Relationship of Dietary Soy Protein to Daidzein Metabolism by Cultures of Intestinal Microfloras from Monkeys

Soybeans have been shown to contain larger concentrations of isoflavones than other plant foods. The colonic micro-floras of some individuals metabolize isoflavones, including the soy phytoestrogen daidzein, to compounds with altered estrogenic activity that may affect health. Monkeys have been used as models to predict the effect of colonic microorganisms on the metabolism of phytoestrogens. We studied the effect of consumption of a diet rich in soy protein on the metabolism of added daidzein by the intestinal microfloras of monkeys. The metabolism of daidzein by cultures of the colonic microfloras from eight males and eight females of Macaca fascicularis, 6 - 12 years old, consuming diets containing either soy or casein, and two males and three females of Macaca nemestrina, 3 - 5 months old, consuming infant formula, was investigated using high-performance liquid chromatographic analyses. Cultures from ten of the 16 adult monkeys and all five infant monkeys metabolized the added daidzein within 24 h. Daidzein was metabolized within 48 h by cultures from five other monkeys, but it remained even after 72 h in a culture from one female monkey on a casein diet. Equol and dihydrodaidzein were the only metabolites found. Individual variation among monkeys in the efficiency of daidzein metabolism was observed, but there appeared to be no correlation between diet and daidzein metabolism by the intestinal microflora. The intestinal microfloras of most monkeys tested were efficient in the biotransformation of daidzein to equol, regardless of the animals’ consumption of soy protein. Differences in the metabolism of isoflavones by the colonic microfloras of humans and experimental animals should be considered when extrapolating results from animals to humans.

响应面法优化产二氢大豆苷元菌株发酵培养基

【目的】研究采用单因素试验设计和响应面分析法对产二氢大豆苷元菌株发酵培养基的主要营养成分进行优化。【方法】以脑浸心肉汤培养基(BHI)为基础,通过单因素试验确定主要因素(碳源、氮源、生长因子和无机盐)及其适宜的浓度范围,利用Box-Behnken中心组合试验设计,采用响应面法进行回归分析,确定培养基中的最佳组成成分。【结果】通过单因素试验确定了葡萄糖、蛋白胨、VB_1和KH_2PO_4能够提高二氢大豆苷元的产量,响应面分析法进一步确定在以BHI为基础的条件下,葡萄糖的补充量为10.22 g/L、蛋白胨为6.00 g/L、VB_1为0.49 g/L、KH_2PO_4为0.82 g/L。验证试验显示在培养基优化后的条件下,DHD的产生量为0.27μg/m L,与预测值0.28μg/m L接近。【结论】利用单因素试验和响应面法,分析明确了产二氢大豆苷元菌株发酵培养基最佳成分为38 g/L的BHI、10.22 g/L的葡萄糖、6.00 g/L的蛋白胨、0.49 g/L的VB_1、0.82 g/L的KH_2PO_4。

牛瘤胃分离菌株静息细胞培养体系生物转化黄豆苷原

从牛瘤胃胃液中分离了一株在厌氧条件下能利用其生长细胞将大豆异黄酮黄豆苷原高效还原为二氢黄豆苷原的革兰氏阳性细菌菌株Niu-O16。研究了菌株Niu-O16静息细胞体系转化黄豆苷原的最佳转化条件,通过单因素试验确定菌株Niu-O16静息细胞转化黄豆苷原的最佳条件是:初始pH6.0～8.0,静息细胞浓度32～64mg/mL(湿重),加入底物浓度0.8～1.2mmol/L。通过正交试验确定了静息细胞浓度、加入底物浓度及转化时间的最佳组合为:静息细胞浓度32mg/mL、加入底物浓度0.8mmol/L、转化时间24h;最佳转化条件下底物转化率最高为63.9%。该结果为厌氧菌的静息细胞转化及工业应用提供了参考。

兔肠道大豆异黄酮还原菌株的分离鉴定及其转化特性

【目的】从兔新鲜粪样中分离对大豆异黄酮黄豆苷原和染料木素具有转化作用的特定细菌菌株。【方法】在厌氧工作站内对獭兔新鲜粪样进行梯度稀释后涂板,挑取单菌落与底物黄豆苷原和染料木素分别厌氧混合培养,用高效液相色谱检测底物被转化情况。【结果】分离得到一株对大豆异黄酮黄豆苷原和染料木素均具有转化作用的革兰氏阳性严格厌氧细菌菌株AUH-JLR41(KJ188150)。根据产物的高效液相保留时间、紫外吸收图谱和质谱分析结果,将菌株AUH-JLR41代谢底物黄豆苷原和染料木素生成的产物分别鉴定为二氢黄豆苷原和二氢染料木素。经手性高效液相系统检测,产物二氢黄豆苷原和二氢染料木素均呈现两个等面积物质峰,表明这两个产物的对映体过量率均为0。通过转化动态研究发现,菌株AUH-JLR41分别在底物黄豆苷原和染料木素加入48 h和72 h后将底物全部转化为产物,该菌株能转化底物黄豆苷原和染料木素的最大浓度均为0.6 mmol/L。经BLAST比对,菌株AUH-JLR41的16S r RNA基因序列与斯奈克氏菌属菌株Slackia equolifaciens DZE(EU377663)的相似性高达99.6%。【结论】兔肠道分离的斯奈克氏菌属菌株Slackia sp.AUH-JLR41在厌氧条件下能将大豆异黄酮黄豆苷原和染料木素分别还原为二氢黄豆苷原和二氢染料木素。

重组酿酒酵母催化二氢大豆苷元生产雌马酚

雌马酚是大豆异黄酮的代谢产物,是一种天然的选择性雌激素受体调节剂,稳定性和生物学活性高。为实现雌马酚的微生物合成,采用模块途径工程策略,构建编码雌马酚合成关键酶基因orf-1、orf-2和orf-3的表达载体,成功用于转化酿酒酵母BY4741,得到工程菌株。结果表明,工程菌株有效表达了外源基因,并可将大豆异黄酮代谢中间体二氢大豆苷元转化为雌马酚。为构建从头合成雌马酚的微生物细胞工厂提供了重要科学参考。

产S-雌马酚梭菌C1三代全基因组测序及功能基因筛选鉴定

【目的】挖掘产S-雌马酚梭菌C1转化大豆苷元产生S-雌马酚的功能基因,为梭菌C1的S-雌马酚转化机制研究提供参考,并为利用合成生物学方法生产S-雌马酚提供新基因资源。【方法】利用GridION测序平台,对梭菌C1进行第三代全基因组测序、基因组组装和功能注释等分析,从C1菌全基因组中筛选和鉴定参与S-雌马酚生物转化的功能基因。【结果】C1全基因组大小为3035113 bp,预测编码3166个基因,包含53个tRNA、15个rRNA、4个ncRNA和1个基因岛。通过生物信息学分析,发现C1-07020基因编码蛋白与已报道的Lactococcus sp.20-92大豆苷元还原酶具有44.8%的氨基酸序列相似性和相同的3个功能保守结构域,体外蛋白功能验证表明,C1-07020具有大豆苷元还原酶功能。此外,C1菌中没有发现与已知产S-雌马酚菌相似的功能基因簇或大豆苷元还原酶以外的其他功能基因。【结论】在C1中鉴定到一个新的产S-雌马酚功能基因,并发现了C1可能具备特殊的产S-雌马酚机制,实验所获基础数据可为进一步挖掘产S-雌马酚新功能基因、了解S-雌马酚的生成机制及体外产S-雌马酚基因资源的应用提供参考。