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。     

植物乳杆菌合成共轭亚油酸过程分析研究

在5L发酵罐上,对植物乳杆菌(Lactobacillus plantarum)分批发酵合成共轭亚油酸(CLA)过程进行了分析研究.研究表明,接种后3h,菌体生长进入对数期,15h后进入稳定期.发酵后6h进入快速耗糖期,15h后耗糖减慢.发酵后12 h CLA快速生成,24h后CLA生成停止.植物乳杆菌合成CLA是一动态过程,大部分CLA在pH值≥4.5阶段生成,pH值≤4.4后,CLA的生成基本停止.     

产共轭亚油酸植物乳杆菌的筛选、鉴定与诱变

从传统泡菜中筛选得到1 株乳酸菌lp15 能够合成共轭亚油酸(CLA),经16S rRNA 全序列分析法和API 系统鉴定法鉴定为植物乳杆菌(Lactobacillus plantarum)。利用人工诱变方法,以lp15 为出发菌株,采用紫外线、硫酸二乙酯(DES)依次诱变处理,经进一步液体发酵复筛获得多株突变菌株,CLA合成能力较出发菌株提高了29.3%～52.2%。其中lp15-2-1 突变菌株为CLA 生成能力最高菌株,MRS 培养液中添加0.2mg/mL LA 培养48h,CLA 产量达30.13μg/mL。经气相色谱(GC)检测分析,产物中cis9, trans11- 共轭亚油酸(c9, t11-CLA)占76.5%,trans10, cis12-共轭亚油酸(t10,c12-CLA)占23.5%。     

酸奶中共轭亚油酸的强化

比较了3种不同形式的共轭亚油酸(CLA)对酸奶的感官可接受性、pH值、滴定酸度和保水性的影响,并研究了CLA在酸奶中的稳定性.结果表明:酸奶中添加质量分数0.3%的共轭亚油酸甘油酯(CLA-TG)感官可接受性较好.添加3种不同形式的CLA对牛乳中保加利亚乳杆菌、嗜热链球菌的生长和发酵及酸奶的保水性没有影响,CLA在酸奶中稳定性良好.     

乳酸菌制备CLA的研究

我们利用从酸菜汁中分离出的一株植物乳杆菌Lactobacillus plantarumL18转化亚油酸(LA)来制备共轭亚油酸(CLA)。在MRS培养基中添加0.06%(wt/vol)的LA作为诱导剂,获得制备CLA的洗涤细胞。以游离LA为底物,植物乳杆菌Lactobacillus plantarumL18的洗涤细胞为催化剂,厌氧环境有利于生成CLA。0.1M的磷酸钠缓冲液、pH7.0、LA浓度2%(wt/vol)、细胞浓度为20%(wt/vol)、30℃,反应64h,CLA的产量最高。反应液中生成的CLA产物为c9,t11/t9,c11-CLA和t10,c12-CLA异构体的混合物。     

嗜酸乳杆菌发酵脱脂乳生成CLA的条件优化

为提高发酵乳中共轭亚油酸(CLA)含量,以经化学诱变的嗜酸乳杆菌(Lactobacillus acidophilus)发酵添加亚油酸(LA)的脱脂乳,通过三因素二次正交旋转组合设计对该菌株发酵脱脂乳生成共轭亚油酸的条件进行了优化。结果表明:培养温度37℃、pH5.5、培养时间28h时为最佳优化条件,此时CLA产率达33.4%。     

产共轭亚油酸丙酸菌的筛选及转化条件初探

通过富集培养、梯度密度稀释和液体培养发酵,采用紫外分光光度法测定共轭亚油酸(CLA),从市售奶酪中筛选获得1株转化生成CLA能力相对较高的菌株P9:考察了菌体接种量、亚油酸(LA)的添加量、反应温度、反应体系pH值以及乳化剂种类等因素对菌株P9 CLA生成量的影响.通过对菌株P9的菌落和形态特征、产丙酸特性及生理生化特性分析,初步鉴定该菌株为费氏丙酸杆菌(Propionibacterium frudenreichii).研究结果显示,菌株P9在菌体接种量10%(v/v),LA添加量0.75mg/mL,pH值为6.8,反应温度30℃,Tween-80作为乳化剂的条件下,CLA生成量为63.371μg/mL,亚油酸转化率为8.45%,表现出较好的产共轭亚油酸能力.     

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。     

产共轭亚油酸菌株的筛选及其发酵性质研究

共轭亚油酸(CLA)是一类具有不同位置和几何异构体的十八碳二烯酸的总称。CLA因结构多样而具有不同的生理功能。目前研究较多的活性异构体为c9,t11-CLA和t10,c12-CLA。生物合成法因产物结构单一、安全性高而受到研究人员的青睐,然而其产量仍有待提高。本研究从内蒙古传统发酵乳中筛选鉴定到10种菌株,选择CLA产量较高的植物乳杆菌HB-01,测定其发酵性能。利用均匀设计优化发酵条件为接种量4%,LA添加量0.7 mg/mL,pH 6.5,发酵温度37℃,发酵时间32 h,4℃后熟12 h。     

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。     

Determination of ethanol,volatile fatty acids,lactic and succinic acids in fermentation liquids by gas chromatography

A rapid and simple quantitative method was developed to determine, by gas chromatography, the concentrations in fermentation liquids of ethanol, the C₂-C₆ volatile fatty acids, and lactic and succinic acids. Aqueous samples were acidified with 250μlml^?1 metaphosphoric acid (5:1 ratio), centrifuged, and injected directly on to a column containing a porous aromatic polymer (Chromosorb 101) maintained at 200°C in a gas chromatograph fitted with a flame ionisation detector. It was unnecessary to purify samples further before injection, although distillation and ion-exchange methods were examined. Derivatisation of lactic and succinic acids before injection was not necessary, but the lowest level of detection of these two relatively non-volatile acids was about four times greater than that for the volatile fatty acids. The method described was suitable for the analysis of rumen fluid, methane digester fluid, silage extracts and other anaerobic fermentation fluids. The relative retention times are given for 23 organic acids and six other fermentation end-products.     

Effects of abomasal infusions of fatty acids and 1-carbon donors on apparent fatty acid digestibility and incorporation into milk fat in cows

Our primary objective was to determine the effects of the abomasal infusion of 16-carbon (16C) and 22-carbon (22C) fatty acids (FA) on apparent FA digestibility, plasma FA concentrations, and their incorporation into milk fat in cows. Our secondary objective was to study the effects of 1-carbon donors choline and l-serine on these variables. Five rumen-cannulated Holstein cows (214 ± 4.9 d in milk; 3.2 ± 1.1 parity) were enrolled in a 5 × 5 Latin square experiment with experimental periods lasting 6 d. Abomasal infusates consisted of (1) palmitic acid (PA; 98% 16:0 of total fat), (2) PA + choline chloride (PA+CC; 50 g/d of choline chloride), (3) PA + l-serine (PA+S; 170 g/d of l-serine), (4) behenic acid (BA; 92% 22:0 of total fat), and (5) docosahexaenoic acid algal oil (DHA; 47.5% DHA of total fat). Emulsions were formulated to provide 301 g/d of total FA and were balanced to provide a minimum of 40 and 19 g/d of 16:0 and glycerol, respectively, to match the content found in the infused algal oil. Apparent digestibility of FA was highest in DHA, intermediate in PA, and lowest in BA. Digestibility of 16C FA was lowest in BA and highest in PA. The digestibility of 22C FA was highest in DHA relative to BA (99 vs. 58%), whereas 1-carbon donors had no effect on 22C FA digestibility. Plasma 16C FA concentrations were greatest with PA treatment, and 22C FA concentrations were ~3-fold greater in DHA-treated cows relative to all other treatments. Milk fat 16:0 content was highest in PA relative to BA and DHA (e.g., 37 vs. 27% in PA and DHA), whereas the milk yield of 16:0 was higher in PA relative to DHA (i.e., 454 vs. 235 g/d). Similarly, milk 22:0 content and yield were ~10-fold higher in BA relative to all other treatments, whereas DHA treatment resulted in higher content and yield of 22:6 in milk fat relative to all other treatments (41- and 38-fold higher, respectively). Consequently, the content of FA >16C (i.e., preformed) was higher in milk fat from cows infused with BA and DHA relative to PA. De novo FA content in milk did not differ between PA, PA+CC, and PA+S (~16% of milk fat) but was higher in BA and DHA treatments (19 and 21%, respectively). We conclude that FA carbon chain length and degree of saturation affected FA digestibility and availability for absorption as well as their incorporation into milk fat. The abomasal infusion of choline chloride and l-serine did not modify these variables relative to infusing palmitic acid alone.     

Short communication: Eicosatrienoic acid and docosatrienoic acid do not promote vaccenic acid accumulation in mixed ruminal cultures

Previous research found that docosahexaenoic acid (C22:6n-3) was a component of fish oil that promotes trans-C18:1 accumulation in ruminal cultures when incubated with linoleic acid. The objective of this study was to determine if eicosatrienoic acid (C20:3n-3) and docosatrienoic acid (C22:3n-3), n-3 fatty acids in fish oil, promote accumulation of trans-C18:1, vaccenic acid (VA) in particular, using cultures of mixed ruminal microorganisms. Treatments consisted of control, control plus 5 mg of C20:3n-3 (ETA), control plus 5 mg of C22:3n-3 (DTA), control plus 15 mg of linoleic acid (LA), control plus 5 mg of C20:3n-3 and 15 mg of linoleic acid (ETALA), and control plus 5 mg of C22:3n-3 and 15 mg of linoleic acid (DTALA). Treatments were incubated in triplicate in 125-mL flasks, and 5 mL of culture contents was taken at 0 and 24 h for fatty acid analysis by gas-liquid chromatography. After 24 h of incubation, the concentrations of trans-C18:1 (0.87, 0.88, and 0.99 mg/culture), and VA (0.52, 0.56, and 0.62 mg/culture) were similar for the control, ETA, and DTA cultures, respectively. The concentrations of trans-C18:1 (5.51, 5.41, and 5.36 mg/culture), and VA (4.78, 4.62, and 4.59 mg/culture) were also similar between LA, ETALA, and DTALA cultures, respectively. These data suggest that C20:3n-3 and C22:3n-3 are not the active components in fish oil that promote VA accumulation when incubated with linoleic acid.     

奶粉脂肪酸与乳制品风味关系研究

用气质（GC—MS）联用色谱分析了11个商业奶粉样品的脂肪酸组成以及含量,每个样品均检测到了28种脂肪酸,在表现奶粉风味的4个呈味脂肪酸,也即辛酸、己酸、壬酸和葵酸中只检测到了辛酸和葵酸。辛酸和葵酸含量在进口奶粉中普遍高于国产奶粉。国产奶粉中辛酸和葵酸的含量以2号最好,3号其次。亚油酸含量在国产奶粉中普遍高于进口奶粉。     

气相色谱法同时快速测定食品中丙酸、山梨酸、苯甲酸及脱氢乙酸

通过液液萃取净化样品研究,建立了食品中丙酸、山梨酸、苯甲酸、脱氢乙酸及其盐含量气相色谱同时快速测定方法,适用于固体非酯(脂)类食品的检测。结果表明:丙酸的回收率在85.1%~91.3%之间,其余3种防腐剂的回收率均在95.2%~99.4%之间;实验室内变异系数(CV,n=6)最大值≤4.7%,4种防腐剂检出限均在0.002 g/kg以下。4种目标物在有杂质干扰时,可用不同的极性毛细管柱做进一步的确认。本方法具有适用范围广、检测效率高、重现性好、准确度高、检出限低的特点,推广应用对我国食品安全的监督检验具有重要的意义。     

花生四烯酸、二十二碳六烯酸和二十碳五烯酸 在炎症中的作用概述

心脑血管疾病、肿瘤、糖尿病、神经系统疾病、自身免疫等疾病严重危害着人类的生命和健康,并消耗着大量医疗资源。事实上,很多疾病发生和发展的背后都伴随着炎症反应,炎症是众多疾病的病理基础,甚至是导致这些疾病的诱因。炎症本身是机体的防御性反应,但过度的炎症反应和长期慢性炎症会损害机体的稳态。炎症的调节和控制由炎症介质介导,花生四烯酸(arachidonic acid,AA)、二十二碳六烯酸(docosahexaenoic acid,DHA)和二十碳五烯酸(eicosapentaenoic acid,EPA)等长链多不饱和脂肪酸(10ng-chain polyunsaturated fatty acids,LC-PUFAs)的衍生物是一类重要的调控炎症的介质。炎性细胞间的交流和细胞内信号传递与LC-PUFAs有关。AA经环氧酶和脂氧合酶合成的类二十烷酸主要起促炎作用,但有的也有抗炎作用。DHA和EPA在体内起抗炎作用,由它们合成的消退素(resolvins,Rvs)和保护素(protectin,PD)是重要的抗炎活性物质。DHA和EPA还可以干扰炎性细胞内信号传导途径来抑制炎症反应。本文从炎症与疾病的关系、LC-PUFAs的衍生物及其促炎和抗炎机制等方面综述了AA、DHA和EPA在炎症中的作用。     

Growth of Aeromonas hydrophila K144 as Affected by Organic Acids

The influence of different acids on the aerobic growth kinetics of Aeromonas hydrophila was studied in BHI broth with 0.5 and 2.0% NaCl incubated at 5 and 19°C. Growth curve data were analyzed by the Gompertz equation and a nonlinear regression program; generation and lag times were calculated from the Gompertz parameters. Type of acid, pH, NaCl level and temperature influenced lag and generation times. The organic acids (acetic, lactic, citric and tartaric) inhibited growth at higher pH values than inorganic acids (HCl and H₂SO₄). The high NaCl level interacted with type of acid and pH to restrict growth of the organism at the lower temperature of incubation. Acetic and lactic acids were effective in controlling the growth of A. hydrophila and could readily be combined with low holding temperature to render foods free of the organism.     

酸味酿造产品中三酸比例评析

酸味酿造产品中乳酸、醋酸、丁酸共存,但比例不同形成的酸味特征也不同。控制不同的环境条件,创造出不同的微生物区系,形成不同的三酸比例,才能形成不同的产品风格。该文对常见的酸味酿造产品中微生物区系的变化及三酸含量进行了分析。     

Anti-obesity effects of conjugated linoleic acid, docosahexaenoic acid, and eicosapentaenoic acid

Obesity has become a prevailing epidemic throughout the globe. Effective therapies for obesity become attracting. Food components with beneficial effects on "weight loss" have caught increasing attentions. Conjugated linoleic acid (CLA), docosahexaenoic acid (DHA), and eicosapentaenoic acid (EPA) belong to different families of polyunsaturated fatty acids (PUFA). However, they have similar effects on alleviating obesity and/or preventing from obesity. They influence the balance between energy intake and expenditure; and reduce body weight and/or fat deposition in animal models, but show little effect in healthy human subjects. They inhibit key enzymes responsible for lipid synthesis, such as fatty acid synthase and stearoyl-CoA desaturase-1, enhance lipid oxidation and thermogenesis, and prevent free fatty acids from entering adipocytes for lipogenesis. PUFA also exert suppressive effects on several key factors involved in adipocyte differentiation and fat storage. Despite their similar effects and shared mechanisms, they display differences in the regulation of lipid metabolism. Moreover, DHA and EPA exhibit "anti-obesity" effect as well as improving insulin sensitivity, while CLA induces insulin resistance and fatty liver in most cases. A deeper and more detailed investigation into the complex network of anti-obesity regulatory pathways by different PUFA will improve our understanding of the mechanisms of body weight control and reduce the prevalence of obesity.     

杂多酸催化合成辛酸蔗糖酯

以蔗糖、辛酸为原料,杂多酸为催化剂合成辛酸蔗糖酯。用L16(45)正交设计优化实验,高效液相色谱法分析反应液组成。考察了催化剂种类和用量、反应温度、原料配比、反应时间等因素对辛酸蔗糖酯产率的影响,发现以二甲基亚砜为溶剂、蔗糖与辛酸摩尔比1∶9、磷钨酸用量为蔗糖质量的2.0%、110℃反应时间6h,蔗糖转化率达60%,产物产要是二酯。动力学研究发现,蔗糖反应级数为一级,反应表观速率常数为0.0059min-1(90℃)、0.0117min-1(110℃),反应表观活化能Ea=39.57kJ/mol。