竹节参雌配子体发育的研究

本文报道了竹节参(Panax japonicus C.A.Mey)雌配子体(胚囊)的发育过程。竹节参大孢子母细胞减数分裂产生线形排列的大孢子四分体。胚囊发育属蓼型,由合点端大孢子发育而成。游离核胚囊时期,胚囊珠孔端的细胞器种类和数量都较胚囊合点端多;胚囊合点端相邻的珠被细胞中有含淀粉粒的小质体,与胚囊珠孔端相邻的退化中的非功能大孢子中则有含淀粉粒的大质体和大类脂体。成熟胚囊中,反足细胞较早退化;极核融合成次生核;卵细胞高度液泡化,细胞器数量较少;助细胞则有丰富的细胞器和发达的丝状器。PAS反应表明,受精前的成熟胚囊中积累淀粉粒。次生核受精后,很快分裂产生胚乳游离核,到几十至数百个核时形成胚乳细胞。卵细胞受精后则要经过较长的休眠期。     

ULTRASTRUCTURE OF THE DEVELOPING MEGASPORE MOTHER CELL OF GINKGO BILOBA

The immature megaspore mother cell of Ginkgo biloba is essentially spherical and is surrounded by a thick, complex wall. A large nucleus occupies the central region of the cell, and the organelles appear to be randomly arranged in the cytoplasm. With approaching maturity and the onset of meiosis, the cell elongates in the direction of the ovular axis. An extensive system of ER develops at the micropylar pole of the cell during elongation, and the plastids and mitochondria migrate to the opposite or chalazal pole. The micropylar end of the mature megaspore mother cell is usually devoid of plastids and mitochondria, but these organelles are densely packed in the chalazal end of the cell below the nucleus. The dictyosomes and dense spherosome-like bodies do not show such polarity in their distribution. At meiosis I plastids and mitochondria are, as a rule, restricted to the chalazal dyad cell that is destined to produce the functional megaspore. The wall of the megaspore mother cell consists of a middle lamella which is irregularly thickened, an outer wall layer resembling the walls of the surrounding nutritive cells, and an inner layer resembling the middle lamella in appearance.     

同源四倍体水稻小孢子发生的超微结构

利用透射电子显微镜对同源四倍体水稻小孢子母细胞减数分裂前及期间的超微结构进行观察,结果发现:(1)减数分裂前及减数分裂早期,小孢子母细胞核糖体密度高,线粒体、质体等细胞器丰富;粗线期核糖体密度显著下降,线粒体、质体等细胞器数量减少;终变期核糖体密度逐渐恢复到减数分裂前状态,而其他细胞器的数量除在二分体时期出现短暂的回升,终变期以后的时期均较少.(2)小孢子母细胞间的连接在小孢子母细胞时期以典型的胞间连丝为主,进入细线期,胞间连丝数量显著减少,宽孔道的胞质通道逐渐增多,粗线期小孢子母细胞间基本通过胞质通道连接,终变期小孢子母细胞间完全分离.(3)随着减数分裂的进行,药壁四层细胞逐渐液泡化,绒毡层细胞中部分小液泡融合成大液泡,形成胞内"空腔";药室内壁细胞出现大量的具有叶绿体结构特征的质体,内含丰富的淀粉粒,到了四分体时期质体数量及内含的淀粉粒显著减少.     

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。     

Pre-fertilization ovule development inCapsella: ultrastructure and ultracytochemical localization of acid phosphatase in the meiocyte

Summary Pre-meiotic and prophase I ovules ofCapsella bursa-pastoris (L.) Medic.(monosporic,Polygonum type of gametophyte development) were fixed routinely or incubated in a modified Gomori medium containing -glycerophosphate as a substrate. Prior to the beginning of meiosis the potential meiocyte is ultrastructurally similar to the other cells of the nucellus and is distinguished only by its size and position. At the initiation of prophase I dramatic ultrastructural and ultracytochemical changes take place in the female meiocyte. These include the sudden appearance of cytoplasmic structures composed of single and multiple concentric cisternae, distinctive changes in plastids and mitochondria, and the blebbing of 0.3 m double-membraned vesicles from the nuclear envelope. The concentric cisternae encapsulate portions of cytoplasm containing ribosomes, plastids, mitochondria, ER fragments and vesicles. Both single and multiple concentric cisternae localize high levels of acid phosphatase and function as autophagic vesicles (AVs) that sequester ribosomes and organelles for destruction during meiosis. Plastids stop dividing and become more spherical during prophase I. Some plastids localize acid phosphatase and many show continuities between the outer membrane and the plastid envelope and acid phosphatase-rich RER cisternae. Mitochondria appear as dense, contracted spheres or rods. Some mitochondria localize acid phosphatase but they do not show membrane confluencies with the ER. Some of the plastids and mitochondria that are segregated into the functional megaspore at meiosis II are destroyed but others apparantly survive meiosis and give rise to the plastid and mitochondrial populations of the young gametophyte (Schulz andJensen, unpublished). The lateral and end walls of the meiocyte show patches of intense aniline blue fluorescence and the chalazal end wall of the cell is perforated with large numbers of plasmodesmata.Research supported by NSF Grant PCM-79-11018. The authors gratefully acknowledge the valuable assistance of David Lee Ivans in this project.     

The Formation of Pollenkitt in Apium nodiflorum (Apiaceae)

Apium nodiflorum produces a considerable amount of pollenkittwithin a secretory tapetum. ER and plastids (elaioplasts) participatein pollenkitt formation. Both organelles deposit precursorswithin vesicles, which finally fuse to form pollenkitt. Apium nodiflorum L., Apiaceaesecretory tapetum, pollenkitt, ER, plastids, elaioplasts     

Cellular organisation in meiotic and early post-meiotic rice anthers

We have used fluorescent, confocal laser and transmission electron microscopy (TEM) to examine cellular organisations, including callose (1,3-beta-glucan) behaviour, in meiotic and early post-meiotic rice anthers. These features are critical for pollen formation and provide information to better understand pollen sterility caused by abiotic stress in rice and other monocotyledonous species. Among organelles during meiosis, abundant plastids, mitochondria and nuclei of the anther cells show distinctive features. Chloroplasts in the endothecium store starch and indicate a potential for photosynthetic activity. During meiosis, the middle layer cells are markedly compressed and at the tetrad stage are either vacuolated or filled with degenerating electron-opaque organelles. Viable mitochondria, stained with Rhodamine 123, are seen in the endothecium and tapetum, but the mitochondria in the middle layer are not stained during meiosis. The radial walls of the tapetum are disorganised and degenerating, indicating the formation of a syncytium; pro-orbicules are located at the locular walls at the tetrad stage. Immunohistochemical studies show that the sporogenous cells are entirely enveloped by a thick callosic layer at early meiosis. Cell plate callose was assembled in a plane between the dyad cells. In the tetrads, however, callose formed only at the centre, showing that the tetrad microspores are not enveloped but separated by callose walls. Thick, undulating electron-opaque walls around the tetrads indicate the beginning of exinous microspore wall differentiation.     

Development of the pollen grain and tapetum of wheat (Triticum aestivum) in untreated plants and plants treated with chemical hybridizing agent RH0007

Summary A study of pollen development in wheat was made using transmission electron microscopy (TEM). Microspores contain undifferentiated plastids and mitochondria that are dividing. Vacuolation occurs, probably due to the coalescence of small vacuoles budded off the endoplasmic reticulum (ER). As the pollen grain is formed and matures, the ER becomes distended with deposits of granular storage material. Mitochondria proliferate and become filled with cristae. Similarly, plastids divide and accumulate starch. The exine wall is deposited at a rapid rate throughout development, and the precursors appear to be synthesized in the tapetum. Tapetal cells become binucleate during the meiosis stage, and Ubisch bodies form on the plasma membrane surface that faces the locule. Tapetal plastids become surrounded by an electron-translucent halo. Rough ER is associated with the halo around the plastids and with the plasma membrane. We hypothesize that the sporopollenin precursors for both the Ubisch bodies and exine pollen wall are synthesized in the tapetal plastids and are transported to the tapetal cell surface via the ER. The microspore plastids appear to be involved in activities other than precursor synthesis: plastid proliferation in young microspores, and starch synthesis later in development. Plants treated with the chemical hybridizing agent RH0007 show a pattern of development similar to that shown by untreated control plants through the meiosis stage. In the young microspore stage the exine wall is deposited irregularly and is thinner than that of control plants. In many cases the microspores are seen to have wavy contours. With the onset of vacuolation, microspores become plasmolyzed and abort. The tapetal cells in RH0007-treated locules divide normally through the meiosis stage. Less sporopollenin is deposited in the Ubisch bodies, and the pattern is less regular than that of the control. In many cases, the tapetal cells expand into the locule. At the base of one of the locules treated with a dosage of RH0007 that causes 95% male sterility, several microspores survived and developed into pollen grains that were sterile. The conditions at the base of the locule may have reduced the osmotic stress on the microspores, allowing them to survive. Preliminary work showed that the extractable quantity of carotenoids in RHOOO7-treated anthers was slightly greater than in controls. We concluded that RH0007 appears to interfere with the polymerization of carotenoid precursors into the exine wall and Ubisch bodies, rather than interfering with the synthesis of the precursors.     

Pollen and Tapetum Development in Male Fertile Rosmarinus Officinalis L. (Lamiaceae)

The development of microspores/pollen grains and tapetum was studied in fertile Rosmarinus officinalis L. (Lamiaceae). Most parts of the cell walls of the secretory anther tapetum undergo modifications before and during meiosis: the inner tangential and radial cell walls, and often also the outer tangential and radial wall, acquire a fibrous appearance; these walls become later transformed into a thin poly-saccharidic film, which is finally dissolved after microspore mitosis. Electron opaque granules found within the fibrous/lamellated tapetal walls consist of sporopollenin-like material, but cannot be interpreted as Ubisch bodies. The middle lamella and the primary wall of the outer tangential and radial tapetal walls remain unmodified, but get covered by an electron opaque, sporopollenin-like layer. Pollenkitt is formed only by lipid droplets from the ground plasma and/or ER profiles, the plastids do not form pollenkitt precursor lipids. Tapetum maturation (“degeneration”) does not take place before late vacuolate stage.

The apertures are determined during meiosis by vesicles or membrane stacks on the surface of the plasma membrane. The procolumellae are conical, but at maturity the columellae are more cylindrical in shape. The columellar bases often fuse, but a genuine foot layer is lacking. The formation of the endexine starts with sporopollenin-accumulating white lines adjacent to the columellar bases. Later, the endexine grows more irregularly by the accumulation of sporopollenin globules. In mature pollen the intine is clearly bilayered.

Generative cells (GCs) and sperm cells contain a comparatively large amount of cytoplasm, and organelles like mitochondria, dictyosomes, ER, and multi-vesicular bodies, but no plastids; GCs and sperms are separated from the vegetative cell only by two plasma membranes.     

Structure of the Needles in the Early Phases of Development in Pinus ponderosa P. et C. Lawson with Special Reference to Plastids

Before they emerged from the fascicular sheath, the tissuesof young needles of Pinus ponderosa P. et C. Lawson alreadyshowed some characteristics typical of mature needles. The organelles,particularly the plastids, had undergone different development.The plastids in different types of cell varied in their ultrastructureand in association with the endoplasmic reticulum (ER). A sheathof ER was observed around the amoeboid plastids in epidermalcells, epithelial cells of resin ducts and maturing transfusiontracheids whereas there was no ER sheath around the young mesophyllchloroplasts, the fusiform chloroplasts in some transfusiontracheids and the proplastids in xylem and phloem cells. Thecontent of chlorophyll (a+b) was 0·85 g kg^-1 dry matterand chlorophyll a/b ratio was 2·70. The needles may becomephotosynthetically active whilst still within the fascicularsheaths.Copyright 1993, 1999 Academic Press Pinus ponderosa, ponderosa pine, needle structure, needle ontogeny, plastids, endoplasmic reticulum     

ULTRASTRUCTURE OF TETRASPOROGENESIS IN THE CORALLINE ALGA HALIPTILON CUVIERI(RHODOPHYTA)1

Tetrasporogenesis begins with the formation of the tetra-sporocyte, an elongate, apparently wall-less, cell containing few organelles. The tetrasporocyte rapidly elongates and a distinctive cell wall forms before the onset of meiosis. During this elongation phase there is also an increase in the number of plastids and mitochondria. The meiotic tetrasporocyte is characterized by extensive development of perinuclear endoplasmic reticulum (PNER) and peripheral endoplasmic reticulum (PER) and during the latter stages of sporogenesis by internuclear endoplasmic reticulum. Immediately next to the nuclear envelope the inter-cisternal spaces of the PNER are filled with very electron dense material and the PNER cisternae are quite narrow, while further away from the nucleus the PNER cisternae dilate. Throughout meiosis there is continued replication of plastids and mitochondria as well as synthesis of starch and the formation of Golgi-derived vesicles with very osmiophilic contents. Cytokinesis begins with the formation of striated thickenings on the inside of the tetrasporocyte wall, at the sites where the cleavage furrow, produced by infurrowing of the plasmalemma, will be formed. Early in cytokinesis the PER disappears and is replaced by osmiophilic vesicles and mitochondria. Tubular plasmalemma invaginations of 27–30 nm width also appear during the early stages of tetraspore wall formation. The ultra-structure of the early stages of tetraspore germination is also described.     

ORGANELLE DISTRIBUTION AND APPORTIONMENT DURING MEIOSIS IN THE MICROSPOROCYTE OF GINKGO BILOBA L.

Microsporocytes of Ginkgo biloba were observed in stages of meiosis with both the light and electron microscopes. After telophase I, all of the plastids and mitochondria were located in the equatorial region of the cell and this non-random pattern of distribution was maintained until nuclear division had ceased. The ensuing apportionment of organelles among tetrad members was approximately equal, and was coincident with centripetal formation of the partitioning walls. Although no mechanisms for the initial equatorial positioning or later dispersal of the organelles could be ascertained, membrane proliferations were prevalent and may have played a role in maintaining the pattern of organelle distribution through the duration of the second division. Microtubules, which permeate the central region of the cell may have also functioned to maintain the non-random pattern of organelle distribution.     

杨树顶芽细胞内质网与其他膜系统的结构联系及其在休眠过程中的变化

杨树（Ｐｏｐｕｌｕｓ ｄｅｌｔｏｉｄｅｓ Ｂａｒｔｒ．ｅｘ Ｍａｒｓｈ）顶芽分生组织细胞经一种改良的高锰酸钾固定法固定后,显示出一种十分清晰的内膜结构,尤其展现了内质网与其他膜系统存在一种结构上的密切联系。一些与核膜相连接的内质网伸展到细胞质中与线粒体、质体及高尔基体发生联系,可延伸到质膜。还有些内质网的一端与一个细胞的核膜相连结,其另一端穿过胞间连丝与邻近的另一个细胞的核膜相连结,在两个相邻的细     

Ca2+-homeostasis Differs Between Plant Species with Different Cold-tolerance at 4℃ Chilling

Electron microscopic observations revealed that the tissues of poplar (Populus deltoides Bartr. ex Marsh) apical bud cells, which were fixed by a modified procedure of potassium permanganate fixative, showed a distinct endomembrane organization, in particular, the structural associations of the endoplasmic reticulum (ER) with other membrane systems. The striking findings are that some ER elements were in connection with the nuclear envelopes of two adjacent cells through plasmodesmata, and many ER elements were also associated with mitochondria, plastids, Golgi bodies or the plasma membrane (PM), forming a bridge-like continuum among various endomembrane systems or between nucleus to nucleus. A great number of plasmodesmata existed between cells, indicating a perfectly integrated symplasmic structure in poplar apical bud meristem grown in a long day environment. During the short day-induced dormancy, ER contracted, leading to its disassociation between nuclei, and between the nucleus and organelles/plasmalemma in many cells. After dormancy broke and shoots growth resumed, contracted ER was no longer observed in the apical bud cells. The ER associations with other endomembrane systems and the intercellular communication channels were re-established similar to that of plants before dormancy induction. These observations suggest that ER may play an important role in linking-up between the nucleus and organelles, and between the nucleus and the nucleus (or cell-to-cell), and seemingly coordinating various physiological processes by the bridging-like associations. And the contraction of ER under short-day may result in the growth cessation and the development of dormancy in poplar.     

大葱小孢子母细胞至二胞早期花粉发育的超微结构观察

用电镜观察了章丘大葱 (AlliumfistulosumL .)从小孢子母细胞至二胞早期花粉发育的超微结构。终变期的花粉母细胞 ,胼胝壁外方的相邻初生壁间及胞间隙内 ,存在胞间物质 ,四分体期 ,此物质尚部分存在。小孢子母细胞减数分裂前 ,细胞质内含有脂滴 ,小孢子有丝分裂以后 ,脂滴增多增大。小孢子分裂后期 ,质体已积累淀粉粒 1至多个。二胞早期花粉之营养细胞质内 ,有些含淀粉质体亦含脂滴。各发育期 ,核糖体及多聚合糖体丰富 ,并有很多的粗面内质网、高尔基体及小泡、线粒体 ,显示蛋白质、糖类及其它物质合成及运输作用的活跃。小孢子缺中央大液泡。有丝分裂后期 ,细胞器集中于未来的营养细胞极。小孢子胞质分裂期 ,有些内质网贴近或与花粉质膜相连 ,它们或有可能互相融合 ,扩大质膜面积而适应花粉的生长。还讨论了不同时期高尔基体小泡的作用。     

The endoplasmic reticulum in the cortex of developing guard cells: coordinate studies with chlorotetracycline and osmium ferricyanide

The distribution of endoplasmic reticulum (ER) was investigated in young guard cells of Vicia faba and Allium cepa in order to gain more information on the control of guard cell development. Young, living guard cells of V. faba fluoresce when exposed to 25-100 microM chlorotetracycline (CTC). Intense fluorescence is restricted to the cytoplasm between the nucleus and adjacent regions of the ventral and paradermal walls. Much of the fluorescence is fibrillar in appearance and seems to arise from endomembranes, but not from particulate organelles such as mitochondria and plastids. A similar fluorescence pattern is produced by the membrane probes oxytetracycline and N-phenyl-1-napthylamine. Procaine and dibucaine render the fluorescence highly prone to photobleaching. Fluorescence appears near the ventral wall during early stages of cell development but declines when the guard cells mature. Epidermal tissue of V. faba and A. cepa was examined in the electron microscope with the aid of osmium ferricyanide staining. ER appears to be concentrated in regions of the guard cell that exhibit intense CTC fluorescence, while no other organelles (e.g., mitochondria) are similarly distributed. Much of the ER consists of a tubular network in close proximity to the plasmalemma. Our results indicate that the ER becomes asymmetrically distributed in young guard cells adjacent to those regions of the cell wall that undergo extensive thickening during cell differentiation. Furthermore, these membranes appear to sequester divalent cations such as Ca2+.     

Sporogenesis in Eusporangiate Ferns: II. Polyplastidic Meiosis in Ophioglossum (Ophioglossales)

Ophioglossum petiolatum . Unlike Angiopteris (Marattiales), which is monoplastidic, Ophioglossum undergoes polyplastidic meiosis like members of the fern-seed plant clade. The meiotic spindle is distinctly multipolar in origin and is consolidated into a bipolar spindle that is variously twisted and curved to accommodate the large number of chromosomes. Although a phragmoplast forms after first meiosis, no wall is deposited. Instead, an organelle band consisting of intermingled plastids and mitochondria is formed in the equatorial region between the dyad domains. Following second meiosis, a complex of phragmoplasts forms among sister and non-sister nuclei. Cell plates are deposited first between sister nuclei and then in the region of the organelle band resulting in a tetrad of spores each with a equal allotment of organelles. Received 30 January 2001/ Accepted in revised form 24 April 2001     

Ultrastructure of Non-Articulated Laticifers in Allamanda violacea

Ultrastructure studies on the differentiation of non-articulatedbranched laticifers in Allamanda violacea Gardn. were carriedout. Growing laticifers show sequential changes. In the earlystage, the laticifers possess electron dense cytoplasm, abundantmitochondria, ER, ribosomes, small vacuoles, nucleus and plastidwith starch-grains. The ER dilates to form small vacuoles whichcoalesce at the later stages. A large central vacuole is formedin the mature laticifers due to the cellular autophagy of cytoplasmincluding the cell organelles. At this stage, the mitochondriapossess a few cristae and plastids with plastoglobuli and smallstarch grains. Towards the end of differentiation the cytoplasmis restricted to a thin parietal layer along the cell wall,the remaining organelles being either reduced in number or degenerate.Plasmodesmata and primary pit fields are occasionally observedbetween the laticifer and the adjacent parenchyma cell. Allamanda violacea, laticifers, ultrastructure