BACKGROUND: Oritavancin is a new generation of semi-synthetic glycopeptide antibiotics against Gram-positive bacteria, which served as the first and only antibiotic with a single-dose therapeutic regimen to treat ABSSSI. A naturally occurring glycopeptide A82846B is the direct precursor of oritavancin. However, its application has been hampered by low yields and homologous impurities. This study established a multi-step combinatorial strategy to rationally construct a high-quality and high-efficiency biosynthesis system for A82846B and systematically optimize its fermentation process to break through the bottleneck of microbial fermentation production.
RESULTS: Firstly, based on the genome sequencing and analysis, we deleted putative competitive pathways and constructed a better A82846B-producing strain with a cleaner metabolic background, increasing A82846B production from 92 to 174 mg/L. Subsequently, the PhiC31 integrase system was introduced based on the CRISPR-Cas12a system. Then, the fermentation level of A82846B was improved to 226 mg/L by over-expressing the pathway-specific regulator StrR via the constructed PhiC31 system. Furthermore, overexpressing glycosyl-synthesis gene evaE enhanced the production to 332 mg/L due to the great conversion of the intermediate to target product. Finally, the scale-up production of A82846B reached 725 mg/L in a 15 L fermenter under fermentation optimization, which is the highest reported yield of A82846B without the generation of homologous impurities.
CONCLUSIONS: Under approaches including blocking competitive pathways, inserting site-specific recombination system, overexpressing regulator, overexpressing glycosyl-synthesis gene and optimizing fermentation process, a multi-step combinatorial strategy for the high-level production of A82846B was developed, constructing a high-producing strain AO-6. The combinatorial strategies employed here can be widely applied to improve the fermentation level of other microbial secondary metabolites, providing a reference for constructing an efficient microbial cell factory for high-value natural products.

Chondroitin sulfate (CS) is a linear polysaccharide, which is widely used in medical, health care and other fields. Compared with the traditional animal tissue extraction method, microbial synthesis of CS has the advantages of controllability and easiness of scaling-up. In order to achieve an efficient synthesis of chondroitin sulfate A (CSA), we constructed a recombinant Pichia pastoris GS115 strain capable of synthesizing chondroitin (Ch) from glycerol by introducing the Ch synthase coding genes kfoC, kfoA and UDP-glucose dehydrogenase coding gene tuaD into the P. pastoris chromosome. The titer of Ch reached 2.6 g/L in fed-batch cultures upon optimizing the synthesis pathway of Ch. After further expressing the chondroitin-4-O-sulfotransferase (C4ST), we developed a one-pot biosynthesis system for CSA production by directly adding 3\'-adenosine-5\'-phosphoryl sulfate and C4ST into the high-pressure homogenized recombinant P. pastoris cells. Eventually, controllable synthesis of 0-40% CSA with different sulfation degrees were achieved by optimizing the catalytic conditions. The one-pot biosynthesis system constructed here is easy to operate and easy to scale up for industrial production of CSA. The idea of the present study may also facilitate the biosynthesis of other glycosaminoglycan, for instance, heparin.