水稻矮缩病毒第10号片段编码区的cDNA克隆及序列分析

采用聚合酶链式反应技术,扩增了水稻矮缩病毒(RDV)基因组第10号片段的编码序列,该片段编码病毒的非结构蛋白。对扩增产物进行了克隆和限制性内切酶分析,并绘制了物理图谱。克隆片段大小为1150 bp,含Sac I、Hind III、Nde I、BamH I、Sai I 等酶切位点,引物设计时还在该片段两侧增加了Bgl II和 EcoR I 切点,以便克隆到植物中间载体质粒。利用上述酶切位点对该片段进行了亚克隆和序列分析,结果表明,本研究克隆的RDV中国流行林基因组第10号片段的编码区与日本流行株的相应区域比较,核酸的同源率为96.03％,编码的氨基酸的同源率为97.17％。     

剑麻蛋白酶的分离纯化及其部分特性的研究

采用乙醇分步沉淀和 DEAE-纤维素柱层析,可从剑麻 Agave sisalana 叶汁中分离到一个均一的蛋白酶组分,其结晶为平面六边形。该酶可为半胱氨酸和 EDTA 所激活,受 PCMB(p-chloromercuribenzoatc)、DTNB(5,5′-dithiobis(2-nitrobenzoic acid))及 Hg~(2 )、Ag~( )、Cu~(2 )的可逆抑制和碘乙酸(pH 7.5)的不可逆抑制。该酶以酪蛋白为底物时,酶反应的最适 pH 值约为7.5,最适温度为50℃,Km 值为0.0625%酪蛋白,该酶在45℃(含45℃)以下较为稳定。且在6.0—10.0的 pH 值范围内稳定。     

脉叶罗汉松化学成分的研究

从脉叶罗汉松(Podocarpus neriifolius D.Don)的枝叶中分离到11种化合物,根据光谱数据和物理常数测定,分别鉴定为正三十四烷醇(1)、β-谷甾醇硬脂酸酯(2)、β-谷甾醇(3)、金松双黄酮(sciadopitysin,3)、罗汉松双黄酮 B(podocarpusflavone B,12)、罗波斯塔黄酮-7″-甲醚(robustaflavone-7″-methyl ether,13)罗汉松双黄酮 A(podocarpusflaveone A,14)、罗波斯塔黄酮(robustaflavone,15)、对羟基苯甲酸(p-hydroxyl-benzoic acid,16)、2″-O-鼠李糖扫帚黄甙(2″-O-rhamnosylscoparin,23)和2″-O-鼠李糖牡荆黄甙(2″-O-rhamnosylvitexin,24)。其中,化合物23和24为首次从罗汉松科分得的化合物,化合物8、13和15首次从该植物分离到。     

野芹菜体细胞胚胎发生早期变化的细胞学研究

通过光学与电子显微镜观察研究了野芹菜(Angelica polymorpha Maxim.)叶柄外植体胚性细胞的起源与原胚状体的发生。叶柄切段植入 MS 2mg/L2,4-D 0.25 mg/L KT固体培养基后,以DNA合成和细胞分裂为指标,判明了胚状体发生与紧贴维管束的鞘细胞层密切相关;鞘细胞通过有丝分裂形成多层结构的细胞群,它们仍含大液泡及薄层胞质,成片被覆在维管束表面;胚性细胞团即不同步地发生在该多层组织较内层的局部位点上,细胞具大核,胞质稠密,经持续有丝分裂发展成大小不同呈瘤状突起的原胚状体。伴随着鞘细胞的剧烈变化,韧皮部薄壁细胞亦分裂增殖,原有筛管变形衰退,部分新增殖的细胞分化为新筛分子;木质部中,原导管束附近朝向韧皮部一侧的部分薄壁细胞亦进一步分化为孔纹导管。外植体中维管系统的再次分化,显然是与输导功能强化以适应原胚状体发生时对营养物质的大量需求有关。     

运用α-吡啶羧酸筛选水稻抗稻瘟病细胞变异体的研究

利用α-吡啶羧酸为胁迫因子,研究了花药培养筛选水稻(Oryza sativa L.)抗稻瘟病(Pyricularia oryzae Cav.)细胞变异体的效果。α-吡啶羧酸可抑制水稻花药(粉)愈伤组织的形成与生长,用40mg-L α-吡啶羧酸进行诱导、继代和分化筛选,可获得抗性愈伤组织并再生绿苗,但仅有一半绿苗自然加倍结实,并具备对稻瘟病孢子悬浮液的抗性。经两代选择与鉴定,获得了抗稻瘟病 ZA_1和 ZB_(11)小种、但感 ZG_1小种的变异体2-07和4-091。     

Phytopathogenic bacteria utilize host glucose as a signal to stimulate virulence through LuxR homologues

Chemical signal-mediated biological communication is common within bacteria and between bacteria and their hosts. Many plant-associated bacteria respond to unknown plant compounds to regulate bacterial gene expression. However, the nature of the plant compounds that mediate such interkingdom communication and the underlying mechanisms remain poorly characterized. Xanthomonas campestris pv. campestris (Xcc) causes black rot disease on brassica vegetables. Xcc contains an orphan LuxR regulator (XccR) which senses a plant signal that was validated to be glucose by HPLC-MS. The glucose concentration increases in apoplast fluid after Xcc infection, which is caused by the enhanced activity of plant sugar transporters translocating sugar and cell-wall invertases releasing glucose from sucrose. XccR recruits glucose, but not fructose, sucrose, glucose 6-phosphate, and UDP-glucose, to activate pip expression. Deletion of the bacterial glucose transporter gene sglT impaired pathogen virulence and pip expression. Structural prediction showed that the N-terminal domain of XccR forms an alternative pocket neighbouring the AHL-binding pocket for glucose docking. Substitution of three residues affecting structural stability abolished the ability of XccR to bind to the luxXc box in the pip promoter. Several other XccR homologues from plant-associated bacteria can also form stable complexes with glucose, indicating that glucose may function as a common signal molecule for pathogen–plant interactions. The conservation of a glucose/XccR/pip-like system in plant-associated bacteria suggests that some phytopathogens have evolved the ability to utilize host compounds as virulence signals, indicating that LuxRs mediate an interkingdom signalling circuit.     

The Relationship Between Phytoplankton Diversity and Ecosystem Functioning Changes with Disturbance Regimes in Tropical Reservoirs

Ecosystems - The relationship between species diversity and ecosystem functioning is one of central topics in modern ecology, but variable and controversial patterns have been found depending on...