紫外线诱变深黄被孢霉选育花生四烯酸高产菌株

为获得生长活力较强, 产花生四烯酸能力强的菌株, 以微生物油脂产量和花生四烯酸产量为评价指标, 采用2轮紫外线诱变的方法, 利用单因素试验确定紫外线照射时间, 并采用气相色谱分析花生四烯酸含量。试验结果表明: 紫外灯功率20 W, 照射距离30 cm, 照射时间80 s, 其致死率为76.4%。经过诱变及菌种筛选, 获得1株高产菌株Z80s2-109, 其总油脂含量为16 g/L, 花生四烯酸产量为2.34 g/L, 花生四烯酸产量比原始对照菌株提高377%, 并且遗传性能稳定。     

花生四烯酸高产菌株的选育

本研究以一株能产生花生四烯酸的被孢霉菌为出发菌株,通过紫外线诱变筛选出一株高产花生四烯酸的突变株Ｍ１０,发酵试验结果表明：突变株Ｍ１０的每升培养液中干菌体得率为３１ｇ,油脂含量为８．３ｇ,而原菌株仅为２０．３ｇ和５．４ｇ,气相色谱分析结果Ｍ１０所产花生四烯酸的量占总脂的１０．０６％（０．８３ｇ／Ｌ培养液）。同时对Ｍ１０菌株的生长和发酵特性及发酵过程中菌丝体形态变化作了一定的探讨。     

深黄被孢霉3.3410原生质体的制备和再生研究

目的:为了获得数目较多且稳定性较好的深黄被孢霉原生质体,对影响深黄被孢霉原生质体制备和再生的因素进行了研究.方法:以培养20h的幼嫩菌丝体为材料,在1.5%纤维素酶+0.5%的蜗牛酶+1%溶菌酶混合酶作用下,以0.8mol/L MgSO4·7H2O作渗透压稳定剂于30℃酶解3h,然后用血球计数板计数,计算原生质体产量.结果:在上述条件下,原生质体浓度可达到5.5 × 107个/ml.并对该原生质体在高渗培养基上进行再生实验,其再生率达到25.40%.为深黄被孢霉原生质体诱变及融合育种奠定了基础.     

深黄被孢霉△5-脱饱和酶基因在花生四烯酸合成中的作用

【目的】研究△5-脱饱和酶基因的mRNA表达量与花生四烯酸产量之间的关系。【方法】实验利用荧光定量PCR方法检测了△5-脱饱和酶在五株深黄被孢霉的同一培养时间及菌株YZ-124在不同发酵阶段的mRNA表达水平,同时利用气相色谱仪测定其花生四烯酸含量。【结果】结果表明:不同菌株的△5-脱饱和酶基因的mRNA表达水平不同,原始菌株As3.3410最低,诱变菌株YZ-124最高;深黄被孢霉YZ-124不同发酵阶段的△5-脱饱和酶基因mRNA表达量随菌龄的增加逐渐增加。【结论】结合ARA的得率显示,△5-脱饱和酶基因mRNA表达量与培养物油脂中ARA含量呈一定的正相关关系。     

被孢霉生物合成花生四烯酸的初步研究

花生四烯酸不仅是细胞膜的重要成分,在维持细胞膜的结构与功能上发挥重要作用,而且是人体前列腺素合成的前体物质,对人体生理功能具有重要的调节作用。近年来研究发现,花生四烯酸在保护皮肤、降低胆固醇、抑制血小板聚集、提高免疫能力、促进胎儿发育等方面具有独特的...     

KLa对高山被孢霉产花生四烯酸的影响

研究了体积溶氧系数(K1a)对被孢霉产生四烯酸的影响。结果表明在摇瓶水平放大培养中,K1a、被孢霉生长、花生四烯酸（AA）产量均降低。利用0.3％Tween20作为氧载体提高各级的K1a,可以较大幅度提高AA产量。     

γ——亚麻酸生产菌深黄被孢霉原生质体的形成和再生

采用２％的溶壁酶加４％的蜗牛酶,从深黄被孢霉的菌丝中获得了大量的原生质体,同时对菌丝的培养时间,渗透压稳定性,酶解系统和酶解温度等因素了进行了系统的观察,从而获得了制备深黄被孢霉原生质体的最适条件,并对该原生质体在高渗培养基上进行了再生实验,其再生率为３２％。     

花生四烯酸油脂高产菌株的选育

以高山被孢霉为出发菌株,抗氧化剂——没食子酸辛酯为筛选剂,经过紫外-LiCl复合诱变处理,筛选出抗脂肪酸脱氢酶抑制剂的菌株。将筛选出的菌株经过摇瓶发酵复筛,筛选到1株生产性能优于出发菌株的突变株R807。与原始菌株相比,该菌株的油脂组成脂肪酸分布中C18系列脂肪酸相对较少,花生四烯酸(ARA)占总脂肪酸的含量保持在40%(质量分数)以上。其菌体生物量达到39.2 g/L,油脂产量达到16.3 g/L,ARA占总脂肪酸含量为41.72%(质量分数),ARA产量达6.81 g/L。各数值比原始菌株分别提高了22.9%、3.2%、35.1%和39.8%。连续传代多次,其产量性状无显著变化。     

高山被孢霉产花生四烯酸发酵条件的研究

通过一株高山被孢霉M_(20)(Mortierella alpina)产花生四烯酸的摇瓶发酵研究,确定了其最佳发酵培养基组成及最适摇瓶发酵工艺条件。摇瓶实验确定的最佳培养基组成为(g/L):玉米粉水解液葡萄糖150,酵母粉15,KH_2PO_4 3.0,NaNO_3 3.0,MgSO_4·7H_2O 0.5。最佳发酵工艺条件为:初始pH6.5,装液量为50ml/500ml摇瓶,摇床转速150r/min,温度在菌体生长前三天控制在25℃培养,以后调至20℃培养。在此条件下,发酵培养被孢霉的生物量、菌体总油脂及花生四烯酸分别高达35.5g/L、13.2g/L及2.2g/L,在15L及1000L自动机械搅拌罐进行发酵试验,AA产量分别高达1.86g/L及1.70g/L。     

An isolation procedure for arachidonic acid producing Mortierella species

Malt extract agar and an incubation temperature of 5 °C were used to selectively isolate representatives of the genus Mortierella from soil. Fungi in a soil sample from mountain grassland able to grow under these conditions, amounted to a total of 2640 colony forming units per gram soil. Circa 94% of the total fungal isolates represented Mortierella subgenus Mortierella. The rest of the colony-forming units consisted of Mucor isolates (6.0%) and higher fungi (1.5%). All the Mortierella isolates produced arachidonic acid.     

高山被孢霉产花生四烯酸及其遗传改造的研究进展

花生四烯酸作为一种重要的多价不饱和脂肪酸,因其具有多种生理功能而被认为是潜在的食品添加剂和药物。近年来,利用高山被孢霉合成花生四烯酸已成为研究热点。前期相关研究主要集中在菌种选育及发酵调控方面。随着研究的不断深入,关于高山被孢霉合成花生四烯酸的代谢途径的研究取得了较大进展。以下简要概述前期工作进展,着重论述花生四烯酸合成途径的关键酶及其高山被孢霉的遗传改造的研究情况,包括生物合成花生四烯酸代谢途径、关键酶及其应用、高山被孢霉的遗传操作系统的构建以及遗传改造的应用,并对其研究前景进行了展望。     

Isolating Mortierella alpina strains of high yield of arachidonic acid

AIMS: To develop a fast isolation method for arachidonic acid-producing fungi of high yield. METHODS AND RESULTS: Relation between the staining degree of mycelia of Mortierella alpina stained with triphenyltetrazolium chloride (TTC) and arachidonic acid content in the fungal lipids was investigated. Results showed that staining degree of mycelia stained with TTC increased when arachidonic acid content in mycelia lipids increased. This finding was used to isolate strains of high arachidonic acid yield. Arachidonic acid producing fungi were selectively isolated from soil at a low temperature of 4 degrees C and the mycelia of these isolates were stained with TTC. CONCLUSIONS: The strain M. alpina M6 that had the highest staining degree had the highest arachidonic acid content (72.3%). The yield of arachidonic acid in this strain reached 4.82 g l(-1). SIGNIFICANCE AND IMPACT OF THE STUDY: A fast and effective method to isolate strains of high arachidonic acid yield was established according to the finding that staining degree of mycelia of M. alpina was positively correlated with arachidonic acid content in mycelia lipid.     

Production of gamma-linolenic acid by disrupted mycelia of Mortierella isabellina

AIMS: To optimize the production of linolenic acid by disrupted mycelia of Mortierella isabellina. METHODS AND RESULTS: Effects of incubation conditions such as incubation time, pH of reaction mixture, concentration of Mg2+ or malate and incubation temperature on production of linolenic acid were studied. The production of gamma-linolenic acid reached 224 mg g-1 dry cells when the reaction mixture was composed of 1.0 g (dry mycelial mass) of disrupted mycelia of M. isabellina, 50 ml (50 mmol l(-1)) potassium phosphate buffer supplemented with 0.312 mmol l(-1) of Mg2+ and 10 mmol l(-1) of malate, pH 7.0 and incubated at 5 degrees C for 1 day. CONCLUSIONS: Incubation temperature, concentration of Mg2+ and malate showed major effects on the increased linolenic acid production. SIGNIFICANCE AND IMPACT OF THE STUDY: This study highlights conditions for increasing gamma-linolenic acid production by cell-free mycelia of M. isabellina and an insight into rapidly gaining high production of polyunsaturated fatty acids.     

利用甘蔗糖蜜发酵生产花生四烯酸的研究

通过培养高山被孢霉利用糖蜜来发酵生产花生四烯酸(ARA),研究了不同甘蔗糖蜜预处理方法对ARA发酵生产的影响。研究表明:H2SO4法是最利于ARA发酵生产的糖蜜预处理方法。利用预处理的甘蔗糖蜜发酵生产ARA,通过单因素实验设计,确定了最优的培养条件,包括初始还原糖80 g/L,N源6 g/L,接种量20%,初始pH6.0和培养温度25℃,在此条件下发酵,干细胞质量、油脂含量、ARA产量和糖利用率分别达到28.5 g/L、11.7g/L、3.68 g/L和94.5%。     

Improving arachidonic acid fermentation by Mortierella alpina through multistage temperature and aeration rate control in bioreactor

Effective production of arachidonic acid (ARA) using Mortierella alpina was conducted in a 30-L airlift bioreactor. Varying the aeration rate and temperature significantly influenced cell morphology, cell growth, and ARA production, while the optimal aeration rate and temperature for cell growth and product formation were quite different. As a result, a two-stage aeration rate control strategy was constructed based on monitoring of cell morphology and ARA production under various aeration rate control levels (0.6–1.8 vvm). Using this strategy, ARA yield reached 4.7 g/L, an increase of 38.2% compared with the control (constant aeration rate control at 1.0 vvm). Dynamic temperature-control strategy was implemented based on the fermentation performance at various temperatures (13–28°C), with ARA level in total cellular lipid increased by 37.1% comparing to a constant-temperature control (25°C). On that basis, the combinatorial fermentation strategy of two-stage aeration rate control and dynamic temperature control was applied and ARA production achieved the highest level of 5.8 g/L.