Biosynthesis of Heliotropin by a Novel Strain of Serratia liquefaciens

Trametes hirsuta as an Attractive Biocatalyst for the Preparative Scale Biotransformation of Isosafrole into Piperonal

Piperonal is a compound of key industrial importance due to its attractive olfactory and biological properties. It has been shown that among the fifty-six various fungal strains tested, the ability to cleave the toxic isosafrole into piperonal through alkene cleavage is mainly found in strains of the genus Trametes. Further studies involving strains isolated directly from different environments (decaying wood, fungal fruiting bodies, and healthy plant tissues) allowed the selection of two Trametes strains, T. hirsuta Th2_2 and T. hirsuta d28, as the most effective biocatalysts for the oxidation of isosafrole. The preparative scale of biotransformation with these strains provided 124 mg (conv. 82%, isolated yield 62%) and 101 mg (conv. 69%, isolated yield 50.5%) of piperonal, respectively. Due to the toxic impact of isosafrole on cells, preparative scale processes with Trametes strains have not yet been successfully performed and described in the literature.

Chemo-enzymatic oxidative cleavage of isosafrole for the synthesis of piperonal

Piperonal is a key feedstock for the fine chemical industry. A novel process for its production from isosafrole is described, based on lipase-mediated perhydrolysis in flow, followed by batch alkaline treatment and by MnO2 oxidation in flow.

Game animals as a reservoir of rarely recorded opportunistic bacteria

In Poland, the population of game animals, including wild boars, roe and deer, is constantly increasing. The tonsils of wild game animals are a place of large variety of microorganisms. The pathogenic bacteria present in them, such as E. coli, Y. enterocolitica and Salmonella sp. are the most common source of meat infection. The opportunistic bacteria R. aquatilis, P. fluorescens, S. liquefaciens, S. fonticola and S. plymuthica also play an important role in public health. S. liquefaciens may be an opportunistic pathogen and in people causes sepsis and inflammation of the cornea. The protease, nuclease, phospholipase A, flagella, elastase and toxins haemolysin and proteolysin are responsible for its ability to cause disease symptoms. S. plymuthica, a rod commonly found in the environment, produces a red dye. It is most often isolated from soil, water and food. In humans, it causes infections of burn wounds, soft leg tissue as well as post-operative wounds and bacteraemia. Typically, the environmental rod S. fonticola differs from other Serratia sp. by the lack of extracellular enzymes. It causes wound infections and bacteraemia resulting from urinary tract infections. Bacteria from the genus Serratia sp. show a natural resistance to glycopeptides, rifampicin and erythromycin. The aquatic rod R. aquatilis in humans causes opportunistic infections of the urinary tract, wounds, bacteraemia and endocarditis. It exhibits natural resistance to antibiotics from the group of cephalosporins, penicillins and macrolides and quinolones. It is conditioned by the presence of class 1 integrons and class A β-lactamases. The virulence factors of R. aquatilis are also LPS and adhesin. P. fluorescens in humans is responsible for bacteraemia. It also exhibits resistance to human serum thanks to outer membrane proteins and has T3SS, which effectively infects the host.

Highly Efficient Biosynthesis of Heliotropin by Engineered Escherichia coli Coexpressing Trans-Anethole Oxygenase and Formate Dehydrogenase

Heliotropin, a compound with important roles in the spice and fragrance industries and broad application prospects, is mainly produced through chemical methods. Here, we established a novel process for the synthesis of heliotropin by Escherichia coli whole cells through biotransformation of isosafrole. Directed evolution and high-throughput screening based on 2,4-dinitrophenylhydrazine were used to improve the activity of trans-anethole oxygenase toward isosafrole, and a mutant (TAO_3G2) was obtained that had a high ability to oxidize isosafrole. Formate dehydrogenase (FDH) and TAO_3G2 were coexpressed in E. coli, significantly increasing the catalytic efficiency by regenerating more NADH to promote isosafrole oxidation. Furthermore, after optimizing the molar ratio of isosafrole to the auxiliary substrate, the final concentration of heliotropin was increased from 9.15 to 19.45 g/L, and the maximum yield and space-time yield reached 96.02% and 3.89 g/L/h, respectively. These results suggest that the biosynthesis of heliotropin should have excellent industrial application value.