Construction and characterization of nitrate and nitrite respiring Pseudomonas putida KT2440 strains for anoxic biotechnical applications.

Pseudomonas putida KT2440 is frequently used in biotechnical research and applications due to its metabolic versatility and organic solvent resistance. A major drawback for a broad application is the inability of the bacterium to survive and grow under anoxic conditions, which prohibits the production of oxygen-sensitive proteins and metabolites. To develop a P. putida strain, which is able to survive under anoxic conditions, the enzymatic systems of anaerobic nitrate and nitrite respiration were introduced into KT2440. For this purpose, two cosmids encoding all structural, maturation and regulatory genes for P. aeruginosa nitrate reductase (pNAR) and nitrite- and nitric oxide reductase (pNIR-NOR) were stably maintained in P. putida KT2440. Transcriptome analyses revealed expression of the encoded nar, nir and nor operons and accessory genes under anoxic conditions. The produced enzyme systems efficiently reduced nitrate or nitrite, respectively, sustaining anaerobic life of recombinant KT2440. Interestingly, anaerobic life of P. putida induced genes involved in arginine-fermentation and genes encoding a putative copper stress resistance operon.

Integrated organic-aqueous biocatalysis and product recovery for quinaldine hydroxylation catalyzed by living recombinant Pseudomonas putida.

In an earlier study, biocatalytic carbon oxyfunctionalization with water serving as oxygen donor, e.g., the bioconversion of quinaldine to 4-hydroxyquinaldine, was successfully achieved using resting cells of recombinant Pseudomonas putida, containing the molybdenum-enzyme quinaldine 4-oxidase, in a two-liquid phase (2LP) system (Ütkür et al. J Ind Microbiol Biotechnol 38:1067-1077, 2011). In the study reported here, key parameters determining process performance were investigated and an efficient and easy method for product recovery was established. The performance of the whole-cell biocatalyst was shown not to be limited by the availability of the inducer benzoate (also serving as growth substrate) during the growth of recombinant P. putida cells. Furthermore, catalyst performance during 2LP biotransformations was not limited by the availability of glucose, the energy source to maintain metabolic activity in resting cells, and molecular oxygen, a possible final electron acceptor during quinaldine oxidation. The product and the organic solvent (1-dodecanol) were identified as the most critical factors affecting biocatalyst performance, to a large extent on the enzyme level (inhibition), whereas substrate effects were negligible. However, none of the 13 alternative solvents tested surpassed 1-dodecanol in terms of toxicity, substrate/product solubility, and partitioning. The use of supercritical carbon dioxide for phase separation and an easy and efficient liquid-liquid extraction step enabled 4-hydroxyquinaldine to be isolated at a purity of >99.9% with recoveries of 57 and 84%, respectively. This study constitutes the first proof of concept on an integrated process for the oxyfunctionalization of toxic substrates with a water-incorporating hydroxylase.

Regioselective aromatic hydroxylation of quinaldine by water using quinaldine 4-oxidase in recombinant Pseudomonas putida.

Biocatalytic hydrocarbon oxyfunctionalizations are typically accomplished using oxygenases in living bacteria as biocatalysts. These processes are often limited by either oxygen mass transfer, cofactor regeneration, and/or enzyme instabilities due to the formation of reactive oxygen species. Here, we discuss an alternative approach based on molybdenum (Mo)-containing dehydrogenases, which produce, rather than consume, reducing equivalents in the course of substrate hydroxylation and use water as the oxygen donor. Mo-containing dehydrogenases have a high potential for overcoming limitations encountered with oxygenases. In order to evaluate the suitability and efficiency of a Mo-containing dehydrogenase-based biocatalyst, we investigated quinaldine 4-oxidase (Qox)-containing Pseudomonas strains and the conversion of quinaldine to 4-hydroxyquinaldine. Host strain and carbon source selection proved to be crucial factors influencing biocatalyst efficiency. Resting P. putida KT2440 (pKP1) cells, grown on and induced with benzoate, showed the highest Qox activity and were used for process development. To circumvent substrate and product toxicity/inhibition, a two-liquid phase approach was chosen. Without active aeration and with 1-dodecanol as organic carrier solvent a productivity of 0.4 g l (tot) (-1) h(-1) was achieved, leading to the accumulation of 2.1 g l (tot) (-1) 4-hydroxyquinaldine in 6 h. The process efficiency compares well with values reported for academic and industrially applied biocatalytic oxyfunctionalization processes emphasizing the potential and feasibility of the Qox-containing recombinant cells for heteroaromatic carbon oxyfunctionalizations without the necessity for active aeration.