以代谢高效防治螨、蚜虫等的米尔贝霉素的冰城链霉菌为研究对象。前期完成、发表了冰城链霉菌全基因组测序，并诱变选育获得两株高产米尔贝霉素、且米尔贝霉素A3、A4两个组分比例差异大的突变菌株。对这两株高产突变菌株进行了全基因组重测序，比较两株突变株与原始菌株，两株突变菌株之间全基因组序列的位点差异，并根据构建的冰城链霉菌初级代谢通路图，发现8个突变基因与米尔贝霉素生物合成所需前体的初级代谢相关，它们可能影响米尔贝霉素发酵单位产量和米尔贝霉素A3、A4生物合成的比例。本项目拟对这8个突变基因进行基因点突变，基因替换与回补，以及体内过表达重要影响初级代谢的乙酰辅酶A羧化酶和丙酰辅酶A合成酶。明确能提高米尔贝霉素发酵单位产量，和影响米尔贝霉素A3、A4生物合成比例的初级代谢关键酶基因。为冰城链霉菌代谢流的改造，及高产、单组分米尔霉素优良工程菌的构建奠定基础，为实际构建冰城链霉菌初级代谢通路图积累数据。

Milbemycins are possessed of extremely high activity against various insects, such as mites and aphis. Streptomyces bingchenggensis is a milbemycin producing strain with self-owned intellectual property rights. And its complete genome has been sequenced. Two mutant strains with high yield of milbemycins were obtained by physical and chemical mutagenesis technologies. A remarkable difference in constituent proportion of milbemycins A3 and A4 was observed between the two mutants. Then the genomes of the two mutants were re-sequenced and compared with that of the wild-type strain. Based on the speculative diagram of primary metabolic pathway, we found that eight genes with mutation were related to primary metabolism which was associated with the precursors of milbemycins. The mutation of these eight genes may influence the yield of milbemycins and the constituent proportion of milbemycins A3 and A4. We will study the eight genes thoroughly by site-directed mutagenesis, gene disruption and complementation, and over express two important primary metabolic enzymes, acetyl-coA carboxylase and propionyl coA synthetase in vivo to nail down the key primary metabolic genes which can affect the yield and constituent proportion of milbemycins A3 and A4. This study is aimed to pave a profound way for the change of metabolic fluxes and the construction of engineered strains with high-yield and unicomponent milbemycins, and to provide data for constructing the actual diagram of primary metabolic pathway.