莴苣大孢子发生过程中钙的分布动态

莴苣胚囊发育为蓼型,减数分裂形成的4个大孢子中只有合点端的一个大孢子可继续发育,其余3个大孢子从珠孔端依次退化.大孢子母细胞中的钙沉淀颗粒很少,减数分裂后的四分体中的钙沉淀颗粒稍有增加.以后,4个大孢子中的钙沉淀颗粒在数量上有明显差异:即将退化的大孢子中钙明显减少,而未退化大孢子细胞质中则保持有较多的细小钙沉淀颗粒.大孢子的退化是一种细胞程序死亡现象,细胞中的钙浓度降低时可能启动了大孢子细胞的程序性死亡过程,而细胞中的钙浓度高时则保持大孢子细胞的继续发育.文章首次揭示了大孢子发生过程中钙的分布特征.     

五唇兰大孢子发生的超微结构观察

五唇兰(Doritis pulcherrima Lind l．)大孢子母细胞在减数分裂前呈长圆形,细胞核偏向珠孔端,细胞呈现极性分化。大孢子母细胞第一次减数分裂形成二分体。随后,二分体珠孔端的一个细胞退化,合点端的一个细胞体积增大成为功能大孢子。功能大孢子进行第二次减数分裂,形成二核胚囊。这一过程属于双孢子葱型胚囊的大孢子发生类型。珠孔端的二分体细胞(大孢子)在退化过程中质膜保持完好,液泡数量增多,染色质高度凝集,具有细胞程序死亡的部分特征。功能大孢子的细胞器和染色质分布均匀。功能大孢子合点端的细胞壁上有发达的胞间连丝,二核胚囊期胞间连丝消失。在功能大孢子靠近合点端一侧有吞噬结构,其内含有结构模糊的细胞器     

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     

鹤顶兰胚囊发育过程中Ca~（2＋）分布的超微细胞化学定位（英文）

用焦锑酸盐沉淀法对鹤顶兰（Phaius tankervilliae）胚囊发育过程中的Ca2＋状态进行超微细胞化学定位。观察结果发现：功能大孢子时期,珠孔端的胚囊壁上开始出现小颗粒的Ca2＋沉淀,但功能大孢子细胞内未见明显的Ca2＋标记;四核胚囊时期胚囊壁上的Ca2＋沉淀明显增多,液泡膜上有Ca2＋沉淀出现,珠孔处的Ca2＋沉淀颗粒较大;成熟胚囊时期,胚囊壁上的Ca2＋沉淀进一步增多,且胚囊内Ca2＋分布明显增多,且极性明显,珠孔端助细胞、卵细胞比合点端反足细胞有更多的Ca2＋沉淀。鹤顶兰成熟胚囊内Ca2＋积累的来源有：（1）在胚囊成熟前主要由珠被细胞、珠细胞通过胞间连丝向胚囊运输;（2）以沉淀有大量Ca2＋的小泡形式跨过胚囊壁进入胚囊。     

陆地棉雌蕊的花粉管生长途径中钙分布的超微细胞化学定位

用焦锑酸盐沉淀法对陆地棉(Gossypium hirsutum L.)授粉前后的柱头、花柱、珠孔与珠心组织中的钙进行了超微细胞化学定位。X射线波谱与能谱分析证明所定位的沉淀确系焦锑酸钙。观察结果表明:在整个花粉管生长途径中的雌蕊组织,钙分布均较其它相邻组织密集;钙主要分布在细胞壁与胞间基质等质外体系统中。在雌蕊中生长的花粉管,其尖端细胞器区也有丰富的钙。     

灵武长枣正常果及裂果中Ca2+的细胞化学定位研究

采用焦锑酸钾沉淀法,对灵武长枣正常果发育过程中的Ca2+及不同开裂度果实中的Ca2+进行细胞化学定位,在透射电镜下观察并比较Ca2+的分布特征和积累规律.结果表明:(1)正常长枣青果期的外果皮细胞及胞间隙中检测到大量的钙沉淀颗粒,而果肉细胞以及叶绿体中很少有钙沉淀颗粒.红果期很多外果皮细胞中钙沉淀颗粒特异性地沿细胞壁呈一圈分布,且越靠近内方的细胞中钙沉淀颗粒越少、越小.果肉细胞中仍无钙沉淀颗粒分布.(2)具轻微开裂的长枣很多外果皮细胞中无钙沉淀颗粒,只有少数细胞中有且集中分布于大液泡中;细胞质沿细胞壁分布,也无钙沉淀颗粒;在果肉细胞中几乎看不到钙沉淀颗粒分布.(3)完全开裂的长枣中钙沉淀颗粒只分布在少数体积较小的外果皮细胞中,而果肉细胞的细胞壁边缘或细胞壁以及胞间隙中分布有大量的钙沉淀颗粒.     

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。     

甘蓝型油菜授粉前后珠孔和胚囊中钙分布的超微细胞化学定位

用焦锑酸盐沉淀法对甘蓝型油菜（ＢｒａｓｉｃａｎａｐｕｓＬ．）授粉前后珠孔和胚囊中的钙进行了超微细胞化学定位。Ｘ射线能谱微区定性分析（ＥＤＸＡ）表明前法所得沉淀确系焦锑酸钙。同时利用图像处理系统对胚囊成员细胞中钙沉淀颗粒的体密度和大小进行了定量分析。结果显示,授粉前后内、外珠孔处钙沉淀明显较珠被其它部位为多,钙主要分布在细胞壁和胞间基质等质外体系统中。授粉前２个助细胞中均含有较其它细胞为多的钙沉淀,约为卵细胞的２５倍,中央细胞的１９倍;但沉淀颗粒的直径仅为它们的２／３左右。助细胞中含钙最多的部位是丝状器和细胞核。授粉后１对姊妹助细胞均明显退化,钙含量显著增高,约为授粉前的２４倍;钙颗粒明显减小,不足授粉前的１／３。讨论了钙的分布与助细胞的退化及其功能的关系。     

车桑子大孢子发生与雌配子体发育

采用常规石蜡切片法,对车桑子大孢子的发生和雌配子体的发育进行观察,探讨车桑子自然结籽率低的原因和明确其胚胎发育特征。结果表明:(1)车桑子花柱有花柱道,子房3室,中轴胎座,横生胚珠,每心室两枚胚珠,双珠被,厚珠心,无承珠盘。(2)位于珠心表皮细胞下的孢原细胞经平周分裂产生造孢细胞,造孢细胞发育为大孢子母细胞,大孢子母细胞经减数分裂形成线性四分体,靠近珠孔端3个大孢子退化消失,靠合点端大孢子发育为功能大孢子,大孢子发生类型为单孢子发生型。(3)单核胚囊经3次有丝分裂形成7细胞8核的成熟胚囊,胚囊发育类型为蓼型。(4)花器官形态的变化和大孢子发育过程有一定联系,可根据雌花形态特征大致判断大孢子发育时期。研究认为,车桑子雌配子体发育过程中出现的胚囊不中空、游离核不进一步细胞化等异常现象,可能是导致车桑子自然结籽率低的原因之一。     

大黍(Panicum maximum Jacq.)的胚珠附器

观察了大黍(Panicum,maximum Jacq．)胚珠附器的发生时间、位置和发育过程及其细胞化学特征。结果显示：(1)大孢子母细胞时期,珠孔端有一个或多个珠心表皮细胞开始伸长、膨大,特化为胚珠附器。(2)当胚珠附器伸长、膨大至最大程度时,胚珠附器细胞表现出显著的极性特征：细胞核位于细胞的珠孔端,大而清晰;细胞内同时形成了一个特大的液泡,几乎占据了整个细胞的合点端;细胞质则被挤到珠孔端一侧,集中分布在核的周围。(3)胚珠附器从开始出现到发育成熟,都没有淀粉粒的积累;但是,PAS反应显示胚珠附器细胞壁和细胞质都比普通珠心细胞的染色程度深,这说明其细胞壁和细胞内部富含可溶性多糖。     

Localization of calcium in the pericarp cells of tomato fruits during the development of blossom-end rot

Summary. Blossom-end rot (BER) of tomato (Lycopersicon esculentum) fruits is considered to be a physiological disorder caused by calcium deficiency. We attempted to clarify the localization of calcium in the pericarp cells and the ultrastructural changes during the development of BER. Calcium precipitates were observed as electron-dense deposits by an antimonate precipitation method. Some calcium precipitates were localized in the cytosol, nucleus, plastids, and vacuoles at an early developmental stage of normal fruits. Calcium precipitates were increased markedly on the plasma membrane during the rapid-fruit-growth stage compared with their level at the early stage. Cell collapse occurred in the water-soaked region at the rapid-fruit-growth stage in BER fruits. There were no visible calcium precipitates on the traces of plasma membrane near the cell wall of the collapsed cells. The amount of calcium precipitates on plasma membranes near collapsed cells was smaller than that in the cells of normal fruits and normal parts of BER fruits, and the amount on cells near collapsed cells was small. The amount of calcium precipitates on the plasma membranes increased as the distance from collapsed cells increased. On the other hand, calcium precipitates were visible normally in the cytosol, organelles, and vacuoles and even traces of them in collapsed cells. The distribution pattern of the calcium precipitates on the plasma membrane was thus considerably different between normal and BER fruits. On the basis of these observations, we concluded that calcium deficiency in plasma membranes caused cell collapses in BER tomato fruits.Correspondence and reprints: National Institute of Vegetable and Tea Science, National Agricultural Research Organization, Ano, Mie, 514-2392, Japan.     

洋葱花药发育中钙离子分布特征

采用焦锑酸钾沉淀钙离子技术,对洋葱（Alliumcepa）花药发育中Ca^2＋分布进行了研究。在小孢子母细胞时期,小孢子母细胞中的钙沉淀颗粒很少,但绒毡层细胞的内切向壁已出现明显的钙沉淀颗粒。在四分体时期,四分体小孢子的胼胝质壁中出现较多的钙沉淀颗粒;绒毡层细胞内切向壁的钙沉淀颗粒消失,而在外切向壁和径向壁部位的钙沉淀颗粒增加。在小孢子早期,小孢子中也出现了钙沉淀颗粒,而绒毡层细胞内切向壁表面出现了很多絮状物,其上附有细小钙沉淀颗粒。到小孢子晚期,小孢子中出现一些小液泡,细胞质中的钙沉淀颗粒有所下降。此时绒毡层细胞已明显退化,但在绒毡层膜上仍有一些乌氏体和钙沉淀颗粒。在二胞花粉早期,营养细胞中的液泡收缩、消失,细胞质中又出现了较多的钙沉淀颗粒,在质体和其内部的淀粉粒表面上附有较多的钙沉淀颗粒。到二胞花粉晚期,花粉中的钙沉淀颗粒已明显下降,仅在花粉外壁中还有一地钙沉淀颗粒．     

A structural investigation of the ovule in sugar beet, Beta vulgaris: Integuments and micropyle

The micropyle and the integuments of sugar beet (Beta vulgaris) ovules have been investigated by light and electron microscopy during differentiation and maturation of the ovule. The micropyle itself is formed by the inner integument which is surrounded by the outer integument at its base. The micropyle containts a fibrillar PAS+ substance and is often covered by a thin sheet or hymen. Both integuments are cuticle-covered thin sheets, each 2-few cell layers in thickness. In the outer integument an increase in starch accumulation occurs during ovule maturation and probably functions as nutrient storage for embryo development. The inner epidermis of the inner integument differentiates as the most conspicuous cell layer of the beet ovule. During growth and maturation of the ovule a system of small perinuclear vacuoles containing dense material increases steadily in these cells. At maturity this system fills up more than half of each cell and very dense material has accumulated in each vacuole. This vacuole content is highly refractive and contains tannins and/or polyphenols.     

Cytological and histological studies on female gametophyte of Leucojum aestivum (Amaryllidaceae)

In this study, gynoeceum, development of megasporangium, megasporogenesis, megagametogenesis and female gametophyte of Leucojum aestivum were examined cytologically and histologically. Ovules of L. aestivum are of anatropous, bitegmic and crassinucellate type. Inner integument forms the micropyle. Archesporial cell develops directly into a megasporocyte. Embryo sac development is of bisporic Allium type. Filiform apparatus is observed in synergids. Polar nuclei fuse before fertilization to form secondary nucleus near the antipodals.     

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.     

The distribution of ionic calcium in the tissues of the gynoecium ofAntirrhinum majus

Summary The distribution of ionic calcium in the tissues of the gynoecium ofAntirrhinum majus flowers has been studied using the glyoxal bis (2-hydroxy-anil) staining procedure.The highest concentration of ionic calcium is found in the cells of the placenta and the cells lining the inner ovary wall. The cells of the ovule are comparatively low in calcium, and there is no higher concentration of calcium in the region of the micropyle and embryo sac. The cells of the stigma contain less calcium than those of the placenta, but almost the same as the cells of the ovule. The stigmatoid tissue and surrounding parenchyma in the style contain a low amount of calcium, lower than that found in the ovule and stigma. The relevance of these data to the growth and chemotropism of pollen tubes is discussed.This study was made possible by a grant from the Brown-Hazen Fund of Research Corporation and by Grant GB 3243 from the National Science Foundation. The technical assistance of Miss Annabelle M. Birrow is gratefully acknowledged.     

Calcium in the synergid cells and other regions of pearl millet ovaries

Summary The synergids and other cells of mature, unpollinated pearl millet ovaries were investigated using: (1) freeze-substitution fixation in conjunction with scanning electron microscope observations and energy-dispersive X-ray microanalysis to localize total calcium (Ca) and other elements, and (2) antimonate precipitation to selectively localize loosely sequestered, exchangeable calcium (Ca⁺⁺). In freeze-fixed ovaries, the synergid cells, ovary wall, nucellus, and other regions of the ovary displayed, respectively and relatively, extremely high, high, moderate, and low levels of Ca. In antimonate-fixed ovaries, Ca-containing antimonate precipitates exhibited similar distribution patterns. In ovaries fixed using the conventional 2% (w/v) antimonate in fixatives, the synergids were disrupted due to precipitate overload. In the ovary wall, precipitates were mainly located in the intercellular spaces. Some precipitates were observed at the micropyle and along the outer ovule integument, associated with diffuse extracellular material, and in the cell walls of nucellar cells proximal to the micropyle. Examination of precipitate distribution inside the synergids was possible in ovaries fixed using 0.5% (w/v) antimonate in the fixatives. Cytoplasmic organelles of all synergids examined exhibited variable states of disintegration. The amount of precipitates associated with the degenerated organelles appeared to be proportional to the degree of their degeneration. Distinct precipitates were localized in contiguous regions of the nucellar cells fused with the embryo sac, the micropylar half of the embryo sac wall, and the filiform apparatus. The results are discussed in relation to the involvement of Ca⁺⁺ in mediating the functions of synergid cells during fertilization in angiosperms.On Specific Cooperative Agreement 58-43YK-8-0026 with the Department of Biochemistry, University of Georgia, Athens, GA 30602, USA     

Programmed cell death promotes male sterility in the functional dioecious Opuntia stenopetala (Cactaceae)

Background and Aims

The sexual separation in dioecious species has interested biologists for decades; however, the cellular mechanism leading to unisexuality has been poorly understood. In this study, the cellular changes that lead to male sterility in the functionally dioecious cactus, Opuntia stenopetala, are described.

Methods

The spatial and temporal patterns of programmed cell death (PCD) were determined in the anthers of male and female flowers using scanning electron microscopy analysis and histological observations, focusing attention on the transition from bisexual to unisexual development. In addition, terminal deoxynucleotidyl transferase-mediated dUTP nick-end labelling assays were used as an indicator of DNA fragmentation to corroborate PCD.

Key results

PCD was detected in anthers of both female and male flowers, but their patterns differed in time and space. Functionally male individuals developed viable pollen, and normal development involved PCD on each layer of the anther wall, which occurred progressively from the inner (tapetum) to the outer layer (epidermis). Conversely, functional female individuals aborted anthers by premature and displaced PCD. In anthers of female flowers, the first signs of PCD, such as a nucleus with irregular shape, fragmented and condensed chromatin, high vacuolization and condensed cytoplasm, occurred at the microspore mother cell stage. Later these features were observed simultaneously in all anther wall layers, connective tissue and filament. Neither pollen formation nor anther dehiscence was detected in female flowers of O. stenopetala due to total anther disruption.

Conclusions

Temporal and spatial changes in the patterns of PCD are responsible for male sterility of female flowers in O. stenopetala. Male fertility requires the co-ordination of different events, which, when altered, can lead to male sterility and to functionally unisexual individuals. PCD could be a widespread mechanism in the determination of functionally dioecious species.     

Translocation of Uranin within the Living Ovules of Vanilla

In the ovules of Vanilla (Vanilla planifolia Andr.) before fertilization, outer integument surrounded the lower part of ovule. Uranin got into ovule through funiculus, forming, the first center of fluorescence at the chalaza zone of ovule. Then uranin was transported to micropyle end along inner integument, forming the second center of fluorescence at micropyle end of inner integument. Soon, fluorescence appeared in the egg apparatua. After fertilization, the outer integument ovule extended upward, forming micropyle ogerber with inner integument. After getting into ovule through funiculus, uranin spreads to- ward several directions: l. transported to outer integument at the entrance of micropyle; 2. transported downward to chalaza zone along outer integument at the side of funiculus; 3. extended from chalaza zone to the inside and to the outer integument at the side far from funiculus The ovules of Vanilla had no vascular bundles. On transporting in inner integument, however, the cells in inner layer next to the embryo sac appeared to be the major passage. In mature embryo sac, there was cuticle between inner integument and embryo sac at the half of micropyle end. But between embryo sac at the half of chalaza end and nucellus, cuticle was absent. Nutrient could get into embryo sac from chalaza end undoubtedly. As egg apparatus showed the fluorescence after formation of fluorescence center of inner integument at micropylar end, the possibility that nutrient got into embryo sac from micropyle could not be excluded.