Wu Jane-Yii, Yeh Kuei-Ling, Lu Wei-Bin, Lin Chung-Liang, Chang Jo-Shu
Department and Graduate Program of Bioindustry Technology, Da-Yeh University, Chang-Hua, Taiwan.
Bioresour Technol. 2008 Mar;99(5):1157-64. doi: 10.1016/j.biortech.2007.02.026. Epub 2007 Apr 16.
Rhamnolipid is one of the most effective and commonly used biosurfactant with wide industrial applications. Systematic strategies were applied to improve rhamnolipid (RL) production with a newly isolated indigenous strain Pseudomonas aeruginosa EM1 originating from an oil-contaminated site located in southern Taiwan. Seven carbon substrates and four nitrogen sources were examined for their effects on RL production. In addition, the effect of carbon to nitrogen (C/N) ratio on RL production was also studied. Single-factor experiments show that the most favorable carbon sources for RL production were glucose and glycerol (both at 40 g/L), giving a RL yield of 7.5 and 4.9 g/L, respectively. Meanwhile, sodium nitrate appeared to be the preferable nitrogen source, resulting in a RL production of 8.6g/L. Using NaNO(3) as the nitrogen source, an optimal C/N ratio of 26 and 52 was obtained for glucose- and glycerol-based culture, respectively. To further optimize the composition of fermentation medium, twenty experiments were designed by response surface methodology (RSM) to explore the favorable concentration of three critical components in the medium (i.e., glucose, glycerol, and NaNO(3)). The RSM analysis gave an optimal concentration of 30.5, 18.1, and 4.9 g/L for glucose, glycerol, and NaNO(3), respectively, predicting a maximum RL yield of 12.6 g/L, which is 47% higher than the best yield (8.6 g/L) obtained from preliminary selection tests and single factor experiments (glucose and NaNO(3) as the carbon and nitrogen source). The NMR and mass spectrometry analysis show that the purified RL product contained L-rhamnosyl-beta-hydroxydecanoyl-beta-hydroxydecanoate (RL1) and L-rhamnosyl L-rhamnosyl-beta-hydroxydecanoyl-beta-hydroxydecanoate (RL2). Meanwhile, HPLC analysis indicates that the molar ratio of RL1 and RL2 in the purified rhamnolipid product was ca. 1:1.
鼠李糖脂是最有效且常用的生物表面活性剂之一,具有广泛的工业应用。采用系统策略,利用从台湾南部一个受石油污染场地新分离出的本地菌株铜绿假单胞菌EM1来提高鼠李糖脂(RL)的产量。研究了七种碳源和四种氮源对RL产量的影响。此外,还研究了碳氮比(C/N)对RL产量的影响。单因素实验表明,最有利于RL生产的碳源是葡萄糖和甘油(均为40 g/L),RL产量分别为7.5 g/L和4.9 g/L。同时,硝酸钠似乎是较好的氮源,RL产量为8.6 g/L。以NaNO₃作为氮源,基于葡萄糖和甘油的培养分别获得了最佳C/N比为26和52。为了进一步优化发酵培养基的组成,采用响应面法(RSM)设计了20个实验,以探索培养基中三种关键成分(即葡萄糖、甘油和NaNO₃)的适宜浓度。RSM分析得出葡萄糖、甘油和NaNO₃的最佳浓度分别为30.5 g/L、18.1 g/L和4.9 g/L,预测最大RL产量为12.6 g/L,比初步筛选试验和单因素实验(以葡萄糖和NaNO₃作为碳源和氮源)获得的最佳产量(8.6 g/L)高出47%。核磁共振和质谱分析表明,纯化的RL产物含有L-鼠李糖基-β-羟基癸酰基-β-羟基癸酸酯(RL1)和L-鼠李糖基-L-鼠李糖基-β-羟基癸酰基-β-羟基癸酸酯(RL2)。同时,高效液相色谱分析表明,纯化的鼠李糖脂产物中RL1和RL2的摩尔比约为1:1。
