Nucleotide-level characterization and improvement of l-arabinose- and l-rhamnose-inducible systems in E. coli using a high-throughput approach.

The commonly used arabinose- and rhamnose-inducible Escherichia coli promoters, PBAD and PRha, exhibit tight regulation through activation via their respective transcription factors, AraC and RhaS, alongside the cyclic AMP receptor protein. The mechanisms of these promoters have been characterized on a parts level, but nucleotide-level analysis has yet to be elucidated. Therefore, we describe here a massively parallel reporter assay that maps regulatory sites at the nucleotide level. The relative importance of nucleotides in each binding site is revealed, including loci not included in previous annotations. For PBAD, we confirm known sites and reveal novel binding sites involved in modulating gene expression. In PRha, we refine the length and sequence specificity of rhaI half-sites, updating previous annotations and providing nucleotide level insights into RhaS-mediated regulation. Mutations that lead to increased promoter strength, wider dynamic range, and altered basal expression are identified for both promoters. Engineered versions of PBAD and PRha promoters based on this data show improvements in dynamic range alongside a seven- and three-fold increase in promoter strength, respectively, with a slight increase in basal expression for the PBAD promoters and no significant increase for PRha. This work expands the genetic parts "toolkit" and increases the understanding of these important commonly used promoters.