海洋放线菌M058菌株抗生素的合成条件和提取方法研究
|
摘要
用双层琼脂扩散法检测海洋放线菌M023、M056、M058、M066、M220、M230的抗菌谱,部分菌株具有一定抑菌活性,其中M058对金黄色葡萄球菌(革兰氏阳性球菌)、假单胞菌有较强的抑菌作用,对大肠杆菌(革兰氏阴性细菌)、白色念珠菌(酵母状真菌)也有抑制作用,而对铜绿假单胞菌抑制作用相对较弱,以对金黄色葡萄球菌的抑菌活性尤为明显,是一株具有广谱抗菌活性的菌株,因此对M058进行了进一步的研究。
通过观察菌丝形态、孢子形状、在不同培养基上的培养特征及明胶液化、淀粉水解、纤维素上生长情况、H2S的产生、碳源利用一系列生理生化特征,按照《链霉菌鉴定手册》将M058菌株初步归类为链霉菌属金色类群,类似菌:金色链霉菌Streptomyces aureus。
为提高抗生素产量,对M058的液体培养基成分进行了优化。通过杯碟法检测发酵液中抗生素的含量, 筛选出最佳碳源为可溶性淀粉, 最佳氮源为硝酸钾, 通过改变碳、氮比及进行碳、氮源及磷酸盐的正交实验,获得碳源、氮源及磷酸盐配比为:可溶性淀粉1%,KNO30.15%,K2HPO40.075%。
发酵工艺条件的研究结果表明最适初始pH为7.0~7.5,最适温度为25℃,最适接种量为10%,250ml的三角瓶装入50 ml为最佳装液量。在优化后的培养基和最佳发酵条件下,36~48小时抗生素的分泌量达到最高峰,为获得大量抗生素,采取工艺放大,进行罐发酵,在发酵液中抗生素活性达到高峰时结束发酵,放罐。
将发酵液除菌体后进行浓缩、采用乙酸乙酯分级萃取、活性炭吸附除盐,丙酮溶液洗脱的方法获得酯溶性抗生素粗品A和水溶性抗生素粗品B,经检测粗品A和B均对金黄色葡萄球菌均有抑制作用,同时通过GF254高效硅胶板检测出A、B所含组分,选用200-300目硅胶柱,通过柱层析的方法使粗品A和B各个组分得到了初步分离,探索了抗生素粗品A、B的初步纯化方法,获得抗生素粗品A、B的部分理化性质,为进一步纯化奠定基础。
Antimicrobial activity of marine antinomycetes M023、M056、M058、M066、M220、M230 strains were studied by method of double layers agar and the results showed some strains had an antimicrobial activities. Strain M058 had strong activity against Staphylococcus aureus(Gram-positive bacteria) and Pseudomonas, also had activity against Escherichia coli(Gram-negative bacteria) and Candida albicans(fugal), and had low activity against Pseudomonas aeruginosa , Marine antinomycete M058 was a strain of yielding broad-spectrum antibiotic, so strain M058 was studied further.
The morphology of mycelium and spores in Gause’s syntetic No1 media, growth situation and physiol-biochemical characteristics in different media were observed. According to Identification Manual of Streptomyces, strain M058 was identified to be Aureus group of genus Streptomyces, and similar to Streptomyces aureus.
For increasing production of antibiotic, the liquid media composition were studied. Antibiotic content of the fermented liquid was determined by cylinde-plate method, the screening result indicated that the optimal carbon source was soluble starch, and the optimal nitrogen source was KNO3. By changing the ratio of carbon source and nitrogen source , and orthogonal tests of carbon, nitrogen and phosphate , the optimal proportion of these component was obtained and percentage of these component was soluble starch 1%, KNO3 0.15%, K2HPO4 0.075%.
The suitable technical parameters in fermentation were: initial pH 7.0~7.5, 25℃, 10% inoculum, loading liquid volume 50 ml(in 250ml flask). On the conditions of the optimal media and the suitable fermentation condition, the antibiotic yield of strain M058 reached maximum in 36~48 hours. Fermentation process of strain M058 in 20L fermenter was designed to yield more antibiotic for further study, and fermented liquid was determined by cylinde-plate method ,and stopped fermenting when the antibiotic yield of strain M058 reached maximum.
The fermented liquid was filtrated, the filtrate was concentrated. The concentrated product was extracted by ethyl acetate, then the concentrated product was adsorbed by active carbon, and the active carbon was eluted by acetone solution. Oil-soluble antibiotic A and water-soluble antibiotic B were gained. Both oil-soluble antibiotic A and water-soluble antibiotic B had activity against Staphylococcus aureus. Components of A and B were determined by silica GF254( HPTLC). Components of A and B were purified
primarily by 200~300 sizes silica. Method of purifying oil-soluble antibiotic A and water-soluble antibiotic B were studied primarily. Part physico-chemical properties of A and B were found, which were bases for purifying of A and B further.
通过观察菌丝形态、孢子形状、在不同培养基上的培养特征及明胶液化、淀粉水解、纤维素上生长情况、H2S的产生、碳源利用一系列生理生化特征,按照《链霉菌鉴定手册》将M058菌株初步归类为链霉菌属金色类群,类似菌:金色链霉菌Streptomyces aureus。
为提高抗生素产量,对M058的液体培养基成分进行了优化。通过杯碟法检测发酵液中抗生素的含量, 筛选出最佳碳源为可溶性淀粉, 最佳氮源为硝酸钾, 通过改变碳、氮比及进行碳、氮源及磷酸盐的正交实验,获得碳源、氮源及磷酸盐配比为:可溶性淀粉1%,KNO30.15%,K2HPO40.075%。
发酵工艺条件的研究结果表明最适初始pH为7.0~7.5,最适温度为25℃,最适接种量为10%,250ml的三角瓶装入50 ml为最佳装液量。在优化后的培养基和最佳发酵条件下,36~48小时抗生素的分泌量达到最高峰,为获得大量抗生素,采取工艺放大,进行罐发酵,在发酵液中抗生素活性达到高峰时结束发酵,放罐。
将发酵液除菌体后进行浓缩、采用乙酸乙酯分级萃取、活性炭吸附除盐,丙酮溶液洗脱的方法获得酯溶性抗生素粗品A和水溶性抗生素粗品B,经检测粗品A和B均对金黄色葡萄球菌均有抑制作用,同时通过GF254高效硅胶板检测出A、B所含组分,选用200-300目硅胶柱,通过柱层析的方法使粗品A和B各个组分得到了初步分离,探索了抗生素粗品A、B的初步纯化方法,获得抗生素粗品A、B的部分理化性质,为进一步纯化奠定基础。
Antimicrobial activity of marine antinomycetes M023、M056、M058、M066、M220、M230 strains were studied by method of double layers agar and the results showed some strains had an antimicrobial activities. Strain M058 had strong activity against Staphylococcus aureus(Gram-positive bacteria) and Pseudomonas, also had activity against Escherichia coli(Gram-negative bacteria) and Candida albicans(fugal), and had low activity against Pseudomonas aeruginosa , Marine antinomycete M058 was a strain of yielding broad-spectrum antibiotic, so strain M058 was studied further.
The morphology of mycelium and spores in Gause’s syntetic No1 media, growth situation and physiol-biochemical characteristics in different media were observed. According to Identification Manual of Streptomyces, strain M058 was identified to be Aureus group of genus Streptomyces, and similar to Streptomyces aureus.
For increasing production of antibiotic, the liquid media composition were studied. Antibiotic content of the fermented liquid was determined by cylinde-plate method, the screening result indicated that the optimal carbon source was soluble starch, and the optimal nitrogen source was KNO3. By changing the ratio of carbon source and nitrogen source , and orthogonal tests of carbon, nitrogen and phosphate , the optimal proportion of these component was obtained and percentage of these component was soluble starch 1%, KNO3 0.15%, K2HPO4 0.075%.
The suitable technical parameters in fermentation were: initial pH 7.0~7.5, 25℃, 10% inoculum, loading liquid volume 50 ml(in 250ml flask). On the conditions of the optimal media and the suitable fermentation condition, the antibiotic yield of strain M058 reached maximum in 36~48 hours. Fermentation process of strain M058 in 20L fermenter was designed to yield more antibiotic for further study, and fermented liquid was determined by cylinde-plate method ,and stopped fermenting when the antibiotic yield of strain M058 reached maximum.
The fermented liquid was filtrated, the filtrate was concentrated. The concentrated product was extracted by ethyl acetate, then the concentrated product was adsorbed by active carbon, and the active carbon was eluted by acetone solution. Oil-soluble antibiotic A and water-soluble antibiotic B were gained. Both oil-soluble antibiotic A and water-soluble antibiotic B had activity against Staphylococcus aureus. Components of A and B were determined by silica GF254( HPTLC). Components of A and B were purified
primarily by 200~300 sizes silica. Method of purifying oil-soluble antibiotic A and water-soluble antibiotic B were studied primarily. Part physico-chemical properties of A and B were found, which were bases for purifying of A and B further.
引文
[1] 陈代杰编著, 微生物药物学, 华东理工大学出版社, 1999,37~52
[2] Okami Y. Marine microorganisms as a source of bioactive agents [J]. Microb Ecol, 1986,12:65~78
[3] 刘志鸿, 海洋生物活性物质的研究概况, 中国水产科学, 1999,6(4):99~103
[4] Okami Y and K Hotta, Search and discovery of new antibiotics, In: Goodfellow M, Williams S T,et al ed. Actinomycetes in biotechnology. San Diego: Academic Press Inc,1988,33~67
[5] 林永成主编, 海洋微生物及其代谢产物, 化学工业出版社,2003,169~219
[6] Davidson, B.S. 1995. “New dimensions in natural products research: Cultured marine microorganisms.” Curr.Opin.Biotechnol. 6:284~291
[7] Fenical, W. 1993. “Marine bacteria: Developing a new chemical resource.” Chem. Rev. 93:1673~1683
[8] Okami, Y. J. 1993. “The search for bioactive metabolites from marine bacteria.” Mar. Biotechnol. 1: 59~65
[9] Pathirana, C., P.R . Jensen, and W. Fenical. 1992. “Marinone and debromomarinone, antiobiotic sesquiterpenoid naphthoquinones of a new structure class from a marine bacterium.” Tetrahedron Lett. 33: 7663~7666
[10] Trischman, J. A., P. R. Jensen, W. Fenical. 1994a. “Halobacillin, a cytotoxic cyclic acylpeptide of the iturin class produced by a marine bacillus.” Tetrahedron Lett. 35:5571~5574
[11] Trischman, J. A.,D.M. Tapiolas, P.R. Jensen, R. Dwight, T.C. McKee, C.M. Ireland, T.J. Stout, J.Clardy. 1994b. “Salinzmides A and B: Anti-inflammatory depsipeptides from a marine streptomycete.” J. Am. Chem. Soc. 116: 757~758
[12] Belofsky, G. N., P.R. Jensen, M.K. Renner, and W. Fenical. 1998. “New cytotoxic sesquiterpenoid nitrobenzoyl esters from a marine isolate of the fungus Aspergillus versicolor.” Tetrhedron. 54:1715~1724
[13] Cheng, X.C., M. Varoglu, L. Abrell, P. Crews, et. al. 1994. “Chloriolins A-C, chlorinated sesquiterpenes produced by fungal cultures separated from a Jaspis marine sponge.” J. Org. Chem.59:6344
[14] Kakeya, H., I. Takehashi, G. Okasa, K. Isono, et. al. 1995. “Epolactaene, a novel neuritogic compound human neuroblastoma cells, produced by a marine fungus.” J.Aantibiot. 48:733~735
[15] Numata, A., C. Takahashi, T. Matsushita, T. Miyamoto, K. Kawai, Y. Usami, E. Matsumura, M. Inoue, H. Ohishi, and T. Shingu. 1992. “Fumiquinazolines, novel metabolites of a fungus
isolated from a saltfish.” Tetrahedron Lett. 33:1621~1624
[16] Takahashi, C., Y. Takai, Y. Kimura, A. Numata, N. Shigemastu, and H. Tanaka. 1995. “Cytotoxic metabolites from a fungal adherent of a marine alga.” Phytochemistry 38:155~158
[17] Yayanos, A.A. 1995. “Microbiology to 10,500 metres in the deep sea.” Annu. Rev. Microbiol. 49:777~805
[18] 李利君等, 海洋微生物生物活性物质的研究, 集美大学学报(自然科学版), 2000,5(2):80~86
[19] Okami Y, 海洋微生物产生的生物活性产物, 应用微生物学, 1988,6:44~46
[20] Takahashi C. et al. Halichomycin, a new class of potent cytotoxic macrolide produced by an actinomycete from a marine fish. Tetrahedron Lett, 1994,35(28):5013~5014.
[21] Kala P. R. Microbial production of antibiotics from mangrove ecosystem. CMFRJ Special Publication:Cochin, 1995, 61: 117~122
[22] Fenical, W. and Jensen P. R.(1993) In: Marine Biotechnology, V(1): pharmaceutical and bioactive natural products pp. 419~457, (eds) David . Attaway and Oskar R. Zaborskt, Plenum press, New York
[23] 黄耀坚等, 厦门海区潮间带的游动放线菌及其抗菌活性, 海洋通报, 1999,18(3):30~34
[24] 周美英,郑志成, 海洋放线菌S-216菌株鉴定及其抗真菌抗生素合成条件研究, 厦门大学学报(自然科学版), 1997,36(6):109~114
[25] 郑志成,周美英, 海洋链霉菌产生的抗生素S-111-9的研究, 厦门大学学报(自然科学版), 1993,32(5):647~652
[26] 周世宁等, 从海洋沉积物分离的产抗菌素和环肽的放线菌, 中山大学学报(自然科学版), 1997,36(6):127~128
[27] 郑忠辉等, 厦门海区潮间带海洋动植物共附生微生物的抗菌活性, 台湾海峡, 1998,17(4):439~444
[28] 李影林主编, 培养基手册, 吉林科学技术出版社 , 1991
[29] 中国科学院微生物研究所放线菌分类组编著, 链霉菌鉴定手册,科学出版社, 1975
[30] 罗文新,陈晓佳等, 来自海洋的链霉菌抑菌活性与其培养条件的关系, 微生物学通报, 1998,25(6):325~328
[31] Gauthier M.J, Shewan J M, Gibson D M et al Gener Microbiol, 1975,87(1):211~218
[32] 安徽农业大学生物工程系微生物教研室, 普通微生物学实验指导, 2000
[33] 邵振和编, 实验数据分析, 上海科学技术文献出版社, 1994
[34] 汪世山,陈守文,喻子牛. 吸水链霉菌井冈霉素发酵中氮源及碳氮比的优选.华中农业大学学报,2001,20(6):554~556
[35] 彭海萍,王兰,曹健等,培养基成分对泰乐菌素产量的影响. 粮食与饲料工业,2002(4):26~28
[36] 熊宗贵主编, 发酵工艺原理, 中国医药科技出版社,2000
[37] 张和春,王武. 天蓝色链霉菌产色素的摇瓶发酵优化.食品与发酵工业.1999,25(5):23~27
[38]孟庆芳,张汀等. 拮抗链霉菌S23发酵条件的研究.中国生物防治,2002,18(2):79~82
[39] 张修军,文世香. 链霉菌融合子SR-7产生抗细菌新活性物质的适宜条件. 湖北农学院学报,2000,20(2):164~165
[40] 黄威译,生长、产物形成和发酵技术,269~272
[41] 曹延弼,宋中枢,胡振英. 盐霉素发酵工艺的研究.1998(5):3~5
[42] 范代娣,陈斌等, 红霉素发酵工艺优化研究, 生物工程学报, 1999,15(1):104~108
[43] 范秀容,沈萍编, 微生物学实验, 高等教育出版社, 1980
[44] 徐积恩,朱明珍编, 抗生素, 科学出版社, 1982,151~163
[45] 徐宝梁,李瑾,马颖, 有关杯碟法测定壮观霉素灵敏度的影响研究, 微生物学通报, 1997,24(6):372~375
[46] 陈执中,张叔良编著, 抗生素检定法, 人民卫生出版社, 1959
[47] 方金瑞等,海洋耐、嗜碱放线菌产生的抗生素的研究Ⅰ抗菌物质2B-B,中国海洋药物。1993,45(1):3~5
[48] 黄钟奇,周世宁等. 南海海洋细菌110的代谢产物的研究. 中山大学学报(自然科学版),1997,36(6):129~130
[49] 吴倩,金莲舫等.链霉菌335发酵液中活性成分的分离和结构测定.中国抗生素杂志,1998,23(3):175~220
[50] 肖春玲,张月琴等.放线菌G0041-3菌株的初步分类、发酵及产物的提取和分离.中国抗生素杂志,1996,21(5):321~324
[51]《抗菌素生物理化性质》编写组编, 抗菌素生物理化性质(第二分册), 人民卫生出版社, 1981
[52] 何丽一编著, 平面色谱方法及应用, 化学工业出版社,2000
[53] 顾觉奋,魏爱琳, 大孔网状吸附剂在微生物制药分离纯化上的应用, 离子交换与吸附, 2002,18(3):281~288
[54] 毛忠贵主编, 生物工程下游技术, 中国轻工业出版社, 1999
[55] 顾觉奋主编, 抗生素, 上海科学技术出版社,2001
[56] 周世宁等, 海洋微生物的生物活性物质研究, 海洋药物, 1997,32(3):26~29
[57] 徐怀恕等, 海洋微生物技术, 青岛海洋大学学报, 1998,28(4):573~581
[58] 方金瑞,黄维真, 日本从海洋微生物开发新型生物活性物质研究的新进展, 中国海洋药
物, 1995,14(4):21~25
[59] 李越中,陈琦, 海洋微生物资源及其产生生物活性代谢产物的研究, 生物工程进展, 2000,20(5):28~31
[60] 第四次全国抗生素学术会议论文集(上、下), 上海科学技术文献出版社, 1985
[61] 丁爱云,郑继法等, 拮抗菌R31菌株种的鉴定, 山东农业大学学报, 1998,29(3):387~390
[62] 阮继生, 刘志恒等编著, 放线菌研究及应用, 科学出版社, 1990
[63] 阮继生编著, 放线菌分类基础, 科学出版社, 1977
[64] 姜成林等著, 放线菌分类学, 云南大学出版社, 1995
[65] 阎逊初编著, 放线菌的分类和鉴定, 科学出版社, 1992
[66] 郭勇主编, 生物制药技术, 中国轻工业出版社,2000
[2] Okami Y. Marine microorganisms as a source of bioactive agents [J]. Microb Ecol, 1986,12:65~78
[3] 刘志鸿, 海洋生物活性物质的研究概况, 中国水产科学, 1999,6(4):99~103
[4] Okami Y and K Hotta, Search and discovery of new antibiotics, In: Goodfellow M, Williams S T,et al ed. Actinomycetes in biotechnology. San Diego: Academic Press Inc,1988,33~67
[5] 林永成主编, 海洋微生物及其代谢产物, 化学工业出版社,2003,169~219
[6] Davidson, B.S. 1995. “New dimensions in natural products research: Cultured marine microorganisms.” Curr.Opin.Biotechnol. 6:284~291
[7] Fenical, W. 1993. “Marine bacteria: Developing a new chemical resource.” Chem. Rev. 93:1673~1683
[8] Okami, Y. J. 1993. “The search for bioactive metabolites from marine bacteria.” Mar. Biotechnol. 1: 59~65
[9] Pathirana, C., P.R . Jensen, and W. Fenical. 1992. “Marinone and debromomarinone, antiobiotic sesquiterpenoid naphthoquinones of a new structure class from a marine bacterium.” Tetrahedron Lett. 33: 7663~7666
[10] Trischman, J. A., P. R. Jensen, W. Fenical. 1994a. “Halobacillin, a cytotoxic cyclic acylpeptide of the iturin class produced by a marine bacillus.” Tetrahedron Lett. 35:5571~5574
[11] Trischman, J. A.,D.M. Tapiolas, P.R. Jensen, R. Dwight, T.C. McKee, C.M. Ireland, T.J. Stout, J.Clardy. 1994b. “Salinzmides A and B: Anti-inflammatory depsipeptides from a marine streptomycete.” J. Am. Chem. Soc. 116: 757~758
[12] Belofsky, G. N., P.R. Jensen, M.K. Renner, and W. Fenical. 1998. “New cytotoxic sesquiterpenoid nitrobenzoyl esters from a marine isolate of the fungus Aspergillus versicolor.” Tetrhedron. 54:1715~1724
[13] Cheng, X.C., M. Varoglu, L. Abrell, P. Crews, et. al. 1994. “Chloriolins A-C, chlorinated sesquiterpenes produced by fungal cultures separated from a Jaspis marine sponge.” J. Org. Chem.59:6344
[14] Kakeya, H., I. Takehashi, G. Okasa, K. Isono, et. al. 1995. “Epolactaene, a novel neuritogic compound human neuroblastoma cells, produced by a marine fungus.” J.Aantibiot. 48:733~735
[15] Numata, A., C. Takahashi, T. Matsushita, T. Miyamoto, K. Kawai, Y. Usami, E. Matsumura, M. Inoue, H. Ohishi, and T. Shingu. 1992. “Fumiquinazolines, novel metabolites of a fungus
isolated from a saltfish.” Tetrahedron Lett. 33:1621~1624
[16] Takahashi, C., Y. Takai, Y. Kimura, A. Numata, N. Shigemastu, and H. Tanaka. 1995. “Cytotoxic metabolites from a fungal adherent of a marine alga.” Phytochemistry 38:155~158
[17] Yayanos, A.A. 1995. “Microbiology to 10,500 metres in the deep sea.” Annu. Rev. Microbiol. 49:777~805
[18] 李利君等, 海洋微生物生物活性物质的研究, 集美大学学报(自然科学版), 2000,5(2):80~86
[19] Okami Y, 海洋微生物产生的生物活性产物, 应用微生物学, 1988,6:44~46
[20] Takahashi C. et al. Halichomycin, a new class of potent cytotoxic macrolide produced by an actinomycete from a marine fish. Tetrahedron Lett, 1994,35(28):5013~5014.
[21] Kala P. R. Microbial production of antibiotics from mangrove ecosystem. CMFRJ Special Publication:Cochin, 1995, 61: 117~122
[22] Fenical, W. and Jensen P. R.(1993) In: Marine Biotechnology, V(1): pharmaceutical and bioactive natural products pp. 419~457, (eds) David . Attaway and Oskar R. Zaborskt, Plenum press, New York
[23] 黄耀坚等, 厦门海区潮间带的游动放线菌及其抗菌活性, 海洋通报, 1999,18(3):30~34
[24] 周美英,郑志成, 海洋放线菌S-216菌株鉴定及其抗真菌抗生素合成条件研究, 厦门大学学报(自然科学版), 1997,36(6):109~114
[25] 郑志成,周美英, 海洋链霉菌产生的抗生素S-111-9的研究, 厦门大学学报(自然科学版), 1993,32(5):647~652
[26] 周世宁等, 从海洋沉积物分离的产抗菌素和环肽的放线菌, 中山大学学报(自然科学版), 1997,36(6):127~128
[27] 郑忠辉等, 厦门海区潮间带海洋动植物共附生微生物的抗菌活性, 台湾海峡, 1998,17(4):439~444
[28] 李影林主编, 培养基手册, 吉林科学技术出版社 , 1991
[29] 中国科学院微生物研究所放线菌分类组编著, 链霉菌鉴定手册,科学出版社, 1975
[30] 罗文新,陈晓佳等, 来自海洋的链霉菌抑菌活性与其培养条件的关系, 微生物学通报, 1998,25(6):325~328
[31] Gauthier M.J, Shewan J M, Gibson D M et al Gener Microbiol, 1975,87(1):211~218
[32] 安徽农业大学生物工程系微生物教研室, 普通微生物学实验指导, 2000
[33] 邵振和编, 实验数据分析, 上海科学技术文献出版社, 1994
[34] 汪世山,陈守文,喻子牛. 吸水链霉菌井冈霉素发酵中氮源及碳氮比的优选.华中农业大学学报,2001,20(6):554~556
[35] 彭海萍,王兰,曹健等,培养基成分对泰乐菌素产量的影响. 粮食与饲料工业,2002(4):26~28
[36] 熊宗贵主编, 发酵工艺原理, 中国医药科技出版社,2000
[37] 张和春,王武. 天蓝色链霉菌产色素的摇瓶发酵优化.食品与发酵工业.1999,25(5):23~27
[38]孟庆芳,张汀等. 拮抗链霉菌S23发酵条件的研究.中国生物防治,2002,18(2):79~82
[39] 张修军,文世香. 链霉菌融合子SR-7产生抗细菌新活性物质的适宜条件. 湖北农学院学报,2000,20(2):164~165
[40] 黄威译,生长、产物形成和发酵技术,269~272
[41] 曹延弼,宋中枢,胡振英. 盐霉素发酵工艺的研究.1998(5):3~5
[42] 范代娣,陈斌等, 红霉素发酵工艺优化研究, 生物工程学报, 1999,15(1):104~108
[43] 范秀容,沈萍编, 微生物学实验, 高等教育出版社, 1980
[44] 徐积恩,朱明珍编, 抗生素, 科学出版社, 1982,151~163
[45] 徐宝梁,李瑾,马颖, 有关杯碟法测定壮观霉素灵敏度的影响研究, 微生物学通报, 1997,24(6):372~375
[46] 陈执中,张叔良编著, 抗生素检定法, 人民卫生出版社, 1959
[47] 方金瑞等,海洋耐、嗜碱放线菌产生的抗生素的研究Ⅰ抗菌物质2B-B,中国海洋药物。1993,45(1):3~5
[48] 黄钟奇,周世宁等. 南海海洋细菌110的代谢产物的研究. 中山大学学报(自然科学版),1997,36(6):129~130
[49] 吴倩,金莲舫等.链霉菌335发酵液中活性成分的分离和结构测定.中国抗生素杂志,1998,23(3):175~220
[50] 肖春玲,张月琴等.放线菌G0041-3菌株的初步分类、发酵及产物的提取和分离.中国抗生素杂志,1996,21(5):321~324
[51]《抗菌素生物理化性质》编写组编, 抗菌素生物理化性质(第二分册), 人民卫生出版社, 1981
[52] 何丽一编著, 平面色谱方法及应用, 化学工业出版社,2000
[53] 顾觉奋,魏爱琳, 大孔网状吸附剂在微生物制药分离纯化上的应用, 离子交换与吸附, 2002,18(3):281~288
[54] 毛忠贵主编, 生物工程下游技术, 中国轻工业出版社, 1999
[55] 顾觉奋主编, 抗生素, 上海科学技术出版社,2001
[56] 周世宁等, 海洋微生物的生物活性物质研究, 海洋药物, 1997,32(3):26~29
[57] 徐怀恕等, 海洋微生物技术, 青岛海洋大学学报, 1998,28(4):573~581
[58] 方金瑞,黄维真, 日本从海洋微生物开发新型生物活性物质研究的新进展, 中国海洋药
物, 1995,14(4):21~25
[59] 李越中,陈琦, 海洋微生物资源及其产生生物活性代谢产物的研究, 生物工程进展, 2000,20(5):28~31
[60] 第四次全国抗生素学术会议论文集(上、下), 上海科学技术文献出版社, 1985
[61] 丁爱云,郑继法等, 拮抗菌R31菌株种的鉴定, 山东农业大学学报, 1998,29(3):387~390
[62] 阮继生, 刘志恒等编著, 放线菌研究及应用, 科学出版社, 1990
[63] 阮继生编著, 放线菌分类基础, 科学出版社, 1977
[64] 姜成林等著, 放线菌分类学, 云南大学出版社, 1995
[65] 阎逊初编著, 放线菌的分类和鉴定, 科学出版社, 1992
[66] 郭勇主编, 生物制药技术, 中国轻工业出版社,2000