Cloning and functional verification of PhAEP gene, a key enzyme for biosynthesis of heterophyllin A in Pseudostellaria heterophylla / 中国中药杂志

This paper aimed to study the role of asparagine endopeptidase(AEP) gene in the biosynthesis mechanism of cyclic peptide compounds in Pseudostellaria heterophylla. The transcriptome database of P. heterophylla was systematically mined and screened, and an AEP gene, tentatively named PhAEP, was successfully cloned. The heterologous function verification by Nicotiana benthamiana showed that the expression of the gene played a role in the biosynthesis of heterophyllin A in P. heterophylla. Bioinformatics analysis showed that the cDNA of PhAEP was 1 488 bp in length, encoding 495 amino acids with a molecular weight of 54.72 kDa. The phylogenetic tree showed that the amino acid sequence encoded by PhAEP was highly similar to that of Butelase-1 in Clitoria ternatea, reaching 80%. The sequence homology and cyclase active site analysis revealed that the PhAEP enzyme may specifically hydrolyse the C-terminal Asn/Asp(Asx) site of the core peptide in the HA linear precursor peptide of P. heterophylla, thereby participating in the ring formation of the linear precursor peptide. The results of real-time quantitative polymerase chain reaction(RT-qPCR) showed that the expression level of PhAEP was the highest in fruits, followed by in roots, and the lowest in leaves. The heterophyllin A of P. heterophylla was detected in N. benthamiana that co-expressed PrePhHA and PhAEP genes instantaneously. In this study, the PhAEP gene, a key enzyme in the biosynthesis of heterophyllin A in P. heterophylla, has been successfully cloned, which lays a foundation for further analysis of the molecular mechanism of PhAEP enzyme in the biosynthesis of heterophyllin A in P. heterophylla and has important significance for the study of synthetic biology of cyclic peptide compounds in P. heterophylla.

Cloning, structure analysis and functional verification of MYB10 in Ribes L / 生物工程学报

This study aims to investigate the molecular mechanism of the transcription factor MYB10, which is involved in anthocyanin biosynthesis, in different colors of Ribes L. fruitification. Rapid amplification of cDNA ends (RACE) was used to clone the MYB10 genes from Ribes nigrum L. (RnMYB10), Ribes rubrum L. (RrMYB10), and Ribes album L. (RaMYB10), respectively. Phylogenetic analysis showed that RnMYB10 and RrMYB10 were evolutionarily homologous. Real-time quantitative PCR (RT-qPCR) showed that the expression of MYB10 in the fruits of Ribes nigrum L. was higher than that of Ribes rubrum L. and much higher than that of Ribes album L. The expression of RnMYB10 and RrMYB10 increased at first and then decreased as the fruit diameter increased and the fruit color deepened (the maximum expression level was reached at 75% of the fruit color change), while the expression level of RaMYB10 was very low. Overexpression of RnMYB10 and RrMYB10 in Arabidopsis thaliana resulted in purple petioles and leaves, whereas overexpression of RaMYB10 resulted in no significant color changes. This indicates that MYB10 gene plays an important role in the coloration of Ribes L. fruit.

Functional identification of plant secondary metabolite biosynthesis gene in Saccharomyces cerevisiae by cell feeding / 中草药

Objective: To screen the most efficient cell feeding way and provide guidance for functional verification of genes in Saccharomyces cerevisiae. Methods: Firstly, the recombinant industrial S. cerevisiae strains containing PsCPR and PsP6H genes were constructed. Then four different cell feeding methods were used. At the end, the downstream product dihydrosanguinarine was detected via UPLC Q-TOF MS/MS. Results: The best method of cell feeding was that the recombinant industrial strain induced by galactose for 31 h and then incubated in the TE solution buffer (pH = 8.0) for 24 h. Conclusion: Different cell feeding ways have different effects on the downstream products of recombinant industrial S. cerevisiae. The optimized cell feeding method shows stability and good repeatability.