Recombineering Pseudomonas protegens CHA0: An innovative approach that improves nitrogen fixation with impressive bactericidal potency.

Pseudomonas protegens CHA0 is a well-characterized, root-colonizing bacterium with broad-spectrum biocontrol ability. Therefore, it has a great potential to curb plant diseases and to partly replace synthetic chemical pesticides that are harmful to humans. Here, we obtained the multifunctional mutant CHA0-ΔretS-Nif via Red/ET recombineering technology. After deletion of the retS gene and integration of the nitrogen-fixing gene island (Nif) into the CHA0 genome, the resulting mutant, CHA0-ΔretS-Nif, manifested improved both bactericidal activity and biological nitrogen-fixation function. A pot experiment of Arabidopsis thaliana indicated that the strain CHA0-ΔretS-Nif promoted plant growth via expressing several secondary factors, such as the antibiotic 2,4-diacetylphloroglucinol (2,4-DAPG) and nitrogenase. In order to grow this biocontrol strain at an industrial level, the growth conditions in a 1 L continuous-flow fermenter were optimized to 28 °C, pH of 7.0, and 600 rpm. Moreover, growth experiments in a 5 L fermenter with these optimal growth conditions yielded the maximum cell density, providing vital insights for the industrialization and large-scale fermentation of P. protegens CHA0 for further applications. CHA0-ΔretS-Nif possesses both bactericidal and nitrogen-fixation activities and thus could be used as a biological agent to enhance crop production.

Yield improvement of epothilones in Burkholderia strain DSM7029 via transporter engineering.

Transporter engineering has been shown to be a positive approach for enhancing natural product titers in microbial cell factories by expelling target compounds out of feasible hosts. In this work, two multidrug efflux pumps, Orf14 and Orf3, were modulated in the epothilone production strain Burkholderia DSM7029::Tn5-km-epo (named G32) via Red/ET engineering to increase heterologous polyketide epothilone yields. Compared with the prior G32 strain, the total production of several epothilones in the G32::orf14-orf3 mutant was meaningfully doubled according to high-performance liquid chromatography-mass spectrometer analysis. Typically for epothilone B, in simple and clear liquid medium CYMG, the overall productivity in the engineered high-yield producer G32::orf14-orf3 was improved for almost 3-fold, from 2.7 to about 8.1 µg/l. Additionally, the ratio of extracellular to intracellular accumulation of epothilone B was raised from 9.3:1 to 13.7:1 in response to expression of two putative transport genes orf14 and orf3. Hence, we strongly recommend that the Orf14 and Orf3 transporters export epothilone, thus promotes the forward reaction of biosynthesis on epothilone manufacture inside the cells. Our results afford a practical stage for yield improvement of other heterologous natural products in broad chassis cells.