A biorefinery concept for the production of fuel ethanol, probiotic yeast and whey protein from a by-product of the cheese industry

1.AbstractAgroindustrial by-products and residues can be transformed into valuable compounds in biorefineries. Here we present a new concept: production of fuel ethanol, whey protein and probiotic yeast from cheese whey. An initial screening under industrially relevant conditions, involving thirty Kluyveromyces marxianus strains, was carried out using spot assays to evaluate their capacity to grow on cheese whey or on whey permeate (100 g lactose/L), under aerobic or anaerobic conditions, in the absence or presence of 5% ethanol, at pH 5.8 or pH 2.5. The four best growing K. marxianus strains were selected and further evaluated in a miniaturized industrial fermentation process using reconstituted whey permeate (100 g lactose/L) with cell recycling (involving sulfuric acid treatment). After five consecutive fermentation cycles, the ethanol yield on sugar reached 90% of the theoretical maximum in the best cases, with 90% cell viability. Cells harvested at this point displayed probiotic properties such as capacity to survive the passage through the gastrointestinal tract and capacity to modulate innate immune response of intestinal epithelium, both in vitro. Furthermore, the CIDCA 9121 strain was able to protect against histopathological damage in an animal model of acute colitis. Our findings demonstrate that K. marxianus CIDCA 9121 is capable of efficiently fermenting the lactose present in whey permeate to ethanol and that the remaining yeast biomass has probiotic properties, enabling an integrated process for the obtainment of whey protein, fuel ethanol and probiotics from cheese whey.2.ImportanceCheese whey is the liquid remaining following the precipitation and removal of milk casein during cheese-making. This by-product represents about 85-95% of the milk volume and retains 55% of milk nutrients so it can be exploited as a source of valuable end products. However, at a global level around 50% of cheese whey is wasted, representing an important environmental impact and indicating the need to develop alternative processes to recover value. Kluyveromyces marxianus is capable of fermenting lactose, generally regarded as safe, and has been explored separately as an ethanol producer and as a viable bioactive microorganism. The significance of our research is to establish the proof of concept that a biorefinery for fuel ethanol production using whey and K. marxianus can also be exploited to obtain viable probiotic biomass, conferring an added value to the process and providing an alternative to reduce environmental impact.