Enabling growth-decoupled recombinant protein production based on the methanol-free P promoter.

The current transition towards the circular bioeconomy requires a rational development of biorefineries to sustainably fulfill the present demands. The use of () can meet this challenge, since it has the capability to use crude glycerol as a carbon-source, a by-product from the biodiesel industry, while producing high- and low-added value products. Recombinant protein production (RPP) using has often been driven either by the methanol induced promoter (P ) and/or the constitutive promoter (P ). In the last years, strong efforts have been focused on developing novel expression systems that expand the toolbox variety of to efficiently produce diverse proteins that requires different strategies. In this work, a study was conducted towards the development of methanol-free expression system based on a heat-shock gene promoter (P) using glycerol as sole carbon source. Using this promoter, the recombinant expression is strongly induced in carbon-starving conditions. The classical P was used as a benchmark, taking for both strains the lipase B from (CalB) as model protein. Titer of CalB expressed under P outperformed P controlled expression in shake-flask cultivations when using a slow-release continuous feeding technology, confirming that P is induced under pseudo-starving conditions. This increase was also confirmed in fed-batch cultivations. Several optimization rounds were carried out for P under different feeding and osmolarity conditions. In all of them the P controlled process outperformed the P one in regard to CalB titer. The best P approach reached 3.6-fold more specific productivity than P fed-batch at low μ. Compared to the optimum approach for P -based process, the best P fed-batch strategy resulted in 2.3-fold higher titer, while the specific productivity was very similar. To summarize, P is an inducible promoter that exhibited a non-coupled growth regulation showing high performance, which provides a methanol-free additional solution to the usual growth-coupled systems for RPP. Thus, this novel system emerges as a potential alternative for RPP bioprocess and for revaluing crude glycerol, promoting the transition towards a circular economy.