A method for preparing a hyper-cellulolytic catabolite derepressed mutants of ascomycetes fungus, especially variants of Penicillium funiculosum. Selection media used to isolate such variants include amorphous cellulose and a high concentration of glucose. Cellulase activities of mutant ID-10, in particular such as FPase and β-glucosidase were 1.5 times higher than Penicillium funiculosum MRJ-16 (parent). Furthermore, fungal mutant morphology was changed and no pH adjustment was required throughout the enzyme production process.

A method for preparing a fermented drink is described. The method comprises the initiation of fermentation by inoculating the fermentable drink with fermentative bacteria in the form of biofilm.

A method for preparing a fermented drink is described. The method comprises the initiation of fermentation by inoculating the fermentable drink with fermentative bacteria in the form of biofilm.

The present invention provides isolated acidophilic Fusarium oxysporum strains, such as MK7, and their progeny, compositions comprising such strains and their progeny, methods of producing such strains and their progeny, and methods of using such strains and their progeny.

The present invention concerns novel Saccharomyces cerevisiae yeast strains capable of multiplying on a substrate comprising at least one C5 sugar with a speed and rate of multiplication compatible with the industrial production of yeast. It also concerns novel strains which, when cultured, make it possible to obtain yeasts having an application efficiency, i.e. an efficiency that is satisfactory in applications and uses of interest in industries such as breadmaking, biomass production, flavour production, the production of secondary metabolites, protein production, ethanol production, brewing, winemaking or the production of yeast extract.

The present invention concerns novel Saccharomyces cerevisiae yeast strains capable of multiplying on a substrate comprising at least one C5 sugar with a speed and rate of multiplication compatible with the industrial production of yeast. It also concerns novel strains which, when cultured, make it possible to obtain yeasts having an application efficiency, i.e. an efficiency that is satisfactory in applications and uses of interest in industries such as breadmaking, biomass production, flavour production, the production of secondary metabolites, protein production, ethanol production, brewing, winemaking or the production of yeast extract.

Methods and compositions relating to processing of plant material into bacterial feedstock, such as bacterial feedstock suitable for nanocellulose production, are disclosed. Cellulosic plant fiber may be contacted with a catalyst such as an acid catalyst or an enzymatic catalyst or both, and the mixture can be hydrolyzed into a hydrolysate. The hydrolysate may be used to form a culture medium which can be used to support bacterial growth to form the nanocellulose.

Methods and compositions relating to processing of plant material into bacterial feedstock, such as bacterial feedstock suitable for nanocellulose production, are disclosed. Cellulosic plant fiber may be contacted with a catalyst such as an acid catalyst or an enzymatic catalyst or both, and the mixture can be hydrolyzed into a hydrolysate. The hydrolysate may be used to form a culture medium which can be used to support bacterial growth to form the nanocellulose.

The present invention provides a growth method for a microbe which can enhance the growth of the microbe without removing growth inhibitors from a saccharified solution. The growth method for a microbe comprises the steps of: obtaining a mixed saccharified solution by diluting the saccharified solution containing a growth inhibitor which inhibits the growth of the microbe with a sugar solution having a smaller growth inhibitor concentration than that of the saccharified solution such that the growth inhibitor concentration is decreased; and allowing the microbe to grow by adding the microbe to the mixed saccharified solution.

The present invention provides a growth method for a microbe which can enhance the growth of the microbe without removing growth inhibitors from a saccharified solution. The growth method for a microbe comprises the steps of: obtaining a mixed saccharified solution by diluting the saccharified solution containing a growth inhibitor which inhibits the growth of the microbe with a sugar solution having a smaller growth inhibitor concentration than that of the saccharified solution such that the growth inhibitor concentration is decreased; and allowing the microbe to grow by adding the microbe to the mixed saccharified solution.