预防仔猪腹泻无抗性基因工程菌株的构建

以原来含热不稳定肠毒素B亚单位基因质粒DNA为载体,插入lacZ基因,构建了一个既能表达LT-B亚单位又能表达B-半乳糖苷酶的含四环索抗性基因的重组体。在该重组DNA的四环素抗性基因内再插入K 88粘附因子抗原基因,从而灭活了四环素抗性基因。经测定该重组体能表达LT－B和K88两种抗原,lacZ基因取代四环素抗性基因,成为良好筛选标记。所构建的重组质粒能稳定存在。     

体液酸碱平衡的维持

正常人体体液的pH值常稳定在7.35—7.45范围内,平均为7.4。维持体液酸碱度的相对衡定,对人体正常生理活动是非常重要的。本文拟就体液酸碱平衡的维持做一简单介绍。缓冲系统缓冲系统是维持体液酸碱平衡的重要因素之一,每个缓冲系统都是由几对具有缓冲作用的物质(缓冲对)所组成,每一“缓冲对”又都是由一种弱酸和这种弱酸的碱性盐组成。人体组织和血液内的缓冲系统可分为三类: 1.碳酸氢盐系统包括 NaHCO_3/H_2CO,(存于血浆内)和KHCO_3/H_2CO_3(存于细胞内)。 2.磷酸盐系统包括 Na_2HPO_4/NaH_2PO_4     

微菌落观察法快速检测和鉴别结核杆菌培养物的研究

将取自肺结核患者的219例痰标本接种匡氏琼脂平板,共分离到112例结核菌生长物。其中培养法104例(92.8％)阳性,微菌落观察法108例(96.4％)阳性,微菌落法阳性率稍高。培养法和微菌落法阳性标本首次检出时间分别为18.6d和11d,微菌落检出时间更短(P<0.01)。常规菌型鉴别方法与微菌落法对结核杆菌菌型鉴别的符合率为99％。     

杂交水稻及其“三系”线粒体DNA的AP—PCR指纹图谱

为了研究水稻（Ｏｒｙｚａ ｓａｔｉｖａ Ｌ．）细胞质雄性不育（ＣＭＳ）与线粒体基因组的关系,应用ＡＰ－ＰＣＲ 分析,用７ 个任意单引物对６ 种水稻品系线粒体ＤＮＡ 进行了扩增。水稻线粒体ＤＮＡ 的ＡＰ－ＰＣＲ 产物可分为三种类型：（１）所有供试品系均能扩增的片段,它们代表了线粒体ＤＮＡ 在进化上的保守性序列。有４ 个引物检测到这类片段。（２）２ 个以上水稻品系共同出现而在全部供试材料间存在差异的扩增片段,这类片段是检测水稻线粒体ＤＮＡ多态性的主要来源。（３）一种细胞质类型所特有的扩增片段,从引物Ｒ２ 和Ｖ５ 的扩增产物中发现了这类片段,它们可能与ＣＭＳ有关联。另外,ＷＡ型不育系珍汕９７Ａ 与其杂种之间在６ 个引物的扩增图谱上均存在不同程度的差异,说明两者的线粒体ＤＮＡ序列结构可能存在某种差别     

植物乳杆菌谷氨酸脱羧酶催化pH范围的理性改造及高效转化生产g-氨基丁酸

γ-氨基丁酸可由谷氨酸脱羧酶(glutamate decarboxylase, GAD)催化谷氨酸一步合成,反应体系成分简单、环境友好。然而,绝大多数GAD酶催化pH偏酸性且反应范围狭小,需要加入无机盐维持最适催化环境,增加了生产附加成分。此外,随着产物γ-氨基丁酸的生成,溶液pH会逐渐上升,不利于GAD酶的持续转化。本研究首先从实验室保藏的一株高产γ-氨基丁酸的植物乳杆菌(Lactobacillus plantarum)中克隆得到谷氨酸脱羧酶LpGAD,基于酶蛋白表面电荷修饰,选择9个位点进行定点突变及组合突变,酶学性质表征结果显示三突变体LpGAD^{S24R/D88R/Y309K}在催化pH区间内酶活力整体提高,尤其拓宽了在偏中性pH 6.0下的酶活,为野生酶的1.68倍。接下来,通过分子动力学模拟解析了酶活提高的机理。此外,将Lpgad与Lpgad^{S24R/D88R/Y309K}突变基因分别在谷氨酸棒杆菌(Corynebacterium glutamicum) E01中过表达,通过优化确定了摇瓶最适转化条件为反应温度40 ℃,菌体量OD₆₀₀=20,底物L-谷氨酸100.0 g/L,5-磷酸吡哆醛添加量为100 μmol/L。5 L发酵罐中,不调节pH,通过分批投料底物L-谷氨酸,γ-氨基丁酸产量高达402.8 g/L,较对照菌株提高了1.63倍。本研究成功拓宽了LpGAD的pH催化范围及酶活,提高了γ氨基丁酸的转化效率,为实现其规模化工业生产奠定了基础。     

理解运动行为抑制调控的新视角：乙酰胆碱门控氯离子通道受体

Acetylcholine, the first identified neurotransmitter, plays crucial roles in various brain functions. One well-known case is its involvement as an activating neurotransmitter in the regulation of locomotion. However, its inhibitory regulatory role, particularly in locomotion, remains poorly understood. In a study conducted by Polat et al., the authors investigated the inhibitory role of acetylcholine in locomotion in C. elegans. In this organism, the acetylcholine-gated chloride channel receptor consists of four subunits. The authors thoroughly examined the loss-of-function of each subunit in movement regulation. Interestingly, the mutant worms were still capable of performing various movements such as forward, backward crawling, and turning, suggesting that the overall movement was not significantly affected. However, quantitative behavior analysis revealed subtle yet significant differences in the timing and postures of the movement in these mutants. Furthermore, the authors employed optogenetics to stimulate a specific neuron involved in backward crawling and demonstrated that the loss-of-function of the receptors in individual neurons affects the transitioning between locomotion modes. This work provides evidence for the inhibitory regulatory role of acetylcholine in locomotion. The loss-of-function of acetylcholine-gated chloride channel receptors likely disrupts the balance of neuronal and circuit physiology, thereby affecting the regulation of locomotion. Moreover, this study highlights the powerful role of quantitative behavior analysis in discovering and understanding more sophisticated functions of neural circuits.