Production of oil replacements such

Production of oil replacements such as ethanol for biofuel and
lactic acid for polylactate, a constituent of biodegradable plastic,
from renewable resources has been the subject of interest worldwide
to prevent global warming and to reduce greenhouse gas
emissions (1,2). Lignocellulosic biomass, such as wheat straw and
corn stover, is composed of cellulose, hemicellulose, and lignin as
the main components and is considered one of the preferred raw
materials for producing an oil replacement as it contains large
amounts of fermentable sugars in the form of glucose and xylose
(3). For practical use, it is necessary to degrade these into
fermentable sugars so as to convert them into target material
efficiently. In particular, xylose, which is a kind of pentose, is
difficult to ferment compared to hexoses such as glucose, and the
development of an efficient conversion method for xylose is
therefore necessary (2,3).
The fungus Rhizopus oryzae is known to produce optically pure
L (þ)-lactic acid from glucose (1,4). The fungus also has amylolytic
ability and can produce lactic acid from starchy by-products such as
potato pulp (5,6). Furthermore, it can produce optically pure L (þ)-
lactic acid from xylose (7), and various studies have investigated its
ability to produce lactic acid from lignocellulosic biomass such as
wheat straw (8), corn stover (9,10), and also paper waste (11,12).
Although production of lactic acid from biomass has also been
conducted by using lactic acid bacteria, the cost of media for their
growth tends to be higher than those of other microorganisms
because of their nutritional requirement, and the product often
becomes the racemic mixture of lactic acid. In contrast, R. oryzae
could produce optically pure lactic acid in chemically defined
medium, which saves the cost, simplifies product purification, and
is preferred to polylactate production (1). Therefore, R. oryzae is
considered a promising species for the effective use of