青藏高原Bian蓄,车前叶绿体超微结构研究

对生长在青藏高原两个海拔高度的Ｂｉａｎ蓄和车前叶绿体进行超微观察表明：１．高海拔地区Ｂｉａｎ蓄的叶绿体发生变形,叶绿体的长度缩短、厚度增加,被膜模糊,而车前叶绿体的形态变化不大。２．高海拔地区的两种植物叶绿体的基粒片层和基质片层都呈现肿胀现象,尤以Ｂｉａｎ蓄为显著。３．高海拔地区的两处植物叶绿体中基粒片层的叠垛程度均比低海拔地区的高。以上特征是青藏高原特殊的高寒生态条件长期影响的结果。     

不同海拔火绒草叶绿体超微结构的比较

利用透射电镜对生长于青藏高原东北部3个不同海拔地区(2300m、2700m和3800m)的火绒草叶绿体超微结构进行了比较观察。结果发现,随着海拔的升高,叶绿体结构差异明显。海拔2300m处,叶绿体呈扁船形,沿细胞壁分布,基粒片层排列整齐,片层可达32层;海拔2700m处,叶绿体呈扁船形,沿细胞壁分布,基粒片层排列不规则,片层下降到十几层,类囊体出现轻微膨大;海拔3800m处,叶绿体呈圆形,位于细胞中央,基粒片层则严重扭曲,片层只有几层,类囊体膨大严重,出现脂质小球。研究表明,火绒草叶绿体结构的变化是对逆境的一种适应,是青藏高原特殊生态条件长期胁迫的结果。     

油菜细胞质雄性不育系及其保持系叶绿体超微结构的研究

本工作以油菜细胞质雄性不育系及其保持系为材料,比较观察了叶肉细胞叶绿体超徽结构之间的差异,发现保持系的叶绿体片层系统由基粒及基质两部分组成,片层的排列比较整齐;但是,不育系叶绿体类囊体片层中大多数基粒的垛叠层数明显减少,同时连接基粒与基粒之间的基质片层变细,以致断裂,从而造成片层系统排列上一定程度的紊乱。这一现象同育性改变有关,值得重视。     

盐胁迫下芦苇叶肉细胞超微结构的研究

对青藏高原柴达木盆地柯柯盐湖边盐碱地上生长的芦苇叶肉细胞的超微结构进行了研究,并以西宁地区非盐碱地上生长的芦苇作对照。结果表明：西宁地区的芦苇叶肉细胞的叶绿体呈椭圆形,其膜系统完整,基粒片层和基质片层发育良好。在盐碱地上生长的芦苇叶肉细胞的叶绿体呈圆形,叶绿体内出现较大的淀粉粒,并发现有线粒体嵌入叶绿体的现象。叶绿体的类囊体膨大,线粒体的嵴也有膨大的现象。在盐湖水中生长的芦苇叶肉细胞,叶绿体的类囊体排列紊乱、扭曲、松散。类囊体膜局部被破坏,部分类囊体膜解体,空泡化,甚至消失,一些溶解了的类囊体流进细胞质中。综上所述,芦苇叶肉细胞超微结构的变化是该植物适应柯柯盐湖地区盐渍、低温、低气压、强辐射等环境因子的结果。     

糜子不同生育时期不同叶位叶片超微结构研究

对糜子不同生育时期、不同叶位叶片进行电镜观察.结果显示:(1)在籽粒灌浆中期以前,叶肉细胞排列整齐,细胞间隙小,细胞中叶绿体、线粒体等细胞器含量多.叶绿体、线粒体基质含量浓厚,高基粒片层数增加,胞问连丝畅通;(2)在籽粒灌浆中期以后,叶片迅速衰老,细胞解体,细胞间出现间隙,叶绿体减少,叶绿体基粒片层、基质片层解体.嗜锇颗粒变大增多.胞间连丝受到阻碍.(3)不同生育时期不同叶位叶绿体的高基粒片层数差异较大,其中在灌浆中期各叶位叶绿体高基粒片层数最高,在各生育时期旗叶的为最大.     

青海湖盐碱湿地灰绿藜叶的形态解剖学研究

利用光学显微镜和透射电镜对生长于青海湖湖滨盐碱湿地的先锋植物灰绿藜（Chenopodium glaucum Linn.）及生长于甘肃兰州大学校园内中生环境对照灰绿藜叶片的显微、超微结构进行了比较观察研究。结果发现中生环境灰绿藜叶片较薄,有明显的栅栏与海绵组织分化;叶绿体呈椭圆形,基粒片层较发达且普遍含有淀粉粒。与对照相比,生长于高海拔湖滨盐碱湿地灰绿藜叶为等面叶,叶片厚,角质层厚,栅栏组织发达,气室明显,具表皮毛;线粒体较多,但嵴不发达,叶绿体呈扁船型沿着壁的边缘排列,叶绿体的基粒片层不发达且普遍含有脂质球,一些细胞中常出现大量的多层膜结构。研究结果表明2种生态型灰绿藜的形态结构已发生了深刻的变异,湖滨灰绿藜表现出适应区域的寒旱化的明显特征。     

达坂山蚤缀和裸茎金腰叶绿体超微结构的研究

对高山植物达坂山蚤缀和裸茎金腰叶绿体超微结构的研究表明,叶绿体和线粒体镶嵌很紧密;基粒和基质类囊体膨大,膨大的类囊体呈梭形或圆形,没有发现脂质小球的存在;基粒叠垛程度很低,平均每个基粒类囊体的片层数为5．4。这2种高山植物叶绿体超微结构上的特征是青藏高原特殊的生态条件,包括低温、低气压、强辐射影响的结果。     

关于高等植物两种光系统Ⅱ反应中心及其在叶绿体膜中分配的探讨

探究了暗适应的蓖麻叶绿体及其放氧光系统Ⅱ制剂的光诱导荧光上升动力学,这种放氧制剂几乎只含基粒片层。PSⅡ_β的相对数量(β_(max))及PSⅡ_α和PSⅡ_β的光反应速度常数(k_α和k_α),在蓖麻的基粒片层中和整个叶绿体片层中没有什么差别。也研究了几种阴生和阳生植物的叶绿体的荧光诱导动力学,这些植物叶绿体的Chla/b比值和β_(max)之间没有什么相关性。这些结果是一致的,但与Melis等人的研究结果不同,他们假定PSⅡ_β在基粒隔片,PSⅡ_β在暴露於间质的片层中。 除此以外,也检测了诱导光强度及预照光后的暗间隔对β_(max)的影响。PSⅡ_β的电子受体Q_β似乎是与Joliot & Joliot所说的Q_2及Echert和Meiburg等人所说的X_α相应的。     

小麦黄化突变体叶绿体超微结构研究

利用透射电镜对小麦自然黄化突变体及其突变亲本(西农1718)叶片细胞叶绿体的数目、形态及超微结构进行比较分析。结果发现:(1)3种不同黄化程度突变体的叶绿体分布、数目、形状及大小与突变亲本无明显差异;(2)突变体叶绿素含量为野生型58%的黄绿植株与其突变亲本叶绿体超微结构无明显差异,基质类囊体与基粒类囊体高度分化,基粒数目以及基粒片层数目较多;(3)突变体金黄和绿黄植株的叶绿素含量分别为野生型的17%、24%,其叶绿体超微结构与突变亲本明显不同,突变体的叶绿体发育存在明显缺陷,其中突变体金黄植株的叶绿体内无基粒、基质片层清晰可见,有淀粉粒,嗜锇颗粒较多,而突变体绿黄植株的叶绿体内有基粒,但明显少于突变亲本,且基粒片层较少,基质类囊体较发达。结果表明该黄化突变体叶绿体超微结构的改变,是由于叶绿素含量降低造成,推测,该黄化突变是由于叶绿素合成受阻导致的。     

花粒期光照对夏玉米光合特性和叶绿体超微结构的影响

在大田条件下,以夏玉米品种‘登海605’为试验材料,研究花粒期不同光照强度(正常光照、开花至收获期遮阴和开花至收获期增光)对夏玉米叶片光合、荧光性能和叶绿体超微结构的影响.结果表明:与对照相比,花粒期遮阴影响叶绿体排布及内部结构发育,基粒个数和基粒片层数均有不同程度减少,叶片的净光合速率、蒸腾速率、气孔导度、叶绿素含量下降,PSⅡ反应中心的实际光化学效率和最大光化学效率降低,非光化学淬灭系数数值增加,导致产量降低;增光后叶绿体结构良好,基粒片层排列紧致、清晰且数量增加,PSⅡ反应中心的实际光化学效率增加,净光合速率、蒸腾速率、气孔导度、叶绿素含量上升,叶片光合性能增强,产量增加.即花粒期遮阴破坏了夏玉米叶片叶绿体超微结构,降低了叶片光合能力,产量下降;花粒期增光增加了叶肉细胞中叶绿体的基粒和基粒片层,导致基粒片层排列紧密有序,有利于增加作物产量潜力.     

THE EFFECT OF LIGHT INTENSITY AND TEMPERATURE ON PLANT GROWTH AND CHLOROPLAST ULTRASTRUCTURE IN SOYBEAN

Soybean plants grown in controlled environment cabinets under light intensities of 220 w/m² or 90 w/m² (400–700 nm) and day to night temperatures of 27.5–22.5 C or 20.0–12.5 C in all combinations, exhibited differences in growth rate, leaf anatomy, chloroplast ultrastructure, and leaf starch, chlorophyll, and chloroplast lipid contents. Leaves grown under the lower light intensity at both temperatures had palisade mesophyll chloroplasts containing well-formed grana. The corresponding leaves developed under the higher light intensity had very rudimentary grana. Chloroplasts from high temperature and high light had grana consisting of two or three appressed thylakoids, while grana from the low temperature were confined to occasional thylakoid overlap. Spongy mesophyll chloroplasts were less sensitive to growth conditions. Transfer experiments showed that the ultrastructure of chloroplasts from mature leaves could be modified by changing the conditions, though the effect was less marked than when the leaf was growing.     

青海高原不同海拔珠芽蓼叶绿体超微结构的比较

 用电子显微镜技术观察研究了生长于青海高原3个海拔地带(2500m、3200m、3980m)的珠芽蓼(polygonum viviparum L．)叶绿体的超微结构,发现随着海拔的升高,叶绿体结构呈现显著的变化趋势。2500m和3200m处叶绿体形状规则,分布在细胞边缘。3980m处叶绿体膨大变形,且分布在整个细胞当中。海拔升高,类囊体膜减少,膜垛叠程度减小。不同海拔珠芽蓼叶绿体的类囊体膜结构差异较大,特点显著。随海拔升高,珠芽蓼叶绿体破坏程度增加。主要表现为类囊体膜肿胀、类囊体膜溶解和叶绿体破裂。许多破裂的叶绿体中残留有发达的基粒和大而多的淀粉粒。珠芽蓼叶绿体的这些结构特征,既是环境胁迫的结果,又是植物适应性的表现。     

锌对番茄叶绿体亚显微结构的影响与光强度的关系(简报)

番茄植物缺锌时,茎尖停止生长,叶部和茎上出现褐色斑点,有明显的小叶病症状。此外,叶绿素含量减少,光合强度降低,叶绿体结构遭到破坏。陈保生和崔澂发现叶绿体含锌量显著降低,并提出缺锌阻碍了叶绿体的发育。Hoagland发现锌在植物中的生理作用与光有关,此后,不少人对植物需锌与光的关系进行了研究,证明植物在光下较暗中需锌较多。通过进一步研究,李佳格和崔澂证明锌对自养生长的绿色植物的作用与光有关,而对异养的非绿色植物的作用与光无关。Spencer还报道锌和光影响叶绿体希尔反应活性。由此看来,锌与叶绿体的结构和功能是密切相关的。但锌在     

定位于类囊体膜的PPF1在转基因拟南芥中的表达影响叶绿体的发育

PPF1是一个与植物营养生长相关的基因。它编码的产物可能是一个膜蛋白并与拟南芥叶绿体中的类囊体蛋白ALB3有很高的同源性。免疫电镜分析表明PPF1蛋白同样主要定位于类囊体膜 ,而且在短日照G2豌豆开花两周后仍发育良好的叶绿体中有很高的表达 ,在长日照豌豆同时期非正常叶绿体中丰度非常低。对转基因拟南芥和野生型植株的叶片衰老进程比较发现 ,PPF1在拟南芥中的过量表达可以延缓叶片的衰老 ,而用PPF1反义mRNA抑制拟南芥中的同源基因ALB3则明显加快叶片衰老速度。对转基因拟南芥的超微结构分析显示 ,PPF1在拟南芥中过量表达时 ,转基因植株的叶绿体比野生型植株的叶绿体大并含有更多的基粒和基质类囊体膜 ;相反 ,反义PPF1表达抑制其在拟南芥中的同源物时 ,转基因植株的叶绿体比野生型植株的叶绿体小并含有较少的基粒和发育较差的类囊体膜系统。这些数据表明叶绿体的发育状况与PPF1或拟南芥同源物ALB3的表达水平呈正相关。我们的结果提示PPF1基因可能通过控制叶绿体的发育状况来调节植物的发育。     

Comparison of Photosynthetic Adaptability Between Kobresia humilis and Polygonum viviparum on Qinghai Plateau

The chlorophyll fluorescence parameters of Kobresia humilis Serg. and Polygonum viviparum L. grown at two different altitudes (3200 m, 3980 m) were measured and the ultrastructure of chloroplasts were observed for studying the photosynthetic adaptability of plants to the influences of stress conditions in alpine environment. Rfd -values, the vitality index, in leaves of K. humilis and P.viviparum grown at 3980 m were higher than those at 3200 m. The higher ratio of Fv/Fo and Fv/Fm in leaves of K. humilis and P.viviparum indicated that the rate of photosynthetic conversion of light energy increased at higher altitude. Ratios of Fv/Fo and Fv/Fm and Rfd -values in K.humilis were higher than that in P.viviparum grown at the same altitude. There were more irregular chloroplasts in leaves of both species grown at higher altitude. Many irregular chloroplasts such as swollen thylakoid, deformed chloroplast envelope, were observed in P.viviparum grown at 3980 m, but few in K.　humilis . These results were discussed in relation to the photosynthetic adaptability of alpine plants and the different adaptive competence between K.humilis and P.viviparum.     

几种高山植物叶绿体淀粉粒的变化特征

利用透射电镜对生长于青藏高原东北部达坂山（海拔3900m）的5种高山植物叶绿体超微结构进行了观察。结果发现,在所研究的5种高山植物叶绿体中,淀粉粒数量均较多,淀粉粒呈长椭圆形或圆形,沿叶绿体长轴分布。在珠芽蓼的叶绿体中,淀粉粒的电子密度内外不均匀,外周电子密度低,中央电子密度高。在其余4种高山植物中,淀粉粒的电子密度均较低。另外,在这5种高山植物叶绿体中还出现了脂质小球。其类囊体均出现了不同程度的膨大现象。研究表明,高山植物叶绿体中淀粉粒的这种变化是对逆境的一种适应,是青藏高原特殊生态条件长期胁迫的结果。     

青海高原矮嵩草和珠芽蓼的光合适应性比较(英文)

对生长在两个海拔地带 (3 2 0 0m ,3 980m)的矮嵩草 (KobresiahumilisSerg.)和珠芽蓼 (PolygonumviviparumL .)叶片的叶绿素荧光特性及其叶绿体超微结构进行了比较研究。海拔升高 ,矮嵩草和珠芽蓼叶片的Fv/Fo、Fv/Fm和Rfd值均增大 ,且矮嵩草的Fv/Fo、Fv/Fm 和Rfd值均大于珠芽蓼。叶绿体超微结构的结果显示 ,海拔升高 ,珠芽蓼和矮嵩草的叶绿体都表现出一定程度的变形 ,但珠芽蓼的叶绿体变形和类囊体膜肿胀现象更为显著。研究表明 ,矮嵩草和珠芽蓼光合作用对高山胁迫环境具有很强的适应性 ,且矮嵩草的适应能力比珠芽蓼强。     

Effects of low light stress on rubisco activity and the ultrastructure of chloroplast in functional leaves of peanut

Aims In recent years, intercropping system has become one of the major practice of peanut (Arachis hypogaea) cultivation in northern China because of the high land and energy utilization efficiency, to some extent compensating for the production loss caused by decreasing area of cultivation land. Intercropped peanut plants often have a lower pod yield compared with monoculture due to constraint on light availability. This study was conducted to explore the shade-tolerance mechanism in two peanut cultivars, ‘Huayu 22’ and ‘Baisha 1016’, that grew in an intercropping system, by studying chloroplast ultrastructure and rubisco activity under different levels of shading.
Methods A field experiment was conducted with three levels of light treatments, including full natural light (CK), 50% natural light indensity (NLI), and 15% NLI. The ‘Huayu 22’ was used as a shade-tolerant cultivar and the ‘Baisha 1016’ as a shade-susceptible cultivar based on previous studies. Experimental plants of both cultivars were shaded for 40 days from emergency in 2006. Rubisco activity, the number and shapes of chloroplasts and starch grains, and number of grana and granum lamella were investigated in functional leaves of plants in all treatments.
Important findings The functional leaves of peanut plants in the 50% and 15% NLI treatments had a lower rubisco activity than those in the CK treatment. In the ‘Baisha 1016’, the reduction in rubisco activity was 40.1% in the 50% NLI treatment and 59.4% in the 15% NLI treatment, respectively, compared to the CK treatment;whereas no significant differences were found among treatments in the ‘Huayu 22’ in the rubisco activity. Compared with the CK, the number of chloroplasts remained unchanged, the number of grana and lamella in grana increased, and the individual chloroplast was longer and in perfect development in the functional leaves of plants of the ‘Huayu 22’ grown in the 50% NLI treatment. In contrast, the number of chloroplasts, grana and starch grains of the ‘Huayu 22’ plants decreased significantly, the chloroplast membrane and grana lamella were damaged, the number of granum lamella increased, and the individual chloroplast became longer in the 15% NLI treatment. The number and ultrastructure of chloroplasts in the ‘Baisha 1016’ plants followed similar patterns of changes as those of the ‘Huayu 22’ in the 50% NLI treatment. For plants of the ‘Baisha 1016’ in the 15% NLI treatment, their chloroplasts became more roundly shaped, with decreasing number of grana lamella and increasing number of starch grains, compared with the CK. There were a greater decrease in the grana number and more damage in the grana lamella in plants of the ‘Baisha 1016’ than those of the ‘Huayu 22’. In conclusion, the shade tolerance of the ‘Huayu 22’ resulted from lack of changes in rubisco activity and less damage in the ultrastructure of chloroplasts when under low light stress compared with the ‘Baisha 1016’.     

Fine Chloroplast Structure in Cucumber and Pea Leaves Developed under Red Light

Photosynthetic activity, the content of various photosynthetic pigments, and the chloroplast ultrastructure were examined in the leaves of cucumber (Cucumis sativus L.) and pea (Pisum sativum L.) plants of different ages grown under red light (600–700 nm, 100 W/m²). In pea leaves tolerant to red-light irradiation, chloroplast ultrastructure did not essentially change. In the first true leaves of cucumber plants susceptible to red-light irradiation, we observed a considerable increase in the number and size of plastoglobules, the appearance of chloroplasts lacking grana or containing only infrequent grana, and stromal thylakoids. In the upper leaves of 22-day-old cucumber plants, the chloroplast structure was essentially similar to that of the control chloroplasts in white light, and we therefore suppose that these plants have acclimated to red light.     

弱光胁迫对花生功能叶片RuBP羧化酶活性及叶绿体超微结构的影响

间作套种是我国主要的花生(Arachis hypogaea)种植方式之一。然而, 与单作相比, 在间作套种体系中, 花生截获的光能较少, 生长发育差, 产量低, 研究不同品种耐阴机理对选择适宜间作套种的花生品种具有重要意义。该研究用耐阴性不同的两个花生品种‘花育22号’ (强耐阴性)和‘白沙1016’ (弱耐阴性)为材料, 在大田条件下采用不同透光率遮阴网设置50%自然光强(中度弱光胁迫)和15%自然光强(严重弱光胁迫) 2个弱光处理, 从出苗期开始遮阴40天, 以自然光强为对照, 研究了弱光胁迫对花生功能叶片RuBP羧化酶活性和叶绿体超微结构的影响。结果表明: 光强为自然光照50%和15%的处理, ‘花育22号’ RuBP羧化酶活性与对照相比虽有降低, 但差异不显著, 而‘白沙1016’分别比对照低40.1%和59.4%, 显著低于对照。与对照相比, 50%自然光强下‘花育22号’叶绿体数不变, 叶绿体基粒数和基粒片层数显著增多, 叶绿体变长且发育完好, 15%自然光强下, 叶绿体数、基粒数和淀粉粒数显著减少, 叶绿体膜和基粒片层出现破损, 但叶绿体变长, 基粒片层数增加; ‘白沙1016’在50%自然光强下, 叶绿体数目和超微结构变化同‘花育22号’相似, 在15%自然光强下叶绿体变圆, 基粒数的降幅和基粒片层破损程度大于‘花育22号’且基粒片层数减少, 淀粉粒数增多。因此, 弱光胁迫特别是严重弱光胁迫条件下, 功能叶RuBP羧化酶活性降低幅度小、叶绿体超微结构受损程度低是‘花育22号’耐阴的光合生理基础。