RESUMO
Valorization, the process whereby waste materials are converted into more valuable products, is rarely practiced in industrial fermentation. We developed a model valorization system whereby Saccharomyces cerevisiae that had previously been engineered to produce high concentrations (>100 g/L) of extracellular ß-farnesene was further engineered to simultaneously produce intracellular carotenoids, both products being isoprenoids. Thus, a single fermentation generates two valuable products, namely, ß-farnesene in the liquid phase and carotenoids in the solid biomass phase. Initial attempts to produce high levels of canthaxanthin (a ketocarotenoid used extensively in animal feed) in a ß-farnesene production strain negatively impacted both biomass growth and ß-farnesene production. A refined approach used a promoter titration strategy to reduce ß-carotene production to a level that had minimal impact on growth and ß-farnesene production in fed-batch fermentations and then engineered the resulting strain to produce canthaxanthin. Further optimization of canthaxanthin coproduction used a bioprospecting approach to identify ketolase enzymes that maximized conversion of ß-carotene to canthaxanthin. Finally, we demonstrated that ß-carotene is not present in the extracellular ß-farnesene at a significant concentration and that which is present can be removed by a simple distillation, indicating that ß-farnesene (the primary fermentation product) purity is unaffected by coproduction of carotenoids.
Assuntos
Carotenoides , beta Caroteno , Saccharomyces cerevisiae , Cantaxantina , BiomassaRESUMO
There are numerous potential applications for melanin-binding compounds, and new methods are of interest to identify melanin-binding agents. A portion of the polymerization to eumelanin, the black to brown pigment in humans, is thought to be supramolecular aggregation of nanoparticles derived from dihydroxyindoles. Starting with chloroquine, a known eumelanin-binding compound, the ability of small molecules to influence aggregation in synthetic eumelanin polymerizations was investigated. Twenty-eight compounds were tested, including pharmaceuticals, dyes, aromatics, and amines. Compounds that either accelerate or delay the appearance of macroscopic particles in synthetic eumelanin polymerizations were uncovered.