文献类型：期刊文献

中文题名：化学诱导对一株海洋来源土曲霉C23-3次生代谢产物及其生物活性的影响

英文题名：Influence of chemical induction on the secondary metabolites and biological activities of a marine-derived fungal strain Aspergillus terreus C23-3

作者：杨静明[1];杨文聪[1];刘亚月[1];聂影影[1];雷晓凌[1];张翼[1,2]

机构：[1]广东海洋大学食品科技学院广东省水产品加工与安全重点实验室广东省海洋食品工程技术研究中心水产品深加工广东普通高等学校重点实验室湛江市脑健康海洋药物与营养品重点实验室广东海洋大学海洋药物研究所,广东湛江524088;[2]广东海洋大学深圳研究院,广东深圳518120

年份：2019

卷号：46

期号：3

起止页码：441

中文期刊名：微生物学通报

外文期刊名：Microbiology China

收录：CSTPCD、、北大核心2017、CSCD2019_2020、北大核心、CSCD

基金：广东省扬帆计划引进紧缺拔尖人才项目(201433009);广东省自然科学基金(2018A030307046);广东海洋大学科研启动项目(E15155);广东海洋大学优秀教学团队(校人事[2017]18号);深圳市科创委基础研究自由探索项目(JCYJ20170306165013264);食品微生物学课程群广东省省级优秀教学团队(粤教高函[2015]133号)~~

语种：中文

中文关键词：海洋真菌;化学诱导;丁内酯;抗氧化;抑制乙酰胆碱酯酶

外文关键词：Marine fungi;Chemical induction;Butyrolactones;Antioxidant;Anti-acetylcholinesterase

中文摘要：【背景】海洋微生物是药理活性先导化合物的重要源泉,而化学诱导是深入挖掘其次生代谢潜力的一种便捷手段。【目的】以一株海洋来源土曲霉C23-3为出发菌株,筛选出可促进其产生更丰富代谢产物(包括丁内酯类化合物)的发酵条件,进一步开发菌株在抗阿尔茨海默症方面的潜力。【方法】分别选用海水马铃薯培养基、麦芽浸膏培养基、大米培养基和大豆培养基4种基础培养基,利用丁酸钠、辛二酰苯胺异羟肟酸(Suberoylanilidehydroxamicacid,SAHA)、5-氮杂胞嘧啶核苷(5-azacytidine,5-azaC)、盐酸普鲁卡因(Procaine hydrochloride)、ZnCl_2和CuCl_2共6种化学诱导剂对土曲霉C23-3进行微量的诱导培养。观察该菌菌丝体形态变化,并根据薄层层析(Thin-layerchromatography,TLC)指纹图谱、化学显色及生物活性自显影结果初筛出代谢产物丰富且乙酰胆碱酯酶抑制活性与抗氧化活性产物丰富的诱导条件,并进行进一步常量发酵。采用上述手段及高效液相色谱-二极管阵列检测器(High performance liquid chromatography-Diode array detector,HPLC-DAD)分析常量发酵代谢产物的总体多样性及丁内酯类化合物的多样性。【结果】发现CuCl_2、ZnCl_2、SAHA和5-azaC可引起土曲霉C23-3菌丝体生长形态显著变化,海水马铃薯培养基+100μmol/L丁酸钠等6种诱导条件在微量培养初筛及常量发酵复筛中均可使该菌株产生多样化的活性代谢产物,其丁内酯类代谢产物也具有一定差异性。【结论】化学诱导手段可促使土曲霉C23-3产生丰富且新颖的活性代谢产物,为多样化的抗阿尔茨海默症天然产物的发现奠定了基础。

外文摘要：[Background] Marine microorganisms are important source of pharmaceutical active leading compounds and chemical induction can be used as a convenient approach to mine their secondary metabolic potential. [Objective] Based on a marine-derived fungus Aspergillus terreus C23-3, this study aimed to optimize fermentation conditions for more abundant metabolites(including butyrolactones), and exploit the potential of the strains in drugs targeting Alzheimer’s disease. [Methods] The strain was first cultivated on micro-scale, by taking four basic cultures mediums including seawater potato medium, malt extract medium, rice medium and soybean medium, and adopting six chemical inducers including sodium butyrate, suberoylanilide hydroxamic acid(SAHA), 5-azacytidine(5-azaC), procaine hydrochloride, ZnCl2 and CuCl2. The morphological variation of the mycelia was observed. Then, based on the thin layer chromatography(TLC) fingerprints, chemical coloration and bioautography results, inducing conditions with rich new metabolites and rich anti-acetylcholinesterase and antioxidant products were initially screened out for further routine-scale fermentation. Using the above methods and high-performance liquid chromatography-diode array detector(HPLC-DAD) analysis, the diversity of the total metabolites and of butyrolactones was analyzed for the routine fermentation. [Results] The results indicated that CuCl2,ZnCl2, SAHA and 5-azaC caused remarkable changes in the growth morphology of Aspergillus terreus C23-3 mycelium. Six chemical inducing conditions, e.g. seawater potato medium plus 100 μmol/L sodium butyrate, led to diverse bioactive metabolites both in micro-scale cultivation and routine-scale fermentation. Furthermore, its butyrolactone metabolites also displayed difference under different conditions. [Conclusion] Chemical induction approaches can prompt the Aspergillus terreus C23-3 to produce rich bioactive substances, laying foundation for the discovery of diverse anti-Alzheimer’s disease natural products.