向日葵柱头,花柱和珠孔中钙分布的超微细胞化学定位

用焦锑酸盐沉淀法对向日葵（ＨｅｌｉａｎｔｈｕｓａｎｎｕｕｓＬ．）授粉前后柱头、花柱和珠孔中的钙进行了超微细胞化学定位。同时还运用Ｘ射线能谱（ＥＤＸ）和波谱（ＷＤＸ）两种方法进行了Ｘ射线定性分析,证明了前法所得沉淀确系焦锑酸钙。观察表明,花粉萌发和花粉管生长所经的柱头接受面,花柱引导组织和珠孔引导组织中含钙较柱头、花柱和珠孔的其它部位明显地多。柱头乳突细胞的表面和花柱引导组织的胞间基质中、尤其胞间基质与细胞壁外层相接之处钙很密集。在珠孔外端引导组织中,以角质层为界,钙主要分布于其近珠柄侧。花粉管壁果胶质层中有相当多的钙。结合向日葵中已有的研究和其他文献,讨论了钙的分布与花粉管生长的关系     

钙在被子植物受精过程中的作用

近年来,花粉管中的钙信号和生理功能的研究又取得了明显的进展,同时在雌蕊系统中有关钙分布的研究也初步显示了其时、空特征与被子植物的受精作用密切相关。该文总结了花粉萌发和花粉管生长过程中外源钙的作用机制,结合雌蕊组织中钙分布的特征,进一步探讨了钙在被子植物受精过程中的功能。     

钙在被子植物受精过程中的作用

近年来,花粉管中的钙信号和生理功能的研究取得了明显的进展,同时在雌蕊系统中有关钙分布的研究也初步显示了其时、空特征与被子植物的受精作用密切相关。该文总结了花粉萌发和花粉管生长过程中外源钙和内源钙的作用机制,结合雌蕊组织中钙分布的特征,进一步探讨了钙在被子植物受精过程中的功能。     

甘蓝油菜雌蕊中花粉管生长途径的钙离子定位

用焦锑酸钾定位 Ca~(2 )的技术,证明了甘蓝油菜(Brassica napus)柱头乳突细胞的少量分泌物、柱头表皮下的引导组织细胞间隙、花柱引导组织细胞壁外表面和胞间隙的分泌物以及子房假隔膜分泌区的表皮细胞外和内部引导组织细胞壁外表面和胞间隙的分泌物中均有 Ca~(2 )沉淀存在,而花柱皮层薄壁细胞无此种现象。花粉管生长的整个途径中 Ca~(2 )的存在与花粉管在雌蕊中的定向生长有关。     

猕猴桃花粉原位生长过程中Ca2+的超微细胞化学定位

应用扫描电镜和荧光显微镜对软枣猕猴桃同种花粉在柱头上原位萌发及花粉管生长情况进行了观察,并用焦锑酸盐沉淀法对其授粉前后柱头及花柱中Ca2+进行超微细胞化学定位.结果显示:(1)猕猴桃柱头属于干性柱头,具有一道裂沟,乳突呈长圆柱形,授粉前后形态差异不明显.(2)授粉后3 h,花粉管生长穿过柱头表面,授粉后7 h,花粉管生长到达花柱底部;(3)授粉前后,柱头接受面靠近柱头外围细胞的角质层一侧细胞器内含有丰富的钙,而柱头非接受表面钙颗粒分布很少;(4)授粉前和授粉后3 h,花柱顶端钙颗粒较少,基部钙颗粒较多;授粉后7 h,花柱顶端和基部钙分布密度无明显差别;(5)授粉前后花柱顶端钙主要均匀分布在细胞质膜位置;在花柱基部授粉前钙主要分布在引导组织胞间隙中,授粉后3 h主要分布在细胞质内,授粉后7 h主要存在于细胞质、内质网上.研究表明,猕猴桃授粉前后,柱头和花柱组织中均含有钙,授粉前和授粉后3 h花柱中的钙呈现出梯度分布,授粉后7 h钙的梯度分布现象减弱甚至消失.     

宁夏枸杞柱头和萌发花粉中钙分布特征

用焦锑酸钾沉淀法对宁夏枸杞柱头和花粉中的钙离子分布进行了研究.结果显示,宁夏枸杞柱头表皮有一覆盖层,其中有许多含钙沉淀颗粒的小泡,当花粉落到柱头后从覆盖层中吸水,在萌发孔的表面上聚集了较多的钙沉淀颗粒.同时,花粉内部出现许多含钙的小液泡,使花粉体积增大,内部产生膨压,花粉萌发;生长在覆盖层中的花粉管顶端穿过覆盖层小泡时,附近聚集了较多的钙沉淀颗粒,在花粉管壁上也附着较多的细小钙沉淀颗粒.萌发的花粉粒中由大液泡占据,在其亚顶端的细胞质中,聚集较多钙沉淀颗粒的线粒体膨大形成了一些含钙沉淀颗粒的小液泡,由这些小液泡融合形成的大液泡,将花粉管细胞质挤到其顶端,使其极性生长.这是首次发现在植物柱头覆盖层中有钙离子的现象,从体内证明了钙离子在花粉萌发过程中的现象.讨论了枸杞柱头组织中钙的分布和花粉管的萌发与生长的关系.     

花粉管引导机制的研究进展

花粉管引导是指显花植物在受精过程中,雌蕊组织与花粉管相互作用使花粉管定向生长并最终到达胚囊的过程,其机制颇为复杂。该文基于调控花粉管生长的孢子体引导和配子体细胞引导两个主要过程,阐述雌蕊中不同蛋白分子和其它小分子物质的浓度梯度在花粉管的孢子体组织引导中的作用,以及胚囊中不同类型的细胞及其相关基因与蛋白在花粉管的配子体细胞引导中的作用。同时,该文也对精细胞在花粉管引导中的作用进行了阐述。     

莴苣授粉前后柱头与花柱中钙的分布变化

莴苣柱头呈两裂片状,有接受花粉的接受面和非接受面之分。授粉前后,柱头接受面乳突细胞的细胞壁中贮存丰富的细小钙颗粒,而非接受面的表皮细胞壁中的钙颗粒很少。在花柱组织中钙的分布具有明显特征,在同一水平上,钙主要分布在引导组织的质外体中,如细胞壁和细胞间隙中,而在引导组织外的薄壁组织中钙主要分布在的细胞内液炮和细胞壁中以及维管束导管内。在花柱不同水平上,花柱中的钙呈现出梯度分布,顶端各组织中的钙颗粒较少,基部各组织中的钙颗粒较多。授粉后1h花柱基部组织的钙颗粒增多,钙梯度分布现象增强。花柱引导组织中的钙梯度分布很可能是吸引花粉管向下生长的原因。讨论了莴苣花柱引导组织中钙梯度分布特征和花粉管在其体内生长的关系。     

莴苣授粉前后柱头与花柱中钙的分布变化

莴苣柱头呈两裂片状,有接受花粉的接受面和非接受面之分。授粉前后,柱头接受面乳突细胞的细胞壁中贮存丰富的细小钙颗粒,而非接受面的表皮细胞壁中的钙颗：粒很少。在花柱组织中钙的分布具有明显特征,在同一水平上,钙主要分布在引导组织的质外体中,如细胞壁和细胞间隙中,而在引导组织外的薄壁组织中钙主要分布在的细胞内液泡和细胞壁中以及维管束导管内。在花柱不同水平上,花柱中的钙呈现出梯度分布,顶端各组织中的钙颗粒较少,基部各组织中的钙颗粒较多。授粉后1h花柱基部组织的钙颗粒增多,钙梯度分布现象增强。花柱引导组织中的钙梯度分布很可能是吸引花粉管向下生长的原因。讨论了莴苣花柱引导组织中钙梯度分布特征和花粉管在其体内生长的关系。     

烟草花粉萌发和花粉管生长期间柱头和花柱中的钙分布

烟草柱头表面有两层覆盖物,其中含有少量细小的钙颗粒.花粉落到柱头上后,储存在花粉外壁中的钙被释放到覆盖层中.当花粉管穿过覆盖层长入柱头细胞之间时,花粉管顶端的细胞壁中出现了大量的细小钙颗粒.开花后22 h观察时,在花柱引导组织中形成了钙的梯度分布:花柱上部引导组织中的钙较少,而下部连接子房处的花柱引导组织中含有较多的钙颗粒.去雄花开花后1 d时,花柱上部引导组织中的钙明显增多;3 d时,连柱头细胞中也出现了较多的钙颗粒.讨论了烟草花柱引导组织中钙梯度分布和花粉管生长的关系.     

Ultracytochemical Localization of Calcium in the Stigma,Style and Micropyle of Sunflower

Calcium was localized ultracytochemically in the stigma, style and micropyle of sun-flower (Helianthus annuus L. ) by pyroantimonate precipitation technique. To identify the element constitution of the pyroantimonate deposits, wave-dispersive X-ray microanalysis (WDX) method was employed in addition to the energy-dispersive X-ray microanalysis (EDX) and the deposits observed were directly proved as calcium pyroantimonate. In the stigma, calcium was more abundant on the receptive surface, especially outside and inside the papillae, than on the noo-receptive surface. In the style, more calcium was seen in the transmitting tissue as compared with the adjacent parenchymatous tissue, and was concentrated at the intercellular matrix and the boundary between the cell wall and the intercellular matrix. In micropyle region, the transmitting tissue on the side proximal to the funicle contained large amount of calcium, where as more calcium was localized in the intercellular matrix. As for the pollen tubes growing along the gynoecium, calcium was mainly localized at the pectin layer of the tube wall after 1.5 hours of pollination.     

Ultracytochemical Localization of Calcium in Micropyle and Embryo Sac of Brassica napus Before and After Pollination

Potassiam antimonate was used to localize Ca2+ in the micropyle and embryo sac of Brassica napus L. before and after pollination. To identify the nature of the pyroantimonate deposits, energy-dispersive X-ray microanalysis (EDXA) was employed and the deposits were proved to contain calcium pyroantimonate. Image processing system was employed to measure the volume density and the diameter of the deposits. Before and after pollination, calcium was more abundant in the exostome and endostome as compared with the other regions of the integuments, and was concentrated at the apoplast system, i.e. the intercellular matrix of the micropyle canal and the cell wall. Before pollination, each of the two sister synergids accumulated more calcium than the other embryo sac cells. Although the mean diameter of the deposits in the synergid was only two-thirds as that in the egg cell and central cell, the volume density of the deposits in the synergid was about 2.5 times and 1.9 times as that in the egg cell and the central cell respectively. The filiform apparatus and the nucleus had the most abundant calcium within a synergid. After pollination both sister synergids degenerated conspicuously and were characterized by much more deposited calcium (about 2.4 times more than before); and the diameter of the deposits decreased dramatically, which was less than one-third as before. The relationship between calcium distribution and synergid degeneration as well as its functions was discussed.     

Cytohistochemical techniques for calcium localization and their application to diseased plants

Lesion delimitation and resistance of old bean (Phaselous vulgaris L., cv. Red Kidney) plants to Rhizoctonia solani Kühn have been suggested to result from increased calcium pectate formation in walls. Ultrastructural histochemistry was used to determine the site of calcium in tissues adjacent to lesions and in older bean hypocotyls. Hypocotyl lesion tissue and uninoculated control tissue were treated with ammonium oxalate or potassium pyroantimonate during fixation. Treatment with potassium pyroantimonate, but not with oxalate, resulted in granular deposits in cell walls of healthy and lesion tissue. Granules also occurred on the plasma membrane of cells adjacent to lesions and in organelles of damaged cells, but wall granule density was not increased. Cell walls from healthy 24-day-old plants had a greater granule density than those for 8-day-old plants. Wall granules were removed from thin sections with ethylene glycol bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid. Energy dispersive analysis of x-rays also suggested that potassium pyroantimonate localized calcium. Chemical analyses showed that some calcium was retained in tissues after fixation. The results suggest that there are different mechanisms for lesion delimitation and age-induced resistance.     

Ultrastructure of the micropyle and its relationship to pollen tube growth and synergid degeneration in sunflower

Summary Ultrastructural studies made on the micropyle of sunflower before and after pollination resulted in the following observations. (1) The micropyle is closed instead of a hole or canal. The inner epidermis of the integument on both sides of the micropyle is in close contact at the apex of the ovule. The boundary between the two sides consists of two layers of epidermal cuticle. (2) The micropyle contains a transmitting tissue. The micropyle is composed of an intercellular matrix produced by the epidermal cells of the integument. (3) The micropyle is asymmetrical, and is much wider on the side proximal to the funicle. On the funicle side the cells adjacent to the micropyle are similar to those of the transmitting tissue: they have large amounts of intercellular matrix and contain abundant dictyosomes, rough ER, and starch grains, and provide an appropriate environment for growth of the pollen tubes. The cells distal to the funicle are rich in rough ER and lipid bodies; they lack large intercellular spaces. (4) The micropyle is variable in the axial direction, i.e., it is much larger and more asymmetric at the level distal to the embryo sac than at a level close to the embryo sac. After pollination, one to four pollen tubes are seen in a micropyle. During their passage through the micropyle, most pollen tubes are restricted to the side proximal to the funicle. There is a greater tendency (81%) for the degenerate synergid to be located toward the funicle, i.e., at the same side as the pollen tube pathway. The data indicate a close relationship between micropyle organization, orientation of pollen tube growth, and synergid degeneration.     

荔枝雌蕊发育过程中钙分布变化与细胞程序性死亡

应用焦锑酸钾沉淀法研究了荔枝雌花和雄花雌蕊发育过程中钙的分布变化。在大孢子母细胞阶段,雌花近珠孔内珠被细胞和花柱细胞的钙沉淀颗粒主要分布在细胞壁和细胞间隙,少部分在液泡;雌花花柱维管细胞中含有很多的钙沉淀颗粒;在雄花的近珠孔内珠被细胞钙沉淀颗粒大多在液泡中;雄花花柱细胞和维管细胞中钙沉淀颗粒很少。大孢子母细胞减数分裂后,雌花雌蕊继续发育,雄花雌蕊败育。雌花维管中的钙沉淀颗粒数量减少,可能被转运到将要发生花粉萌发和受精的部位。雌花近珠孔内珠被细胞壁的钙沉淀颗粒分布增加,花柱细胞从上（近柱头）到下（近子房）钙沉淀颗粒量递增。雄花近珠孔内珠被细胞发生程序性死亡：液泡中的钙进入细胞核启动细胞程序性死亡,核周隙与质膜腔形成连续的通道,钙在核与细胞质之间的流动不受限制;在特定的时间段,钙沉淀颗粒出现在线粒体、过氧化物体和线型内质网的外膜上。钙在细胞中重新分布可能触发和调节细胞程序性死亡的进程。缺乏钙沉淀颗粒的雄花花柱细胞迅速解体。     

华北落叶松花粉发育过程中的钙动态分布

运用焦锑酸钾沉淀法研究了华北落叶松(Larix principis-rupprechtii Mayr)小孢子发育过程中不同阶段Ca2 的分布情况.减数分裂时期,小孢子囊壁表皮和中层细胞的细胞壁及细胞间隙Ca2 分布较多,绒毡层只有外切向面的细胞膜有Ca2 分布,小孢子母细胞的各部位则很少有Ca2 ;四分体时期,包围四分小孢子的胼胝质壁上有大量的Ca2 分布,在四分孢子壁上也有较多沉淀;游离小孢子时期,钙离子在小孢子壁的分布较四分体时期有所减少,而到花粉成熟时又逐渐增多;从四分体到花粉成熟,乌氏体周围的Ca2 有增多的趋势.对四分体外壁Ca2 的大量分布与花粉壁的形成及信号物质在花粉表面贮存的关系,以及小孢子囊的外壁、绒毡层和乌氏体在Ca2 向花粉运输中所起的作用进行了讨论.     

水稻雌蕊与胚囊中钙的超微细胞化学定位

用焦锑酸盐沉淀法对水稻（OryzasativaL．）授粉前后雌蕊和胚囊中的钙进行了超微细胞化学定位。结果表明,柱头乳突细胞表面和花柱薄壁细胞中均含钙沉淀;开花前1d,整个胚囊中含钙较少,两个助细胞中钙分布无差异;临近开花时,1个助细胞已退化,其钙含量明显增加;开花后6h,胚囊已受精,退化助细胞中钙含量进一步增加;受精前卵细胞中钙主要分布在液泡中,核和胞质中较少;受精后,其钙含量明显增加,主要分布于核中。重点讨论了钙与助细胞退化和卵细胞激活的关系。     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻（Oryza sativa）受精过程中雌雄性细胞融合时的形态特征及时间进程,确定合子期,为花粉管通道转基因技术的实施提供理论依据。结果表明：授粉后,花粉随即萌发,花粉管进入羽毛状柱头分支结构的细胞间隙,继续生长于花柱至子房顶部的引导组织的细胞间隙中,而后进入子房,在子房壁与外珠被之间的缝隙中向珠孔方向生长,花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞,释放精子。精子释放前,两极核移向卵细胞的合点端：两精子释放于卵细胞与中央细胞的间隙后,先后脱去细胞质,然后分别移向卵核和极核,移向卵核的精核快于移向极核的精核：精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下：授粉后,花粉在柱头萌发：花粉萌发至花粉管进入珠孔大约需要0．5小时：授粉后0．54,时左右,花粉管进入一个助细胞,释放精子：授粉后0．5—2．5小时,精卵融合形成合子：授粉后约10．0小时,合子第1次分裂,合子期为授粉后2．5-10．04,时：授粉后1．0-3．04,时,精核与两极核融合：授粉后约5．0小时,初生胚乳核分裂。’     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻(Oryz a sativa)受精过程中雌雄性细胞融合时的形态特征及时间进程, 确定合子期, 为花粉管通道转基因技术的实施提供理论依据。结果表明: 授粉后, 花粉随即萌发, 花粉管进入羽毛状柱头分支结构的细胞间隙, 继续生长于花柱至子房顶部的引导组织的细胞间隙中, 而后进入子房, 在子房壁与外珠被之间的缝隙中向珠孔方向生长, 花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞, 释放精子。精子释放前, 两极核移向卵细胞的合点端; 两精子释放于卵细胞与中央细胞的间隙后, 先后脱去细胞质, 然后分别移向卵核和极核, 移向卵核的精核快于移向极核的精核; 精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下: 授粉后, 花粉在柱头萌发; 花粉萌发至花粉管进入珠孔大约需要0.5小时; 授粉后0.5小时左右, 花粉管进入一个助细胞, 释放精子; 授粉后0.5-2.5小时, 精卵融合形成合子; 授粉后约10.0小时, 合子第1次分裂, 合子期为授粉后2.5-10.0小时; 授粉后1.0-3.0小时, 精核与两极核融合; 授粉后约5.0小时, 初生胚乳核分裂。