By combining cellulase production,

By combining cellulase production, cellulose hydrolysis, and sugar fermentation into a single step, consolidated
bioprocessing (CBP) represents a promising technology for biofuel production. Here we report engineering
of Saccharomyces cerevisiae strains displaying a series of uni-, bi-, and trifunctional minicellulosomes.
These minicellulosomes consist of (i) a miniscaffoldin containing a cellulose-binding domain and three cohesin
modules, which was tethered to the cell surface through the yeast a-agglutinin adhesion receptor, and (ii) up
to three types of cellulases, an endoglucanase, a cellobiohydrolase, and a
-glucosidase, each bearing a
C-terminal dockerin. Cell surface assembly of the minicellulosomes was dependent on expression of the
miniscaffoldin, indicating that formation of the complex was dictated by the high-affinity interactions between
cohesins and dockerins. Compared to the unifunctional and bifunctional minicellulosomes, the quaternary
trifunctional complexes showed enhanced enzyme-enzyme synergy and enzyme proximity synergy. More importantly,
surface display of the trifunctional minicellulosomes gave yeast cells the ability to simultaneously
break down and ferment phosphoric acid-swollen cellulose to ethanol with a titer of
1.8 g/liter. To our
knowledge, this is the first report of a recombinant yeast strain capable of producing cell-associated trifunctional
minicellulosomes. The strain reported here represents a useful engineering platform for developing
CBP-enabling microorganisms and elucidating principles of cellulosome construction and mode of action.