烟草氨基酸代谢及其调控机制

综述了植物氨同化以及烟草中苯丙氨酸代谢、脯氨酸代谢、美拉德反应及其与烟叶风味和品质关系的研究进展,并分析了环境因素对烟草氨基酸代谢的影响,为深入研究氨基酸对烟叶品质和风味影响的机制奠定了基础。     

鹅源草酸青霉产果胶酶对肥胖模型大鼠体重、脂肪沉积及脂质代谢的影响

本试验旨在研究鹅源草酸青霉产果胶酶对肥胖大鼠体重、脂肪沉积及脂质代谢影响。随机选取雄性大鼠108只,体重220~240 g,适应性饲养3 d。分为对照组(Ⅰ组)、高脂组(Ⅱ组)和高脂模型组;高脂模型组造模成功后,将其按体重随机分为7组,每组3个重复,每个重复4只;各组在基础饲粮中分别添加0(Ⅲ组)、0.01%(Ⅳ组)、0.05%(Ⅴ组)、0.1%(Ⅵ组)、0.2%(Ⅶ组)、0.4%(Ⅷ组)、0.8%(Ⅸ组)的果胶酶。试验期8周。结果表明:1)鹅源草酸青霉产果胶酶能够有效抑制肥胖模型大鼠体重的增长,降低Lee’s指数,控制体型发育。2)鹅源草酸青霉产果胶酶能够降低肥胖模型大鼠机体脂肪沉积量。3)鹅源草酸青霉产果胶酶能够有效地对肥胖模型大鼠由于摄入高脂饲粮引起的脂肪肝进行干预,使其恢复到正常水平。4)鹅源草酸青霉产果胶酶能够降低肥胖模型大鼠血清总胆固醇、甘油三酯、低密度脂蛋白胆固醇、游离脂肪酸含量,提高血清高密度脂蛋白胆固醇含量。5)鹅源草酸青霉产果胶酶能够降低肥胖模型大鼠谷丙转氨酶和谷草转氨酶活性,提高血清脂蛋白酯酶和肝酯酶活性。由此可见,鹅源草酸青霉产果胶酶对肥胖模型大鼠脂肪沉积和脂质代谢具有显著干预修复作用,降脂效果明显。     

益生菌大肠杆菌Nissle 1917抗逆性能、猪肠上皮细胞黏附率及抑菌效果研究

本试验旨在研究益生菌大肠杆菌Nissle 1917(Ec N)抗逆性能、猪肠上皮细胞黏附率及抑菌效果。采用体外法对Ec N进行生长曲线绘制和耐酸、耐胆盐、耐热性能的测定;以猪肠上皮细胞IPEC-J2细胞为体外细胞模型,考察了Ec N对该细胞的黏附率以及对致病菌大肠杆菌K88的黏附抑制率;同时通过蛋白质印迹法检测了Ec N对IPEC-J2细胞β-防御素-2和Toll样受体4的水平的影响。结果表明:1)Ec N对高酸、高胆盐和高温环境具有一定耐受能力。2)Ec N对IPEC-J2细胞的黏附作用以对数期最佳,黏附率达33.96%,显著高于迟缓期、稳定期和衰亡期(P0.05)。3)Ec N对致病菌大肠杆菌K88具有良好的抑制效果,黏附抑制率达87.84%。4)Ec N还能上调IPEC-J2细胞β-防御素-2和Toll样受体4水平。结果提示,益生菌Ec N具有较好的抗逆性能,能够良好地黏附猪肠上皮细胞,对致病菌大肠杆菌K88具有良好的抑制作用。     

健康家兔肠道中乳酸菌的分离鉴定

本试验选用MRS、MRS+10%家兔硬粪浸出液和MRS+10%泡菜汁3种选择培养基,对健康家兔肠道的乳酸菌群分别进行需氧和厌氧培养,根据可培养细菌菌落特征、染色特性、显微镜形态观测,共分离出7株乳酸菌株,其中需氧菌2株,厌氧菌5株。结合生化试验初步鉴定,需氧菌株分别为乳酸乳球菌和短乳杆菌,厌氧菌株分别为嗜酸乳杆菌,嗜粪乳杆菌,肠乳杆菌,乳酸乳杆菌和弯曲乳杆菌。本实验为弄清健康家兔肠道的有益菌群,以便下一步制作更易于在畜禽的肠道中定植存活的复合动物微生态制剂做准备。     

河南省郏县红牛肠道寄生虫感染情况调查

为了解河南省郏县红牛肠道寄生虫感染情况，采用卢戈氏碘液染色法、饱和蔗糖溶液漂浮法和改良抗酸染色法对河南省郏县地区某红牛养殖场及散养红牛的218份新鲜粪便样本进行了检查，结果发现寄生虫总感染率为66.5%，共检出4种肠道寄生虫，其中球虫、圆线虫、鞭虫和绦虫感染率分别为61.5%、2.3%、6.9%和7.8%，混合感染率为11.5%，阳性粪便中虫卵或卵囊感染强度以轻度感染为主。结果表明，河南省郏县红牛肠道寄生虫感染较为普遍，应加强其肠道寄生虫病的防治。     

The Alleviating Effect of Elevated CO2 on Heat Stress Susceptibility of Two Wheat (Triticum aestivum L.) Cultivars

This study analysed the alleviating effect of elevated CO₂ on stress‐induced decreases in photosynthesis and changes in carbohydrate metabolism in two wheat cultivars (Triticum aestivum L.) of different origin. The plants were grown in ambient (400 μl l^?1) and elevated (800 μl l^?1) CO₂ with a day/night temperature of 15/10 °C. At the growth stages of tillering, booting and anthesis, the plants were subjected to heat stress of 40 °C for three continuous days. Photosynthetic parameters, maximum quantum efficiency of photosystem II (PSII) photochemistry (F_v/F_m) and contents of pigments and carbohydrates in leaves were analysed before and during the stress treatments as well as after 1 day of recovery. Heat stress reduced P_N and F_v/F_m in both wheat cultivars, but plants grown in elevated CO₂ maintained higher P_N and F_v/F_m in comparison with plants grown in ambient CO₂. Heat stress reduced leaf chlorophyll contents and increased leaf sucrose contents in both cultivars grown at ambient and elevated CO₂. The content of hexoses in the leaves increased mainly in the tolerant cultivar in response to the combination of elevated CO₂ and heat stress. The results show that heat stress tolerance in wheat is related to cultivar origin, the phenological stage of the plants and can be alleviated by elevated CO₂. This confirms the complex interrelation between environmental factors and genotypic traits that influence crop performance under various climatic stresses.     

Cotton Research Center,Shandong Academy of Agricultural Sciences,Jinan 250100, China

During the long process of evolution, plants have adapted to their environments through the biosynthesis of secondary metabolites (SM) using the acetate-malonate pathway, mevalonic acids pathway, or shikimic acid pathway, leading to resistance to different pests. As a major cash crop, cotton can produce many secondary metabolites with insecticidal activity, and show self-defense mechanisms under biotic stress conditions. These characteristics of cotton ensure reduced pest incidence and maintenance of ecological balance. This paper discusses the types of SMs, their synthesis, and insect resistance of cotton secondary metabolites in relation to their defense function. We propose possible pest-control strategies using secondary metabolites in cotton.     

Effects of dietary oregano essential oil supplementation on growth performance,intestinal antioxidative capacity,immunity, and intestinal microbiota in yellow-feathered chickens

Essential oils are plant-derived aromatic volatile oils, and they contain bioactive compounds that have been shown to improve poultry nutrition. In this study, we investigated the effects of oregano essential oil (OEO) on intestinal antioxidative capacity, immunity, and gut microbiota of young yellow-feathered chickens. A total of nine hundred and sixty 1-d-old female Qingyuan partridge chickens were randomly allocated to four treatment groups with six replicates of 40 birds each, and the feeding trial was lasted for 30 d. The controls were fed on a basal diet without in-feed antibiotics; the birds in the antibiotic group were fed the basal diet supplemented with 20 mg/kg virginiamycin; the remaining birds were fed the basal diet containing 150 or 300 mg/kg OEO, respectively. Dietary supplementation with 150 or 300 mg/kg OEO increased average daily feed intake (P = 0.057) and average daily gain (P < 0.05). The activities of glutathione peroxidase and total antioxidative capacity in plasma, jejuna, and ileal mucosa were increased by OEO supplementation (P < 0.05), with a trend of lower jejunal content of malonaldehyde (P = 0.062). Moreover, dietary OEO increased the content of secretory immunoglobulin A (P = 0.078) and the relative expression of Claudin 1, Mucin 2, and Avain beta-defensin 1 in ileum (P < 0.05). Sequencing data of 16S rRNA indicated that dietary OEO increased the relative abundance of Firmicutes phylum, and Clostridium and Lactobacillus genera, and decreasing that of Romboutsia. Functional analyses indicated that microbial amino sugar and nucleotide sugar metabolism, replication, and repair systems were higher in OEO groups than those of controls and antibiotic treatment. In conclusion, dietary supplementation with OEO enhanced growth performance, alleviated local oxidative stress in intestine, improved production of natural antibodies, and favorably modulated intestinal microbiota composition.     

Effect of feed restriction on dairy cow milk production: a review

In the dairy cow, negative energy balance affects milk yield and composition as well as animal health. Studying the effects of negative energy balance on dairy cow milk production is thus essential. Feed restriction (FR) experiments attempting to reproduce negative energy balance by reducing the quantity or quality of the diet were conducted in order to better describe the animal physiology changes. The study of FR is also of interest since with climate change issues, cows may be increasingly faced with periods of drought leading to a shortage of forages. The aim of this article is to review the effects of FR during lactation in dairy cows to obtain a better understanding of metabolism changes and how it affects mammary gland activity and milk production and composition. A total of 41 papers studying FR in lactating cows were used to investigate physiological changes induced by these protocols. FR protocols affect the entire animal metabolism as indicated by changes in blood metabolites such as a decrease in glucose concentration and an increase in non-esterified fatty acid or β-hydroxybutyrate concentrations; hormonal regulations such as a decrease in insulin and insulin-like growth factor I or an increase in growth hormone concentrations. These variations indicated a mobilization of body reserve in most studies. FR also affects mammary gland activity through changes in gene expression and could affect mammary cell turnover through cell apoptosis, cell proliferation, and exfoliation of mammary epithelial cells into milk. Because of modifications of the mammary gland and general metabolism, FR decreases milk production and can affect milk composition with decreased lactose and protein concentrations and increased fat concentration. These effects, however, can vary widely depending on the type of restriction, its duration and intensity, or the stage of lactation in which it takes place. Finally, to avoid yield loss and metabolic disorders, it is important to identify reliable biomarkers to monitor energy balance.