High-Level Biosynthesis of Chlorogenic Acid from Mixed Carbon Sources of Xylose and Glucose through a Rationally Refactored Pathway Network.

Chlorogenic acid (CGA) has incredible potential for various pharmaceutical, nutraceutical, and agricultural applications. However, the traditional extraction approach from plants is time-consuming, further limiting its production. Herein, we design and construct the de novo biosynthesis pathway of CGA using modular coculture engineering in Escherichia coli, which is composed of MG09 and BD07 strains. To accomplish this, the phenylalanine-deficient MG09 strain was engineered to utilize xylose preferentially and to overproduce precursor caffeic acid, while the tyrosine-deficient BD07 strain was constructed to consume glucose exclusively to enhance another precursor quinic acid availability for the biosynthesis of CGA. Further pathway modularization and balancing in the context of syntrophic cocultures resulted in additional production improvement. The coculture strategy avoids metabolic flux competition in the biosynthesis of two CGA precursors, caffeic acid and quinic acid, and allows for production improvement by balancing module proportions. Finally, the optimized coculture based on the aforementioned efforts produced 131.31 ± 7.89 mg/L CGA. Overall, the modular coculture engineering strategy in this study provides a reference for constructing microbial cell factories that can efficiently biomanufacture complex natural products.

Population genomics study of Vibrio alginolyticus.

Vibrio alginolyticus is a Gram-negative bacillus that causes vibriosis to human and aquatic products, including fish, shrimp and shellfish. It poses a threat to public health and causes enormous economic losses to the aquaculture industry. However, research on genetic diversity and pathogenicity-related genetic elements based on whole genome is still lacking. In this study, sixty-eight strains of V. alginolyticus were collected from four provinces of China and the whole genome sequences were obtained. Combined with 113 publicly available genome sequences downloaded from NCBI, we inferred the population structure of V. alginolyticus by using fineSTRUCTURE software, and identified the virulence and antibiotic resistance factors using the VFDB, CARD and ResFinder database. The results indicated that V. alginolyticus included two main lineages, named Lineage 1 and Lineage 2. Both lineages distributed in America and Asia, but all the European genomes were classified into Lineage 1. A single cross-ocean transmission event was inferred from one of the 12 identified clonal groups in our dataset. V. alginolyticus genome contains a variety of virulence factors, such as tlh, OmpU, and IlpA, etc. The distribution of virulence factors revealed no lineage-specificity, but some of which revealed differences in their geographical distribution. A lower frequency of VP1611, vcrD, vopD, fleR/flrC and a higher frequency of IlpA were observed in genomes of Europe than other continents. In China, a lower frequency of fleR/flrC, and no IlpA were observed in genomes from Guangxi province. Among the identified antibiotic resistance genes, TxR and fos are significantly enriched in Lineage 2. In addition, TxR is more common in genomes from Asia, compared with the American and European genomes. But in China, the frequency of TxR in Sichuan genomes is much lower than in other provinces. We also found that large fragments of plasmids or ICEs that carried multiple drug resistance genes were present in five V. alginolyticus genomes (VA24, VA28, 2014V-1011, ZJ-T and Vb1833). Based on population genomics analysis, our study delineated the population structure, distribution of virulence and antibiotic resistance related factors of V. alginolyticus, which lays a foundation for future study of genetic characters and pathogenesis mechanism of this pathogen and will improve the works on monitoring, prevention and control of this pathogen.