Giuliana Franzosi

Lipid production for second generation biodiesel by the oleaginous yeast Rhodotorula graminis

The increasing cost of vegetable oils is turning the use of microbial lipids into a competitive alternative for the production of biodiesel fuel. The oleaginous yeast Rhodotorula graminis is able to use a broad range of carbon sources for lipid production, and is able to resist some of the inhibitors commonly released during hydrolysis of lignocellulosic materials. Using undetoxified corn stover hydrolysate as substrate, the yeast achieved a lipid productivity and lipid content of 0.21 g/L/h and 34%w/w, respectively. The corresponding results with crude glycerol as carbon source were 0.15 g/L/h and 54%w/w, respectively. Therefore, R. graminis appears to be a suitable candidate for fermentation processes involving renewable resources.

STEREOSELECTIVE MICROBIAL HYDROLYSIS OF 2-ARYLOXYPROPIONITRILES

Abstract2-Aryloxypropionic acids 3a–f, compounds with herbicidal activity, have been prepared with high enantiomeric purity by microbial hydrolysis of the corresponding racemic nitriles and amides in presence ofBrevibacteriumimperiale cells.

Characterization of lipid accumulation and lipidome analysis in the oleaginous yeasts Rhodosporidium azoricum and Trichosporon oleaginosus

The influence of cultural conditions on lipid production was investigated in two species, Trichosporon oleaginosus and Rhodosporidium azoricum. We showed that nitrogen limitation is not the main factor triggering the mechanism of lipid accumulation in T. oleaginosus. Moreover, a scarce availability of oxygen negatively affected lipid synthesis to a lesser extent in T. oleaginosus than in R. azoricum. This highlights how the importance of controlling fermentation parameters is strictly linked to the yeast species employed. We showed that these parameters affect the activity of important enzymes, influencing the metabolic fluxes into different pathways, in particular pentose phosphate pathway and cytoplasmic pyruvate bypass. Furthermore, T. oleaginosus exhibited wider substrate flexibility, faster growth and higher lipid accumulation in fed-batch cultivation. Microbial oils obtained from both yeasts proved a valuable feedstock, alternative to vegetable oils, for advanced diesel biofuel production.