牛TLR4基因生物信息学分析

为了更加深入地了解牛TLR4基因的功能、结构及与该基因有关联的疾病识别及其致病机理,利用牛TLR4基因的氨基酸序列对其编码蛋白的基本理化性质、蛋白质译后的磷酸化位点和糖基化位点以及跨膜结构域和蛋白质结构进行预测。结果显示,牛TLR4基因一共编码841个氨基酸,负电荷残基总和(Asp+Glu)为84,正电荷残基总和(Arg+Lys)为76,不稳定指数小于40,表明该基因编码产物稳定性较好。在该基因整个编码产物中,亲水氨基酸占比较多,平均分值为-0.011,由此得知TLR4基因编码的蛋白质是一种易溶蛋白。有9个潜在的N-糖基化位点;78个磷酸化位点以及存在一个跨膜蛋白和存在信号肽,其切割位点在第25和第26个氨基酸之间。蛋白质的二、三级结构预测结果显示,二级结构和三级结构均由α-螺旋、β-折叠和无规则卷曲组成,其在生物合成、基因表达与调控等方面有重要作用。本研究结果可为牛TLR4基因深入研究提供理论基础。     

虾肽有机肥与磷肥配施对苹果产量和品质的影响

[目的]研究虾肽有机肥(SPOF)与磷肥配施的协同增效作用。[方法]采用田间小区试验,设尿素1.4 kg/株(CK)、尿素1.4 kg/株+农家肥50 kg/株+磷酸二氢钾1.54 kg/株(TT1)、尿素1.4 kg/株+SPOF 30 kg/株+磷酸二氢钾1.54 kg/株(TT2)、尿素1.4 kg/株+SPOF 30 kg/株+普通过磷酸钙0.83 kg/株+磷酸二氢钾1.25 kg/株(TT3)。[结果]各处理的产量TT3>TT2>TT1>CK,且TT3达到了显著水平;TT3的品质指标,即可溶性固形物、维生素C、蔗糖、葡萄糖以及硬度均达到了显著水平。[结论]TT3处理虾肽有机肥和磷肥(SSP+KH2PO4)协同将其效力发挥到最大。     

Intensive organic vegetable production increases soil organic carbon but with a lower carbon conversion efficiency than integrated management

Intensive vegetable production in greenhouses has rapidly expanded in China since the 1990s and increased to 1.3 million ha of farmland by 2016, which is the highest in the world. We conducted an 11‐year greenhouse vegetable production experiment from 2002 to 2013 to observe soil organic carbon (SOC) dynamics under three management systems, i.e., conventional (CON), integrated (ING), and intensive organic (ORG) farming. Soil samples (0–20 and 20–40 cm depth) were collected in 2002 and 2013 and separated into four particle‐size fractions, i.e., coarse sand (> 250 µm), fine sand (250–53 µm), silt (53–2 µm), and clay (< 2 µm). The SOC contents and δ¹³C values of the whole soil and the four particle‐size fractions were analyzed. After 11 years of vegetable farming, ORG and ING significantly increased SOC stocks (0–20 cm) by 4008 ± 36.6 and 2880 ± 365 kg C ha^?1 y^?1, respectively, 8.1‐ and 5.8‐times that of CON (494 ± 42.6 kg C ha^?1 y^?1). The SOC stock increase in ORG at 20–40 cm depth was 245 ± 66.4 kg C ha^?1 y^?1, significantly higher than in ING (66 ± 13.4 kg C ha^?1 y^?1) and CON (109 ± 44.8 kg C ha^?1 y^?1). Analyses of ¹³C revealed a significant increase in newly produced SOC in both soil layers in ORG. However, the carbon conversion efficiency (CE: increased organic carbon in soil divided by organic carbon input) was lower in ORG (14.4%–21.7%) than in ING (18.2%–27.4%). Among the four particle‐sizes in the 0–20 cm layer, the silt fraction exhibited the largest proportion of increase in SOC content (57.8% and 55.4% of the SOC increase in ORG and ING, respectively). A similar trend was detected in the 20–40 cm soil layer. Over all, intensive organic (ORG) vegetable production increases soil organic carbon but with a lower carbon conversion efficiency than integrated (ING) management.     

龙眼DCL4的亚细胞定位分析及其对外源ABA和SA的响应

为了研究DlDCL家族中DlDCL4基因在龙眼中的功能,本研究通过氨基酸序列比对、系统发育进化树的构建、亚细胞定位验证、实时荧光定量PCR（qPCR）等方法,对其进行初步探究。结果表明：遗传进化分析显示,DCL4氨基酸序列在所选的物种间相似度高于50%,其中龙眼与甜橙（Citrus sinensis）的亲缘关系最近。在激光共聚焦显微镜观察下,洋葱细胞核发出绿色荧光,其他部位不发出荧光,表明龙眼DCL4蛋白定位于细胞核中。在24 h内,100 μmol/L的外源脱落酸（ABA）对 DlDCL4都有极显著的下调效果;100 μmol/L的水杨酸（SA）对其表达量有显著的上调效果,其中8 h时表达量最大,提示 DlDCL4对不同激素的响应效果不同且不同处理时长下响应效果也会有影响。     

不同季节高寒草甸牧草瘤胃发酵特性和体外消化率分析

本文旨在探讨不同生育时期高寒草甸牧草的牦牛瘤胃体外发酵参数及CH₄产量。通过测定返青期、青草期和枯草期3个生育时期牧草的营养品质、瘤胃发酵参数和CH₄产量。结果表明：青草期牧草总能（Gross energy，GE）、粗蛋白（Crude protein，CP）和粗脂肪（Ether extract，EE）等均显著高于返青期和枯草期（P<0.05）；青草期牧草在各发酵时间点的体外干物质消化率（Dry matter digestibility，DMD）、粗蛋白消化率（Crude protein digestibility，CPD）和有机物质消化率（Organic matter digestibility，OMD）均显著高于返青期和枯草期（P<0.05）；青草期牧草12，24和48 h瘤胃NH₃-N、乙酸、丙酸、异丁酸、丁酸和异戊酸含量显著高于返青期和枯黄期（P<0.05）；不同发酵时间牧草总产气量和CH₄产量变化规律为：返青期>青草期>枯草期。综上所述，青草期草地生物量最高，牧草营养品质和体外消化率最高，CH₄排放最低，瘤胃发酵模式最优。建议选择青草期牧草放牧。     

EPS364, a Novel Deep-Sea Bacterial Exopolysaccharide,Inhibits Liver Cancer Cell Growth and Adhesion

The prognosis of liver cancer was inferior among tumors. New medicine treatments are urgently needed. In this study, a novel exopolysaccharide EPS364 was purified from Vibrio alginolyticus 364, which was isolated from a deep-sea cold seep of the South China Sea. Further research showed that EPS364 consisted of mannose, glucosamine, gluconic acid, galactosamine and arabinose with a molar ratio of 5:9:3.4:0.5:0.8. The relative molecular weight of EPS364 was 14.8 kDa. Our results further revealed that EPS364 was a β-linked and phosphorylated polysaccharide. Notably, EPS364 exhibited a significant antitumor activity, with inducing apoptosis, dissipation of the mitochondrial membrane potential (MMP) and generation of reactive oxygen species (ROS) in Huh7.5 liver cancer cells. Proteomic and quantitative real-time PCR analyses indicated that EPS364 inhibited cancer cell growth and adhesion via targeting the FGF19-FGFR4 signaling pathway. These findings suggest that EPS364 is a promising antitumor agent for pharmacotherapy.     

纳米Fe3O4负载酸改性炭对水体中Pb2+、Cd2+的吸附

为探讨纳米Fe₃O₄负载联合硝酸改性椰壳炭对Pb²⁺、Cd²⁺单一及复合溶液的吸附特性，通过静态吸附实验，针对吸附剂的表面特性、投加量、溶液初始pH、吸附时间、重金属初始浓度等影响因素进行了探讨，应用等温吸附模型及吸附动力学模型对吸附特性进行了研究。结果表明，纳米Fe₃O₄负载酸改性炭比表面积较未改性椰壳炭增加了221.03 m²·g^-1，表面含氧官能团如O-H、C=O、C-O-C增加，芳香性增强，等电点提高至5.68。从经济效率角度考虑5 g·L^-1为合理吸附剂用量，pH为5.0时，吸附效果最好，吸附在4 h达到平衡。准二级动力学模型对吸附的拟合度更高，吸附主要是化学吸附，吸附由快速外扩散和颗粒内扩散共同作用，Pb²⁺、Cd²⁺的吸附分别更符合Langmuir和Freundlich等温吸附模型。纳米Fe₃O₄负载酸改性椰壳炭对Pb²⁺、Cd²⁺的最大吸附量（Q_m）分别达42.54 mg·g^-1和25.79 mg·g^-1，为未改性椰壳炭的1.87倍和2.23倍，复合溶液中Pb²⁺、Cd²⁺的Q_m分别为单一溶液的65.16%和54.21%，这揭示了离子共存条件下的吸附竞争现象。研究表明，纳米Fe₃O₄负载联合硝酸改性提高了椰壳炭对Pb²⁺、Cd²⁺的吸附能力，且Pb²⁺的吸附性能及吸附竞争性优于Cd²⁺。     

辛基酚对家蚕（Bombyx mori L.）生长发育的影响

为探讨辛基酚对鳞翅目模式昆虫家蚕生长发育的影响,使用添加0.01～0.08 g·kg~(-1)辛基酚(4-tert-octylphenol,4-t-OP)的人工饲料饲养家蚕(Bombyx mori L.),研究了4-t-OP对家蚕幼虫和蛹的生长发育速度、生长量、发育整齐度和生命力等影响。结果表明:连续取食0.01 g·kg~(-1)以上浓度4-t-OP的饲料,家蚕幼虫和蛹的生长发育速度(幼虫期和蛹期发育经过时间)、生长量(幼虫期体质量和蛹期茧层量)、生命力(3龄起蚕绝食生命时数、4龄起蚕结茧率、蚕茧的死笼率和羽化率)等都明显下降,抑制眠蚕体质量。4-t-OP对家蚕幼虫生长发育后期、化蛹及羽化等发育变态期的影响更加明显,其在家蚕体内可能有累积效应。添食0.08 g·kg~(-1)4-t-OP的家蚕不能完成生活史。研究表明,4-t-OP对家蚕生长发育毒性影响有显著的浓度效应和时间效应。     

拟南芥DUF647家族成员RUS4植物表达载体的构建及亚细胞定位

ROOT UV-B SENSITIVE4 (RUS4)是拟南芥DUF647蛋白家族的一个功能未知的成员。RUS1和RUS2曾经报道和根UV-B-感应途径相关联,并在拟南芥早期幼苗形态发生和发育中发挥重要作用。为了探究RUS4的分子功能,本研究对RUS4蛋白进行了亚细胞定位分析。首先,我们通过Gateway TOPO载体系统,构建了融合蛋白表达载体pMDC83-RUS4;然后,通过农杆菌介导的花苞转化法,获得了转化pMDC83-RUS4的转基因拟南芥株系;对转基因植物叶肉原生质体的荧光显微镜观察显示,RUS4-GFP信号与叶绿体的自发荧光共定位,说明RUS4蛋白定位叶绿体中。该结果为进一步研究RUS4的分子功能奠定了良好的基础。