Another possibility could be that each dimer interacts more efficiently with RNAP, but one might then predict that the maximum level of expression from Pm would also be increased compared
to wild type XylS. The behavior of XylS in the absence of inducer (m-toluate) can be explained by the same model (Figure 6g-i). DNA Damage inhibitor Dimerization of the regulator is strongly stimulated in the presence of inducer, but a certain low fraction of XylS dimerizes also in the absence of inducer. However, much higher total concentrations of the regulator are required before the maximum dimer concentration is reached. As a consequence aggregation will also start at much higher XylS expression levels. If this model holds true it leads to an interesting
prediction that if one could mutagenize xylS, such that its protein product could form higher SN-38 mw concentrations of active dimers (less aggregate formation), expression from Pm could be further stimulated. A screening for such variants should probably be done under conditions of excessive amounts of XylS present in the cells, to make sure that the desired phenotype is actually detected. StEP-13 was identified while expressed from Ps2 (and thus at low levels), and other types of variants may then dominate Epigenetics inhibitor the screening outcome. Even though XylS is known to be produced at low levels from its natural Ps2 promoter [5] these small amounts are sufficient for successful applications of Pm in recombinant protein production [24, 25]. The results reported here indicate that expression can be further stimulated by increasing the intracellular concentration of XylS, and by fine-tuning this level and expressing XylS in trans the induction ratio can also be maximized. As shown here this allowed for high expression levels while maintaining an induction ratio of 700-fold, which exceeds the reported
induction ratios both reached by 5′-UTR variations [29] and by regulation of XylS expression by a promoter Mirabegron which is activated by the same inducer as Pm[31]. In earlier studies a linear correlation between the copy number of plasmids that carry the complete XylS/Pm system and expression levels from Pm has been observed [23–25]. It is common to assume that this well known effect is caused by increased dosage of the gene to be expressed, but for a given XylS/Pm-based system the results presented here indicate that it is the increased amounts of XylS that lead to more expression from Pm. Fortunately the performance of the XylS/Pm system is not limited exclusively by concentrations of XylS dimers, since expression from Pm can be drastically stimulated by using combinations of various types of mutations in the expression cassette [28].