岩蕨属植物配子体发育初报

本文为岩蕨属植物心岩蕨、岩蕨和耳羽岩蕨配子体个体发育和比较形态学初步研究。报道了用无机琼脂培养基由孢子培养配子体的方法。由孢子萌发到配子体成熟分四个时期:萌发期,原丝体发育期,过渡期和原叶体发育期。大多数原丝体发育到七个细胞,与顶端细胞相隔的原丝体细胞开始胞间细胞纵向分裂,进入过渡期。同时顶端细胞的横分裂受到抑制,直至原叶体顶端细胞形成开始原叶体发育期。岩蕨成熟配子体精子器盖细胞不分裂,耳羽岩蕨分裂为一个圆形细胞和一个镰刀形细胞,而心岩蕨两种情况兼而有之,配子体比较形态特征支持心岩蕨可能是以岩蕨和耳羽岩蕨为双亲的异源双二倍体的假设[5]。     

Age-related and origin-related control of the numbers of plasmodesmata in cell walls of developing Azolla roots

Plasmodesmata were counted in the longitudinal and transverse walls in developmental sequences of merophytes in roots of Azolla pinnata R.Br. The differences between certain categories of longitudinal wall were traced to factors that govern the surface area of the cell plates, the density of plasmodesmata (number per unit area of cell plate), and the amount by which each type of plate expands. No evidence for secondary augmentation of plasmodesmatal numbers after the cell-plate stage of development was found, but plasmodesmata are lost from the walls of sieve and xylem elements during their differentiation. Losses caused by cell separation occur in other tissues. The relatively high density of plasmodesmata in transverse walls is based not so much on a high density in the cell plates as on the relatively low expansion that these walls undergo. There appears to be a compensatory mechanism that relates initial plasmodesmatal density to the future expansion of the cell plate. The root shows determinate growth, the apical cell dividing about 55 times. Beginning at about the 35th division there is a progressive failure to maintain the plasmodesmatal frequencies that were developed in earlier cell divisions in the apical cell. The divisions that occur within the later-produced merophytes also show progressive diminution of plasmodesmatal numbers. The result is that the apex of the root, and particularly the apical cell, becomes more and more isolated symplastically, a phenomenon which could account for its limited lifespan and the determinate growth pattern of the root.     

THE INITIATION OF SPOROPHYTES BY OBLIGATE APOGAMY IN CHEILANTHES CASTANEA

The initiation of apogamous sporophytes in Cheilanthes castanea was recorded by daily photography of individual gametophytes. Whereas an ordinary embryo arises from a zygote, apogamous embryos of C. castanea originate from one to three initial cells which occur just behind the apical region of the prothallus. The initial (or initials) produce cells with small chloroplasts behind the sinus of the gametophyte. The appearance of cells with smaller chloroplasts than those normally found in gametophytes is the first indication that apogamy is occurring. The cells with small plastids produce a group of densely-cytoplasmic meristematic cells. The size of the meristematic mass increases until shoot and root apices of the apogamous embryo are organized.     

Directional cell-to-cell communication in theArabidopsis root apical meristem I. An ultrastructural and functional analysis

Summary As a foundation for studies on directional intercellular communication and its regulation in apical development, the network of plasmodesmata inArabidopsis root apical meristems was characterized by quantitative electron microscopy and dye-coupling analysis, using symplasmic probes, and real-time imaging in confocal laser scanning microscopy. A tissue-specific plasmodesmatal network, which interconnected the cells in the root apical meristem, was characterized by the following features, (a) Plasmodesmatal distribution and density were found to be tissue-specific, (b) Primary and secondary plasmodesmata were differentially grouped and regulated. Primary plasmodesmata were formed in large numbers in the transverse walls of each tissue, and were subject to deletion during cell differentiation. Secondary plasmodesmata were mostly distributed in longitudinal walls between cell files and common walls between neighboring tissues; they also provided a symplasmic path between different initial tiers in the meristem. Small fluorescent tracers moved through the plasmodesmatal network of the root apical meristem in two distinct phases. At low concentrations molecules trafficked in a non-tissue-specific manner, whereas at higher concentrations, their distribution reflected the presence of tissue-specific movement consistent with plasmodesmatal distribution. These findings are discussed in terms of the role of tissue-specific plasmodesmatal domains in the control of root development.     

Intercellular translocation of molecules via plasmodesmata in the multiseriate filamentous brown alga,Halopteris congesta (Sphacelariales,Phaeophyceae)

Despite the high number of studies on the fine structure of brown algal cells, only limited information is available on the intercelluar transportation of molecules via plasmodesmata in brown algae. In this study, plasmodesmatal permeability of Halopteris congesta was examined by observing the translocation of microinjected fluorescent tracers of different molecular sizes. The tip region of H. congesta consists of a cylindrical apical cell, while the basal region is multiseriate. Fluorescein isothiocyanate‐dextran (FD; 3, 10, and 20 kDa) and recombinant green fluorescent protein (27 kDa) were injected into the apical cell and were observed to diffuse into the neighboring cells. FD of 40 kDa was detected only in the injected apical cell. The plasmodesmatal size exclusion limit was considered to be more than 20 kDa and less than 40 kDa. The extent of translocation of 3 and 10 kDa FD from the apical to neighboring cells 2 h postinjection was estimated based on the fluorescence intensity. It was suggested that the diffusing capacity of plasmodesmata varied according to molecular size. In order to examine acropetal and/or basipetal direction of molecular movement, 3 and 10 kDa FD were injected into the third cell from the apical cell. Successive observations indicated that the diffusion of fluorescence in the acropetal direction took longer than that in the basipetal direction. No ultrastructural difference in plasmodesmata was noted among the cross walls.     

Maintaining apical dominance in the fern gametophyte

A kinetic model is developed for cell differentiation in the fern gametophyte to test hypotheses on the role of spatially patterned plasmodesmata networks in development. Of particular interest is the establishment and maintenance of apical cell type in a single cell, with concurrent suppression of this character in all other cells (apical dominance). Steps towards understanding apical cell localization in geometrically simple gametophytes may shed light on the establishment and maintenance of apical meristems in higher plants. The model, based on the plasmodesmata maps of Tilney and colleagues and involving kinetics for a requisite minimum of two morphogens. successfully produces the apical/non-apical cell differentiation patterns of normal development, and redifferentiation due to cell isolation, in six stages from 0-30 d of development. Our results indicate that increasing apical cell plasmodesmata number, as development progresses, is not required for effective transport across apical cell walls in maintaining apical dominance.     

Directional cell-to-cell communication in theArabidopsis root apical meristem II. Dynamics of plasmodesmatal formation

Summary Cell development in the root apical meristem is thought to be regulated by position-dependent information, but as yet, the underlying mechanism for this remains unknown. In order to examine the potential involvement of the symplasmic transmission of positional signals, plasmodesmatal frequency and distribution was quantitatively analyzed in root apical meristem cell walls ofArabidopsis thaliana during root development. A consistent distribution pattern of plasmodesmata was observed in the root apex over four weeks. While cells within initial tiers were uniformly interconnected, more symplasmic connections between the initial tiers and their immature-cell (primary-meristem) derivatives were observed than within the initial tiers. Immature cells were connected across transverse walls by primary plasmodesmata according to a tissue-specific pattern. Cells of the immature vascular tissue and cortex had the highest plasmodesmatal frequencies, followed by the immature epidermis and root cap. Although the numbers of plasmodesmata in transverse walls (primary plasmodesmata) was reduced in all tissues as the root aged, the tissue-specific distribution remained constant. The extent of symplasmic coupling across the boundaries of each tissue appeared to be limited by fewer secondary plasmodesmata in longitudinal walls. The frequency of all plasmodesmata decreased as the root aged. The primary plasmodesmata within each tissue increased at one week and then dramatically decreased with root age; the frequency of secondary plasmodesmata in longitudinal walls also decreased, but more gradually. These findings are discussed with respect to the roles likely played by plasmodesmata in facilitating transport of position-dependent information during root development.     

Ultrastructure of unique plasmodesmata in Selaginella willdenowii

Summary All meristematic cells of dorsal angle meristems of Selaginella willdenowii Baker cultured in vitro possessed expanded plasmodesmata, unlike the conventional plasmodesmata which were also found in these cells. Apical tissues of stems, roots and shoots from intact plant also possessed these structures though to a lesser degree than angle meristems. Root tips and stem apices had numerous conventional plasmodesmata in their walls. The expanded plasmodesmata, with their marked symmetry, represent a unique variation of plasmodesmatal structure.This study was partially supported by NSF Grant GB 37945 to Zachary S. Wochok.     

香鳞毛蕨配子体发育的研究

研究了香鳞毛蕨(Dryopteris fragrans (L.)Schott)配子体的发育过程。结果发现孢子极面观为椭圆形,赤道面观为半圆形,单裂缝。孢子萌发为书带蕨型;丝状体2～9个细胞长,有明显顶端细胞,可形成多细胞的广阔板状片状体;片状体顶端分生组织继续分裂,发育为幼原叶体;原叶体发育为三叉蕨型;毛状体数量丰富,均为单细胞;颈卵器和精子器几乎同时形成,较小;成熟原叶体倒卵状心脏形。该配子体表现为进化性状。     

Plasmodesmal Dynamics in Both Woody Poplar and Herbaceous Winter Wheat Under Controlled Short Day and in Field Winter Period

Electron microscopic observation revealed that poplar (Populus deltoides Marsh.) and winter wheat (Triticum aestivum L. cv. Seward 80004) plasmodesmatal structures significantly changed under short day (SD, 8 h light) and in winter period, and such changes differed also noticeably between these two woody and herbaceous plants. Under long day (LD, 16 h light), many plasmodesmata with strong stain appeared in the cell wall of both poplar apical buds and winter wheat young leaf tissues, and connections of cytoplasmic endoplasmic reticulum (ER) with the ER in some plasmodesmata were observed. In addition, the typical “neck type” plasmodesmata were observed in winter wheat young leaf tissues, and their central desmotubules (appressed-ER) could be clearly identified. Under SD, many poplar plasmodesmata showed only a partial structure in the cell wall and appeared to be discontinued; some plasmodesmata swelled in the mid-wall, forming the cavity, and no appressed-ER appeared. In winter wheat, however, no noticeable alterations of plasmodesmata occurred, and the plasmodesmatal structure essentially remained same as it was under LD. In winter period, poplar plasmodesmata had a similar morphology as those observed under SD, however, winter wheat manifested at least two types of significant plasmodesmatal alterations: one plugged by electron-dense materials and the other of reduced neck region compared to those under LD. The above dynamic difference of the two species plasmodesmata under SD and winter period revealed the difference of their dormancy development under those environmental conditions.     

Subcellular localization of ubiquitin in plant protoplasts and the function of ubiquitin in selective degradation of outer-wall plasmodesmata in regenerating protoplasts

Immunocytochemical localizations in Vicia faba L. protoplasts and cultures of regenerating Solanum nigrum L. protoplasts support former observations that in plant cells ubiquitin occurs within the cytoplasm, the nucleus, the chloroplasts and at the plasmalemma, but not within the vacuole or the cell wall. Immunoresponses were also observed within mitochondria and associated with the endoplasmic reticulum, which is in accordance with previous findings on animal cells. Moreover, the tonoplast membrane system was found to be labelled. For regenerating S. nigrum protoplasts, evidence is given that ubiquitin plays a role in selective degradation even of whole subcellular structures. Most of the discontinuous plasmodesmata formed in the newly deposited outer cell walls during the early stages of culture disappear later on, except for those near the periphery of division walls or of non-division walls, which are probably used for the formation of continuous cell connections during further culture. Outer-wall plasmodesmata which are destined to disappear show high immunoreactivity to ubiquitin antibody, but no conspicuous immunolabelling was observed with the remaining plasmodesmata. Thus, the selective disintegration of whole plasmodesmatal structures is obviously regulated by ubiquitination of plasmodesmatal proteins. A model for the mechanism of degradation of outer-wall plasmodesmata during extension growth of the cell wall is presented.Dedicated to Professor Dr. Andreas Sievers on the occasion of his retirementThis work was supported by grants to R. K. (Deutsche Forschungsgemeinschaft) and to M. S. (Bennigsen-Foerder Preis des Landes Nordrhein-Westfalen). We thank Dipl.— Biol. Kirsten Leineweber for help with the V. faba protoplast isolation and Dr. Olaf Parge, Institut für Psychologie und Sozialforschung, Kiel, Germany, for giving assistance with the statistical analysis.     

Plasmodesmata: composition,structure and trafficking

Plasmodesmata are highly specialized gatable trans-wall channels that interconnect contiguous cells and function in direct cytoplasm-to-cytoplasm intercellular transport. Computer-enhanced digital imaging analysis of electron micrographs of plasmodesmata has provided new information on plasmodesmatal fine structure. It is now becoming clear that plasmodesmata are dynamic quasi-organelles whose conductivity can be regulated by environmental and developmental signals. New findings suggest that signalling mechanisms exist which allow the plasmodesmatal pore to dilate to allow macromolecular transport. Plant viruses spread from cell to cell via plasmodesmata. Two distinct movement mechanisms have been elucidated. One movement mechanism involves the movement of the complete virus particle along virus-induced tubular structures within a modified plasmodesma. Apparently two virus-coded movement proteins are involved. A second movement mechanism involves the movement of a non-virion form through existing plasmodesmata. In this mechanism, the viral movement protein causes a rapid dilation of existing plasmodesmata to facilitate protein and nucleic acid movement. Techniques for the isolation of plasmodesmata have been developed and information on plasmodesma-associated proteins is now becoming available. New evidence is reviewed which suggests that plasmodesmatal composition and regulation may differ in different cells and tissues.     

The frequency of plasmodesmata increases early in the whole shoot apical meristem of Sinapis alba L. during floral transition

 The frequency of plasmodesmata increases in the shoot apical meristem of plants of Sinapis alba L. induced to flower by exposure to a single long day. This increase is observed within all cell layers (L1, L2, L3) as well as at the interfaces between these layers, and it occurs in both the central and peripheral zones of the shoot apical meristem. The extra plasmodesmata are formed only transiently, from 28 to 48 h after the start of the long day, and acropetally since they are detectable in L3 4 h before they are seen in L1 and L2. These observations indicate that (i) in the Sinapis shoot apical meristem at floral transition, there is an unfolding of a single field with increased plasmodesmatal connectivity, and (ii) this event is an early effect of the arrival at this meristem of the floral stimulus of leaf origin. Since (i) the wave of increased frequency of plasmodesmata is 12 h later than the wave of increased mitotic frequency (A. Jacqmard et al. 1998, Plant cell proliferation and its regulation in growth and development, pp. 67–78; Wiley), and (ii) the increase in frequency of plasmodesmata is observed in all cell walls, including in walls not deriving from recent divisions (periclinal walls separating the cell layers), it is concluded that the extra plasmodesmata seen at floral transition do not arise in the forming cell plate during mitosis and are thus of secondary origin. Received: 4 October 1999 / Accepted: 23 December 1999     

Cytokinins induce photomorphogenic development in dark-grown gametophytes of Ceratopteris richardii

The cytokinins benzylaminopurine, kinetin and isopentenyladenine induce photomorphogenesis in dark-grown gametophytes of the fern Ceratopteris richardii. At sub-nanomolar concentrations each altered the rate and pattern of cell division, elongation and differentiation, mimicking aspects of the light-mediated transition from filamentous to prothallial growth. Untreated dark-grown gametophytes grow as narrow, elongate, asexual filaments with an apical meristem. Cytokinin treatments as low as 10(-12) M reduced the length-to-width ratio through decreased cell elongation, increased periclinal cell division and induced the formation of rhizoid initials in the cells immediately below the apical meristem. Higher concentrations (10(-9)-10(-8) M) induced conversion of the meristem from apical to notch morphology. Cytokinins induced both red- and blue-light-mediated photomorphogenic events, suggesting stimulation of both phytochrome and cryptochrome signaling; however, cytokinin treatment only partially substituted for light in that it did not induce hermaphroditic sexual development or spore germination in the dark. Additionally, cytokinins did not increase chlorophyll synthesis in dark-grown gametophytes, which unlike angiosperms are able to produce mature chloroplasts in the dark. Cytokinin treatment had only slight effects on light-grown gametophytes. These results suggest evolutionary conservation between angiosperms and pteridophytes in the role of cytokinins in regulating photomorphogenesis.     

阔叶鳞盖蕨配子体发育及卵发生的研究

采用显微镜和透射电镜对阔叶鳞盖蕨(Microlepia platyphylla)的配子体发育和卵发生过程进行了观察,以阐明其卵发生的细胞学机制,探讨其演化地位。阔叶鳞盖蕨孢子褐色,四面体形,具三裂缝,接种5~10d后孢子萌发,经丝状体和片状体阶段发育为心形原叶体,原叶体发育是铁线蕨型,通常为雌雄异株,精子器产生于不规则配子体的表面,颈卵器产生于心形原叶体生长点的下方,性器官是薄囊蕨型。卵发生研究表明,阔叶鳞盖蕨颈卵器产生于生长点下方表面细胞,经两次分裂形成了顶细胞、初生细胞和基细胞。其中初生细胞再经两次不等分裂产生卵细胞、腹沟细胞和颈沟细胞,此3个细胞通过胞间连丝紧密相连,随发育,腹沟细胞与卵细胞间形成了分离腔,但在孔区处始终通过胞间连丝相连,成熟卵细胞上形成了卵膜和受精孔,卵核表面产生了核外突,通过比较表明阔叶鳞盖蕨卵发生与蕨（Pteridium aquilinum）卵发生相似。     

Filament Disruption in Funaria Protonemata: Occlusion of Plasmodesmata

Plasmodesmata are occluded when Funaria chloronemata are fragmented by the development of tmema cells (TCs). The TC deposits a new wall layer along the cross wall toward the neighbouring non-sister cell (NC). This wall layer cuts off the plasmodesmata and its connection with the cross wall is soon lost. The plasmodesmata become isolated when the NC forms a new wall layer along the former cross wall. At the end of TC development, before its disintegration, the sister cell (SC) also deposits a new wall layer along the cross wall toward the TC, cutting off the plasmodesmata. For some time the plasmalemma of the plasmodesmata remains connected to the NC or the TC, whereas the desmotubule soon disappears. Relicts of the plasmalemma remain even after the isolation of the plasmodesmata and the disintegration of the TC. During the decay of the plasmodesmata, a cylinder of electron-dense material is frequently formed along the border of the plasmodesmatal channel. This may extend over the surface of the cell wall. Eventually, the plasmodesmatal channel is filled with wall material. Callose is only observed around functional plasmodesmata and does not seem to play a role in their occlusion.     

粗茎鳞毛蕨原叶体细胞有丝分裂过程中微管列阵的变化

应用Steedman‘s wax切片法,间接免疫荧光标记技术和激光共聚焦扫描显微镜技术研究了粗茎鳞毛蕨（Dryopteris crassirhizoma Nakai)原叶体大液泡化细胞和分生组织细胞有丝分裂过程中微管列阵的变化。结果显示：应用高浓度的多聚甲醛（8%）可以很好地保持大液泡化细胞的结构和微管的抗原性。结果也显示Steedman‘s wax切片法和间接免疫荧光标记技术的优点;（1）避免在微管标记过程中酶解细胞壁;（2）在乙醇脱水过程中样品中叶绿素的自发荧光被减到最小;（3）能够详细观察到有丝分裂过程中微管骨架的变化。因此,这种方法可以被广泛用来调查简单植物体和复杂植物体中细胞的有丝分裂过程以及发育过程中微管骨架的变化。     

Evolution of shoot apical meristem structures in vascular plants with respect to plasmodesmatal network

Vascular plants have evolved shoot apical meristems (SAMs), whose structures differ among plant groups. To clarify the evolutionary course of the different structural types of SAMs, we compared plasmodesmatal networks in the SAMs for 17 families and 24 species of angiosperms, gymnosperms, and pteridophytes, using transmission electron microscopy (TEM). The plasmodesmata (PD) in almost all cell walls in median longitudinal sections of SAMs were counted, and the PD density per unit area was calculated for each cell wall. Angiosperm and gymnosperm SAMs have low densities, with no difference between stratified (tunica-corpus) and unstratified structures. SAMs of ferns, including Psilotum and Equisetum, have average densities that are more than three times higher than those of seed plants. Interestingly, microphyllous lycopods have both the fern and seed-plant types of PD networks; Selaginellaceae SAMs with single apical cells have high PD densities, while SAMs of Lycopodiaceae and Isoetaceae with plural initial cells have low PD densities, equivalent to those of seed plants. In summary, PD networks are strongly correlated to SAM organizations-SAMs with single and plural initial cells have the fern and seed-plant types of PD, respectively. The two SAM organizations may have evolved separately in lycophytes and euphyllophytes and may be associated with gain or loss of the ability to form secondary PD.     

The effects of methionine and cobalt ions on sex expression and development of <Emphasis Type="Italic">Anemia phyllitidis</Emphasis> gametophytes

One of the prime precursor for ethylene synthesis — L-methionine and the inhibitor of 1-aminocyclopropane-1-carboxylic acid oxidase (ACO) — Co²⁺-were tested for their effects on sex expression and development of Anemia phyllitidis fern gametophytes. Five concentrations of both chemicals (0, 10, 25, 50, 100 μM) were analysed with reference to antheridia and archegonia formation, number and size of cells as well as thalli length using the three-zone model of gametophyte structure. Both substances, however at different concentrations, enhanced the number of GA₃-induced antheridia and similarly stimulated the cell number and inhibited thalli length. Both of them at 100 μM concentrations without GA₃ induced meristematic area formation while methionine also induced archegonia in the apical parts of gametophytes. These findings correspond with the previous observations concerning the important role of ethylene synthesis precursor (ACC) in controlling gibberellic acid-induced male sex expression in ferns and broaden the knowledge about the mechanisms of fern gametophyte development.     

Photocontrol of the orientation of cell division inAdiantum

The rate of transition from one- to two-dimensional growth of fernAdiantum gametophytes under white light depends on the age of gametophyte cultured under red light. When gametophytes were cultured for longer period under red light, the rate of transition decreased and the number of abnormal gametophytes increased. Although the first step of the transition was the first longitudinal cell division following the two transverse ones (Wada and Furuya, 1970), the time-lapse-video study revealed that the apical cell of protonemata became flattened in the plane perpendicular to the incident ray of white light before the first longitudinal cell division. Analytical study of growing part of the apical cell with grains of activated charcoal as markers revealed that the apical cell flattening occurred evenly throughout the equatorial circumference of the cell even in the shaded side of the protonemata as well as in the side irradiated with white light.