NF-κB决定小鼠胎肝激酶-1基因启动子的基本活性

为克隆小鼠胎肝激酶-1（fetal liver kinase-1,FLK-1）基因上游启动子序列,并观察其不同截短片段在小鼠血管内皮细胞中的启动子活性,以小鼠全基因组为模板,通过PCR扩增方法获得-258～+299 bp、-96～+299 bp、-71～+299 bp、-36～+299 bp大小的FLK-1启动子片段,将其定向克隆入pGL3 Basic,构建荧光素酶报告基因载体,并制备NF -κB结合位点的突变或缺失体.在阳离子脂质体介导下,报告基因载体瞬时转染小鼠血管内皮细胞株SVEC 4-10.结果发现,在小鼠血管内皮细胞中,各FLK-1启动子片段均有活性;－71～－36 bp区存在FLK-1启动子的核心调控元件.针对该区域NF-κB结合位点进行突变或缺失,能导致启动子活性显著降低;凝胶电泳迁移率实验表明该区段能结合转录因子NF-κB.结果提示,成功克隆了在血管内皮细胞中具有活性的FLK-1上游启动子序列,NF-κB是决定其基本活性的重要转录因子,为进一步研究FLK-1基因的转录调控机制奠定了基础.     

植物耐盐的分子生物学基础

植物分子水平的耐盐研究是近年的研究热点,通过综述与耐盐有关的几种重要分子的性质和作用,总结了几种与植物耐盐有关的基因以及它们在盐分胁迫下的表达和调控。     

南沙参的组织培养与快速繁殖

1植物名称南沙参[Adenophora tetraphylla (Thunb.) Fisch.],别名轮叶沙参。2材料类别种子。3培养条件基本培养基为MS。(1)种子萌发培养基:MS 6-BA0.5mg·L-1(单位下同) NAA0.1;     

加拿大一枝黄花的组织培养及植株再生

1植物名称加拿大一枝黄花(Solidago canadensis Linn.)。2材料类别带腋芽的茎段。3培养条件(1)诱导愈伤组织培养基:MS 2,4-D0.5mg·L-1(单位下同);(2)芽分化培养基:MS 6-BA1.0;(3)生根培养基:MS。     

花花柴Na+/H+反向运输载体的表达和抗血清制备

文章建立了检测耐盐植物功能基因抗体制备和蛋白表达的方法。     

昆明山海棠的组织培养与快速繁殖

1植物名称昆明山海棠[Tripterygium hypoglaucum(Leul.)Hutchin]。2材料类别幼嫩叶片。3培养条件基本培养基为WPM和MS。     

Anion channel SLAH3 functions in nitrate‐dependent alleviation of ammonium toxicity in Arabidopsis

Slow anion channels (SLAC/SLAH) are efflux channels previously shown to be critical for stomatal regulation. However, detailed analysis using the β‐glucuronidase reporter gene showed that members of the SLAC/SLAH gene family are predominantly expressed in roots, in addition to stomatal guard cells, implicating distinct function(s) of SLAC/SLAH in the roots. Comprehensive mutant analyses of all slac/slah mutants indicated that slah3 plants showed a greater growth defect than wild‐type plants when ammonium was supplied as the sole nitrogen source. Ammonium toxicity was mimicked by acidic pH in nitrogen‐free external medium, suggesting that medium acidification by ammonium‐fed plants may underlie ammonium toxicity. Interestingly, such toxicity was more severe in slah3 mutants and, particularly in wild‐type plants, was alleviated by supplementing the media with micromolar levels of nitrate. These data thus provide evidence that SLAH3, a nitrate efflux channel, plays a role in nitrate‐dependent alleviation of ammonium toxicity in plants.     

Comparative transcriptome analysis of developmental stages of the Limonium bicolor leaf generates insights into salt gland differentiation

With the expansion of saline land worldwide, it is essential to establish a model halophyte to study the salt‐tolerance mechanism. The salt glands in the epidermis of Limonium bicolor (a recretohalophyte) play a pivotal role in salt tolerance by secreting excess salts from tissues. Despite the importance of salt secretion, nothing is known about the molecular mechanisms of salt gland development. In this study, we applied RNA sequencing to profile early leaf development using five distinct developmental stages, which were quantified by successive collections of the first true leaves of L. bicolor with precise spatial and temporal resolution. Specific gene expression patterns were identified for each developmental stage. In particular, we found that genes controlling salt gland differentiation in L. bicolor may evolve in a trichome formation, which was also confirmed by mutants with increased salt gland densities. Genes involved in the special ultrastructure of salt glands were also elucidated. Twenty‐six genes were proposed to participate in salt gland differentiation. Our dataset sheds light on the molecular processes underpinning salt gland development and thus represents a first step towards the bioengineering of active salt‐secretion capacity in crops.     

野生棘胸蛙消化器官蛋白酶的分布及酶活力

本研究在不同p H和温度条件下以离体方式对野生棘胸蛙(Quasipaa spinosa)不同消化器官的蛋白酶活力进行了分析。结果表明,食道、胃、胰的蛋白酶活力受到酶体系p H的显著影响(P0.05),且随p H升高呈现典型的单峰型活力曲线。食道和胃的蛋白酶活力在p H为1.5时达到峰值,胰的酶活力在p H为9.6时达到峰值,而肠道酶活力在p H为7.4时达到峰值。各消化器官蛋白酶活力具有明显的温度依赖性(P0.05),酶活力随温度升高也均呈典型的单峰型活力曲线,不同消化器官的最大酶活力温度分别为,食道50℃、胃50℃、胰45℃、前肠45℃、后肠45℃、直肠45℃。在最大酶活力的p H和30℃条件下,各消化器官蛋白酶活力由高到低依次为胰、食道、胃、直肠、前肠、后肠。由此可见,蛋白酶在棘胸蛙消化系统的分布具有明确的规律性,且不同来源的蛋白酶需要在特定p H和温度下才能表现出最大的反应活性。     

Energy intake,oxidative stress and antioxidant in mice during lactation

Reproduction is the highest energy demand period for small mammals, during which both energy intake and expenditure are increased to cope with elevated energy requirements of offspring growth and somatic protection. Oxidative stress life history theory proposed that reactive oxygen species(ROS) were produced in direct proportion to metabolic rate, resulting in oxidative stress and damage to macromolecules. In the present study, several markers of oxidative stress and antioxidants activities were examined in brain, liver, kidneys, skeletal muscle and small intestine in non-lactating(Non-Lac) and lactating(Lac) KM mice. Uncoupling protein(ucps) gene expression was examined in brain, liver and muscle. During peak lactation, gross energy intake was 254% higher in Lac mice than in Non-Lac mice. Levels of H2O2 of Lac mice were 17.7% higher in brain(P<0.05), but 21.1%(P<0.01) and 14.5%(P<0.05) lower in liver and small intestine than that of Non-Lac mice. Malonadialdehyde(MDA) levels of Lac mice were significantly higher in brain, but lower in liver, kidneys, muscle and small intestine than that of Non-Lac mice. Activity of glutathione peroxidase(GSH-PX) was significantly decreased in brain and liver in the Lac group compared with that in the Non-Lac group. Total antioxidant capacity(TAOC) activity of Lac mice was significantly higher in muscle, but lower in kidneys than Non-Lac mice. Ucp4 and ucp5 gene expression of brain was 394% and 577% higher in Lac mice than in Non-Lac mice. These findings suggest that KM mice show tissuedependent changes in both oxidative stress and antioxidants. Activities of antioxidants may be regulated physiologically in response to the elevated ROS production in several tissues during peak lactation. Regulations of brain ucp4 and ucp5 gene expression may be involved in the prevention of oxidative damage to the tissue.