Abstract
Hyaluronan is widely used in cosmetics and pharmaceutics. Development of robust and safe cell factories and cultivation approaches to efficiently produce hyaluronan is of many interests. Here, we describe the metabolic engineering of Corynebacterium glutamicum and application of a fermentation strategy to manufacture hyaluronan with different molecular weights. C. glutamicum is engineered by combinatorial overexpression of type I hyaluronan synthase, enzymes of intermediate metabolic pathways and attenuation of extracellular polysaccharide biosynthesis. The engineered strain produces 34.2 g L−1 hyaluronan in fed-batch cultures. We find secreted hyaluronan encapsulates C. glutamicum, changes its cell morphology and inhibits metabolism. Disruption of the encapsulation with leech hyaluronidase restores metabolism and leads to hyper hyaluronan productions of 74.1 g L−1. Meanwhile, the molecular weight of hyaluronan is also highly tunable. These results demonstrate combinatorial optimization of cell factories and the extracellular environment is efficacious and likely applicable for the production of other biopolymers.
Highlights
Hyaluronan is widely used in cosmetics and pharmaceutics
Hyaluronic acid (HA) synthases from P. multocida, S. pyogenes, S. uberis, and S. equi subsp. zooepidemicus HasA were selected and overexpressed individually in the host strain C. glutamicum ATCC 13032
We found that UDP-glucose 6-dehydrogenase (UgdA) from different species exhibited different abilities to promote HA biosynthesis (4.5 g L−1, Fig. 1c)
Summary
Hyaluronan is widely used in cosmetics and pharmaceutics. Development of robust and safe cell factories and cultivation approaches to efficiently produce hyaluronan is of many interests. We describe the metabolic engineering of Corynebacterium glutamicum and application of a fermentation strategy to manufacture hyaluronan with different molecular weights. C. glutamicum is engineered by combinatorial overexpression of type I hyaluronan synthase, enzymes of intermediate metabolic pathways and attenuation of extracellular polysaccharide biosynthesis. The molecular weight of hyaluronan is highly tunable These results demonstrate combinatorial optimization of cell factories and the extracellular environment is efficacious and likely applicable for the production of other biopolymers. It is a natural substance in vertebrates and mainly found in the eyes, joints and skin, where it absorbs large amounts of water for joint lubrication[1], cell coating or repair of damaged skin tissue[2]. Phosphate N-acetyltransferase) or blocking the synthesis of unwanted metabolites (e.g., L-lactate) were adopted to drive the generation of intermediate metabolites required for HA synthesis[29,30]
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