Poly D-lactic acid is an important

Poly D-lactic acid is an important polymer because it improves the thermostability of poly L-lactic acid by stereo
complex formation. To demonstrate potency of continuous fermentation using a membrane-integrated fermentation
reactor (MFR) system, continuous fermentation using genetically modified Saccharomyces cerevisiae which produces Dlactic
acid was performed at the low pH and microaerobic conditions. D-Lactic acid continuous fermentation using the
MFR system by genetically modified yeast increased production rate by 11-fold compared with batch fermentation. In
addition, the carbon yield of D-lactic acid in continuous fermentation was improved to 74.6 ± 2.3% compared to
39.0 ± 1.7% with batch fermentation. This dramatic improvement in carbon yield could not be explained by a reduction
in carbon consumption to form cells compared to batch fermentation. Further detailed analysis at batch fermentation
revealed that the carbon yield increased to 76.8% at late stationary phase. S. cerevisiae, which exhibits the Crabtreepositive
effect, demonstrated significant changes in metabolic activities at low sugar concentrations (Rossignol et al.,
Yeast, 20, 1369e1385, 2003). Moreover, lactate-producing S. cerevisiae requires ATP supplied not only from the glycolytic
pathway but also from the TCA cycle (van Maris et al., Appl. Environ. Microbiol., 70, 2898e2905, 2004). Our finding was
revealed that continuous fermentation, which can maintain the conditions of both a low sugar concentration and air
supply, results in Crabtree-positive and lactate-producing S. cerevisiae for suitable conditions of D-lactic acid production
with respect to redox balance and ATP generation because of releasing the yeast from the Crabtree effect.