银杏贮粉室发生部位的珠心细胞程序性死亡的形态学观察

银杏（Ginkgo bilobaL)贮粉室的发生涉及位于珠孔端的珠心细胞的程序性死亡（PCD）,本研究观察了贮粉室发生过程中发生PCD的珠心细胞的形态学变化。这些珠心细胞在PCD过程中形态变化显著,细胞组分有序地降解,液泡在此起关键作用。在液泡化过程中,细胞质基质和一些细胞器被液泡所吞噬,此时的细胞器结构完整。当液泡膜破裂,细胞质基质消失之后。细胞器才逐步解体。最终,这些珠心细胞仅具有残留的细胞壁,随着胚珠的生长,细胞壁也被破坏,在整个PCD过程中,内膜系统发生明显改变;细胞质膜出泡,产生多泡体;形成多环膜结构;出现由膜包围的小体,其中含有细胞质基质和一些细胞器;液泡膜破裂;细胞器解体;细胞中出现大量的小膜泡。珠孔端的珠心表皮开裂形成贮粉室的开口有两种方式：一种为专一细胞的自溶,而另一种是在两个邻接细胞的中胶层处分离,没有发生细胞的自溶破裂。贮粉室开口位置的特定表皮细胞在开裂发生前就死亡,从而提前标示出表皮开裂的发生位置。这些细胞形态的变化反映出银杏珠心细胞的死亡是受发育调控的PCD过程。     

银杏胚珠贮粉室的早期发育

对银杏 (GinkgobilobaL .)胚珠贮粉室的早期发育过程以及珠心细胞死亡的细胞学机制进行了研究。DNA电泳出现DNAladder和TUNEL标记说明参与形成贮粉室的珠心细胞死亡是程序性死亡 (PCD)过程 ,并且显示出在贮粉室形成中 ,PCD的发生有一定的空间分布式样。结合扫描电镜观察 ,贮粉室的早期发育可分为 4个阶段 :起始事件是位于珠孔端的 3至 4层珠心细胞纵向伸长 ;接着 ,位于珠心组织最上部 (珠孔端 )的珠心细胞启始死亡 ;然后 ,这些已经纵向伸长的珠心细胞向基地和侧向地逐渐死亡 ,形成一个空腔 ;最后 ,珠孔端珠心表皮细胞以开裂的方式与其余表皮细胞脱离而形成贮粉室的开口。大孢子母细胞时期 ,贮粉室尚未发生 ;四分体阶段 ,贮粉室已经开始形成 ;到雌配子体发育时期 ,贮粉室已经完全产生。反映大孢子发育和贮粉室发生的同步性。     

银杏胚珠贮粉室的早期发育

对银杏(Ginkgo biloba L.)胚珠贮粉室的早期发育过程以及珠心细胞死亡的细胞学机制进行了研究.DNA电泳出现DNA ladder和TUNEL标记说明参与形成贮粉室的珠心细胞死亡是程序性死亡(PCD)过程,并且显示出在贮粉室形成中,PCD的发生有一定的空间分布式样.结合扫描电镜观察,贮粉室的早期发育可分为4个阶段:起始事件是位于珠孔端的3至4层珠心细胞纵向伸长;接着,位于珠心组织最上部(珠孔端)的珠心细胞启始死亡;然后,这些已经纵向伸长的珠心细胞向基地和侧向地逐渐死亡,形成一个空腔;最后,珠孔端珠心表皮细胞以开裂的方式与其余表皮细胞脱离而形成贮粉室的开口.大孢子母细胞时期,贮粉室尚未发生;四分体阶段,贮粉室已经开始形成;到雌配子体发育时期,贮粉室已经完全产生.反映大孢子发育和贮粉室发生的同步性.     

花椒珠心胚的超微结构及珠心细胞ATP酶的细胞化学定位

应用透射电镜对花椒（Xanthoxylum bungeanum Maxim)珠心胚原始细胞,多细胞原胚和此时期的珠心细胞及其ATP酶的分布进行了详细的观察,珠心胚原努细胞具厚的细胞壁,明显分为电子致密的外层和电子透明的内层,无胞间连丝,大的核中未见核仁,细胞质富含细胞器,多细胞原胚的壁比原始细胞的薄,电子透明,均质,具胞间连丝,核体积增大,核仁1至2个,细胞质中细胞数的数量明显增加,珠孔端的珠心细胞比胚性细胞体积大,细胞液泡化程度高,细胞质稀薄而呈现衰退趋势,ATP酶分布于液泡膜及液泡液中,与胚性细胞相接触的最内层珠心细胞胞质降解,核严重变形,最终细胞解体,此时无ATP酶活性反应。     

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。     

鹤顶兰珠心细胞程序性死亡的超微结构研究

应用电子显微镜对鹤顶兰(Phaius tankervilliae(Aiton)Bl.)珠心细胞进行了观察,结果发现,珠心细胞程序死亡(programmed cell death,PCD)过程中伴随着液泡破裂、染色质凝聚、细胞质解体等明显特征。在鹤顶兰功能大孢子形成之前,大孢子母细胞的侧细胞壁存在明显的内突。随着胚囊体积的逐渐增大,衰退珠心细胞残留的细胞壁叠合在一起,从而使胚囊壁不断加厚。胚囊成熟前,合点端珠心细胞与胚囊之间有胞间连丝相连。合点端珠心细胞的细胞质状态,特别是液泡形态与大孢子母细胞、功能大孢子、成熟胚囊时期的细胞状态高度相似。结果表明,衰退的珠心细胞不仅为胚囊的扩大提供空间,同时也为胚囊的发育提供营养,合点端珠心细胞对胚囊发育内环境的稳定性起着重要的屏障作用。     

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     

西瓜胚乳衰退过程中的超微结构变化及其对胚发育的作用

西瓜胚乳细胞衰退过程中 ,质膜、液泡膜突起、形成体积较大的囊泡 ,内质网断裂形成体积较小的囊泡 ;细胞质和细胞核降解形成电子致密的碎片沿细胞壁分布 ;细胞壁在衰退过程逐渐变薄 ,由于部分区域分解而使整个壁呈波浪型 ,细胞降解后的物质可直接穿越薄壁处或通过宽约 5 0 nm的胞间连丝向近胚端的胚乳细胞转移。胚乳与珠心组织分界壁 -胚囊壁上有发达的壁内突 ,有利于珠心组织内的物质向胚乳内转运 ;胚乳发育早期与胚共有的壁上内外两侧均有胼胝质沉积 ,壁上无外连丝型的胞间连丝存在 ,胚乳发育后期共有壁上的胼胝质消失 ,胚乳细胞降解物可穿越共有壁进入胚细胞内。实验结果表明西瓜胚乳在发育后期对胚的发育具有重要的作用。     

栽培甜菜大孢子发生的超微结构

栽培甜菜（Beta vulgaris）的大孢子发生为蓼型。减数分裂时,大孢子母细胞核中出现核液泡,形成联会复合体,细胞壁上有胼胝质加厚,并存在细胞质改组现象。大孢子母细胞减数第1次分裂形成二分体,2个细胞均被较厚的胼胝质壁包裹。合点端的二分体细胞中细胞器丰富,线粒体和质体的形态正常,表明完成了再分化。在大多数情况下,珠孔端的二分体细胞在减数第2次分裂前（或分裂的过程中）退化,合点端的细胞分裂产生大小不等的2个细胞,形成三分体。三分体合点端的大孢子体积较大,发育成单倍体的功能大孢子。     

栽培甜菜大孢子发生的超微结构

栽培甜菜(Beta vulgaris)的大孢子发生为蓼型。减数分裂时, 大孢子母细胞核中出现核液泡, 形成联会复合体, 细胞壁上有胼胝质加厚, 并存在细胞质改组现象。大孢子母细胞减数第1次分裂形成二分体, 2个细胞均被较厚的胼胝质壁包裹。合点端的二分体细胞中细胞器丰富, 线粒体和质体的形态正常, 表明完成了再分化。在大多数情况下, 珠孔端的二分体细胞在减数第2次分裂前(或分裂的过程中)退化, 合点端的细胞分裂产生大小不等的2个细胞, 形成三分体。三分体合点端的大孢子体积较大, 发育成单倍体的功能大孢子。     

Changes in cell structure during the formation of root aerenchyma inSAGITTARIA LANCIFOLIA (Alismataceae)

In many wetland species, root aerenchyma is produced by the predictable collapse of root cortex cells, indicating a programmed cell death (PCD). The objective of this study was to characterize the cellular changes that accompany this PCD in the marsh species Sagittaria lancifolia. Structural changes in membranes and organelles were examined during development of root cortex cells to compare with previous examples of PCD. The organization of cortical microtubule (CMT) arrays in root cells from S. lancifolia was also evaluated as a possible predictor of cell lysis. Nuclear fragmentation and condensation were the earliest changes observed in cells undergoing lysis. Breakdown of the tonoplast and other organelles and disruption of the plasma membrane followed. After loss of cytoplasm, cells collapsed to form gas spaces. These results were compared to collapse of root cortical cells of Zea mays and Oryza sativa during aerenchyma development. Changes in the appearance of the cytoplasm of all three species were similar at later stages of aerenchyma development. The relative timing of disintegration of the tonoplast and middle lamella appeared to differ among the three species. Changes in the organization of CMT arrays did not appear to be a predictor of PCD in S. lancifolia. Aerenchyma production in plants involves a type of PCD that is morphologically distinct from PCD described from many animals.     

Pollen tube reuses intracellular components of nucellar cells undergoing programmed cell death in Pinus densiflora

Through the process known as programmed cell death (PCD), nucelli of Pinus densiflora serve as the transmitting tissue for growth of the pollen tube. We sought to clarify the processes of degradation of nucellar cell components and their transport to the pollen tube during PCD in response to pollen tube penetration of such nucelli. Stimulated by pollination, synthesis of large amounts of starch grains occurred in cells in a wide region of the nucellus, but as the pollen tube penetrated the nucellus, starch grains were degraded in amyloplasts of nucellar cells. In cells undergoing PCD, electron-dense vacuoles with high membrane contrast appeared, assumed a variety of autophagic structures, expanded, and ultimately collapsed and disappeared. Vesicles and electron-dense amorphous materials were released inside the thickened walls of cells undergoing PCD, and those vesicles and materials reaching the pollen tube after passing through the extracellular matrix were taken into the tube by endocytosis. These results show that in PCD of nucellar cells, intracellular materials are degraded in amyloplasts and vacuoles, and some of the degraded material is supplied to the pollen tube by vesicular transport to support tube growth.     

Ultrastructural aspects and programmed cell death in the tapetal cells of Lathyrus undulatus Boiss

Programmed cell death (PCD) in the tapetum of Lathyrus undulatus L. was analyzed based on light, fluorescence and electron microscopy to characterize its spatial and temporal occurrence. Development and processes of PCD in secretory tapetal cells of Lathyrus undulatus L. were correlated with the sporogenous cells and pollen grains. At early stages of development the tapetal cells appeared similar to pollen mother cells, structurally. Concurrent with meiosis, tapetum expanded both tangentially and radially as vacuoles increased in size. Tapetal cells most fully developed at young microspore stage. However, tapetum underwent substantial changes in cell organization including nucleus morphology monitored by DAPI. The TUNEL staining confirmed the occurrence of intra-nucleosomal DNA cleavage. In addition to nuclear degeneration which is the first hallmark of PCD other diagnostic features were observed at vacuolated microspore stage intensely; such as chromatin condensation at the periphery of the nucleus, nuclear membrane degeneration, chromatin release to the cytoplasm, vacuole collapse according to tonoplast rupture, shrinkage of the cytoplasm, the increase and enlargement of the endoplasmic reticulum cisternae and disruption of the plasma membrane. After vacuole collapse due to possible release of hydrolytic enzymes the cell components degraded. Tapetal cells completely degenerated at bicellular pollen stage.     

Programmed cell death of Pinus nucellus in response to pollen tube penetration

In ovules of Pinus densiflora, pollen tubes elongate and branch into the nucellar tissue in the direction of the female gametophyte. After pollination, nucellar cells located around the pollen grain and tube die off. We showed here that the nuclei of the nucellar cells were stained by TUNEL (terminal deoxynucleotidyl transferase-mediated dUTP-fluorescein nick end labeling). The number of TUNEL-positive cells increased during pollen tube growth. The tips of pollen tube branches protruded into the nucellar cells to form a convex–concave junction. At this junction, the cell membrane of nucellar cells was separated from the cell wall and the protoplast shrank. Small vesicles and amorphous materials were released from the protoplast into the space between the cell membrane and wall. Vacuoles were collapsed, chromatin was condensed, and mitochondria and plastids were deteriorated in the shrunken protoplast. Agarose gel analysis of DNA isolated from the ovules showed a DNA ladder, suggesting that the nuclear DNA had undergone internucleosomal cleavage. These results suggest that nucellar cells undergo programmed cell death in response to pollen tube penetration with some features resembling apoptosis and other features peculiar to nucellar cells. Received: April 13, 2001 / Accepted: December 10, 2001     

AtRabD2b共抑制植株死亡茎段的显微和超微结构观察

采用树脂包埋技术,以AtRabD2b共抑制植株死亡发生茎段为实验材料,制备半薄切片和超薄切片,观察突变体茎段死亡的细胞学特征。结果表明:(1)共抑制植株茎细胞的死亡首先在表皮细胞层中发现,然后向切片圆周两侧以及内侧细胞蔓延。(2)共抑制植株茎细胞出现染色质边缘化、叶绿体内囊体片层膜数目减少、细胞器成分被液泡吞噬等异常现象。这些细胞学特征暗示共抑制植株茎段发生了细胞程序性死亡,由此推断AtRabD基因对拟南芥茎顶端细胞的生长有重要的维持作用。     

Root Cell Ultrastructure in Developing Aerenchyma Tissue of Three Wetland Species

Patterns of root cortex cell development and ultrastructurewere analysed in Sagittaria lancifolia L., Thalia geniculataL. and Pontederia cordata L. using scanning and transmissionelectron microscopy (SEM, TEM). In all three species, cortexcells were arranged in radial columns extending from the endodermisto the hypodermis/epidermis. During gas space formation, thecortex cells elongated parallel to the root radius and shrankin the plane perpendicular to the radius leaving long and thinrows of cortex cells extending from the endodermis to the epidermis.Although the cortex cells appeared collapsed in tissue withwell-developed gas spaces, TEM revealed that the cortical cellsas well as the epidermal cells maintained intact membranes andmany normal organelles. Formation of root cortex tissue withwell-developed gas spaces does not require cell death in thesespecies. Living cortex cells in root tissue with mature gasspaces could provide a symplastic pathway for transport betweenthe root stele and the living epidermal cells. Copyright 2000Annals of Botany Company Sagittaria lancifolia, Thalia geniculata, Pontederia cordata, aerenchyma, root, wetland, development     

Studies of vegetative compatibility-incompatibility in higher plants

Summary In order to elucidate the events that lead to cellular autolysis, and thus better understand the mechanism of cellular incompatibility betweenSedum telephoides andSolanum pennellii stems, we have followed the appearance and fate of the hydrolytic enzyme acid phosphatase in both the compatibleSedum autograft and the incompatibleSedum/Solanum heterograft. Acid phosphatase was localized by a modified Gomori-type reaction. Following an initial association with the endoplasmic reticulum and dictyosomes by 6–10 hours after grafting, acid phosphatase activity in the compatibleSedum autograft was associated primarily with the plasmalemma, tonoplast, and vacuole. This strict compartmentation in membranes or organelles and absence of enzyme from the cytosol was maintained throughout the development of the compatible autograft inSedum. Although acid phosphatase activity in the incompatible heterograft betweenSedum andSolanum was initially similar to the compatible autograft inSedum, a marked difference in enzyme localization occurred in the two graft partners over time.Solanum cells accumulated increased amounts of acid phosphatase, but the enzyme remained sequestered in the plasmalemma, tonoplast, and vacuole. In comparableSedum cells, however, there was a dramatic increase in acid phosphatase activity in the cytosol, often without any prior compartmentation within the vacuole. This high activity of acid phosphatase in theSedum cytosol was correlated with cellular autolysis, death, and eventual cell collapse to form the characteristic necrotic layer that insulates the stock from the scion. These results suggest that the lethal cellular senescence associated withSedum cells of the incompatible heterograft is correlated with a cytoplasmic release of acid phosphatase. A similar release of the enzyme does not occur in theSolanum stock or in the compatibleSedum autograft. Thus, while acid phosphatase synthesis and/or activation is induced in both the compatible and incompatible grafts, incompatibility betweenSedum andSolanum involves a failure ofSedum cells to isolate hydrolytic enzymes from the cytosol, which subsequently leads to cellular necrosis.Supported in part by grants from the Academic Senate of UCLA, Sigma Xi, the American Philosophical Society, and the URC of Baylor University.     

Ascorbate free radical enhances vacuolization in onion root meristems

Abstract. Ascorbate free radical (AFR) induced cell elongation in merislems of Allium cepa roots by promoting a high vacuolization as shown by the increased vacuole volume, vacuole volume density, tonoplast surface and tonoplast surface density. Accordingly, both plasma membrane- and tonoplast-associated ATPases and vacuole soluble acid phosphatase of meristematic cells were also increased. Neither the other subcellular organelles nor cell proliferation appeared to be significantly affected. It is suggested that AFR may be involved in some plasma membrane events related to the initiation of plant cell elongation.