文心兰浅绿条纹突变体的生理生化及叶绿素荧光特性研究

以文心兰浅绿条纹突变体为材料,分析叶片光合色素含量和组成、叶绿素合成前体物质含量以及叶绿素荧光参数的变化,观察突变体叶绿体超微结构的改变,以探寻其叶色变异的生理基础。结果表明:(1)突变体叶绿素a(Chl a)、叶绿素b(Chl b)、类胡萝卜素(Car)和总叶绿素(Chl)含量分别比叶色正常植株显著降低了37.1%、34.0%、30.8%和36.3%。(2)突变体叶绿素生物合成受阻于胆色素原(PBG)到尿卟啉原Ⅲ(UrogenⅢ)的反应步骤。(3)突变体叶绿体发育存在明显的缺陷,基粒数目及基粒片层的垛叠层数明显减少,嗜锇颗粒及囊泡较多。(4)突变体初始荧光(Fo)比正常植株高39%,最大荧光(Fm)、最大光化学效率(Fv/Fm)、PSⅡ有效光化学效率(Fv′/Fm′)和PSⅡ实际光化学效率(ΦPSⅡ)均显著低于正常植株,但光化学淬灭系数(qP)和非光化学淬灭系数(NPQ)与正常植株无显著差异。研究结果说明,文心兰叶绿素生物合成受阻和叶绿体结构发育不良,导致叶绿素的含量下降,致使突变体叶片呈现浅绿条纹,光能利用率降低。     

Hormonal regulation of fruit set, parthenogenesis induction and fruit expansion in Japanese pear

The effects of applied gibberellins (GAs), GA₁, GA₃, GA₄ and GA₇ with a cytokinin, N-(2-chloro-4-pyridyl)-N′-phenylurea (CPPU) and indole-3-acetic acid (IAA) on fruit set, parthenogenesis induction and fruit expansion of a number of Rosaceae species were assessed. These included Japanese pear cv. ‘Akibae’ (self-compatible) and cv. ‘Iwate yamanashi’ (a seedless cultivar). Other Rosaceae species (Pyrus communis, Chaenomeles sinensis, Cydonia oblonga, and Malus pumila) were also investigated. GA₄, GA₇ and CPPU are very effective in inducing parthenocarpic fruit growth, whereas GA₁, GA₃ and IAA, have no ability to induce parthenogenesis in Japanese pear. GA₄- and GA₇-induced parthenocarpic fruit tended to be smaller in size, higher in flesh hardness, and showed advanced fruit ripening in comparison to pollinated fruit and to parthenocarpic fruit induced by CPPU. GA₄- and GA₇-induced parthenocarpic fruit also had an increased pedicel length and fruit shape index and also showed a slight protrusion of the calyx end. CPPU, GA₄ and GA₇ alone or combination with uniconazole were also active in inducing parthenogenesis in three other Rosaceae species, although final fruit set was extremely low. GA₁ was essentially inactive in promoting fruit expansion unlike the other bioactive GAs, whose effectiveness in promoting fruit cell expansion was as follow: GA₄ ≈ GA₇ > GA₃ > GA₁.     

湖北海棠实生树童区与成年区基因组DNA的RAPD研究

本试验以具无融合生殖特性的１４年生湖北海棠实生树为试材,对其童区和成年区的叶片基因组ＤＮＡ进行ＲＡＰＤ分析。结果显示：从１５０个引物中由Ｐ７０１从童区叶片基因组ＤＮＡ中扩增出１个约２．１ｋｂ的片段,成年区基因组ＤＮＡ中未能扩增出该片段。文中对阶段转变的机理及基因组ＤＮＡ多态性的原因作了讨论。     

北京市水果消费的生态足迹距离研究

采用生态足迹距离指标方法体系,对2009年至2012年间北京市水果消费的生态足迹距离进行研究。结果表明4年间:跨区转移的生态承载力质量距离,由2009年的11.5×10~8t km逐年增加到了2012年的17.01×10~8t km,共增加了47.91%;生态足迹距离则相对稳定在886.66 km至1073.55 km之间;人均生态足迹距离,总体上由2009年的4.39×10~4km增加到2012年的5.55×104km,共增加了26.42%。从类别的视角,年均生态足迹距离最大的是香蕉(2072 km),最小的是苹果(476 km);年均跨区转移的生物承载力质量距离,最大的是西瓜(4978×10~8kg km),最小的是香蕉(518×10~8kg km);而4年平均人均生态足迹距离,最大的是西瓜(17.7×10~4km),最小的是香蕉(1.92×10~4km)。快速城市化阶段的北京,对外生态依赖范围也迅速扩大,并高于人口增加的速率。     

基于生态系统评价的山水林田湖草生态保护与修复体系构建研究——以乌梁素海流域为例

山水林田湖草系统保护与修复工程实施的重要目标是维护和提升区域生态系统服务。从乌梁素海流域山水林田湖草的生态现状与功能出发,对乌梁素海流域水土流失、土地沙化等生态敏感性及土壤保持、水源涵养、生物多样性等生态功能重要性进行系统评价,形成基于生态敏感性和生态功能重要性相结合的空间格局评价结果。以维护和提升人类福祉所需的重要生态系统服务为目标,以乌梁素海流域生态敏感性和生态功能重要性相结合的空间格局评价结果为基础,制定了“一中心、二重点、六要素、七工程”的乌梁素海山水林田湖草生态保护与修复体系,并基于此将乌梁素海流域生态保护修复分为6个主要治理区域,形成“四区、一带、一网”的生态安全格局,通过具体工程实施,流域生态环境质量和生态服务能力将取得明显提升,防风固沙能力有效增强,生物多样性持续改善,水环境质量稳定达标,生态系统的稳定性明显加强。通过乌梁素海流域的分析案例为流域山水林田湖草生态保护与修复关键区域的识别提供了定量分析方法,为流域尺度构建生态安全格局、实现山水林田湖草系统保护和修复提供思路和途径。     

根区交替控制灌溉条件下玉米根系吸水规律

为了阐明根区交替控制灌溉(CRDAI)条件下玉米根系吸水规律,通过田间试验,在沟灌垄植模式下采用根区交替控制灌溉研究玉米根区不同点位(沟位、坡位和垄位)的根长密度(RLD)及根系吸水动态。研究表明,根区土壤水分的干湿交替引起玉米RLD的空间动态变化,在垄位两侧不对称分布,并存在层间差异;土壤水分和RLD是根区交替控制灌溉下根系吸水速率的主要限制因素。在同一土层,根系吸水贡献率以垄位最大,沟位最低;玉米营养生长阶段,10—30 cm土层的根系吸水速率最大;玉米生殖生长阶段,20—70 cm为根系吸水速率最大的土层,根系吸水贡献率为43.21%—55.48%。研究阐明了交替控制灌溉下根系吸水与土壤水分、RLD间相互作用的动态规律,对控制灌溉下水分调控机理研究具有理论意义。     

蝴蝶兰几丁质酶基因的克隆及表达特性分析

利用RT-PCR及RACE技术,克隆到蝴蝶兰1个几丁质酶基因PhCHT(GenBank登录号为KT992851),该基因cDNA全长1 210bp,包含37bp的5′-UTR、933bp开放阅读框和240bp 3′-UTR,编码310个氨基酸;该蛋白为糖苷水解酶第19家族成员,兼具有溶菌酶活性;生物信息学分析显示,该蛋白具N-端信号肽和跨膜结构,为胞外分泌蛋白;该蛋白与海枣、谷子、油棕和拟南芥的几丁质酶类似蛋白相近,并且在系统进化树上与甘蔗和陆地棉的Ⅶ类几丁质酶同属一个分支。PhCHT基因的表达分析表明,PhCHT在蝴蝶兰营养器官和生殖器官中均有表达,根中表达量最高;13℃/8℃低温处理3、6、9和15d时该基因的表达被抑制,4℃低温处理1、2和4h表达量升高。研究表明,PhCHT基因能够响应短期的冷胁迫。研究结果为进一步研究蝴蝶兰几丁质酶的系统进化及抗性育种奠定了基础。     

NDV诱导HeLa细胞发生核糖体应激及对翻译起始复合体的影响

[目的]研究新城疫病毒(Newcastle disease virus,NDV) HBUN/LSRC/F3株(以下简称NDV F3)诱导宫颈癌细胞(HeLa)发生核糖体应激后对eIF2α介导的翻译起始复合体eIF4F的调控作用。[方法]流式细胞术及CCK-8检测细胞凋亡;实时荧光定量PCR (quantitative real-time polymerase chain reaction,qRT-PCR)检测c-Myc基因表达;流式细胞术分析细胞周期;Western blotting技术检测c-Myc、RPS7、Bcl-2、NP、eIF4E及eIF2α蛋白的表达;Western blotting和免疫荧光染色技术检测NP、eIF4E蛋白定位。[结果]与阴性对照组相比,NDV F3抑制HeLa细胞增殖并诱导细胞凋亡。细胞周期中G₀/G₁期出现停滞,c-Myc表达呈时间依赖性抑制,c-Myc与Bcl-2蛋白表达量在0-48 h内逐渐下降,NP蛋白在24 h时生成并逐渐增加,RPS7、eIF4E和eIF2α蛋白含量在0-48 h内呈先增加后降低趋势。Western blotting定位分析及激光共聚焦显微镜结果显示NP蛋白主要存在细胞质中,NP与eIF4E存在共定位现象。[结论]NDV F3诱导HeLa细胞凋亡并引发核糖体应激反应,NP与eIF4E相互作用而抑制eIF2α介导的翻译起始复合体eIF4F形成,阻断其与宿主mRNA之间的联系,同时促进NDV F3 mRNA的翻译,最终造成宿主蛋白翻译抑制。     

当归延伸因子AsEF 1β基因的克隆及胁迫应答分析

延伸因子1β(EF 1β)是蛋白质生物合成过程中肽链延长必需的调节因子之一。该研究采用同源克隆和RACE扩增技术克隆当归EF 1β基因序列,分析该基因序列特征、蛋白结构特点及UV B辐射胁迫下的组织响应表达,以揭示当归栽培生境变迁过程中对UV B胁迫适应的分子机制。结果显示：(1)成功克隆获得当归EF 1β基因全长序列(950 bp),编码225个氨基酸,命名为AsEF 1β(GenBank登录号：MG736314);AsEF 1β蛋白的分子量为24.5 kD,理论等电点为4.48,属亲水性氨基酸,在其C末端具有一个EF 1B超蛋白家族的典型结构域和保守区,鸟嘌呤核苷酸交换结构域;其氨基酸序列与同为伞形科的胡萝卜氨基酸序列相似性最高,达93%。(2)qRT PCR分析结果显示,AsEF 1β基因在当归根部的表达量显著高于茎和叶(P<0.05);UV B辐射胁迫下,茎及叶中的表达量均上调,分别是自然光照处理的2.43和3.76倍。研究表明,AsEF 1β基因可能参与当归对UV B辐射胁迫的适应过程,为深入研究其在药用植物生长发育、逆境抗性形成及药效物质的生物合成代谢过程的生态调控奠定了基础。     

13C-photosynthate accumulation in Japanese pear fruit during the period of rapid fruit growth is limited by the sink strength of fruit rather than by the transport capacity of the pedicel

In Japanese pear, the application of GA3+4 during the period of rapid fruit growth resulted in a marked increase in pedicel diameter and bigger fruit at harvest. To elucidate the relationship between pedicel capacity and fruit growth and to determine the main factor responsible for larger fruit size at harvest, fruit growth and pedicel vascularization after GA application were examined and the carbohydrate fluxes were monitored in a spur unit by non-invasive techniques using 13C tracer. Histological studies of fruit revealed that GA increased the cell size of the mesocarp but not the cell number and core size. The investigation of carbon partitioning showed that an increase in the specific rate of carbohydrate accumulation in fruit or the strength of fruit should be responsible for an increase of fruit weight in GA-treated trees. Observation of pedicel vascularization showed that an increase in pedicel cross-sectional area (CSA) by GA application mainly resulted from phloem and xylem CSA, but it is unlikely that an increase in the transport system is the direct factor for larger fruit size. Therefore, it can be concluded that larger fruit size resulting from GA application during the period of rapid fruit growth caused an increase in the cell size of the mesocarp and increased carbon partitioning to the fruit. Although GA is closely involved with pedicel vascularization, it seems that photosynthate accumulation in fruit is limited by the sink strength of fruit rather than by the transport capacity of the pedicel.