Creation of an orthogonal and universal auto-inducible gene expression platform by reprogramming a two-component signal circuit for efficient production of industrial enzymes.

Bacterial gene expression systems play a crucial role in producing valuable biological macromolecules, such as recombinant proteins and polysaccharides. However, traditional inducible gene systems have limitations that need costly chemical inducers that can harm the host. To address these challenges, a novel peptide-activated auto-inducible gene expression system was developed in Bacillus subtilis, leveraging Accessory gene regulatory system (Agr), a two-component signal system, from Staphylococcus aureus to trigger gene expression in response to an auto-inducible peptide (AIP).

Data-Driven and -Assisted Design of Broad Host-Range Minimal Intrinsic Terminators Adapted for Bacteria.

Efficient transcription termination relying on intrinsic terminators is critical to maintain cell fitness by avoiding unwanted read-through in bacteria. Natural intrinsic terminator (NIT) typically appears in mRNA as a hairpin followed by approximately eight conserved uridines (U-tract) at the 3' terminus. Owing to their simple structure, small size, and protein independence, assorted NITs have been redesigned as robust tools to construct gene circuits.