小麦胚乳细胞内,细胞间胞质骨架分布格局的超微结构观察

以小麦（ＴｒｉｔｉｃｕｍａｅｓｔｉｖｕｍＬ．）幼嫩胚乳为材料,经ＴｒｉｔｏｎＸ１００抽提、ＤＧＤ（ｄｉｅｔｈｙｌｅｎｅｇｌｙｃｏｌｄｉｓｔｅａｒａｔｅ）渗透、包埋,制备去包埋剂超薄切片,对细胞内、细胞间胞质骨架的分布格局与特征进行了电镜观察。由所获图像可见,胞质骨架呈主要由微管、微丝组成的三维网络结构;特别值得注意的是,有不少５～７ｎｍ的微丝在多处从网络表层向胞壁界面方向突出,并时而可见其横贯分界壁连接相邻骨架网络而将相邻细胞骨架联成一体。胚乳组织中微丝的跨胞分布以两种形式存在,直径达１００～２００ｎｍ微丝束的跨越和单个微丝的分散贯穿,看来这与该组织中开放态胞间通道与正常胞间连丝同时并存相吻合。初步讨论了微丝参与正常胞间连丝结构的可能性。     

去包埋剂制片术揭示小麦珠被组织中微丝的跨胞分布

以DGD(diethylene glycol distearate)包埋、去包埋剂制片法,结合常规电镜制备术,观察研究了小麦珠被组织中胞间连丝的结构与分布特征及其与微丝的关系。试验结果表明,同层珠被细胞间壁上胞间连丝的分布密度比上下层珠被间的要显著地高得多;珠被中胞间连丝保持固有的正常结构,孔径30—40 nm,变动幅度不大,观察不到如作者以前在小麦珠心和胚乳中所见的那种胞间连丝经结构修饰而扩大、转变为开放态的景象。对去包埋剂制片的观察进一步揭示,从胞质骨架网络表层有纤细微丝以分散状向外伸展突入分界壁,时而可见各个微丝横贯分界壁而连接相邻骨架网络的图象。联系珠被中正常胞间连丝结构的稳定性与各个微丝以分散状跨越分界壁,讨论了微丝参与胞间连丝结构的可能性与可能模式。     

The cytoskeleton facilitates a three-dimensional symplasmic continuum in the long-lived ray and axial parenchyma cells of angiosperm trees

The microtubule (MT), microfilament (MF) and myosin components of the cytoskeleton were studied in the long-lived ray and axial parenchyma cells of the secondary xylem (wood) and secondary phloem of two angiosperm trees, Aesculus hippocastanum L. (horse-chestnut) and Populus tremula L. x P. tremuloides Michx. (hybrid aspen), using indirect immunofluorescence localisation and transmission electron microscopy. MTs and MFs were bundled and oriented axially (parallel to the cell's long axis) within all parenchyma cell types after they had fully differentiated. Additionally, actin and myosin were immunolocalised at the thin-walled membranes of the pits, which linked cells in neighbouring files of both ray and axial parenchyma, and at the pits between axial and ray parenchyma cells themselves. Anti-callose antibody immunolocated the plasmodesmata at the pit membranes, and in the same pattern as that of anti-myosin. Ray cells are important symplasmic pathways between the xylem and the phloem throughout the life of trees. We hypothesise that the MT and MF components of the cytoskeleton in the ray and axial parenchyma cells are involved in the transport of materials within those cells, and, in association with the acto-myosin of plasmodesmata at pit fields, are also important in intercellular transport. Thus, the symplasmic coupling between ray cells, between axial parenchyma cells, and between axial parenchyma and ray cells represents an extensive three-dimensional communication pathway permeating the tree from the phloem through the cambium into the wood. We suggest that this cytoskeletal pathway has an important role in delivery of photosynthate, and mobilised reserves, to the actively dividing cambium, and in the movement of materials to sites of reserve deposition, principally within the wood. This pathway could also have an important role in co-ordinating developmental processes throughout the tree.     

The Structural Changes of the Basal Region of Wheat Proembryo in Relation to Nurture Absorption

There are some cellular fail and degeneration in the parietal area of the basal region of developing wheat proembryo. Electron microscopic studies reveal that the envelopment of peripheral wall to the proembryo is partly ruptured in this area and the disassembled protoplasm of the degenerated cells mixes with the disintegrated constituents of adjacent endosperm cells. Hence, in the limited area a direct communication between the inner surviving proembryo cells and the surrounding medium is established. A number of ectodesma-like plasmodesmata and open channels appear at the boundary wall, various nutrients may enter the proembryo via symplastic pathway or by endocytosis. The surrounding macromolecules (disassembled nuclei, mitochondria, cytoplasmic granules and vesicles packed with fibrils) appear to traverse across the wall continually, and it seems that this is'an important mode of nurture translocation. Also, within the proembryo some of the densely distributed plasmodesmata undergo modification and become fully opened for macromolect, les traversing, which is in favor of re-distribution of cell contents amongst proembryo cells. Presumably, the structural changes occurred in the basal region is a special kind of differentiation which results in function of this local area as apparatus of nurture absorption. Evidently, it would enhance the incorporation of external materials into the proembryo, and then the normal proliferation, development and differentiation of proembryo cells would be ensured.     

The distribution of plasmodesmata in the root tip of maize

Summary The distribution of plasmodesmata in different regions of the root apex of Zea mays has been analysed from electron micrographs. There are many more plasmodesmata traversing transverse walls than across longitudinal walls in all the regions studied. When the number of plasmodesmata per unit cell volume is calculated, cells in non-dividing tissue have a considerably lower value than cells in dividing tissue. Evidence for the transport of materials between cells via plasmodesmata is summarised. If it is accepted that plasmodesmata do act as channels for intercellular communication then we believe that their pattern of distribution may be a contributory factor to the process of cell differentiation.     

在三维结构上对百合花粉母细胞actin的免疫定位

传统的切片仅仅能够显示样品的平面结构,不能用于细胞中三维网络结构的研究。笔者在DGD(diethylene glycol distearate)包埋去包埋的基础上,结合电镜免疫胶体金技术对大卫百合花粉母细胞胞间及胞内细胞的骨架系统进行了研究,观察到高反差细胞微梁结构的三维网络,actin这一细胞骨架的主要成员被定位在该微梁结构纤维上。三维结构上的研究表明,actin不但是植物细胞核及细胞质骨架的成员,而且也存在于胞间连接结构(胞质桥和胞间连丝)中,推测它可能与细胞融合有关。实验结果同时表明,三维结构免疫胶体金技术对于细胞骨架和核基质的结构蛋白研究是行之有效的。     

Subcellular localization determines the availability of non-targeted proteins to plasmodesmatal transport

BACKGROUND: Individual plant cells are encased in a cell wall. To enable cell-to-cell communication, plants have evolved channels, termed plasmodesmata, to span thick walls and interconnect the cytoplasm between adjacent cells. How macromolecules pass through these channels is now beginning to be understood. RESULTS: Using two green fluorescent protein (GFP) reporters and a non-invasive transfection system, we assayed for intercellular macromolecular traffic in leaf epidermal cells. Plasmodesmata were found in different states of dilation. We could distinguish two forms of protein movement across plasmodesmata, non-targeted and targeted. Although leaves have generally been considered closed to non-specific transport of macromolecules, we found that 23% of the cells had plasmodesmatal channels in a dilated state, allowing GFP that was not targeted to plasmodesmata to move into neighboring cells. GFP fusions that were targeted to the cytoskeleton or to the endoplasmic reticulum did not move between cells, whereas those that were localized to the cytoplasm or nucleus diffused to neighboring cells in a size-dependent manner. Superimposed upon this non-specific exchange, proteins that were targeted to the plasmodesmata could transit efficiently between 62% of transfected cells. CONCLUSIONS: A significant population of leaf cells contain plasmodesmata in a dilated state, allowing macromolecular transport between cells. Protein movement potential is regulated by subcellular address and size. These parameters of protein movement illustrate how gradients of signaling macromolecules could be formed and regulated, and suggest that non-cell-autonomous development in plants may be more significant than previously assumed.     

Button botany: plasmodesmata in vegetable ivory

The hard endosperm of species of the palm genus Phytelephas (elephant plant), known as vegetable ivory, was used in the manufacture of buttons in the nineteenth century, the early twentieth century, and again in more recent times. Here, we show that the pathways for intercellular communication, including the cytoplasm in opposite pits and the plasmodesmata that traverse the cell wall, can be visualized in century-old inexpensive buttons that are readily available in antique shops.     

Are there symplastic connections between the endosperm and embryo in some angiosperms?—a lesson from the Crassulaceae family

It is believed that there is symplastic isolation between the embryo (new sporophyte) and the endosperm (maternal-parental origin tissue, which nourishes the embryo) in angiosperms. However, in embryological literature there are rare examples in which plasmodesmata between the embryo suspensor and endosperm cells have been recorded (three species from Fabaceae). This study was undertaken in order to test the hypothesis that plasmodesmata between the embryo suspensor and the endosperm are not so rare but also occur in other angiosperm families; in order to check this, we used the Crassulaceae family because embryogenesis in Crassulaceae has been studied extensively at an ultrastructure level recently and also we tread members of this family as model for suspensor physiology and function studies. These plasmodesmata even occurred between the basal cell of the two-celled proembryo and endosperm cells. The plasmodesmata were simple at this stage of development. During the development of the embryo proper and the suspensor, the structure of plasmodesmata changes. They were branched and connected with electron-dense material. Our results suggest that in Crassulaceae with plasmodesmata between the endosperm and suspensor, symplastic connectivity at this cell-cell boundary is still reduced or blocked at a very early stage of embryo development (before the globular stage). The occurrence of plasmodesmata between the embryo suspensor and endosperm cells suggests possible symplastic transport between these different organs, at least at a very early stage of embryo development. However, whether this transport actually occurs needs to be proven experimentally. A broader analysis of plants from various families would show whether the occurrence of plasmodesmata between the embryo suspensor and the endosperm are typical embryological characteristics and if this is useful in discussions about angiosperm systematic and evolution.     

Phragmoplast of the green alga Spirogyra is functionally distinct from the higher plant phragmoplast

Cytokinesis in the green alga Spirogyra (Zygnemataceae) is characterized by centripetal growth of a septum, which impinges on a persistent, centrifugally expanding telophase spindle, leading to a phragmoplast-like structure of potential phylogenetic significance (Fowke, L. C., and J. D. Pickett-Heaps. 1969. J. Phycol. 5:273-281). Combining fluorescent tagging of the cytoskeleton in situ and video- enhanced differential interference contrast microscopy of live cells, the process of cytokinesis was investigated with emphasis on cytoskeletal reorganization and concomitant redistribution of organelles. Based on a sequence of cytoskeletal arrangements and the effects of cytoskeletal inhibitors thereon, cytokinetic progression could be divided into three functional stages with respect to the contribution of microfilaments (MFs) and microtubules (MTs): (1) Initiation: in early prophase, a cross wall initial was formed independently of MFs and MTs at the presumptive site of wall growth. (2) Septum ingrowth: numerous organelles accumulated at the cross wall initial concomitant with reorganization of the extensive peripheral interphase MF array into a distinct circumferential MF array. This array guided the ingrowing septum until it contacted the expanding interzonal MT array. (3) Cross wall closure: MFs at the growing edge of the septum coaligned with and extended along the interzonal MTs toward the daughter nuclei. Thus, actin-based transportation of small organelles during this third stage occurred, in part, along a scaffold previously deployed in space by MTs. Displacement of the nuclei- associated interzonal MT array by centrifugation and depolymerization of the phragmoplast-like structure showed that the success of cytokinesis at the third stage depends on the interaction of both MF and MT cytoskeletons. Important features of the phragmoplast-like structure in Spirogyra were different from the higher plant phragmoplast: in particular, MFs were responsible for the positioning of organelles at the fusion site, contrary to the proposed role of MTs in the higher plant phragmoplast.     

Studies on graft unions

Summary The occurrence of plasmodesmata in the graft interfaces of two heteroplastic grafts (Impatiens walleriana onImpatiens olivieri andHelianthus annum onVicia faba) has been studied. For both systems two types of intercellular strand are described: 1. Continuous plasmodesmata interconnecting the cells of stock and scion and 2. half plasmodesmata traversing the wall part of one partner cell without connection to the abutting cell. Single strands or branched forms occur in both types of plasmodesma. In the case of half plasmodesmata, branchings with extended median nodules predominate. The distribution of half and continuous plasmodesmata varies with the different areas of a graft interface: in the region of bridging vascular tissues most cell connections are continuous. In areas where cortex or pith-derived callus cells and those of misaligned tissues (cortex/vascular tissue; cortex/pith; pith/vascular tissue) match, discontinuous strands predominate.Branched half plasmodesmata also occur in presumably fused walls between related callus cells; they are typical structures secondarily formed in non-division walls.The results are discussed with regard to compatibility/incompatibility phenomena in heterografts and the development and function of interspecific cell bridges.     

洋葱花粉母细胞中胞间连丝和胞质通道内的胞质骨架

用DGD包埋去包埋方法,观察了洋葱花粉母细胞中胞间连丝和胞质通道内的胞质骨架分布。结果发现,在花粉母细胞的胞间连丝内有胞质骨加分布,这些骨架纤维集结成束,穿过胞间连丝。在胞质通道内也有胞质骨架分布,但与胸间连丝内的骨困分布有所不同,主要表现为两种形式;骨架纤维致密或稀少。研究讨论了胞质骨架在胞间连丝和胞质通道内的作用。     

Cytoskeleton-induced alterations of the lectin activity in winter wheat under cold hardening and abscisic acid (ABA)

The roots and leaves of 7-day seedlings of three winter wheat cultivars differing in frost resistant were used to study changes in lectin activity under cytoskeleton modifiers (DMSO-7%; colchicine-1 m m; oryzalin-15 microm; cytochalasin B-15 microm) of non-hardened (23 degrees C) and hardened (2-3 degrees C, 3-7 day) plants. Plants were grown with ABA (30 microm) or without ABA. Pretreatment with colchicine, oryzalin [inhibitors of microtubules (MT) polymerization], cytochalasin B [inhibitor of microfilament (MF) polymerization] increased the activity of cell wall lectins, although pretreatment with DMSO (stabilizer of microtubules) decreased the activity. Both hardening and ABA decreased the effect of the cytoskeletal modifiers. These results could be explained by the appearance of tolerant MTs with less affinity. It is probable that increase in the activity of cell wall lectins may be the compensatory mechanism which stabilizes the cytoskeleton structure in conditions tending to disrupt it. The genotype with low resistance had higher sensitivity of lectin activity to cytoskeleton modifiers than the frost resistant genotype. The results suggest that leaves have more stable MTs and MFs and stronger MT-MF binding than roots.     

Structures of the plant trophic tract: Plastid stromules and cell-wall plasmodesmata

Plastid stromules and cell-wall plasmodesmata are special plant-cell stsructures. They were discovered a century and a half apart: stromules at the beginning of the 21st century and plasmodesmata the end of the 19th. The former and latter are intra- and intercellular fragments, respectively, of endoplasmic reticulum, which is a network for photosynthesis distribution in the plant body. Methods and history of discovery, structural similarities and differences, and series of functional interpretations are discussed. The origins of both structures are connected with photosynthesis and photosynthate export. Their tubular structure and transport function are similar. The mobility of both is under control of the actomyosin cytoskeleton. The temperature regimes of formation and functioning also are the same. Photosynthesis is possible at 0°C and even lower. The structures of the exporting network—stromules and plasmodesmata—do not form below 10°C, and after 20°C the numbers of the former and latter significantly increase in relation to growth of cytoskeleton plasticity. The structural and functional continuity of stromules and plasmodesmata are postulated as the mobile trophic tract of vascular plants.     

贮藏洋葱抽苔时鳞片叶表皮细胞的细胞学变化

利用透射电镜观察了洋葱抽苔时其鳞片叶表皮细胞的亚显微结构变化。幼嫩鳞片叶表皮细胞结构正常：液泡在细胞中央,细胞质在靠近细胞壁的边缘;细胞质中富含质体、线粒体和核糖体等细胞器;胞间连丝直径约为５０ｎｍ。伴随着细胞的衰退,细胞质变得松散,在液泡中出现大量絮状物,细胞器逐渐解体。少数胞间连丝直径扩大,达到８０ｎｍ左右,它可能在大分子胞间转移中起重要作用。在衰老细胞中,核和质体已解体但多数胞间连丝仍维持正常状态。     

Confocal Fluorescence Microscopic Observation on the Transcellular Distribution of Actin Filaments in the Epidermis of Garlic Clove Sheath

By means of paraformaldehyde fixation, Triton X-100 extraction and TRITC-phalloidin staining, the presence and distribution patterns of F-actin in the outer epidermal cells of the garlic (Allium sativum L.) sheath were studied with fluorescence probe technique and confocal laser scanning microscopy. There were a lot of actin filaments (AFs) impenetrate the cell wall, but the AFs with red fluorescence were absent when the cells were treated with cytochalasin D before fixation; the same result was obtained when the cells were treated with unlabeled phalloidin. These results indicate the presence of F-actin in the intercellular channels and that it is related to the plasmodesmata and intercellular trafficking of macromolecules.     

The cellular pathway of photosynthate transfer in the developing wheat grain. III. A structural analysis and physiological studies of the pathway from the endosperm cavity to the starchy endosperm

The cellular pathway of sucrose transfer from the endosperm cavity to the starchy endosperm of developing grains of wheat (Triticum turgidum) has been elucidated. The modified aleurone and sub-aleurone cells exhibit a dense cytoplasm enriched in mitochondria and endoplasmic relicilium. Significantly, the sub-aleurone cells are characterized by secondary wall ingrowths. Numerous plasmodesmata interconnect all cells between the modified aleurone and starchy endosperm. The pro-tonophore carbonylcyanide-m-chlorophenyl hydrazone (CCCP) slowed [¹⁴C]sucrose uptake by grain tissue slices enriched in modified aleurone and sub-aleurone cells but had no effect on uptake by the starchy endosperm. The fluorescent weak acid sulphorhodamine G (SRG) was preferentially accumulated by the modified aleurone and sub-aleurone cells, and this uptake was sensitive to CCCP. The combined plasma membrane surface areas of the modified aleurone and sub-aleurone cells appeared to be sufficient to support the in vivo rates of sucrose transfer to the starchy endosperm. Plasmolysis of intact excised grain inhibited [¹⁴C]sucrose transfer from the endosperm cavity to the starchy endosperm. The sulphydryl group modifier p-chloromercuribenzenesulphonie acid (PCMBS) decreased [¹⁴C]sucrose uptake by the modified aleurone and sub-aleurone cells but had little effect on uptake by the starchy endosperm. In contrast, when PCMBS and [¹⁴C]sucrose were supplied to the endosperm cavity of intact excised grain, PCMBS slowed accumulation by all tissues equally. Estimates of potential sucrose fluxes through the interconnecting plasmodesmata were found to be within the published range. It is concluded that the bulk of sucrose is accumulated from the endosperm cavity by the modified aleurone and sub-aleurone cells and subsequently transferred through the symplast to the starchy endosperm.     

Tobacco mosaic virus movement protein associates with the cytoskeleton in tobacco cells.

Tobacco mosaic virus movement protein P30 complexes with genomic viral RNA for transport through plasmodesmata, the plant intercellular connections. Although most research with P30 focuses on its targeting to and gating of plasmodesmata, the mechanisms of P30 intracellular movement to plasmodesmata have not been defined. To examine P30 intracellular localization, we used tobacco protoplasts, which lack plasmodesmata, for transfection with plasmids carrying P30 coding sequences under a constitutive promoter and for infection with tobacco mosaic virus particles. In both systems, P30 appears as filaments that colocalize primarily with microtubules. To a lesser extent, P30 filaments colocalize with actin filaments, and in vitro experiments suggested that P30 can bind directly to actin and tubulin. This association of P30 with cytoskeletal elements may play a critical role in intracellular transport of the P30-viral RNA complex through the cytoplasm to and possibly through plasmodesmata.     

植物小孢子母细胞胞间细胞融合通道的超显微结构研究

采用常规的透射电子显微镜术研究了百合和黑麦花药小孢子母细胞减数第一次分裂前期孢间细胞融合道（ＩＣＣ）的精细结构。首次发现ＩＣＣｓ内部除包含早期研究所看到的染色质,或核糖体、质体、线粒体等细胞器外,其中还存在有一些形态学特征与微丝和微管类似的细胞骨架系统。该系统穿过ＩＣＣｓ,从一个细胞延伸到相邻细胞的细胞质内,表面与周围的染色质颗粒、核糖体、质体等细胞器相连,方向与细胞质或核物质细胞间运动的方向一致     

Fluorescence Microscopic Observations on the Distribution Patterns of Actin Filaments in the Cells of Developing Endosperm in Triticum aestivum

The presence and distribution patterns of actin filaments (AFs) in the cells of developing wheat (Triticum aestivum L. ) endosperm exhibiting intercellular protoplasmic movement were studied with fluorescence microscopy and video microscopy. By using TRITC-PhaIloidin as fluorescence probe and cytochalasin B (CB) treatment it was uncovered that there were a lot of AFs scattered throughout the cytoplasm and the patterns of AFs varied greatly with the actin localization. Four configurations of AFs could be recognized: an actin meshwork surrouding the nucleus; bundles of AFs radiating from nuclear “basket” and extending to the periplasm; numerous finer AFs densely and randomly distributed in the cortical cytoplasm and fusiform bodies composed of AFs appearing in the endosperm cells lying at the “cheek” of the caryopsis. Judging from the dynamic characters of intercellular movement of the cytoplasmic constituents and the reaction of cytoplasmic strands related to CB treatment, the authors have discussed and proposed that the exhibition of the two kinds of intercellular movement (extrusion of cytoplasmic strands and mass flow of ground substance) might also be in close relation to the different configurations of AF organization in the cytoplasm.