植物乳杆菌p-8转化亚油酸为共轭亚油酸的分析

研究植物乳杆菌（Lactobacillus plantarum）p-8的菌体、菌体破碎液和重组亚油酸异构酶系转化亚油酸（linoleic acid,LA）为共轭亚油酸（conjugated linoleic acid,CLA）的能力和机制。结果表明：L. plantarum p-8在含有LA的MRS上清液和菌体破碎液体外催化LA时,都可以低效产生cis9,trans11-CLA（c9,t11-CLA）、trans10,cis12-CLA（t10,c12-CLA）和trans9,trans11-CLA（t9,t11-CLA）,但菌体中只有很少的t10,c12-CLA。实时聚合酶链式反应结果表明,亚油酸异构酶系的表达水平较低可能是CLA产量较低的原因。独立表达的重组亚油酸异构酶系成员、黄素腺嘌呤二核苷酸（flavin denine dinucleotide,FAD）和烟酰胺腺嘌呤二核苷酸都存在才可完成LA转化为c9,t11-CLA、t10,c12-CLA和t9,t11-CLA,转化途径与L. plantarum AUK1009一致。L. plantarum p-8的亚油酸水合酶经同源建模后有3 个结构域,底物结合位点与FAD位点位于3 个结构域连接处的疏水空腔中,M76和Y180是2 个必需基团。     

一株植物乳杆菌转化生成共轭亚油酸的特性研究

报道了一株植物乳杆菌(L.plantarumLT2-6)发酵转化亚油酸(LA)生成共轭亚油酸(CLA)的特性研究。微氧环境有利于CLA的生成;温度为37℃、初始pH为7.0、底物LA浓度为0.075%时,菌体生长及CLA生成量较高。时间曲线结果表明,接种后8h,CLA开始生成;发酵24h时,CLA生成量达到最高(0.29g/L),LA转化率为387%。生成的CLA产物主要为cis9,trans11/trans9,cis11-CLA。     

优化乳杆菌高产共轭亚油酸的研究进展

共轭亚油酸(CLA)是亚油酸(LA)的一组位置和空间异构体的总称,其中具有生理活性的异构体是c9,t11-CLA和t10,c12-CLA,它们具有丰富的营养价值和医药价值。在乳球菌属和链球菌属等乳酸菌、丙酸杆菌、瘤胃细菌以及其它菌属中,分离纯化得到的亚油酸异构酶,可催化LA异构化为CLA,利用酶法合成CLA可以有效弥补传统化学合成法的缺陷。本文概述了近年来国内外利用紫外、微波、等离子体诱变、离子注入等物理或化学方法诱变、改造亚油酸异构酶,优化产酶条件和酶学特性,还阐述利用定点突变、基因敲除等基因工程方法,对生产菌株进行改造和培养条件优化,提高CLA产量的相关研究,为进一步筛选出高产共轭亚油酸菌株和CLA的产业化应用提供理论依据。     

产CLA嗜酸乳杆菌的筛选诱变与鉴定

从传统泡菜中选育高产共轭亚油酸(Conjugated Linoleic Acid,CLA)的菌株L28,利用人工诱变方法,以L28为出发菌株,采用紫外线、亚硝基胍(NTG)依次诱变及紫外、亚硝基胍复合诱变处理,经进一步液体发酵复筛获得多株突变菌株,CLA的最优产量为95.1425μg/mL.其中L44突变菌株为CLA生成能力最高菌株.经16S rDNA全序列分析法和生理生化试验确定菌株的种属,然后经过Gene Bank基因比对确定同源基因,最后经鉴定为嗜酸乳杆菌(Lactobacillus acidophilus).     

共轭亚油酸异构体生理功能的差异

介绍了共轭亚油酸不同异构体在降低机体脂肪积累、抗肿瘤、抗动脉粥样硬化以及免疫调节方面的研究,讨论了不同共轭亚油酸异构体,尤其是顺9,反11-共轭亚油酸(c9,t11-CLA)和反10,顺12-共轭亚油酸(t10,c12-CLA)在生理功能上的差异,以期更有效地利用不同CLA异构体实现特有的生理功能。     

植物乳杆菌转化生成CLA的研究

从酸菜汁中分离出的一株植物乳杆菌LactobacillusplantarumLT2-6能将亚油酸转化成共轭亚油酸。该菌株在MRS培养基中经0.03%(w/v)的亚油酸诱导培养后,所获得的洗涤细胞具有很强的转化能力。在厌氧环境下利用L.plantarumLT2-6的洗涤细胞进行转化生成CLA的反应。结果表明,适宜反应条件为:温度30℃、pH7.0(0.1mol/L的磷酸盐缓冲系统)、细胞浓度20%(w/v)、游离亚油酸浓度1.5%(w/v)、反应时间64h,获得CLA最高产量为7.87mg/mL,产物为c9、t11/t9、c11-CLA。     

乳酸菌洗涤菌体合成共轭亚油酸的研究

为了解瑞士乳杆菌L7(Lactobacillus helveticusL7)洗涤菌体生物合成共轭亚油酸(CLA)的能力,通过单因素和正交优化研究,确定了瑞士乳杆菌L7洗涤菌体合成c9,t11-CLA的最适条件:0.05mol/LPBS缓冲液(pH5.8)、1.00mg/mL亚油酸、23℃反应12h。在最适转化条件下,c9,t11-CLA产量达到0.54mg/mL。结果表明,洗涤菌体合成CLA的产量和分批发酵相近,可以继续进行瑞士乳杆菌L7固定化细胞发酵生产CLA的研究。     

瘤胃中干酪乳杆菌的亚油酸异构酶基因的克隆与表达

以从黄牛瘤胃中分离到的一株具有将亚油酸转化为c9,t11-共轭亚油酸(conjugated linoleic acid,CLA)的干酪乳杆菌(Lactobacillus casei)Fx为出发菌株,提取其基因组DNA,聚合酶链式反应(polymerase chain reaction,PCR)扩增得到1 700 bp大小的亚油酸异构酶(linoleic acid isomerase,LAI)基因片段,将该基因片段纯化后进行TA克隆,得到重组质粒p UCm-T-LAI,将重组质粒p UCm-T-LAI和表达质粒p ET-Dsb A同时进行双酶切,连接得到重组表达载体p ET-Dsb A-LAI,经PCR鉴定和酶切后,将重组表达载体转化到大肠杆菌BL21中,得到具有LAI活性的重组菌株,能将亚油酸转化为c9,t11-CLA,表明从Lactobacillus casei Fx成功克隆LAI,该研究将有助于深入了解不同瘤胃细菌特异性合成不同CLA异构体的LAI基因差异。     

共轭亚油酸高产菌株的分离与鉴定

共轭亚油酸(CLA)因具有抗肿瘤、增强免疫力、抗动脉粥样硬化、减肥、抗氧化等功效,在医药与保健食品领域显示了巨大的应用潜力。目前获得CLA的主要途径是化学合成法,化学合成法产量高,但产物异构体众多,成分复杂,分离提纯困难,生物法因其反应条件温和,产物成分较单一,在食品医药领域展现出了良好前景。为筛选共轭亚油酸高产菌株,本文在有氧条件下,采用MRS培养基从泡菜环境中分离出16株产共轭亚油酸的菌株,其中PC-3菌株具有较高的CLA转化率,且能将亚油酸转化为具有生物活性的c9,t11-CLA和t10,c12-CLA。经形态学特征(扫描电子显微镜)分析、生理生化试验分析(API-50CHL)及16S r DNA序列分析及同源性分析,PC-3菌株被鉴定为植物乳杆菌(Lactobacillus plantarum PC-3),其16S r DNA基因序列长度为1460 bp,该序列Gen Bank的登陆号为JX270774.1。     

乙醇胁迫提高植物乳杆菌p-8的共轭亚油酸(CLA)转化率和相关酶转录水平

该文研究了在MRS培养基中添加0.05 mg/mL LA（Linoleic acid,LA）和不同浓度的乙醇时植物乳杆菌p-8的CLA（Conjugated linoleic acid,CLA）转化率和CLA合成相关酶转录水平的差异情况。结果显示,发酵液中的三种CLA异构体转化率都是在添加0.50%乙醇时最高,其中转化cis9,trans11-CLA（t9,t11-CLA）异构体最高,为2.49%,比不添加乙醇增加2.37倍。添加不同浓度乙醇的发酵液中trans10,cis12-CLA（t10,c12-CLA）转化率都是最低的。菌体中产生的CLA非常少,但规律与发酵液的基本一致。添加0.50%乙醇菌体中t9,t11-CLA转化率最高,其转化率仅为0.05%,比不添加乙醇增加了5倍。当乙醇浓度高于0.50%时,各种不同CLA异构体的转化率却都减少。结果表明CLA是在胞液内产生后再被运转到胞外的,一定浓度范围内的乙醇胁迫通过提高CLA合成相关的酶基因转录水平,进而促进了CLA的转化,可见CLA合成相关酶基因转录水平是造成CLA转化率差异的主要原因。结果为阐明植物乳杆菌p-8产CLA的分子机制和寻找有效提高CLA生成的调控手段奠定了基础。     

响应面法优化植物乳杆菌lp15-2-1产共轭亚油酸发酵条件

对植物乳杆菌(Lactobacillus plantarum)lp15-2-1 转化亚油酸生成共轭亚油酸(CLA)发酵工艺进行研究。通过单因素试验确定最佳接种量、培养温度、初始pH 值、培养时间、亚油酸添加时间、亚油酸质量浓度。采用响应面Box-Benhnken 试验设计,建立初始pH 值、培养温度和亚油酸质量浓度的二次多项式回归方程模型,所得植物乳杆菌发酵产共轭亚油酸的最佳参数为：温度30℃、亚油酸质量浓度0.21mg/mL、初始pH6.3,此条件下,CLA得率为44.77μg/mL,CLA 理论得率为45.326μg/mL,转化率为21.32%,与优化前转化率7.78% 相比,有了很大提高。     

Conjugated linoleic acid conversion by six Lactobacillus plantarum strains cultured in MRS broth supplemented with sunflower oil and soymilk

Six strains of Lactobacillus plantarum, isolated from traditional dairy products of minority nationalities, were evaluated for their ability to produce conjugated linoleic acid (CLA) from free linoleic acid in vitro. All the 6 strains were found to be capable of converting linoleic acid to CLA when using sunflower oil as substrate or during soymilk fermentation. The inhibitory effect of linoleic acid on the growth of the L. plantarum was also discussed. The production of CLA was increased with adding high concentration of substrate in sunflower oil and IMAU60042 produced the highest CLA both in sunflower oil and soymilk. The CLA was composted by 2 isomers: cis9, trans11-CLA and tran10, cis12-CLA, and cis9, tran s11-CLA covered the most part of the total CLA formed except for L. plantarum P8. The production of CLA was decreased during the storage of fermented soymilk. The CLA contents decreased significantly in the first week, also more quickly in 2 wk. Especially, tran10, cis12-CLA decreased more rapidly than cis9, tran11-CLA. No dramatic change was observed among other 8 fatty acids in soymilk. The proportion of unsaturated fatty acids varied after fermentation with different L. plantrum strains, but all decreased the during storage. The research on the ability of converting CLA of L. plantrum strains could be basis for the future research and development of fermented soymilk products. PRACTICAL APPLICATION: Desirable probiotic traits, such as acid and bile tolerance, aggregation activity, and antibacterial activity, have been proved for the 6 Lactobacillus plantarum strains. The 6 L. plantarum strains might be used in the fermentation of soymilk to produce multifunctional probiotic soymilk products, especially the rich CLA contents.     

产共轭亚油酸鼠李糖乳杆菌的筛选与鉴定

从东北传统酸菜汁中筛选出具有产共轭亚油酸(CLA)能力的乳酸菌菌株15株,采用紫外分光度计法测定发酵液中共轭亚油酸产量,其中菌株A53.2的产量最高,在MRS培养基中添加0.4mg/mL亚油酸(LA),37℃发酵24h,CLA产量达14.91μg/mL。通过对菌体的形态特征和生化特性分析,并结合16SrDNA分子生物学以及系统发育分析鉴定菌株A53.2为鼠李糖乳杆菌。     

超临界法制备玉米共轭亚油酸的工艺研究

以玉米胚芽油为原料,采用超临界法制备玉米共轭亚油酸(CLA)。通过正交试验方法确定最佳工艺条件为温度80℃、油:碱为1:0.5、时间4h、油:溶剂为1:2、压力15MPa,此时异构化效果理想,经气相色谱检测CLA转化率97.65%,产品中c9,t11-CLA与t10,c12-CLA含量分别为27.72%和30.88%。     

Biohydrogenation, duodenal flow, and intestinal digestibility of trans fatty acids and conjugated linoleic acids in response to dietary forage:concentrate ratio and linseed oil in dairy cows

Duodenal flows of hydrogenation intermediates in response to changes in dietary forage:concentrate ratio (F:C) and linseed oil were evaluated using 4 lactating Holstein cows fed a low (65:35 forage to concentrate) or high (35:65) concentrate diet without (LC, HC) added oil or with linseed oil (LCO, HCO) at 3% of DM. A 4 x 4 Latin square design was implemented for 5 wk. Lower hydrogenation of 18:2n-6 and 18:3n-3 was observed with HC, but it increased with LCO or HCO. Duodenal flow of total conjugated linoleic acids (CLA) increased by 1.40 (LCO) to 3.01 (HCO) g/d with linseed oil. This response was associated with greater flows of cis9,trans11- (+0.21 to +0.55 g/d), trans11,cis13- (+0.33 to +0.36), trans11,trans13- (+1.01 to +1.15 g/d), and trans,trans-CLA (+0.12 to +0.72 g/d). Trans10,cis12-CLA flow averaged 0.08 g/d and was not affected by F:C or oil. trans11,cis15-18:2 flow increased by 8.5 (LCO) to 62 (HCO) g/d in response to linseed oil. Total trans-18:1 flow was 37 g/d in cows fed LC and increased to 81 g/d with HC. Feeding oil increased total trans-18:1 to the greatest extent with HCO. Flow of trans10-18:1 was lower with LC than with HC (1.46 vs. 20 g/d). Linseed oil increased trans11-18:1 flow by 40 (LCO) to 113 g/d (HCO). Feeding LCO and HCO also increased flows of trans6+7+8-, trans13+14-, trans15-, and trans16-18:1. Apparent intestinal digestibility of trans-18:1 isomers was largely unaffected by concentrate level and ranged between 67 and 95%. Linseed oil increased digestibility of nearly all isomers by 3 to 16 percentage units. Digestibility of cis9,trans11-CLA was greater in cows fed HC (55%) compared with cows fed LC (32%) and was not affected by linseed oil. Data suggest that high concentrate diets enhanced ruminal outflow of trans10-18:1. We provide initial in vivo evidence that supplemental 18:3n-3 is hydrogenated to trans11,cis15-18:2, trans11-18:1, trans13+14-18:1, trans15-18:1, trans6+7+8-18:1, and trans16-18:1 primarily.     

Relationship among trans and conjugated fatty acids and bovine milk fat yield due to dietary concentrate and linseed oil

Effects on fatty acid profiles and milk fat yield due to dietary concentrate and supplemental 18:3n-3 were evaluated in 4 lactating Holstein cows fed a low- (35:65 concentrate:forage; L) or high- (65:35; H) concentrate diet without (LC, HC) added oil or with linseed oil (LCO, HCO) at 3% of DM. A 4 x 4 Latin square with four 4-wk periods was used. Milk yield and dry matter intake averaged 26.7 and 20.2 kg/d, respectively, across treatments. Plasma acetate and beta-hydroxybutyrate decreased, whereas glucose, nonesterified fatty acids, and leptin increased with high-concentrate diets. Milk fat percentage was lower in cows fed high-concentrate diets (2.31 vs. 3.38), resulting in decreases in yield of 11 (HC) and 42% (HCO). Reduced yields of 8:0-16:0 and cis9-18:1 fatty acids accounted for 69 and 17%, respectively, of the decrease in milk fat yield with HC vs. LC (-90 g/d), and for 26 and 33%, respectively, of the decrease with HCO vs. LCO (-400 g/d). Total trans-18:1 yield increased by 25 (HCO) and 59 (LCO) g/d with oil addition. Trans10-18:1 yield was 5-fold greater with high-concentrate diets. Trans11-18:1 increased by 13 (HCO) and 19 (LCO) g/d with oil addition. Trans13+14-18:1 yield increased by 9 (HCO) and 18 (LCO) g/d with linseed oil. Yield of total conjugated linoleic acids (CLA) in milk averaged 6 g/d with LC or HC compared with 14 g/d with LCO or HCO. Cis9,trans11-CLA yield was not affected by concentrate level but increased by 147% in response to oil. Feeding oil increased yields of trans11,cis13-, trans11,trans13-, and trans,trans-CLA, primarily with LCO. Trans10,cis12-CLA yield (average of 0.08 g/d) was not affected by treatments. Yield of trans11,cis15-18:2 was 1 g/d in cows fed LC or HC and 10 g/d with LCO or HCO. Yields of cis9,trans11-18:2, cis9,trans12-18:2, and cis9,trans13-18:2 were positively correlated (r = 0.74 to 0.94) with yields of trans11-18:1, trans12-18:1, and trans13+14-18:1, respectively. Plasma concentrations of biohydrogenation intermediates with concentrate or linseed oil level followed similar changes as those in milk fat. Milk fat depression was observed when HC induced an increase in trans10-18:1 yield. A correlation of 0.84 across 31 comparisons from 13 published studies, including the present one, was found among the increase in percentage of trans10-18:1 in milk fat and decreased milk fat yield. We observed, however, more drastic milk fat depression when HCO increased yields of total trans-18:1, trans11,cis15-18:2, trans isomers of 18:3, and reduced yields of 18:0 plus cis9-18:1.     

Identification of Lactic Acid Bacterial Strains with High Conjugated Linoleic Acid-Producing Ability from Natural Sauerkraut Fermentations

ABSTRACT:  Natural sauerkraut fermentations contain a great number of lactic acid bacteria. The aim of this study was to identify lactic acid bacterial strains with high conjugated linoleic acid (CLA)-producing ability from natural sauerkraut fermentations. Fifteen CLA-producing lactic acid bacterial strains were isolated in the study. One of these strains, designated as NCUL005, showed the highest CLA-producing ability (0.623 mg/mL). The transformation efficiency of converting linoleic acid into CLA by NCUL005 was 26.67%. The CLA produced by NCUL005 comprised a mixture of 32.2% cis9, trans11-C18:2 isomer and 67.8% trans10, cis12-C18:2 isomer. NCUL005 was identified as Lactobacillus plantarum , based on its cell morphology, characteristics of lactic acid production, and analysis result from Biolog Microbial Identification System (BMIS).     

Conjugated linoleic acid in ewe milk fat

Ewe milk fat from five different herds was studied to determine the content of conjugated linoleic acid (CLA) isomers. Research was carried out by combining gas chromatography-mass spectrometry (GC-MS) of fatty acid methyl esters (FAME) and 4,4-dimethyloxazolyne derivatives (DMOX) with silver ion-high performance liquid chromatography (Ag+-HPLC). Reconstructed mass spectral profiles of CLA characteristic ions from DMOX were used to identify positional isomers and Ag+-HPLC to quantify them. Total CLA content varied from 0.57 to 0.97 g/100 g of total fatty acids. FAME and DMOX were separated into a complex mixture of minor isomers and major rumenic acid (9-cis 11-trans C18:2) by GC-MS using a 100-m polar capillary column. Rumenic acid would represent more than 75% of total CLA. 11-trans 13-trans, 11-13 cis/trans plus trans/cis and 7-9 cis/trans plus trans/cis were the main CLA isomers after rumenic acid. Minor amounts of 8-10 and 10-12 C18:2 isomers were also found. Although most of the isomers were present in each herd's milk, differences in content were observed for some CLA species.     

The Production of High-purity Conjugated Linoleic Acid (CLA) Using Two-step Urea-inclusion Crystallization I and Hydrophilic Arginine-CLA Complex

ABSTRACT: The application of conjugated linoleic acid (CLA) as a functional ingredient has been limited due to the high cost of purification and its water-insoluble nature. In this study, high-purity CLA was obtained from safflower oil and a hydrophilic form of CLA was produced by complexation with arginine (Arg). CLA was prepared by alkali-isomerization and purified up to 95% using urea-inclusion crystallization. Total purified CLA comprised 41% and 50% of cis -9, trans -11 and trans -10, cis -12 isomers, respectively, with 35% recovery. Arg was attached to the carboxyl end of CLA. Optimum weight ratio of CLA to Arg was 1.7 and yield was 91%. Arg-CLA complex could expand the scope of CLA application in various food industries.