ISOLATION AND FUNCTIONAL ANALYSIS OF McMenA,A GENE ENCODING A 1,4‐DIHYDROXY‐2‐NAPHTHOATE OCTAPRENYLTRANSFERASE IN Mylabris cichorii

Cantharidin is a biomolecule with a role in host defense that can also be used as an anticancer drug. The in vivo biosynthetic pathway for cantharidin has been the subject of debate for several decades and the mechanism is not yet completely understood. To study the biosynthetic pathway of cantharidin in blister beetles, Mylabris cichori, a full‐length MenA (McMenA) cDNA was cloned based on the partial sequence of the MenA gene from a suppression subtractive hybridization (SSH) library of male and female adult M. cichorii. The cDNA was 1264 base pairs (bp) with an open reading frame of 1026 bp nucleotides encoding a 341 amino acid protein. Analysis of the McMenA amino acid sequence showed that the aspartate rich motif N/DDxxD represented binding sites for prenyl diphosphate via a Mg²⁺ ion. Phylogenetic analysis showed that McMenA was most closely related to MenA of Tribolium castaneum, and the amino acid sequence similarity was 86%. The expression pattern of McMenA in adults was analyzed using RT‐qPCR, and we found that the highest expression of McMenA occurred during 22–25 days in the sex‐separate breeding males, while the lowest expression occurred in females at the same time. Injection with a specific double‐strand RNA (dsRNA) of McMenA led to a significant reduction of McMenA mRNA levels after 24 h. Cantharidin and ATP concentrations dropped around the same time. Together, our data showed that the McMenA gene might be involved in cantharidin biosynthesis.     

芫菁体内斑蟊素的合成、 转移和生物学功能

斑蟊素是芫菁科昆虫合成的一种防御物质, 已经被证实对多种癌症和其他疾病有着特殊的疗效。芫菁体内存在不同结合态的斑蟊素或斑蟊素衍生物, 包括斑蟊素酸镁、斑蟊素酸钙、羟基斑蟊素、甲基斑蟊胺和脱甲斑蟊素等。不同芫菁种类、不同发育阶段其斑蝥素合成量有显著的差异, 并且有着典型的性二型现象, 性成熟的雄成虫斑蝥素含量最高可达10%。关于斑蝥素的生物合成途径以及斑蝥素在虫体内的分布, 尽管有一些研究, 但仍然没有定论。本文从斑蟊素在芫菁体内的含量、分布、生物合成、代谢及生物学功能等方面对国内外的研究进行概括, 以期为充分发掘芫菁科昆虫资源、指导芫菁的人工养殖、合理的利用资源以及人工合成斑蟊素提供参考。     

DNA assembler,an in vivo genetic method for rapid construction of biochemical pathways

The assembly of large recombinant DNA encoding a whole biochemical pathway or genome represents a significant challenge. Here, we report a new method, DNA assembler, which allows the assembly of an entire biochemical pathway in a single step via in vivo homologous recombination in Saccharomyces cerevisiae. We show that DNA assembler can rapidly assemble a functional d-xylose utilization pathway (∼9 kb DNA consisting of three genes), a functional zeaxanthin biosynthesis pathway (∼11 kb DNA consisting of five genes) and a functional combined d-xylose utilization and zeaxanthin biosynthesis pathway (∼19 kb consisting of eight genes) with high efficiencies (70–100%) either on a plasmid or on a yeast chromosome. As this new method only requires simple DNA preparation and one-step yeast transformation, it represents a powerful tool in the construction of biochemical pathways for synthetic biology, metabolic engineering and functional genomics studies.