially use in transgenic crop development.     

Heterologous pyc gene expression under various natural and engineered promoters in Escherichia coli for improved succinate production

In this study, the expression level of the pyc gene from Lactococcus lactis was fine tuned to improve succinate production in Escherichia coli SBS550MG. IPTG induction in the cultures of SBS550MG with pHL413, a positive control plasmid previously constructed (Sanchez et al., 2005), gave drastically decreased PYC activity and succinate yield. We constructed several plasmids for the expression of pyc to change copy number and variant promoters. Among the constructs, as compared to pHL413, the PYC activity dropped significantly with the Plac, Ptac, Ptrc or native Ppyc promoters in medium or high copy vectors, which resulted in a decrease in succinate yield. Three constructs pThio12, pHL413-Km, and pHL413-Km(lacIq-)N showed considerable PYC activity and improved succinate production in E. coli SBS550MG. The native Ppyc promoter was also modified in order to vary pyc expression levels by site-directed mutagenesis of the −10, −35, −44 regions, and the spacer regions between −10 to −35 and −35 to −44 regions. Out of 9 native promoter variants, the MIII variant resulted in a 20% increase in PYC activity, and improved succinate yield in SBS550MG. We also determined the copy number and stability of pHL413 and pHL413-Km. The two plasmids showed roughly the same copy number, but the pHL413-Km plasmid was relatively more stable. This study provides more understanding of the plasmid characteristics and fine tuning of the expression level of pyc for optimization of the succinate production processes.     

Using inexpensive substrate to achieve high-level lipase A secretion by Bacillus subtilis through signal peptide and promoter screening

Lipase A exhibits great commercial value due to its applications in the food and paper industry, pharmaceutical chemistry and household chemicals. In this study, we first conducted a comparison of different signal peptides and promoters for the construction of the productive lipase A strain. The maximum extracellular lipase activity was identified as 64.9 U/mL after 12-h fermentation at 37 °C by B. subtilis L25 in which the lipase gene was led by SP_lipA and controlled by P₄₃-P_hag. Another aim was to determine whether supplementing a culture medium with a combination of glycerol and Streptomyces sp. SCUT-3 digested chicken feather hydrolysates was beneficial to lipase production. Systematic optimization experiments were designed and carried out. Finally, a satisfactory lipase level of 1164.9 U/mL was accomplished in Terrific-Broth medium at a C/N ratio of 0.5 (v/v). This work demonstrates the feasibility of B. subtilis L25 for lipase A industrial production using glycerol and microbes treated chicken feather hydrolysates as inexpensive carbon and nitrogen source.     

Saturation mutagenesis and self-inducible expression of trehalose synthase in Bacillus subtilis

Trehalose is a nonreducing disaccharide synthesized by trehalose synthase (TreS), which catalyzes the reversible interconversion of maltose and trehalose. We aimed to enhance the catalytic conversion of maltose to trehalose by saturation mutagenesis, and constructed a self-inducible TreS expression system by generating a robust Bacillus subtilis recombinant. We found that the conversion yield and enzymatic activity of TreS was enhanced by saturation mutations, especially by the combination of V407M and K490L mutations. At the same time, these saturation mutations were contributing to reducing by-products in the reaction. Compared to WT TreS, the conversion yield of maltose to trehalose was increased by 11.9%, and the k_cat/K_m toward trehalose was 1.33 times higher in the reaction catalyzed by treS^V407M-K490L. treS^V407M-K490L expression was further observed in the recombinant B. subtilis W800N(Δσ^F) under the influence of P_srfA, P_cry3Aa, and P_srfA-cry3Aa promoters without an inducer. It was shown that P_srfA-cry3Aa was evidently a stronger promoter for treS^V407M-K490L expression, with the intracellular enzymatic activity of recombinant treS^V407M-K490L being over 5,800 U/g at 35 hr in TB medium. These results suggested the combination of two mutations, V407M and K490L, was conducive for the production of trehalose. In addition, the self-inducible TreS^V407M/K490L mutant in the B. subtilis host provides a low-cost choice for the industrial production of endotoxin-free trehalose with high yields.     

Cloning of amidase gene from Rhodococcus erythropolis and expression by distinct promoters in Bacillus subtilis

Amidase was a crucial enzyme responsible for the conversion of acrylamide to acrylic acid in Rhodococcus erythropolis. Its coding gene ami was amplified by PCR using the genomic DNA of R. erythropolis as template. Subsequently, it was ligated to expression plasmids and transformed in Escherichia coli and Bacillus subtilis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis revealed that both recombinant E. coli BL21 (DE3) and B. subtilis generated amidase of 56 kDa. The expression mass and enzyme activity suggested that B. subtilis was more suitable as a host when ami gene was under the control of a powerful promoter. To further study the expression effect of different promoters in B. subtilis, five distinct promoters (sacB, amyE, p43, degQ, aprE) and their native signal peptide genes were employed to separately construct five different vectors harboring ami gene. Of the five novel vectors, the amyE promoter along with its native signal peptide gene was most effective. The maximum specific activity of amidase at pH 7.0 and 37 °C was about 8.7 U/mg and the conversion efficiency could approximately reach 90% within 6 h. This result indicated the expression difference of distinct promoters, which provided the basis for the forthcoming research.     

Insightful directed evolution of Escherichia coli quorum sensing promoter region of the lsrACDBFG operon: a tool for synthetic biology systems and protein expression

Quorum sensing (QS) regulates many natural phenotypes (e.q. virulence, biofilm formation, antibiotic resistance), and its components, when incorporated into synthetic genetic circuits, enable user-directed phenotypes. We created a library of Escherichia coli lsr operon promoters using error-prone PCR (ePCR) and selected for promoters that provided E. coli with higher tetracycline resistance over the native promoter when placed upstream of the tet(C) gene. Among the fourteen clones identified, we found several mutations in the binding sites of QS repressor, LsrR. Using site-directed mutagenesis we restored all p-lsrR-box sites to the native sequence in order to maintain LsrR repression of the promoter, preserving the other mutations for analysis. Two promoter variants, EP01rec and EP14rec, were discovered exhibiting enhanced protein expression. In turn, these variants retained their ability to exhibit the LsrR-mediated QS switching activity. Their sequences suggest regulatory linkage between CytR (CRP repressor) and LsrR. These promoters improve upon the native system and exhibit advantages over synthetic QS promoters previously reported. Incorporation of these promoters will facilitate future applications of QS-regulation in synthetic biology and metabolic engineering.     

Enhanced extracellular production of α-amylase in <Emphasis Type="Italic">Bacillus subtilis</Emphasis> by optimization of regulatory elements and over-expression of PrsA lipoprotein

α-Amylase was used as a heterologous model protein to investigate the effects of promoters, signal peptides and over-expression of an extra-cytoplasmic molecular chaperone, PrsA lipoprotein, on enhancing the secretion of α-amylase in Bacillus subtilis. Four promoters and six signal peptides were compared, successively, and the highest yield of α-amylase was achieved under the promotion mediated by P_AprE, a strong constitutive promoter, and secretion by SP_nprE, a signal peptide from B. subtilis. Moreover, under conditions of overexpressed PrsA lipoprotein, the secretion production and activity of α-amylase increased to 2.5-fold. The performance of the recombinant B. subtilis 1A751PL31 was evaluated with a fed-batch fermentation in a 7.5 l fermentor. Optimization of regulatory elements and over-expression of PrsA lipoprotein had a significant effect on enhancing the production of α-amylase in B. subtilis.     

Global functional analyses of rice promoters by genomics approaches

Promoters play key roles in conferring temporal, spatial, chemical, developmental, or environmental regulation of gene expression. Promoters that are subject to specific regulations are useful for manipulating foreign gene expression in plant cells, tissues, or organs with desirable patterns and under controlled conditions, and have been important for both basic research and applications in agriculture biotechnology. Recent advances in genomics technologies have greatly facilitated identification and study of promoters in a genome scale with high efficiency. Previously we have generated a large T-DNA tagged rice mutant library (TRIM), in which the T-DNA was designed with a gene/promoter trap system, by placing a promoter-less GUS gene next to the right border of T-DNA. GUS activity screens of this library offer in situ and in planta identifications and analyses of promoter activities in their native configurations in the rice genome. In the present study, we systematically performed GUS activity screens of the rice mutant library for genes/promoters constitutively, differentially, or specifically active in vegetative and reproductive tissues. More than 8,200 lines have been screened, and 11% and 22% of them displayed GUS staining in vegetative tissues and in flowers, respectively. Among the vegetative tissue active promoters, the ratio of leaf active versus root active is about 1.6. Interestingly, all the flower active promoters are anther active, but with varied activities in different flower tissues. To identify tissue specific ABA/stress up-regulated promoters, we compared microarray data of ABA/stress induced genes with those of tissue-specific expression determined by promoter trap GUS staining. Following this approach, we showed that the peroxidase 1 gene promoter was ABA up-regulated by 4 fold within 1 day of exposure to ABA and its expression is lateral root specific. We suggest that this be an easy bioinformatics approach in identifying tissue/cell type specific promoters that are up-regulated by hormones or other factors. Su-May Yu and Swee-Suak Ko equally contributed to this work.