千斤拔多糖的提取纯化及其结构鉴定

利用正交试验考察千斤拔多糖的提取工艺,并比较脱蛋白方法中的Sevag法和三氯乙酸法的纯化效果,总糖含量测定采用苯酚-硫酸法,蛋白质含量测定采用考马斯亮蓝法;采用DEAE-52纤维柱法来分离多糖,并运用HPLC色谱来分析千斤拔多糖中的单糖成分。结果表明:经正交试验得出千斤拔多糖的最佳提取条件为时间2.5 h,料液比为1∶30,温度80℃,其多糖得率为8.558%。对比两种脱蛋白的方法,Sevage法萃取3次时蛋白的脱除效果最好。经DEAE-52纤维柱来分离多糖共分得7个组分。经HPLC色谱鉴定出有葡萄糖,甘露糖和阿拉伯糖,主要单糖成分为葡萄糖。     

蕨麻愈伤组织原生质体制备条件的优化

以青海‘蕨麻4号’诱导培养的愈伤组织为材料,采用4因素3水平L9(34)正交实验,研究酶类组合、酶解时间、甘露醇浓度及离心速度等主要因素对蕨麻原生质体分离的影响,建立高效、稳定的蕨麻原生质体分离体系,为进一步通过原生质体融合、基因工程等方法对蕨麻进行品种改良奠定基础。结果表明:各因素对蕨麻原生质体产量的影响顺序为:酶类组合酶解时间甘露醇浓度离心速度;青海‘蕨麻4号’愈伤组织原生质体的最适酶解条件为:2.0%纤维素酶+0.75%果胶酶,40r/min振荡酶解10h,甘露醇浓度为0.5mol/L,离心转速为1 000r/min时原生质体的产量达最大(8.96×10~5 cells/g),活力为92.77%。     

氮、磷、钾肥配施对桂花品种'金玉台阁'开花性状及叶片中叶绿素和营养元素含量的影响

以桂花品种'金玉台阁'(Osmanthus fragrans'Jinyu Taige')盆栽苗为供试材料,采用"3414"肥料效应试验设计方案,研究了不同单株施用量CO(NH2)2(0.0、1.0、2.0和3.0 g)、NH4H2PO4(0.0、1.5、3.0和4.5 g)和KCl(0.0、0.5、1.0、1.5 g)对秋冬生长期(2014年10月至2015年2月)'金玉台阁'开花性状及叶片中叶绿素和营养元素的影响进行了比较和分析,并筛选出适宜的氮、磷、钾肥施用量.结果表明:与CK〔CO(NH2)2、NH4H2PO4和KCl的单株施用量均为0.0 g〕组相比,各氮、磷、钾肥配施处理组'金玉台阁'的单株产花量、花瓣相对含水量、花径以及叶片中叶绿素、全氮、全磷和全钾的含量总体上显著升高.CO(NH2)2单株施用量对'金玉台阁'单株产花量、叶片中叶绿素含量和全氮含量的影响最大,NH4H2PO4单株施用量对这3个指标的影响次之;NH4H2PO4单株施用量对'金玉台阁'叶片中全磷含量的影响最大;KCl单株施用量对'金玉台阁'花瓣相对含水量、花径及叶片中全钾含量的影响最大.在秋冬生长期内叶片中叶绿素含量呈先降低后升高的趋势,均在12月份降至最低值.通过建立'金玉台阁'单株产花量(y)与CO(NH2)2、NH4 H2 PO4和KCl的单株施用量(分别为xN、xP和xK)间的肥料效应模型,得到的三元二次肥料效应模型为y=1.2027+0.7561×xN+0.2632×xP+0.4590×xK-0.2761×xN2-0.1201×xP2-0.5007×xK2+0.1901×xN×xP-0.0960×xN×xK+0.1185×xP×xK.以单株产花量为目标,'金玉台阁'的CO(NH2)2、NH4 H2 PO4和KCl的最佳单株施用量分别为2.58、3.56和0.86 g.     

Improving monitoring tools for spotted wing drosophila,Drosophila suzukii

Drosophila suzukii (Matsumura) (Diptera: Drosophilidae) were trapped in the field using colored plastic sphere traps coated with insect Tangle‐trap. Red and black spheres captured significantly more D. suzukii than white spheres. Translucent deli‐cup traps deployed in cherry orchards and baited with yeast, the Alpha Scents lure, or the Scentry lure captured significantly more flies than the Trécé lure and Suzukii bait; all attractants had poor selectivity for D. suzukii. No‐choice evaluations of attractants conducted in field cages corroborated the cherry orchard field study, though translucent deli‐cup traps provisioned with the yeast bait captured significantly more flies than those baited with the Alpha Scents lure. Red sphere traps baited with the Scentry lure captured 3–6× more flies than the deli‐cup trap baited with the same lure, and 3–4× more flies than the deli‐cup trap baited with yeast bait, demonstrating that a trap integrating both visual and olfactory cues is a superior tool for monitoring D. suzukii. Moreover, this simple sticky, dry trap design requires far less labor and maintenance than does a liquid‐based deli‐cup trap.     

Design,synthesis and biological evaluation of 1,3-dihydroxyxanthone derivatives: Effective agents against acetylcholinesterase

The present work concerns the rational design and development of new inhibitors of acetylcholinesterase (AChE) based on the privileged xanthone scaffold. In order to understand and rationalize the mode of action of these target structures a theoretical study was initially conducted. From the results of rational design, a new variety of amphiphilic xanthone derivatives were synthesized, structurally characterized and evaluated as potential anti-Alzheimer agents. The results showed that most of the synthesized compounds exhibited high AChE inhibitory activity at the micromolar range (IC₅₀, 0.46–12.09 μM). The synthetic xanthone 11 showed the best inhibitory effect on AChE and a molecular modeling study revealed that 11 targeted both the catalytic active site (CAS) and the peripheral anionic site (PAS) of AChE. Therefore, this compound could be considered as a potential lead compound towards new drugs for the treatment of Alzheimer’s disease.     

Perovskite Chalcogenides with Optimal Bandgap and Desired Optical Absorption for Photovoltaic Devices

Solar cells with organic‐inorganic lead halide perovskites have achieved great success and their power conversion efficiency (PCE) has reached to 22.1%. To address the toxicology of lead element and some stability issues associated with the organic‐inorganic lead halide perovskites, inorganic lead‐free perovskites have gained more attentions from the photovoltaic research community. Herein, a series of chalcogenide perovskites are proposed as optical absorber materials for thin‐film solar cells. SrSnSe₃ and SrSnS₃ are predicted to be direct bandgap semiconductors with the bandgap value being within the optimal range of 0.9–1.6 eV. Both SrSnSe₃ and SrSnS₃ not only exhibit good optical absorption properties and carrier mobility, but also possess flexible bandgaps that can be continuously tuned within the grange of 0.9–1.6 eV via the element‐mixing strategy, thereby render both perovskites as promising candidates for photovoltaic applications.     

Maximizing the stability of metabolic engineering‐derived whole‐cell biocatalysts

A systematic and powerful knowledge‐based framework exists for improving the activity and stability of chemical catalysts and for empowering the commercialization of respective processes. In contrast, corresponding biotechnological processes are still scarce and characterized by case‐by‐case development strategies. A systematic understanding of parameters affecting biocatalyst efficiency, that is, biocatalyst activity and stability, is essential for a rational generation of improved biocatalysts. Today, systematic approaches only exist for increasing the activity of whole‐cell biocatalysts. They are still largely missing for whole‐cell biocatalyst stability. In this review, we structure factors affecting biocatalyst stability and summarize existing, yet not completely exploited strategies to overcome respective limitations. The factors and mechanisms related to biocatalyst destabilization are discussed and demonstrated inter alia based on two case studies. The factors are similar for processes with different objectives regarding target molecule or metabolic pathway complexity and process scale, but are in turn highly interdependent. This review provides a systematic for the stabilization of whole‐cell biocatalysts. In combination with our knowledge on strategies to improve biocatalyst activity, this paves the way for the rational design of superior recombinant whole‐cell biocatalysts, which can then be employed in economically and ecologically competitive and sustainable bioprocesses.