posted on 2018-08-09, 00:00authored byJingjing Liu, Jianghua Li, Yanfeng Liu, Hyun-dong Shin, Rodrigo Ledesma-Amaro, Guocheng Du, Jian Chen, Long Liu
l-Malate is an important platform chemical that has extensive
applications in the food, feed, and wine industries. Here, we synergistically
engineered the carbon metabolism and redox metabolism in the cytosol
and mitochondria of a previously engineered Aspergillus oryzae to further improve the l-malate titer and decrease the
byproduct succinate concentration. First, the accumulation of the
intermediate pyruvate was eliminated by overexpressing a pyruvate
carboxylase from Rhizopus oryzae in the cytosol and
mitochondria of A. oryzae, and consequently,
the l-malate titer increased 7.5%. Then, malate synthesis via glyoxylate bypass in the mitochondria was enhanced,
and citrate synthase in the oxidative TCA cycle was downregulated
by RNAi, enhancing the l-malate titer by 10.7%. Next, the
exchange of byproducts (succinate and fumarate) between the cytosol
and mitochondria was regulated by the expression of a dicarboxylate
carrier Sfc1p from Saccharomyces cerevisiae in the
mitochondria, which increased l-malate titer 3.5% and decreased
succinate concentration 36.8%. Finally, an NADH oxidase from Lactococcus lactis was overexpressed to decrease the NADH/NAD+ ratio, and the engineered A. oryzae strain produced 117.2 g/L l-malate and 3.8 g/L succinate,
with an l-malate yield of 0.9 g/g corn starch and a productivity
of 1.17 g/L/h. Our results showed that synergistic engineering of
the carbon and redox metabolisms in the cytosol and mitochondria of A. oryzae effectively increased the l-malate
titer, while simultaneously decreasing the concentration of the byproduct
succinate. The strategies used in our work may be useful for the metabolic
engineering of fungi to produce other industrially important chemicals.