BACKGROUND

The development of biorefinery systems that use lignocellulosic biomass as a renewable carbon source to produce fuels and chemicals is attracting increasing attention. The process cost of enzymatic saccharification of biomass is a major challenge for commercialization. To decrease this cost, researchers have proposed on-site solid-state fermentation (SSF). This study investigated the feasibility of using as a host microorganism for SSF recombinant enzyme production with ammonia-treated rice straw as model biomass. Eight strains were tested, all of which are used in the food industry. We evaluated the effects of acetic acid, a fermentation inhibitor. We also developed a platform strain for targeted recombinant enzyme production by gene engineering technologies.

RESULTS

The SSF validation test showed variation in the visibility of mycelium growth and secreted protein in all eight strains. The strains used to produce and grew better under test conditions. The ammonia-treated rice straw contained noticeable amounts of acetic acid. This acetic acid enhanced the protein production by in a liquid-state fermentation test. The newly developed platform strain successfully secreted three foreign saccharifying enzymes.

CONCLUSIONS

is a promising candidate as a host microorganism for on-site SSF recombinant enzyme production, which bodes well for the future development of a more cost-efficient saccharifying enzyme production system.