Improved elastase production by Bacillus sp. EL31410—further optimization and kinetics studies of culture medium for batch fermentation

An efficient culture medium producing a bacterial elastase with high yields was developed further following preliminary studies by means of response surface method. Central composite design (CCD) and response surface methodology were applied to optimize the medium constituents. A central composite design was used to explain the combined effect of three medium constituents, viz, glucose, K2HPO4, MgSO4·7H2O. The strain produced more elastase in the completely optimized medium, as compared with the partially optimized medium. The fitted model of the second model, as per RSM, showed that glucose was 7.4 g/100 ml, casein 1.13 g/100 ml, corn steep flour 0.616 g/100 ml, KEHPO4 0.206 g/100 ml and MgSO4·7H2O 0.034 g/100 ml. The fermentation kinetics of these two culture media in the flask experiments were analyzed. It was found that the highest elastase productivity occurred at 54 hours. Higher glucose concentration had inhibitory effect on elastase production. At the same time, we observed that the glucose consumption rate was slow in the completely optimized medium, which can explain the lag period of the highest elastase production. Some metal ions and surfactant additives also affected elastase production and cell growth.

Statistical optimization of medium composition and culture condition for the production of recombinant anti-lipopolysaccharide factor of Eriocheir sinensis in Escherichia coli

Anti-lipopolysaccharide factors (ALFs) are important antimicrobial peptides that are isolated from some aquatic species. In a previous study, we isolated ALF genes from Chinese mitten crab, Eriocheir sinensis. In this study, we optimized the production of a recombinant ALF by expressing E. sinensis ALF genes in Escherichia coli maintained in shake-flasks. In particular, we focused on optimization of both the medium composition and the culture condition. Various medium components were analyzed by the Plackett-Burman design, and two significant screened factors, (NH4)2SO4 and KH2PO4, were further optimized via the central composite design (CCD). Based on the CCD analysis, we investigated the induction start-up time, the isopropylthio-D-galactoside (IPTG) concentration, the post-induction time, and the temperature by response surface methodology. We found that the highest level of ALF fusion protein was achieved in the medium containing 1.89 g/L (NH4)2SO4 and 3.18 g/L KH2PO4, with a cell optical density of 0.8 at 600 nm before induction, an IPTG concentration of 0.5 mmol/L, a post-induction temperature of 32.7°C, and a post-induction time of 4 h. Applying the whole optimization strategy using all optimal factors improved the target protein content from 6.1% (without optimization) to 13.2%. We further applied the optimized medium and conditions in high cell density cultivation, and determined that the soluble target protein constituted 10.5% of the total protein. Our identification of the economic medium composition, optimal culture conditions, and details of the fermentation process should facilitate the potential application of ALF for further research.

Optimization of Culture Conditions and Medium Composition for the Marine Algicidal Bacterium Alteromonas sp. DH46 by Uniform Design

Harmful algal blooms(HABs) have led to extensive ecological and environmental issues and huge economic losses.Various HAB control techniques have been developed,and biological methods have been paid more attention.Algicidal bacteria is a general designation for bacteria which inhibit algal growth in a direct or indirect manner,and kill or damage the algal cells.A metabolite which is strongly toxic to the dinoflagellate Alexandrium tamarense was produced by strain DH46 of the alga-lysing bacterium Alteromonas sp.The culture conditions were optimized using a single-factor test method.Factors including carbon source,nitrogen source,temperature,initial pH value,rotational speed and salinity were studied.The results showed that the cultivation of the bacteria at 28℃ and 180 r min-1with initial pH 7 and 30 salt contcentration favored both the cell growth and the lysing effect of strain DH46.The optimal medium composition for strain DH46 was determined by means of uniform design experimentation,and the most important components influencing the cell density were tryptone,yeast extract,soluble starch,NaNO3 and MgSO4.When the following culture medium was used(tryptone 14.0g,yeast extract 1.63g,soluble starch 5.0 g,NaNO3 1.6 g,MgSO4 2.3 g in 1L),the largest bacterial dry weight(7.36 g L-1) was obtained,which was an enhancement of 107% compared to the initial medium;and the algal lysis rate was as high as 98.4% which increased nearly 10% after optimization.

Isolation and Screening of Oenococcus oeni and Its Medium Optimization

[Objectives] This study was conducted to further improve the application of Oenococcus oeni in the wine brewing industry. [Methods] O. oeni was isolated, screened, and identified, and medium optimization was performed to determine the best medium, temperature and oxygen conditions. [Results] O. oeni grew better in mFT80 medium, and the culture conditions were 25 ℃ and an anaerobic condition. [Conclusions] This study provides a reference for the development of China’s wine industry.

附球属真菌DT-014对杂草的致病性及生物学特性研究

以青海省西宁市大通县鹞子沟自然发病的大刺儿菜叶片中分离出的附球属真菌DT-014为研究对象,通过发酵喷雾法接种测定其对4种盆栽杂草猪秧秧(Galium spurium L.)、藜(Chenopodium album L.)、冬葵(Malva verticillate L. var.crispa)、密花香薷(Elsholtzia densa Benth.)的致病性和5种作物蚕豆(Vicia faba L.)、豌豆(Pisum sativum L.)、青稞(Hordeum vulgare L.)、小麦(Triticum aestivum L.)、油菜(Brassica napus L.)的安全性,并通过单因素试验,以菌落直径和其孢子悬浮液OD600值为测量标准,探究菌株DT-014的最适生长培养基、碳源、氮源、固态发酵基质。结果表明,DT-014对藜(C.album)和猪秧秧(G.spurium)致病力较强,其次为密花香薷(E.densa),对冬葵(M.crispa)致病力最低。DT-014对于小麦(T.aestivum)、蚕豆(P.sativum)、青稞(H.vulgare)、豌豆(P.sativum)相对安全,对油菜(B.napus)有轻微影响。DT-014的最适培养基为蛋白胨培养基,最适碳源为葡萄糖,最适氮源为酵母膏,最适固态发酵基质为大豆粉。

蜜环菌菌株M6的液体深层发酵工艺研究

目的:优化蜜环菌菌株M6的发酵工艺及提高其生产效率。方法:以蜜环菌菌株M6为供试菌株,通过摇瓶液体培养,筛选该菌株的最适液体发酵培养基;以摇瓶培养结果为基础,通过多级匀浆制备高活性种子液,进行液体深层发酵,优化发酵条件。结果:筛选出蜜环菌菌株M6最佳液体深层发酵条件为转速150 r/min、接种量5%、溶氧20%及温度28℃,在此条件下使用液体发酵培养基配方1发酵180 h所得蜜环菌菌株M6生物量干重高达18.39 g/L;使用液体发酵培养基2发酵120 h所得蜜环菌菌株M6生物量干重达23.83 g/L。结论:液体培养条件优化后,蜜环菌菌株M6生物量产出较高。本研究促进了蜜环菌菌株M6的快速生产,为应用于天麻种植业提供了技术参考。

富铁酿酒酵母菌株的选育及其培养条件优化

【目的】分离鉴定高效富铁酿酒酵母菌株,优化其培养基组分和发酵条件。【方法】从果园根际土壤中分离选育耐铁酿酒酵母菌,对其进行形态学、生理生化分析和26 S rDNA基因序列分析鉴定;采用单因素试验,分别设置不同碳源种类(葡萄糖、蔗糖、乳糖、果糖、麦芽糖)、氮源种类(硫酸铵、酵母膏、蛋白胨、尿素)及不同质量浓度Fe^(2+)(100,200,300,…,1000,1200,1600,2000μg/mL)、碳源(10,20,30,40,50,60,70,80,90 g/L)、氮源(无机氮源2,4,6,8,10,20 g/L;有机氮源4,8,12,16,20,24,28 g/L)、无机盐(MgSO4·7H2O 0.3,0.5,1.0,1.5,2.0 g/L;KH2PO40.5,1.5,2.5,3.5,4.5 g/L)的培养基进行试验,探究不同培养基组分对酿酒酵母富铁能力的影响。采用单因素试验研究温度(26,28,30,32,34,36,38℃)、初始pH值(3.5,4.0,4.5,5.0,5.5,6.0,6.5,7.0,7.5)、接种量(2%,4%,6%,8%,10%,12%)、转速(140,160,180,200,220 r/min)、装液量(250 mL三角瓶中分别装20,30,40,50,60,70 mL)对酿酒酵母富铁能力的影响。选择温度、初始pH值、接种量、转速进行L9(34)正交试验设计,获得最佳发酵培养条件,并进行验证试验。【结果】从三叶木通果园土壤中分离鉴定获得1株耐铁酿酒酵母菌株ZY-JM16,通过单因素试验,获得该菌株最优培养基组成为:蔗糖50 g/L、尿素4 g/L、酵母膏24 g/L、KH_(2)PO_(4)2.5 g/L、MgSO_(4)·7H_(2)O 0.5 g/L、Fe^(2+)900μg/mL(FeSO_(4)·7H_(2)O 4.5 g/L);通过单因素试验和正交试验优化,发现该菌株高富铁率最佳发酵条件为:起始pH值4.8、温度28℃、转速180 r/min、接种量6%、装液量50 mL(250 mL锥形瓶),发酵时间为40 h。在此条件下,该菌株铁富集率达到91.80%,较优化前提高了229.27%;菌体生物量达13.06 g/L,较优化前提高了59.07%。【结论】获得1株高效富铁酿酒酵母菌ZY-JM16,对其培养条件进行了优化,明晰了其生长规律。

响应面法优化酿酒酵母培养基及培养条件

为了提高酿酒酵母(Saccharomyces cerevisiae)生物量及干燥后复水存活率,采用单因素试验及响应面试验对酿酒酵母的培养基和培养条件进行优化。结果表明,从四种酿酒酵母培养基中优选出酵母浸出粉胨葡萄糖(YEPD)培养基,通过单因素试验及Box-Behnken试验得到其最佳培养基组分为甘蔗糖蜜51 g/L、牛肉膏14 g/L、酵母膏15 g/L、K2HPO41.3 g/L、VB10.01 g/L、VB20.01 g/L、肌醇0.01 g/L,在此优化培养基条件下,酵母菌生物量为12.46 g/L,比优化前提高了32.73%;最佳培养条件为培养时间22 h、摇床转速195 r/min、培养温度29℃、培养pH 5.5。热激温度54℃、热激时间8 min。在此优化培养条件下,酵母菌生物量为11.32 g/L,比优化前提升了36.27%,干燥后的复水存活率达到了86.3%,比优化前提高了10.26%。

猴杰2号液体菌种发酵条件研究

以猴头菌株猴杰2号母种为材料,研究其液体菌种最佳发酵条件,为其大规模栽培生产提供参考。采用单因子试验结合正交优化试验,以发酵所得菌丝球平均干重为衡量指标,并对所有平行数据进行SPSS方差分析,研究猴杰2号菌株液体发酵的最佳碳源、氮源、无机盐及生长因子营养组合,以及最佳初始pH、摇床转速、摇瓶装液量、摇瓶中玻璃珠数等摇床培养条件组合。结果表明,猴杰2号菌株液体发酵的最佳培养基组合为麦芽糖2%+蛋白胨0.3%+磷酸二氢钾0.225%+硫酸镁0.075%+维生素B120 mg/L,菌丝球平均干重可达8.33 g/L;最佳摇床培养条件组合为初始pH 5.0、转速160 r/min、装液量120 mL/250 mL、玻璃珠5颗/瓶,菌丝球平均干重可达8.50 g/L。

解淀粉芽胞杆菌分离鉴定及培养优化的研究进展

解淀粉芽胞杆菌(Bacillus amyloliquefaciens)是芽胞杆菌属的一个种,广泛存在于自然界,具有丰富的生境多样性,其芽胞具有抗逆性,可抵抗不良环境,同时能产生多种抗菌物质,如脂肽、抗菌蛋白和多种酶类,能抗植物病原真菌和有害细菌,该菌能形成生物膜,定植于植物根系,促进植物生长,因此对该菌进行分离鉴定以及培养优化具有重要意义。截至目前,已经从各种生境中分离、鉴定了多种有应用价值的解淀粉芽胞杆菌,通过不同策略对该菌的培养基和培养条件进行优化,使该菌相关功能得以提高。本文综述了近年来对解淀粉芽胞杆菌的生境多样性、分离鉴定及培养基和培养条件优化的策略,简要归纳了国内外关于解淀粉芽胞杆菌重要的工业和商业产品,为更好地研究和应用解淀粉芽胞杆菌提供必要的参考和借鉴。

草莓茎尖组织培养育苗技术的培养基优化

草莓茎尖组织培养育苗技术通常采用诱导分化、增殖、生根3种培养基进行培养,工序较为繁琐,为探索出一种既可用于草莓茎尖诱导分化,也可用于增殖、生根培养步骤的通用培养基,进一步简化操作工序,以草莓“红颜”0.3 mm的茎尖为试材,生长激素采用6-BA、TDZ、NAA、IAA、IBA并分别设置5个不同浓度,应用L_(25)(5^(6))的正交试验,筛选出可用于茎尖诱导分化、增殖、生根培养的通用培养基为MS+6-BA 0.3 mg·L^(-1)+TDZ 0.7 mg·L^(-1)+NAA 0.1 mg·L^(-1)+IAA 0.1 mg·L^(-1)+IBA 0.3 mg·L^(-1),诱导分化率为67.2%,增殖系数为8.5,生根率为95.1%。

镰刀菌YL2产纤维素酶液体发酵工艺优化

为提高镰刀菌YL2发酵产纤维素酶的效率,采用Plackett-Burman试验设计和响应面法设计优化了镰刀菌YL2产纤维素酶的发酵工艺,确定该菌种的最适产酶培养基及最优产酶条件。结果表明:最佳培养基配方为稻草粉31.6 g/L、豆饼粉25 g/L、柠檬酸氢二铵2.0 g/L、硫酸镁1.0 g/L、蔗糖酯1.45 g/L,在发酵培养基初始pH值6.4、500 mL的三角瓶中装液量为80 mL、摇床转速225 r/min、接种量3%、培养温度30℃的最优产酶条件下培养6 d,微晶纤维素酶(AVI)和羧甲基纤维素酶(CMC)酶活为分别6.72和84.36 IU/mL。

瓦尼桑黄核苷类成分的液体发酵工艺优化及其细胞毒活性

瓦尼桑黄(Sanghuangporus vaninii)是一种珍贵的药用真菌,其所含有的核苷类成分可开发为具有抗病毒、抗肿瘤、抗氧化、抗菌等活性的药品或保健产品等.该文通过单因素和正交试验对瓦尼桑黄液体发酵工艺进行优化,以核苷产量为指标,探究了最优发酵条件以及碳源、氮源、无机盐的最佳比例,并考察了添加不同前体物质以及调控因子对核苷产量的影响.试验筛选出影响核苷产量的关键因素之一为外源添加前体物质如次黄嘌呤、腺嘌呤,并确定了最优发酵条件:接种量10%、初始pH值为7、培养温度32℃、摇床转速140 r·min^(-1)、培养时间5 d;最佳培养基配比:葡萄糖15.00 g·L^(-1)、蔗糖20.00 g·L^(-1)、蛋白胨5.00 g·L^(-1)、牛肉膏2.50 g·L^(-1)、MgSO_(4)1.00 g·L^(-1)、CaCl_(2)1.50 g·L^(-1)、ZnSO_(4)1.00 g·L^(-1)、MnSO_(4)0.50 g·L^(-1);最优前体物质和调控因子及其添加量:次黄嘌呤1.50 g·L^(-1)、腺嘌呤2.50 g·L^(-1)、丙酮酸钠3.50 g·L^(-1)、槲皮素0.25 g·L^(-1).在最优工艺下瓦尼桑黄液体发酵核苷产量为291.16±6.21 mg·L^(-1),是优化前的32.3倍.此外,该研究还比较了优化前后以及子实体核苷富集产物的体外细胞毒活性,试验结果表明优化后的核苷富集产物对人肝癌细胞HepG2的抑制活性最好,抑制率高于优化前以及子实体的富集产物,为瓦尼桑黄进一步开发利用提供了理论基础.

丹江口库区土著Pediococcus pentosaceus菌株的分离鉴定及发酵培养基的优化

[目的]筛选出具有自主知识产权、良好适应库区环境的土著戊糖片球菌菌株,再通过对戊糖片球菌的发酵培养基进行条件优化,降低戊糖片球菌的发酵成本。[方法]采用MRS培养基从库区的青贮饲料中分离目的菌株,并进行16S rRNA的分子鉴定,再分别对戊糖片球菌发酵培养基中的碳源种类、碳源浓度、氮源种类、氮源浓度、无机盐离子及离子浓度进行优化。[结果]获得了1株具有自主知识产权的土著Pediococcus pentosaceus菌株,命名为Pediococcus pentosaceus NY001;优化得到较适宜的发酵培养基为葡萄糖40 g/L、酵母粉40 g/L、MgSO_(4)·7H_(2)O 1.0 g/L,在此条件下,戊糖片球菌的最大发酵活菌数可达2.2×10^(9) CFU/mL,显著高于初始发酵水平(2.5×10^(7)CFU/mL)的88倍。[结论]该研究为肠道益生菌的发酵培养及后续畜禽无抗健康养殖研究奠定了坚实基础。

鸡腿菇产纤溶酶液体发酵体系优化

该研究采用液态发酵法发酵鸡腿菇,鸡腿菇纤溶酶活力为评价指标,通过单因素试验、Plackett-Burman试验及Box-Behnken试验对其培养基组成和培养条件进行优化。结果表明,最佳培养基的组成为果糖2.9%,豆饼粉3.6%,KH2PO_(4)0.25%,MgSO_(4)0.2%。最佳培养条件为装液量50 mL/250 mL,接种量10%,发酵温度24℃,发酵时间6 d,摇床转速160 r/min。在此优化培养基及培养条件下,纤溶酶活力为136.89 U/mL,比优化前提高了4.28倍。

中温大曲产淀粉酶菌株的筛选鉴定及培养条件优化

为获得高产淀粉酶菌株,丰富淀粉酶生产菌株资源,该研究以中温大曲为样品,利用淀粉水解圈法初筛、摇瓶发酵复筛得到高产淀粉酶菌株,结合菌落形态观察、革兰氏染色和16S rRNA同源序列分析对其进行菌种鉴定,通过单因素试验、Plackett-Burman试验、最陡爬坡试验和Box-Behnken试验确定其产淀粉酶的最佳培养条件。结果表明,共分离筛选得到6株产淀粉酶菌株,其中一株产淀粉酶活最高的菌株(编号为DQ47)被鉴定为枯草芽孢杆菌(Bacillus subtilis),其最佳培养条件为:可溶性淀粉60 g/L,酵母粉37 g/L,发酵温度39℃,装液量85 mL/250 mL,转速175 r/min,初始pH值6,接种量3%。在此优化条件下,淀粉酶活力为8158.23 U/mL,是优化前的14.75倍。

格氏乳杆菌GU-G23高密度培养因子多维度优化及其验证

为提高具有益生特性格氏乳杆菌GU-G23的生物量,获取其高密度培养因子,该研究首先通过单因素实验和Plackett-Burman实验筛选出该菌株主要的生长营养因子为鱼蛋白胨、胰蛋白胨、柠檬酸三铵。以响应面实验设计组合作为机器模型训练样本,采用随机森林回归(Random Forest Regression,RFR)和径向基神经网络(Radial Basis Function Neural Network,RBF)模型对其培养基配方进行预测。以决定系数(R-squared,R^(2))、平均绝对误差(Mean Absolute Deviation,MAE)、均方误差(Mean-Square Error,MSE)和平均绝对百分误差(Mean Absolute Percentage Error,MAPE)作为模型评价指标,比较认为RBF在该研究中具有更好的预测性能。随后选择RBF神经网络和遗传算法(Genetic Algorithm,GA)结合对培养基主要成分进行了优化。最终获得该菌株培养基的优化配方为:鱼蛋白胨29.89 g/L,胰蛋白胨23.33 g/L,柠檬酸三铵4.34 g/L,蔗糖15.00 g/L,低聚果糖15.00 g/L,乙酸钠5.00 g/L磷酸氢二钾0.40 g/L,七水硫酸镁0.58 g/L,一水硫酸锰0.29 g/L,吐温-801.00 g/L。在此培养基条件下,所得样品活菌数达到5.21×10^(9)CFU/mL,是未优化前的4.57倍。该研究对微生物高密度培养优化预测提供了新的方法。

裂褶菌高产菌丝体发酵培养基的优化

【目的】探明裂褶菌高产菌丝体液体发酵培养基配方,为其菌丝体的批量生产及活性产物的开发提供依据。【方法】采用单因素及正交试验方法,通过摇瓶培养优化裂褶菌高产菌丝体发酵培养基中的碳源(葡萄糖、蔗糖、乳糖、麦芽糖、淀粉)、氮源(牛肉膏、蛋白胨、酵母膏、土豆浸粉、大豆蛋白胨)及生长因子(维生素B 1、L-谷氨酸、α-萘乙酸、油酸、吲哚丁酸)。【结果】筛选出最优碳源(蔗糖)、氮源(牛肉膏)、生长因子(L-谷氨酸)进行正交试验的3个浓度水平(30 g/L、40 g/L和50 g/L,6 g/L、8 g/L和10 g/L,1.5 mg/L、2 mg/L和2.5 mg/L),各因子菌丝体的产量分别为16.10~19.56 g/L,13.26~14.53 g/L,9.40~9.78 g/L;裂褶菌高产菌丝体发酵培养基的优化配方为蔗糖50 g/L+牛肉膏8 g/L+L-谷氨酸2 mg/L+MgSO_(4)·7H_(2) O 1 g/L+KH_(2) PO_(4)2 g/L,pH 6.0。在此条件下裂褶菌菌丝体产量达21.51 g/L,是基础培养基上菌丝体产量的2.03倍。【结论】裂褶菌高产菌丝体液体发酵最佳培养基配方:蔗糖50 g/L+牛肉膏8 g/L+L-谷氨酸2 mg/L+MgSO_(4)·7H_(2) O 1 g/L+KH_(2) PO_(4)2 g/L,pH 6.0。

响应面法优化欧洲冬青‘Ferox Argentea’增殖培养基大量元素配方

利用响应面法探究了培养基大量元素组分和配比对‘Ferox Argentea’试管苗增殖的影响,并构建了该品种专用的增殖培养基,采用Design-Expert响应面最佳优化试验设计,以WPM培养基中5种大量元素无机盐K_(2)SO_(4)、MgSO_(4)·7H_(2)O、KH_(2)PO_(4)、NH_(4)NO_(3)、Ca(NO_(3))_(2)·4H_(2)O为自变量,接种50 d后的增殖率、株高、芽质量等级为因变量,建立数学模型分析并预测大量元素无机盐最佳优化配方。通过单因子效应分析表明,大量元素无机盐中NH_(4)NO_(3)对欧洲冬青‘Ferox Argentea’增殖率影响显著,对株高和芽质量影响极显著,Ca(NO_(3))_(2)·4H_(2)O对株高影响显著,对芽质量影响极显著,K_(2)SO_(4)、MgSO_(4)·7H_(2)O、KH_(2)PO_(4)对各指标影响均不显著。交互效应分析表明,K_(2)SO_(4)和KH_(2)PO_(4)、K_(2)SO_(4)和Ca(NO_(3))_(2)·4H_(2)O的交互作用对增殖率具有显著影响;KH_(2)PO_(4)和Ca(NO_(3))_(2)·4H_(2)O的交互作用对株高具有显著影响;K_(2)SO_(4)和MgSO_(4)·7H_(2)O、K_(2)SO_(4)和NH_(4)NO_(3)、KH_(2)PO_(4)和Ca(NO_(3))_(2)·4H_(2)O的交互作用对芽质量具有显著影响。因此,WPM培养基的大量元素无机盐含量影响欧洲冬青‘Ferox Argentea’的增殖率、株高、芽质量等级,NH_(4)NO_(3)与Ca(NO_(3))_(2)·4H_(2)O是主要影响单因素。响应面软件预测的大量元素无机盐优化配方为:K_(2)SO_(4)495.00 mg·L^(-1)、NH_(4)NO_(3)1200.00 mg·L^(-1)、MgSO_(4)·7H_(2)O 529.10 mg·L^(-1)、KH_(2)PO_(4)362.27 mg·L^(-1)与Ca(NO_(3))_(2)·4H_(2)O 1279.92 mg·L^(-1),进一步对该优化配方进行试验验证,发现验证组试管苗增殖率2.91,株高3.14 cm,芽质量等级2.76,与理论预测无显著差异,且显著优于对照组(1.76、2.44 cm、1.78)。综上,基于响应面法构建了欧洲冬青‘Ferox Argentea’专用的增殖培养基,研究结果不仅解决了该品种的试管苗增殖困难问题,也为其他冬青属植物增殖培养体系构建提供了重要的技术参考。

响应面法优化雨生红球藻培养基

雨生红球藻(Haematococcus pluvialis)是生产高值天然虾青素(Astaxanthin,AST)的优质藻种,优化培养基营养盐组成对提高藻细胞密度和虾青素产量具有重要意义。以雨生红球藻为受试藻株,BG11为基础培养基,作单因素试验筛选NaNO_(3)、MgSO_(4)·7H_(2)O、K_(2)HPO_(4)·3H_(2)O和Na_(2)CO_(3)共4种营养盐最适浓度范围,采用响应面法优化培养基关键营养盐浓度,并作验证试验。结果表明,(1)雨生红球藻相对适宜营养盐NaNO_(3)、MgSO_(4)·7H_(2)O、K_(2)HPO_(4)·3H_(2)O和Na_(2)CO_(3)质量浓度范围分别为1500~2000、80~640、20~60和20~80 mg·L^(-1),对藻细胞密度的影响强弱依次为NaNO_(3)、Na_(2)CO_(3)、K_(2)HPO_(4)·3H_(2)O和MgSO_(4)·7H_(2)O;(2)通过响应面法分析得到上述四种营养盐最佳盐浓度分别为1556.42、51.43、42.18和358.59 mg·L^(-1),其中K_(2)HPO_(4)·3H_(2)O和MgSO_(4)·7H_(2)O具有显著交互作用(P<0.05);(3)使用优化后培养基培养雨生红球藻8 d后,藻细胞Fv/Fm与Chl-a浓度分别为0.69和7268.97μg·L^(-1),均极显著高于对照组(P<0.01),优化组细胞密度为3.53×10^(5)mL^(-1),较对照组显著提高20.48%(P<0.05)。