排序方式: 共有14条查询结果,搜索用时 15 毫秒
1.
用CODEHOP设计简并引物克隆反刍月形单胞菌K6乙酸激酶基因片段 总被引:3,自引:0,他引:3
利用CODEHOP设计细菌乙酸激酶的简并引物,选用1对引物ACKSe以高效丙酸生成菌反刍月形单胞菌K6基因组DNA进行PCR,得到749 bp PCR产物,产物经pMD18-T载体克隆转化至DH5α大肠杆菌中,测序后经Blastx比对,此DNA产物与其他菌属来源的乙酸激酶蛋白序列具有相似性,所克隆的序列即为K6的乙酸激酶基因片段。用CODEHOP程序化设计的简并引物可信性强,阳性率高。该基因的成功克隆为丙酸生成菌K6乙酸代谢工程研究提供了依据。 相似文献
2.
Cell numbers of known species of nitrate- and nitrite-reducing bacteria, Selenomonas ruminantium, Veillonella parvula and Wollinella succinogenes , in the rumen of goats (25–30 kg) were estimated by competitive polymerase chain reaction (PCR). The number of S. ruminantium was the largest of the three species examined, and tended to be greater in goats fed a high-concentrate diet (5.6 × 107 cells/mL rumen fluid) than in goats fed a high-roughage diet (1.3 × 107 cells/mL). The number of V. parvula tended to be greater when goats were fed a high-roughage diet (6.7 × 103 /mL) than when fed a high-concentrate diet (3.2 × 103 /mL). The number of W. succinogenes was below the detectable level (< 1.0 × 102 /mL) when a high-concentrate diet was fed, but was significantly increased by feeding a high-roughage diet (1.6 × 103 /mL). Addition of potassium nitrate (6 g/day) to the high-concentrate diet tended to increase V. parvula , and significantly increased W. succinogenes , indicating that these two bacteria can be increased by feeding a diet containing nitrate. 相似文献
3.
[目的]构建反刍月形单胞菌乙酸生成的缺陷株并分析其发酵特性。[方法]应用转座子标签法,通过转座子供体菌E.coliS17-1/pZJ25∷Tn5对受体菌反刍月形单胞菌进行转座子诱变,采用含卡那霉素和氟乙酸纳的选择性培养基筛选接合子。[结果]共筛选出稳定的对卡那霉素和氟乙酸具有抗性的转座工程菌7株。对反刍月形单胞菌的突变株进行16S rRNA鉴定和Tn5的PCR鉴定,及乙酸激酶(AK)和磷酸乙酰转移酶(PTA)酶比活力分析,确定突变株属于pta基因缺失型氟乙酸抗性菌株。[结论]该研究为进一步研究反刍兽瘤胃微生物乙酸的细胞代谢网络和调控奠定基础。 相似文献
4.
P. Tott J. Nyanjui A. Bensaid D. McKeever 《Veterinary immunology and immunopathology》1999,70(3-4):269-276
Cowdria-specific CD4+ T-cell lines generated from immunised cattle respond to both soluble and membrane proteins of the agent. Furthermore, the lines produced the Cowdria-inhibitory cytokine IFN-γ in response to soluble antigens fractionated by gel filtration and FPLC. Activity eluted as a single peak around fraction 15 for all T-cell lines tested. This fraction induced the highest production of IFN-γ by the lines and was shown by SDS-polyacrylamide gel electrophoresis and silver staining analysis to contain less than 10 different bands ranging from 22 to 32 kDa. Given their high sensitivity and specificity, these short-term CD4+ T-cell lines will be valuable tools for the identification of Cowdria antigens for incorporation in a subunit vaccine. 相似文献
5.
The ability of a nitrate‐reducing and nitrite‐reducing strain of Selenomonas ruminantium ssp. lactilytica (TH1) to utilize lactate was examined at the cell and enzyme levels. The TH1 strain was found to possess NAD‐independent D‐lactate dehydrogenase (iD‐LDH), with little or no lactate racemase or L‐lactate dehydrogenase, implying that TH1 virtually utilizes only the D‐form of lactate. Therefore, the introduction of lactate racemase to TH1 may enhance its ability to utilize lactate in the rumen where both D‐lactate and L‐lactate are produced. Because lactate utilization by Megasphaera elsdenii in the rumen may increase methanogenesis, it is desirable to increase lactate utilization by S. ruminantium, which may decrease methanogenesis. However, the specific activity of iD‐LDH, which represents the amount of enzyme per cell, in TH1 was approximately threefold lower than M. elsdenii. Properties of iD‐LDH, such as optimal pH and temperature, affinity for D‐lactate, and effect of metal ions, did not differ greatly between TH1 and M. elsdenii. The specific activity of iD‐LDH in TH1 increased as the D‐lactate concentration in the medium increased, suggesting that iD‐LDH synthesis is regulated in response to D‐lactate. On the contrary, no iD‐LDH activity was detected when TH1 was grown in the presence of glucose, even when D‐lactate was present. This result suggests that iD‐LDH synthesis is strongly suppressed by glucose. In order to improve the ability of S. ruminantium to utilize lactate and reduce nitrate and nitrite, it is important to enhance iD‐LDH synthesis in addition to the introduction of lactate racemase. 相似文献
6.
The cell number of Selenomonas ruminantium (S. ruminantium) that reduces nitrate and nitrite in the rumen was usually 8–10% of the total number of S. ruminantium (an order of 106/mL). The percentage was not affected by the roughage/concentrate ratio or nitrate content of the diet in 2 weeks. However, feeding a high‐nitrate diet for 12 weeks increased the percentage. The percentage of lactate‐using S. ruminantium, such as the ssp. lactilytica, was less than 1% of the total number of S. ruminantium. No S. ruminantium was found that used formate as an electron donor for nitrate and nitrite reduction. Lactate and H2 appeared to be important for nitrate and nitrite reduction by S. ruminantium. Nitrate reduction by S. ruminantium was enhanced by the coexistence of amylolytic bacteria in a medium containing starch, and as a result, nitrite accumulation increased. Coexistence of cellulolytic bacteria facilitated the growth of S. ruminantium in a medium containing cellulose, and consequently increased nitrite reduction. In order to suppress nitrite accumulation in the rumen, it may be important to enhance fiber digestion. 相似文献
7.
为快速、准确地检测反刍动物埃立克体,本研究以反刍动物埃立克体pCS20为靶基因设计特异性引物和探针,建立了TaqMan和Eva Green荧光定量PCR方法,对其反应的特异性、敏感性和重复性进行了分析,并与OIE推荐的套式PCR方法一起对临床样品进行检测。结果显示,本方法特异性强,与牛巴贝斯虫、牛双芽巴贝斯虫、环形泰勒虫、犬埃立克体、牛埃立克体、马埃立克体和立氏埃立克体无交叉反应;TaqMan和Eva Green荧光定量PCR对pCS20质粒标准品的最低检测限分别为17.4拷贝·μL-1和1.74拷贝·μL-1,标准曲线相关系数大于0.99,组内和组间CV均小于1.5%。对420只钝眼蜱样本的检测显示,TaqMan和Eva Green荧光定量PCR的检出率分别为25.48%和29.29%,与套式PCR检测方法相比,敏感性更高。本研究为反刍动物埃立克体的检测和流行病学调查提供了一种快速、准确的检测方法。 相似文献
8.
Hidenori TAGUCHI Satoshi KOIKE Yasuo KOBAYASHI Isaac K. O. CANN Shuichi KARITA 《Animal Science Journal》2004,75(4):325-332
A gene encoding for xylanase activity in the rumen hemicellulolytic bacterium Eubacterium ruminantium was cloned into pBR322 in Escherichia coli (E. coli ). The primary clone had a 5.7 kb insert produced by Eco RI partial digestion. Subcloning followed by sequencing allowed for the discovery that this enzyme has a glycosyl‐hydrolase family 10 catalytic domain with a family 9 carbohydrate binding module at C‐terminus and a region partially homologous to a family 22 carbohydrate binding module at N‐terminus. Cloned xylanase is specifically active against xylan and oligoxyloside to produce xylobiose and xylotriose, showing optimal pH and temperature at 7.0 and 50°C, respectively. Molecular size of the xylanase (91 kDa) was confirmed by zymogram analysis of the E. coli clone, which agreed with the predicted size from the DNA sequence. Functions of the two modules at C‐ and N‐termini were evaluated by using xylanase variants with and without the respective module and the C‐terminal module was found to be functional in binding to acid‐swollen cellulose and insoluble oat‐spelt xylan, whereas the N‐terminal module was inactive for binding them. 相似文献
9.
Effects of nitrate addition to a diet on fermentation and microbial populations in the rumen of goats,with special reference to Selenomonas ruminantium having the ability to reduce nitrate and nitrite 
下载免费PDF全文
下载免费PDF全文 This study investigated the effects of dietary nitrate addition on ruminal fermentation characteristics and microbial populations in goats. The involvement of Selenomonas ruminantium in nitrate and nitrite reduction in the rumen was also examined. As the result of nitrate feeding, the total concentration of ruminal volatile fatty acids decreased, whereas the acetate : propionate ratio and the concentrations of ammonia and lactate increased. Populations of methanogens, protozoa and fungi, as estimated by real‐time PCR, were greatly decreased as a result of nitrate inclusion in the diet. There was modest or little impact of nitrate on the populations of prevailing species or genus of bacteria in the rumen, whereas Streptococcus bovis and S. ruminantium significantly increased. Both the activities of nitrate reductase (NaR) and nitrite reductase (NiR) per total mass of ruminal bacteria were increased by nitrate feeding. Quantification of the genes encoding NaR and NiR by real‐time PCR with primers specific for S. ruminantium showed that these genes were increased by feeding nitrate, suggesting that the growth of nitrate‐ and nitrite‐reducing S. ruminantium is stimulated by nitrate addition. Thus, S. ruminantium is likely to play a major role in nitrate and nitrite reduction in the rumen. 相似文献
10.