Breeding of Monascus spp.with high monacolin K production by interspecific protoplast fusion of inactivated parental strains

为获得高产Monacolin K的红曲菌菌株,将经农杆菌介导转化获得的携带潮霉素抗性基因且以甘油为原料液态发酵高产Monacolin K的发白红曲菌H2和以大米为原料固态发酵产Monaco-lin K的烟色红曲菌9908作为亲本,对其原生质体分别进行热灭活及紫外灭活,然后对灭活双亲用PEG作融合剂进行原生质体融合.从融合子中选出有潮霉素抗性的突变株,通过发酵与亲本对比,筛选得到一株以大米为原料固态发酵高产Monacolin K的融合株F12-11,其Monacolin K产量达到8.73 mg/g;较发白红曲菌H2与烟色红曲菌9908分别提高了100.23％和48.98％;一株以甘油为原料液态发酵高产Monacolin K的融合株F13-2,其Monacolin K的产量达到1752.46 mg/L,较发白红曲菌H2与烟色红曲菌9908分别提高了32.98％和1979.33％.     

红曲菌次生代谢产物生物合成途径及相关基因的研究进展

红曲菌(Monascus spp.)是我国重要的药食两用微生物资源之一,能够产生天然食品添加剂红曲色素、降血酯活性物质Monacolin K等有益次生代谢产物,但也能分泌真菌毒素桔霉素(Citrinin),红曲菌及其相关产品的安全性由此受到质疑.因此,如何促进红曲菌有益代谢产物的产生,减少或抑制桔霉素的产生成为广大科研工作者研究的重点方向.近年来,红曲菌的分子生物学研究有了较快的发展,红曲菌次生代谢产物生物合成及其调控的研究是热点.本文重点介绍红曲色素、Monacolin K和桔霉素生物合成途径及相关基因的研究进展,以期为有效调控红曲菌次生代谢产物的产生、提高红曲产品的安全性提供参考和借鉴.     

红曲霉发酵生产Monacolin K的研究进展

红曲中的Monacolin K,作为一种抑制胆固醇合成的活性物质,是公认的降低胆固醇的理想药剂,具有高效、低毒、安全的特点.对红曲霉发酵生产Monacolin K的研究进展进行了综述,阐述了Monacolin K的理化性质,对Monacolin K抑制胆固醇合成的作用机理进行了论述,并综述了如何提高Monacolin K含量的途径和检测方法,叙述了毒性物质桔霉素的产生原因和解决方法.     

高产莫纳可林K低产桔霉素红曲霉菌株的筛选和发酵条件初步优化

采集全国各地红曲霉制品中的红曲霉资源,经分离获278株红曲霉菌株。高效液相色谱(HPLC)法测定各菌株发酵液中莫纳可林K(Monacolin K)和桔霉素含量,筛选获1株Monacolin K产量较高、桔霉素含量较低的红曲霉菌株编号为M-22。依据形态特征和ITS基因序列,参照红曲霉属分类检索表,鉴定M-22菌株为紫色红曲霉(Monascus purpureus)。通过摇瓶发酵对温度、初始pH、碳源、氮源、碳氮比(C/N)等因素进行优化,确定M-22菌株摇瓶发酵产Monacolin K适宜条件为发酵温度26℃、初始pH 5.0、转速160 r/min,甘油为碳源、蛋白胨为氮源、碳氮比(C/N)为5:1,Monacolin K产量显著提高,最高为107.16 mg/L。以优化的发酵条件对M-22菌株进行5 L发酵罐发酵,发酵液中Monacolin K产量最高为189.83 mg/L,桔霉素含量32.53μg/L,红曲色素色价为16.38 U/m L。     

高产Monacolin K纯种红曲培养条件的研究

本实验对已有的十株红曲霉菌株进行纯种制曲,筛选出一株生长良好、Monacolin K含量高、不产桔霉素、产色素能力强及糖化酶活力相对较高的红曲霉菌株.以大米为原材料,采用液固联合制曲法,通过单因素实验对纯种红曲的培养条件进行优化.结果表明,固体培养基初始含水量为45％,接种量为8％,变温培养红曲时,红曲霉M-7所得纯种红曲最佳,其Monacolin K含量高达243 μg/g,色价450 U/g,糖化酶活力4 289 U/g.与优化之前比较,Monacolin K含量提高了37.2％.     

用培养条件改进紫红曲NTU601中红曲菌素K，Y-氨基丁酸，和桔霉素的产量

红曲是中国传统的食品发酵真菌,它产生的次级代谢产物有黄,橙,红等色素,一组抗高胆固醇剂,包括红曲菌素K(monacolin K),和降血压剂γ-氨基丁酸(GABA),和杀菌化合物,包括色素和桔霉素(citrinin)。     

固体发酵生产Monacolin K的动力学模型

对红曲霉菌株Monacus-3合成Monacolin K的发酵动力学进行了研究,建立了该菌株固体发酵合成Monacolin K的菌体生长、产物合成和底物消耗的动力学模型,并对模型参数进行了非线形回归。结果表明预测值与实验值有良好的拟和性,说明所建数学模型能较好地描述实际合成Monacolin K的固体发酵过程。     

红曲霉液态发酵生产Monacolin K培养基的优化

利用正交试验设计对红曲霉TQ-57发酵生产Monacolin K的摇瓶发酵培养基进行了初步研究。结果表明:Monacolin K的最适发酵碳源为甘油,最佳添加质量分数为14%,最适氮源为蛋白胨,最佳氮源质量分数为3%,培养基初始pH为6.5,培养周期为8 d,在此条件下Monacolin K产量可达27.75 mg/L。     

水溶性红曲中MonacolinK的稳定性

对红曲中Monacolin K（MK）在水溶液中的稳定性进行研究,考察不同加热温度、时间、pH、盐、维生素C（VC）、氨基酸、蔗糖质量浓度、光照和存放时间对其稳定性的影响。结果表明：100℃保温30min,水溶液中Monacolin K的浓度比20℃保温相同时间仅下降了4．6％。热处理、长时间光照对水溶液中Monacolin K有轻微的破坏作用：pH〈5．0,盐、VC、氨基酸的添加可降低水溶液Monacolin K溶解度。pH〈4．0可使酸型Monacolin K转化为内酯型。在Monacolin K水溶液中添加30g/L蔗糖可使水溶液中Monacolin K饱和质量浓度增至632．9mg／L。     

红曲菌红曲色素的增量法

培养红曲菌产生红曲色素,自古以来中国就用以酿酒,台湾也广泛用以造红酒,老红洒,红腐乳等。近年来。由于红曲菌生产的红曲色素无毒,所以,作为天然色素代替焦油合成红色素,越来越引人注目。     

种间双亲灭活原生质体融合选育高产Monacolin K红曲菌

为获得高产MonacolinK的红曲菌菌株,将经农杆菌介导转化获得的携带潮霉素抗性基因且以甘油为原料液态发酵高产MonacolinK的发白红曲菌H2和以大米为原料固态发酵产Monaco-1inK的烟色红曲菌9908作为亲本,对其原生质体分别进行热灭活及紫外灭活,然后对灭活双亲用PEG作融合剂进行原生质体融合。从融合子中选出有潮霉素抗性的突变株,通过发酵与亲本对比,筛选得到一株以大米为原料固态发酵高产MonacolinK的融合株F12．11,其MonacolinK产量达到8．73mg／g;较发白红曲菌H2与烟色红曲菌9908分别提高了100．23％和48．98％;一株以甘油为原料液态发酵高产MonacolinK的融合株F13-2,其MonacolinK的产量达到1752．46mg／L,较发白红曲菌H2与烟色红曲菌9908分别提高了32．98％和1979．33％。     

不产桔霉素的红曲霉菌种深层发酵生产莫纳可林K

对三株在YES培养基中不产桔霉素的红曲霉菌种,在摇瓶中研究了它们液体发酵生产莫纳可林K的情况。在大米粉培养基中,红色红曲霉不产莫纳可林K,但是紫色红曲霉和烟灰色红曲霉均能产莫纳可林K,前者产量高于后者。在葡萄糖．甘油培养基中,后两者的产量均很低,但是如果在该培养基中添加酵母膏,紫色红曲霉能产生较为可观的莫纳可林K。在2L的发酵罐中,利用添加了酵母膏的葡萄糖-甘油培养基,紫色红曲霉在第13d的莫纳可林K产量可达104mg/L,培养过程中无桔霉素产生。     

The presence and the content of Monacolins in Red Yeast rice prepared from Thai glutinous rice

Red yeast rice which is a product of solid fermentation was prepared from several kinds of Thai glutinous rice (Oryza sativa L.) cv. Korkor 6 (RD6), Kam (Kam), and Sanpatong1 (SPT1). Monascus purpureus CMU001 isolated from available Chinese red yeast rice was used as the fermentation starter. The analysis for the presence and the content of monacolins, the cholesterol-lowering compounds, were carried out using high performance liquid chromatography (HPLC). The presence of the monacolins was confirmed by the retention time of the reference compounds and LC-MS. The results were compared to those obtained from the Chinese red yeast rice and Thai non-glutinous rice (O. sativa L. cv. Mali105). The chromatograms show the presence of monacolin K acid form (MKA), compactin (P1), monacolin M acid form (MMA), monacolin K (MK), monacolin M (MM), and dehydromonacolin K (DMK). A large peak of a compound with the molecular weight of 358 was also detected but could not be identified. The amount of two important monacolins, compactin, and monacolin K, were determined. It was found that the highest amount of compactin and monacolin K were 21.98 and 33.79 mg/g, respectively, when using Thai rice varity O. sativa L. cv. RD6 which was fermented without adding soybean milk.     

氨基酸对于Monascus ruber生物合成Monacolin K影响的研究

在Monacolin K发酵中添加氨基酸后发现较高质量浓度的氨基酸高度抑制了Monacolin K的产量。0.1 g.L-1的D-甲硫氨酸在发酵第4 d添加可以提高产量30%以上,而L-甲硫氨酸则没有此功能,D,L-甲硫氨酸因D-甲硫氨酸的关系也有一定的增产效果。以甲硫氨酸代替蛋白胨作为主要氮源,则抑制了polyketide途径的前期步骤,因此严重抑制了色素及Monacolin K的生产。另外,发现1 g.L-1的L-苯丙氨酸的添加时间越早越有利于Monacolin K的生产,在起始时添加发酵单位可达135.9 mg.L-1,可能是因为L-苯丙氨酸经过脱氨后,可以进入polyketide途径从而促进了Monacolin K的生产。     

Improvement of monacolin K, γ-aminobutyric acid and citrinin production ratio as a function of environmental conditions of<Emphasis Type="Italic"> Monascus purpureus</Emphasis> NTU 601

Monascus, a traditional Chinese fermentation fungus, is used as a natural dietary supplement. Its metabolic products monacolin K and -aminobutyric acid (GABA) have each been proven to be a cholesterol-lowering drug and a hypotensive agent. Citrinin, another secondary metabolite, is toxic to humans, thus lowering the acceptability of red mold rice to the general public. In this study, the influence of different carbon and nitrogen sources, and fatty acid or oils, on the production of monacolin K, citrinin and GABA by Monascus purpureus NTU 601 was studied. When 0.5% ethanol was added to the culture medium, the production of citrinin decreased from 813 ppb to 561 ppb while monacolin K increased from 136 mg/kg to 383 mg/kg and GABA increased from 1,060 mg/kg to 7,453 mg/kg. In addition, response surface methodology was used to optimize culture conditions for monacolin K, citrinin and GABA production, and data were collected according to a three-factor (temperature, ethanol concentration and amount of water supplemented), three-level central composite design. When 500 g rice was used as a solid substrate with 120 ml water and 0.3% ethanol, the production of monacolin K at 30°C increased from 136 mg/kg to 530 mg/kg, GABA production increased from 1,060 mg/kg to 5,004 mg/kg and citrinin decreased from 813 ppb to 460 ppb.     

Elevated yield of monacolin K in Monascus purpureus by fungal elicitor and mutagenesis of UV and LiCl

In China, Monascus spp., a traditional fungus used in fermentation, is used as a natural food additive. Monascus spp. can produce a secondary metabolite, monacolin K namely, which is proven to be a cholesterol-lowering and hypotensive agent. Hence, recently, many researchers have begun focusing on how to increase the production of monacolin K by Monascus purpureus. In the present study, we investigated the effect of the fungal elicitor and the mutagenesis of UV & LiCl on the amount of monacolin K produced by Monascus purpureus. The fugal elicitor, Sporobolomyces huaxiensis, was isolated from tea leaves and its filtrate was added into the culture filtrate of Monascus purpureus during growth to induct the production of monacolin K. The results showed that the highest amount of monacolin K produced by the liquid fermentation was 446.92 mg/mL, which was produced after the fungal elicitor was added to the culture filtrate of Monascus purpureus on the day 4; this amount was approximately 6 times greater than that of the control culture filtrate, whereas the highest amount of monacolin K produced by the mutated strain was 3 times greater than the control culture after the irradiation of UV light in the presence of 1.0 % LiCl in the medium.     

Effects on the sporulation and secondary metabolism yields of Monascus purpureus with mokH gene deletion and overexpression

Monacolin K is a secondary metabolite of Monascus and is known to decrease cholesterol levels in humans. There are 9 genes (mokA-mokI) controlling its biosynthesis, of which mokH is thought to act as a pathway-specific regulator. In this study, the Monascus purpureus M1 strain was compared with mokH gene deletion strains (△H1) and overexpression strains (H7). The monacolin K yields in the △H1 strain were reduced by 52.05 %, and increased in the H7 strain by 82 %. The mycelium samples of the M1, △H1, and H7 strains were found to vary with scanning electron microscopy. Compared to the M1 strain, some mycelium of the △H1 strain showed obvious folding and expansion, while the mycelium of the H7 strain was fuller. Besides, these results indicate that the mokH gene can increase the yield of monacolin K by regulating the expression level of mokA-mokI genes, and influence the production of Monascus pigment. The study is the first to combine deletion and overexpression techniques to further verify the mokH gene and get the desired results in M. purpureus.     

Development of monacolin K-enriched ganghwayakssuk (Artemisia princeps Pamp.) by fermentation with Monascus pilosus

Monacolin K-enriched ganghwayakssuk (Artemisia princeps Pamp.) was developed by fermentation with Monascus sp. Among the 15 Monascus spp. isolated previously from Monascus fermentation products, Monascus pilosus KMU108 produced 2,219 mg/kg of monacolin K during ganghwayakssuk fermentation with no detectable citrinin. The optimum concentrations of ganghwayakssuk and glucose determined from the response surface methodology (RSM) design were 2.2% and 3.8%, respectively. By applying these conditions, the monacolin K productivity was increased to 3,007 mg/kg after 15 days of fermentation. On the other hand, other characteristics such as the total content of flavonoids and phenolic compounds, and the antioxidant activity were relatively unchanged. Therefore, Monascusfermented ganghwayakssuk is an excellent biomaterial for the development of functional foods because of its high level of monacolin K, known to lower cholesterol levels.     

Red mold rice extract represses amyloid beta peptide-induced neurotoxicity via potent synergism of anti-inflammatory and antioxidative effect

Amyloid beta-peptide (Abeta), a risk of Alzheimer's disease (AD), causes cell death by inflammation and oxidative stress. Red mold rice (RMR) fermented by Monascus species is regarded as cholesterol-lowering functional food in virtue of the metabolite monacolin K identified as lovastatin. In addition, RMR is also demonstrated to express antioxidation because of multiple antioxidants. Therefore, this study focuses on the synergism of RMR against Abeta neurotoxicity and compares the effect between lovastatin and RMR including monacolin K and other functional metabolites. In this study, RE 568, an ethanol extract of RMR produced by strain Monascus purpureus NTU 568, is used to protect PC12 cell against Abeta40 neurotoxicity. All tests contain the treatments with lovastatin or RE 568 including equal monacolin K levels in order to compare the effect and investigate whether other metabolites of RE 568 provide potent assistance against Abeta40 neurotoxicity. In the results, monacolin K represses Abeta40 neurotoxicity via repressing small G-protein-mediated inflammation, and other metabolites of RE 568 also exhibit potent antioxidative ability against Abeta-induced oxidative stress. Importantly, stronger effects on repressing the Abeta40-induced cell death, inflammation, and oxidative stress are performed by RE 568 than that by the equal levels of lovastatin, which results from a potent synergism made up of monacolin K, antioxidants, and anti-inflammatory agents. The present study is the first report to demonstrate the potent synergistic protection of RMR against Abeta40 neurotoxicity, which would cause RMR to be developed as potential and novel functional food for the prophylaxis of AD pathogenesis.