蛋白核小球藻发酵产油脂的研究

从5种不同来源的小球藻中筛选到1株油脂产量较高的蛋白核小球藻Chlorella pyrenoi-dosa No.2.研究了培养基组成及培养条件对其细胞生长和油脂积累的影响.结果表明,最适培养基组成为(g/L):葡萄糖20,甘氨酸0.08,MgSO4·7H2O 0.4,K2HPO4 1.0,FeSO4·7H2O 0.004;适宜的培养温度,初始pH、摇床转速和光照强度分别为28℃、6.0、130 r/min和650 Lux.在上述优化条件下培养7 d,Chlorella pyrenoidosa No.2的生物量和油脂含量分别由优化前的3.73 g/L和40.15%提高到6.56 g/L和59.90%,油脂产量提高了162%.Chlorella pyrenoidosa No.2能以木糖为碳源产油脂,可望用于以木质纤维素等可再生生物质资源为原料生产油脂.气相色谱分析表明该油脂的脂肪酸组成与植物油相似,不饱和脂肪酸含量达71%左右,可作为生产生物柴油的原料.     

均匀设计法优化蛋白核小球藻的异养培养基

[目的]通过优化培养基提高异养蛋白核小球藻CP9的生物量产率、蛋白质以及叶绿素含量。[方法]采用5因素8水平的均匀设计法优化小球藻异养培养基的配方,以葡萄糖、KNO_(3)、MgSO_(4)·7H_(2)O以及Fe-EDTA和CaCl_(2)母液为自变量,分析对小球藻生长、蛋白质含量和叶绿素含量的影响,来确定培养基自变量因素的最佳使用浓度。[结果]得到最佳培养基配方为:葡萄糖73.21 g/L、KNO_(3)6.25 g/L、MgSO_(4)·7H_(2)O 0.79 g/L、Fe-EDTA母液13.01 mL/L、CaCl_(2)母液4.80 mL/L。经培养基优化后将蛋白核小球藻CP9的最高细胞密度、蛋白质含量和叶绿素含量分别从11.08 g/L、43.3%和39.42 mg/g提升至15.08 g/L、60.0%和45.06 mg/g。[结论]通过正交优化蛋白核小球藻的异养培养基,将生物量提高了36%,同时藻细胞含有更高的蛋白质(60.0%)和叶绿素含量(45.06 mg/g),可为开发动物饲料或人类食品蛋白质。     

蛋白核小球藻发酵产油脂的研究

从5种不同来源的小球藻中筛选到1株油脂产量较高的蛋白核小球藻Chlorella pyrenoidosa No.2。研究了培养基组成及培养条件对其细胞生长和油脂积累的影响。结果表明, 最适培养基组成为(g/L)：葡萄糖 20, 甘氨酸 0.08, MgSO4·7H2O 0.4, K2HPO4 1.0, FeSO4·7H2O 0.004; 适宜的培养温度、初始pH、摇床转速和光照强度分别为28℃、6.0、130 r/min和 650 Lux。在上述优化条件下培养7 d, Chlorella pyrenoidosa No.2的生物量和油脂含量分别由优化前的3.73 g/L 和 40.15%提高到6.56 g/L和59.90%, 油脂产量提高了162%。Chlorella pyrenoidosa No.2能以木糖为碳源产油脂, 可望用于以木质纤维素等可再生生物质资源为原料生产油脂。气相色谱分析表明该油脂的脂肪酸组成与植物油相似, 不饱和脂肪酸含量达71％左右, 可作为生产生物柴油的原料。     

氮胁迫对埃氏小球藻生长及油脂积累的影响

以生长快、可除污的埃氏小球藻株系SXND-25为试材,研究不同氮浓度培养条件对其生物量和油脂产量的影响,以期建立优化培养体系利用该株小球藻生产优质生物燃油。以硝酸钠为氮源、BG11培养基中的氮浓度为基准(1.5 g/L),设置氮浓度梯度对小球藻进行培养。通过光密度测定、尼罗红染色、转酯化法抽提油脂和GC分析,对小球藻生物量、油脂含量及脂肪酸组分进行分析。结果显示,培养8 d时,在氮浓度为1.5 g/L时,生物量达到最大,干重为3.4 g/L,而油脂含量仅为28.24%,油脂产量为0.96 g/L;在氮浓度为0 g/L时生物量最小,干重为0.49 g/L,而油脂含量最高,为44.57%,油脂产量为0.22 g/L;在氮浓度为0.75 g/L时,干重为3.2 g/L,油脂含量为40.36%,油脂产量最高为1.3 g/L,是标准氮浓度下油脂产量的1.4倍。0.75 g/L氮浓度下连续培养8 d,藻油脂肪酸组成更适于制取优质生物柴油。综合生物量、油脂含量及脂肪酸组成等指标,确定0.75 g/L氮浓度为该埃氏小球藻株系规模化培养以生产优质生物燃油的优化参数。     

基于人工神经网络-遗传算法的樟芝发酵培养基优化

采用优化模型对药用丝状真菌樟芝的复杂发酵过程进行建模,并获得最优发酵培养基组成.对樟芝发酵过程中的形态变化过程进行了观察,并分别采用人工神经网络(ANN)和响应面法(RSM)对樟芝发酵过程进行建模,同时采用遗传算法(GA)优化了发酵培养基组成.结果表明,ANN模型比RSM模型具有更好的实验数据拟合能力和预测能力,GA计算得到樟芝生物量理论最大值为6.2 g/L,并获得发酵最佳接种量及培养基组成:孢子浓度1.76× 105个/mL,葡萄糖29.1 g/L,蛋白胨9.4 g/L,黄豆粉2.8 g/L.在最佳培养条件下,樟芝生物量为(6.1±0.2)g/L.基于ANN-GA的优化方法可用于优化其他丝状真菌的复杂发酵过程,从而获得生物量或活性代谢产物.     

酿酒酵母S.cerevisiae高密度培养条件优化研究

考察了培养基组成和培养条件对酿酒酵母Saccharomyces cerevisiae发酵的影响。以TB培养基为初始培养基,通过正交实验设计优化培养基组成,确定了影响酵母细胞产量最主要的因素是葡萄糖,最适培养基组成为:酪蛋白胨15 g/L,酵母粉25 g/L,葡萄糖30 g/L,KH2PO42.4g/L,K2HPO4.3H2O 16.34 g/L。并确定了最佳培养条件:温度30℃,转速150 r/min。采用优化培养基及培养条件下进行发酵,菌液最高OD600值和细胞密度分别达15.82和2.03×108/mL,比优化前分别提高24.2%和22.0%。     

利用毕赤酵母发酵废液培养原始小球藻的研究

以毕赤酵母发酵废液为水源并提供部分C源和N、P,在500 mL摇瓶中,比较了发酵废液培养基与SE基础培养基对原始小球藻的生长影响,并通过单因素和正交优化发酵废液培养基。结果表明,发酵废液培养基适合于原始小球藻的培养。利用发酵废液培养小球藻,在添加葡萄糖0.05 mol/L,硝酸钠0.01 mol/L,磷酸二氢钾0.003 mol/L,海绿素浓度300μL/L,培养7 d后最高生物量达6.56 g/L,油脂含量达33.68%,两者均高于SE基础培养基。油脂的脂肪酸组成分析表明,废液培养基培养下小球藻油脂的脂肪酸组成主要是C16∶0(25.12%)、C18∶0(4.69%)、C18∶1(50.46%)、C18∶2(6.78%)、C18∶3(8.58%),而SE培养基培养的小球藻油脂脂肪酸组成主要是C16∶0(24.56%)、C18∶0(20.36%)、C18∶1(16.66%)、C18∶2(14.32%)、C18∶3(30.98%),两种培养基培养所得藻油脂肪酸组成虽相差较大,但均适合作为生物柴油的原料。     

不同培养基及组成对2种小球藻生长和油脂的影响

研究了4种培养基及组成对蛋白核小球藻F-9和普通小球藻HYS-2的生长、油脂积累和脂肪酸组成的影响。结果发现knop、Provasoli、f/2、MAV 4种培养基中,f/2培养基更有利于小球藻的快速生长,而MAV培养基更适合油脂积累。在f/2培养基中F-9和HYS-2相对生长速率分别为0.156和0.171,培养9 d细胞干重为0.188 g/L和0.195 g/L。而在MAV培养基中F-9油脂含量最高可达19.67%,HYS-2油脂含量最高为21.91%,脂肪酸最高分别占干重的5.11%和8.71%。N/P为16∶1时小球藻生长最快,培养9 d后F-9和HYS-2的相对生长速率分别为0.23和0.239,最终细胞干重分别为0.107 g/L和0.143 g/L。而F-9和HYS-2在N/P为1∶1条件下积累油脂和脂肪酸含量最高,总脂含量分别占干重的为20.40%和27.39%,总脂肪酸占藻粉干重的含量为12.52%和16.94%。     

小球藻高密度培养及油脂提取条件的优化

【目的】高密度培养小球藻及优化油脂提取条件。【方法】通过进行单因素实验研究不同培养基组成及环境因子对其细胞生长影响,并采用超声波提取法进行正交实验对藻粉油脂提取条件进行研究。【结果】对椭圆小球藻Y4进行异养培养,最适培养条件为:葡萄糖50 g/L,硝酸钾2 g/L,适宜的培养温度、摇床转速和接种量分别为29°C、180 r/min和20%。在此基础上,进行了1 L发酵罐培养实验,获得了干重18.25 g/L的生物量。通过对油脂提取条件进行优化,Y4的油脂提取率由优化前的25.0%提高到60.2%,提高了35.2%。【结论】优化了小球藻的培养条件及油脂提取条件,促进了小球藻的开发和利用。     

不同氮源对异养小球藻生物量和油脂积累的影响

小球藻因其快速生长和易培养等特性可用于制备生物能源。与传统的光自养相比,异养小球藻可获得更多的生物量和更高的油脂含量。低成本的马铃薯淀粉水解液可作为小球藻的理想碳源,在氮饥饿条件下可诱导产生更多的油脂。为了探讨不同氮源对异养小球藻生物量和油脂积累的影响,并筛选出异养条件下的最适氮源,实验研究了不同浓度无机氮源NaNO3以及有机氮源丙氨酸和酪氨酸对异养小球藻生物量和油脂积累的影响。以马铃薯淀粉水解液为唯一碳源,在SE培养基中分别添加不同氮源培养小球藻。设定的NaNO3和丙氨酸浓度均为1.5 mmol/L、3.0 mmol/L、6.0 mmol/L,酪氨酸浓度为0.75 mmol/L、1.5 mmol/L和3.0mmol/L。所有小球藻培养实验均为暗培养并持续10 d时间。实验过程测定的指标为:小球藻的细胞数目、比生长速率、叶绿素含量、中性脂含量和总脂含量。实验结果表明:(1)在异养条件下以硝酸盐为无机氮源时,氮源促进叶绿素积累从而促进小球藻的生长,减少硝态氮可以使小球藻快速进入稳定期积累油脂。在NaNO3中氮含量为1.5 mmol/L时,生物量和油脂含量分别为2.65 g/L和51.21%,总油脂含量为1.36 g/L。(2)在不添加其他氮源的异养培养基中,丙氨酸可促进小球藻的生物量增加,在稳定期仍促进单位细胞的叶绿素含量,但总油脂含量普遍偏低。(3)酪氨酸可抑制小球藻生物量增加,使细胞膨大从而促进单位细胞内叶绿素和油脂合成,油脂含量高达38.78%—47.02%。这些结果表明小球藻可通过诱导氨基酸转运系统适应氮源的变化,其中酪氨酸所在的第三个转运系统在葡萄糖诱导条件下可促进油脂的合成。     

有机碳源对三角褐指藻生长、胞内物质和脂肪酸组分的影响

研究了3种有机碳对三角褐指藻生长、胞内物质和脂肪酸组分的影响。结果表明, 三角褐指藻具有利用有机碳进行兼养生长的能力, 生长速率加快, 倍增时间缩短, 生物量显著提高, 100 mmol/L甘油兼养的生物量最高(713 mg/L), 是自养(460 mg/L)的1.60倍, 乙酸钠和葡萄糖兼养的生物量分别是自养的1.28倍和1.21倍。兼养下蛋白质含量较自养明显下降, 碳水化合物和总脂含量高于自养, 乙酸钠和甘油兼养的总脂含量分别是自养的1.43倍和1.20倍, 葡萄糖兼养的总脂含量与自养无明显差异。3种有机碳兼养的饱和脂肪酸和单不饱和脂肪酸占总脂肪酸的比例增大, 多不饱和脂肪酸比例降低, EPA(eicosapentaenoic acid)比例降低, 乙酸钠兼养的胞内EPA含量(6.23%)和产量(36.59 mg/L)均高于自养, 分别是自养的1.10倍和1.40倍, 甘油和葡萄糖兼养的EPA含量和产量均低于自养。     

Comparison of Trophic Modes to Maximize Biomass and Lipid Productivity of <Emphasis Type="Italic">Micractinium inermum</Emphasis> NLP-F014

An optimum trophic mode condition was investigated to maximize biomass and lipid productivity of Micractinium inermum NLP-F014, which grown successfully in blended wastewater medium. In this study, four trophic modes were used, including photoautotrophic, photoheterotrophic, heterotrophic and mixotrophic modes. Mixotrophic mode showed the highest biomass and lipid productivity. However, a high concentration of organics resulted the negative effect on the growth of M. inermum NLP-F014. Mixotrophic cultivation using glucose below 500 mg/L was able to produce maximum biomass productivity up to 0.90 ± 0.03 g/L/day as well as maximum lipid productivity up to 129.31 ± 0.10 mg/L/day. From lipid analysis on mixotrophic mode using glucose, the major fatty acids are oleic acid (C18:1), linoleic acid (C18:2) and palmitic acid (C16:0). These results suggest that mixotrophic mode cultivation with wastewater containing chemical oxygen demand (COD) below 500 mg/L could be applicable for biodiesel production of M. inermum NLP-F014.     

The effect of mixotrophy on microalgal growth, lipid content, and expression levels of three pathway genes in Chlorella sorokiniana

Nannochloropsis oculata CCMP 525, Dunaliella salina FACHB 435, and Chlorella sorokiniana CCTCC M209220 were compared in mixotrophic and photoautotrophic cultures in terms of growth rate, protein, and lipid content. Growth improved in glucose, and the biomass productivities of N. oculata, D. salina, and C. sorokiniana were found to be 1.4-, 2.2- and 4.2-fold that observed photoautotrophically. However, biomass and lipid production decreased at the highest glucose concentrations. Meanwhile, the content of protein and lipid were significantly augmented for mixotrophic conditions at least for some species. C. sorokiniana was found to be well suited for lipid production based on its high biomass production rate and lipid content reaching 51% during mixotrophy. Expression levels of accD (heteromeric acetyl-CoA carboxylase beta subunit), acc1 (homomeric acetyl-CoA carboxylase), rbcL (ribulose 1, 5-bisphosphate carboxylase/oxygenase large subunit) genes in C. sorokiniana were studied by real-time PCR. Increased expression levels of accD reflect the increased lipid content in stationary phase of mixotrophic growth, but expression of the acc1 gene remains low, suggesting that this gene may not be critical to lipid accumulation. Additionally, reduction of expression of the rbcL gene during mixotrophy indicated that utilization of glucose was found to reduce the role of this gene and photosynthesis.     

花生四烯酸高产突变株的选育及其发酵调控

以拉曼被孢霉（Mortierellaramanniana）SM541为原始菌株,经过紫外线复合氯化锂诱变处理,得到突变株SM541－9,其生物量由126g／L提高到28．8g／L,油脂含量由5．8g／L提高到15.7g／L。花生四烯酸含量由321mg／L增加到623mg／L。传代实验表明,SM541－9具有良好的遗传稳定性,以葡萄糖为碳源,硝酸钾为氮源的最适培养条件下,10L罐发酵,生物量和花生四烯酸含量较原始菌株分别提高了45．2％和109.5％。在液体发酵过程中,菌丝老化、增大溶氧量、间歇流加葡萄糖都有利于花生四烯酸的合成。     

响应面法优化自养小球藻产生物柴油油脂

利用响应面法对小球藻(Chlorella vulgaris)在2L气升式生物反应器中对自养产生物柴油油脂的培养条件进行了优化。首先用Plackett-Burman方法对10个相关影响因素的效应进行评价并筛选出对产油有显著影响的3个因素:KNO3浓度、温度和CO2浓度;再用最陡爬坡实验逼近最大产油区域;最后由中心组合实验及响应面分析确定了影响产油主要因素的最佳条件为:KNO3浓度0.31g/L,温度26.5℃,CO2浓度6.80%,最高产油量达到0.42g/L,比优化前提高了近2倍。优化后,在10L气升式生物反应器中进行了扩大培养。     

利用市政污水培养Chlorella vulgaris生产生物柴油

为了考察利用南昌市政污水规模化培养富油微藻生产生物柴油,同时达到净化污水的目的,取南昌市青山湖污水处理厂未经任何处理的市政污水作为普通小球藻(Chlorella vulgaris)生长的培养液。监测了C.vulgaris在市政污水中连续培养10 d的特定生长率、生物质产量以及与之相关的市政污水中氨氮(NH4+-N)、总磷(TP)、化学需氧量(COD)、总悬浮固体(TSS)和挥发性悬浮固体(VSS)的清除情况。实验表明:营养物质的水平显著地影响了C.vulgaris的生长。C.vulgaris的生长率在培养8 d后达到最大,OD680为2.856,总的生物质产量日均最大积累速率为0.01 g/L,油脂含量为干质量的18%,油脂的平均日产量为0.001 g/L。培养10 d内NH4+-N、TP和COD的去除率分别为50.0%、32.1%和26.0%,TSS和VSS的日平均去除速率分别为0.01 g/L和0.006 1 g/L。     

Bioprocess engineering of microalgae to optimize lipid production through nutrient management

Microalgae have been used commercially as a feedstock for the production of high-value compounds, pigments, cosmetics, and nutritional supplements. In addition, because of their rapid growth rates, high photosynthetic efficiency, and high lipid and protein content, commodity products including biodiesel, feed supplements, and polyunsaturated fatty acids derived from algal biomass are of current interest. Since microalgae lack non-photosynthetic structures and float in water, they do not need massive amounts of structural cellulose found in land plants. Thus, under optimal culture conditions, some oleaginous species can allocate up to 70 % of their biomass to lipids. Lipid production and its regulation in microalgae are species-specific and influenced by environmental conditions. Various strategies have been developed to improve lipid productivity and fatty acid composition to meet specific production goals. Manipulation of physiochemical parameters, trophic modes, and nutrient levels, known as process engineering, is a simple approach that leads to desired alterations in the biochemical composition of algal biomass, including lipid quantity and quality. In this paper, we review the effects of manipulating biochemical parameters such as necessary nutrients (C, N, P, S, Fe, and Si), NaCl concentration, and pH of culture medium to optimize lipid content and profile in some algae strains with commercial potential.     

A two-stage cultivation process for the growth enhancement of Chlorella vulgaris

This study proposes a two-stage cultivation process with an autotrophic growth followed by a mixotrophic process. The results indicated that a two-stage cultivation process using a daily dose of 3 g/L of glucose could achieve 7.4 g/L of biomass, which was about a 64 % increase over simple autotrophic cultivation. In the second stage of mixotrophic cultivation, glucose was regarded as a better carbon source for cell growth, than was glycerol. Linoleic acid (C18:2) would be the primary component in the two-stage cultivation as in the autotrophic cultivation. Even carbon source was provided in the second stage of mixotrophic cultivation; lower light intensity limited the mixotrophic growth, which indicated that photosynthesis still plays an important role in the second stage of mixotrophical cultivation. The final biomass was higher after this two-stage cultivation process, which made it suitable for application in the production scale-up of algal biomass.     

葡萄糖和乙酸钠对湛江等鞭金藻兼养生长的影响

论文探讨了添加外源性有机碳葡萄糖和乙酸钠对湛江等鞭金藻(Isochrysis zhanjiangensis )生长及胞内总脂百分含量的影响.结果表明:随着葡萄糖和乙酸钠浓度的增加,湛江等鞕金藻的生长和产物积累均表现出先促进后抑制的现象.湛江等鞭金藻兼养利用葡萄糖和乙酸钠促进生长的浓度上限分别为50和30g·L^-1.葡萄糖浓度仅15g·L^-1时,对生物量具有显著促进作用,而乙酸钠浓度2.5～15g·L^-1时,对生物量均具有显著促进作用.葡萄糖对藻细胞内总脂百分含量的促进作用浓度范围是1.0～50g·L^-1,而乙酸钠仅在1.0～15g·L^-1时,表现出显著促进作用.葡萄糖浓度为15g·L^-1时,其生物量、总脂百分含量分别比对照增加了30%、30%.乙酸钠浓度为7.5g·L^-1时,其生物量、总脂百分含量分别比对照增加了30%、30%.添加适量的葡萄糖和乙酸钠能够显著促进湛江等鞭金藻生物量及胞内总脂百分含量,葡萄糖和乙酸钠的最适浓度分别是15g·L^-1和7.5g·L^-1.湛江等鞭金藻利用葡萄糖和乙酸钠进行兼养生长的能力是有限的.