Optimization of Biotransformation Technology for 10-DAB Production from Baccatin III Using Response Surface Methodology

doi:10.13560/j.cnki.biotech.bull.1985.2017.04.031

Abstract

Abstract: 10-Deacetyl baccatin III（10-DAB）is the synthetic precursor of docetaxel-a taxanes drug with anti-tumor activity. The biotransformation technology conditions for 10-DAB production from baccatin III by Pantoea agglomerans P2-A-8 was optimized by response surface methodology（RSM）. Using Box-Behnken test and variance analysis,the transformation conditions for baccatin III to 10-DAB were optimized from the followings：cell culture time,cell concentration OD ₆₀₀,substrate final concentration,transformation temperature,and transformation time. The optimized biotransformation conditions were as follows：after the second stage cultivation for 12 h,cells were transferred and the initial OD₆₀₀ of cells was adjusted to 3.0 and the final concentration of baccatin III solution（dissolved in methanol）was 0.007 mg/mL The biotransformation was performed at 32℃ on a rotary shaker（200 r/min）for 4 d. Under the above optimized conditions,the yield of 10-DAB reached 24.5%,which increased by 446.8% compared with that before optimization. This study proved that applying RSM for modeling of 10-DAB production from baccatin III by Pantoea agglomerans P2-A-8 was reasonable and feasible. This result has important application value for docetaxel biosynthesis.

Key words: 10-DAB, baccatin III, Pantoea agglomerans, biotransformation, technology optimization

ZHU Feng-zhi, CHENG Cheng, LIU Xiang-sheng, ZHANG Kun WANG, Li-shuang ,WANG Min, LUO Jian-mei. Optimization of Biotransformation Technology for 10-DAB Production from Baccatin III Using Response Surface Methodology[J]. Biotechnology Bulletin, 2017, 33(4): 238-246.

References

[1] Liang JY, Shen YC, Long H. Synthesis and biological evaluation of deoxypaclitaxel analogues[J]. The Journal of Organic Chemistry, 1999, 64（6）：1814-1822.
[2] Takayama H. Distribution of concanavalin A binding sites on normal human urinary bladder mucosa and bladder tumors by transmission and scanning electron microscopy and X-ray microanalysis[J]. Urological Research, 1984, 12（2）：135-141.
[3] 杨陶, 李明, 陈建民. 红豆杉中紫杉烷类化合物制备10-去乙酰基巴卡亭III[J]. 复旦学报, 2004, 43（6）：1088-1097.
[4] 朱宏莉. 微生物转化法合成天麻素等天然活性成分的研究[D]. 西安：西北大学, 2007.
[5] 吕斯琦, 马琳, 孙静, 等. 中药微生物转化的现状及前景[J]. 药物评价研究, 2010, 33（6）：447-451.
[6] 薛宝金, 蒋德伟, 刘姮, 等. 一种由白色类诺卡放线菌产生的新的巴卡亭III C-10脱乙酰酶[J]. 天然产物研究与开发, 2010, 8：1-4.
[7] 占纪勋, 张元兴, 宁黎丽, 等. 铜绿假单孢菌AS1. 860对紫杉醇的微生物转化[J]. 应用与环境生物学报, 2003, 9（4）：429-432.
[8] Feng X, Sun LZ, Fu SB, et al. Microbial transformation of 7-epi-10-deacetylbaccatinIII to 10-deacetylbaccatinIII[J]. Journal of Molecular Catalysis B：Enzymatic, 2010, 64：45-47.
[9] Hanson RL, Wasylyk JM, NanduriVB, et al. Site-specific enzymatic hydrolysis of taxanes at C-10 and C-13[J]. Biol Chem, 1994, 269：22145-22149.
[10] 刘宝, 孙成逊, 江立, 等. 巴卡亭III C-10位乙酰基水解酶产生菌的筛选和鉴定[J]. 天然产物研究与开发, 2009, 21：16-20.
[11] 李松, 张煜, 周继蓉, 等. 一株能水解巴卡亭III C-10位乙酰基的成团泛菌的筛选和鉴定[J]. 天然产物研究与开发, 2010, 22：72-76.
[12] 李梅青, 张瑜, 代蕾莉, 等. Plackett-Burman试验设计及响应面法优化超声辅助提取明绿豆SOD工艺[J]. 食品科学, 2015, 36（2）：69-74.
[13] 李妍, 吴庆红, 陈义伦, 等. 一株纳豆芽孢杆菌的产酶条件优化[J]. 食品科学, 2013, 34（3）：179-183.
[14] 熊建华, 吴琴, 林丽萍, 等. 响应面分析法优化超声提取樟树籽油的工艺[J]. 中国粮油学报, 2013, 28（3）：65-69.
[15] 孙婉菊. 雄烯二酮耐底物突变株选育及转化条件的优化[D]. 南昌：江西师范大学, 2014.
[16] 王晓鹏. 巴卡亭III C-10位酶法脱乙酰基的研究[D]. 昆明：云南大学, 2008.