Background Promoter evolution by synthetic promoter library (SPL) is a powerful approach to development of functional synthetic promoters to synthetic biology. However, it requires much tedious and time-consuming screenings because of the plethora of different variants in SPL. Actually, a large proportion of mutants in the SPL are significantly lower in strength, which contributes only to fabrication of a promoter library with a continuum of strength. Thus, to effectively obtain the evolved synthetic promoter exhibiting higher strength, it is essential to develop novel strategies to construct mutant library targeting the pivotal region rather than the arbitrary region of the template promoter. In this study, a strategy termed stepwise evolution targeting the spacer of core promoter (SETarSCoP) was established in Bacillus subtilis to effectively evolve the strength of bacterial promoter. Results The native promoter, P srfA , from B. subtilis , which exhibits higher strength than the strong promoter P43, was set as the parental template. According to the comparison of conservation of the spacer sequences between − 35 box and − 10 box among a set of strong and weak native promoter, it revealed that 7-bp sequence immediately upstream of the − 10 box featured in the regulation of promoter strength. Based on the conservative feature, two rounds of consecutive evolution were performed targeting the hot region of P srfA . In the first round, a primary promoter mutation library (pPML) was constructed by mutagenesis targeting the 3-bp sequence immediately upstream of the − 10 box of the P srfA . Subsequently, four evolved mutants from pPML were selected to construction of four secondary promoter mutation libraries (sPMLs) based on mutagenesis of the 4-bp sequence upstream of the first-round target. After the consecutive two-step evolution, the mutant P BH4 was identified and verified to be a highly evolved synthetic promoter. The strength of P BH4 was higher than P srfA by approximately 3 times. Moreover, P BH4 also exhibited broad suitability for different cargo proteins, such as β-glucuronidase and nattokinase. The proof-of-principle test showed that SETarSCoP successfully evolved both constitutive and inducible promoters. Conclusion Comparing with the commonly used SPL strategy, SETarSCoP facilitates the evolution process to obtain strength-evolved synthetic bacterial promoter through fabrication and screening of small-scale mutation libraries. This strategy will be a promising method to evolve diverse bacterial promoters to expand the toolbox for synthetic biology. Electronic supplementary material The online version of this article (10.1186/s12934-019-1148-3) contains suppleme...
Tuneable gene expression controlled by synthetic biological elements is of great importance to biotechnology and synthetic biology. The synthetic riboswitch is a pivotal type of elements that can easily control the heterologous gene expression in diverse bacteria. In this study, the theophylline-dependent synthetic riboswitch and the corresponding variants with varied spacings between Shine-Dalgarno (SD) sequence and start codon were employed to comprehensively characterize the induction and regulation properties through combining a strong promoter aprE in Bacillus subtilis. Amongst the sets of newly constructed expression elements, the expression element with 9-bp spacing exhibited the higher expression level, a superior induction fold performance, and a considerably lower leaky expression than those with longer or shorter spacings. The riboswitch expression element with 9-bp spacing showed an approximately linear dose dependence from 0 to 8 mM of theophylline. Modification of the SD sequence through the insertion of a single A base prior to the native sequence enables the increase of the expression level post induction while decreasing the induction fold as a result of the elevated leaky level. The riboswitch elements with the engineered SD and the optimal 9-bp spacing exhibit an altered dose dependency in which the approximately linear range shifts to 0-4 mM, although it has a similar profile to the induction process. These results not only provide comprehensive data for the induced expression by a theophylline riboswitch combined with a strong native promoter from B. subtilis but also provide the two pivotal features of SD essential to the modular design of other synthetic riboswitches.
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