• Energy Research

We describe a procedure by which filter paper is digested with a cellulolytic enzyme preparation, obtained from Trichoderma reesei cultivated under solid state fermentation conditions and then fermented by a recombinant Saccharomyces cerevisiae strain. The yeast strain produces a β-glucosidase encoded by the BGL1 gene from Saccharomycopsis fibuligera that quantitatively and qualitatively complements the limitations that the Trichoderma enzyme complex shows for this particular activity. The supplemental β-glucosidase activity fuels the progression of cellulose hydrolysis and fermentation by decreasing the inhibitory effects caused by the accumulation of cellobiose and glucose. Fermentation of filter paper by this procedure yields ethanol concentrations above 70 g/L.

Constructs carrying the Saccharomycopsis fibuligera β-glucosidase gene (BGL1) under the control of a constitutive actin or a galactose-inducible promoter were introduced into eleven Saccharomyces strains. In ten of these recombinant strains, BGL1 expression driven by the actin promoter was between 1.6- and 18-fold higher than that obtained with the galactose-inducible promoter. Strains carrying the actin promoter yielded ethanol concentrations from cellobiose of between 0.5% and 14%, depending on their ability to accumulate Bgl1 (between 30 and 250 mU/mL) but also on their genetic background. Comparative analysis of a S. cerevisiae strain and its corresponding petite version showed similar ethanol yields, despite a 3-fold lower β-glucosidase production of the latter, suggesting that respiratory activity could be one of the factors influencing ethanol production when using carbon sources other than glucose. This study provides a selection of strains that may be good candidates as hosts for ethanol biosynthesis from cellulosic substrates.