Enhanced production of reducing sugars from transgenic rice expressing exo-glucanase under the control of a senescence-inducible promoter.

We generated transgenic rice plants that express EXG1 exo-glucanase under the control of a senescence-inducible promoter. When a GUS coding sequence was connected to a promoter region of STAY GREEN (SGR) gene of rice and introduced into rice, GUS activity was specifically observed along with senescence. When an EXG1 cDNA was connected to the SGR promoter and introduced into rice, higher cellulase activities were detected after senescence. The EXG1 transgenic plants showed enhanced enzymatic saccharification efficiencies after senescence, but no significant difference of saccharification efficiencies was observed before senescence. The saccharification efficiencies were correlated with the cellulase activities in the transgenic plants. The EXG1 transgenic plants showed neither morphological abnormality nor sterility, both of which were observed when EXG1 was constitutively overexpressed. These results indicate that expression of cell wall degrading enzymes such as cellulase by a senescence-inducible promoter is one of the ways to enhance the saccharification ability of cellulosic biomass without affecting plant growth for efficient production of biofuels.

Application of fungal laccase fused with cellulose-binding domain to develop low-lignin rice plants.

We observed a reduction of lignin content linked to the expression of fungal laccase in rice plants. The lignin content of L-4, which showed the highest LAC activity among transgenic lines produced, was lower than that of the control line. However, this change was not reflected to the saccharification efficiency.

Enhanced saccharification of rice straw by overexpression of rice exo-glucanase.

BACKGROUND: Efficient production of carbon-neutral biofuels is key to resolving global warming and exhaustion of fossil fuels. Cellulose, which is the most abundant biomass, is physically strong and biochemically stable, and these characteristics lead to difficulty of efficient saccharification of cellulosic compounds for production of fermentable glucose and other sugars. RESULTS: We transformed rice with overexpressing constructs of rice genes encoding each of three classes of cellulases. The exo-glucanase overexpressing plants showed various abnormalities in leaf such as division of leaf blade, crack on leaf surface, excess lacunae in midrib structure and necrotic colour change. The overexpressing plants also showed sterility. Noticeably, these plants showed enhanced saccharification of stems after maturation. These results indicate that overexpression of the exo-glucanase gene brought about various developmental defects associated with modification of cell wall and enhanced saccharification in rice. On the other hand, endo-glucanase-overexpressing plants could not be obtained, and overexpression of ß-glucosidase brought about no effect on plant growth and development. CONCLUSIONS: Our results indicate that genetic engineering of cellulosic biomass plants by overexpressing cellulase genes will be one of the approaches to confer enhanced saccharification ability for efficient production of cellulosic biofuels such as ethanol.