The formation of symplasmic domains by plugging of plasmodesmata: a general event in plant morphogenesis?

Summary The plasmodesmal network was examined in multicellular protoplast-derived calluses of the dicotyledonSolanum nigrum which had not yet formed any visible adventitious organs and in globular proembryogenic structures developed from scutellar calluses of the monocotyledonMolinia caerulea. Electron microscopical analyses revealed that both calluses and proembryos consisted of small, undifferentiated cells. The interconnecting plasmodesmata at many cell interfaces were structurally inconspicuous in both systems; in particular cell walls, however, all plasmodesmata were occluded with an osmiophilic, dense material. As the blocking material was obviously located in the microchannels of the plasmodesmal cytoplasmic sleeves, the plugged plasmodesmata can be assumed to be nonfunctional. Thus, selective occlusion of all the plasmodesmata in specific cell walls resulted in the symplasmic disconnection of particular adjacent cells. Complex patterns of symplasmic continuity and discontinuity were established within the developing tissues. Some cells or groups of cells were entirely symplasmically disconnected from the surrounding cells by plugged plasmodesmata and might function as independent domains. However, blockage of plasmodesmata was achieved by the surrounding cells rather than by those cells belonging to the isolated domains. The demarcation of symplasmic domains might be a general prerequisite for differential morphogenesis, since they were found to be established very early in the course of morphogenetic processes.     

Synchronization of mitotic activity in protoplast-derived Solanum nigrum L. microcalluses is correlated with plasmodesmal connectivity

In protoplast-derived Solanum nigrum microcalluses, plasmodesmal connectivity and cell division behaviour of the sister cells were examined by repeated pressure-injection experiments with the fluorescent dye Lucifer Yellow (LYCH; M_r 457) and concomitant light-microscopical long-term live observations. The studies revealed that the plasmodesmal permeability of the cultured cells differs in the distinct stages of microcallus development. There was a correlation between the symplasmic connectivity of the cells and the synchronousness of their mitotic activity. Sister cells which were symplasmically interconnected by functional plasmodesmata, permitting the diffusion of LYCH, were always found to divide synchronously. However, asynchronous mitotic divisions were exclusively observed in those sister cells whose plasmodesmata were closed to LYCH. The temporary symplasmic isolation is presumably performed by reversible gating of plasmodesmata. Repeated dye-coupling experiments on the same microcalluses showed that symplasmically interconnected sister cells may become uncoupled and vice versa, according to their division behaviour. These findings on cultured cells indicate that modulation of the symplasmic connectivity determines the synchronization of mitotic activity. Yet it remains to be proven whether this is true in planta as well. The results are discussed with respect to the possible role of plasmodesmata in exerting “supracellular control” over mitotic activity by trafficking mitosis-regulating signals. Received: 6 March 1999 / Accepted: 14 July 1999     

Plasmodesmal widening accompanies the short-term increase in symplasmic phloem unloading in pea root tips under osmotic stress

Summary Root tips ofPisum sativum seedlings were exposed to 350 mM mannitol, which was shown to effect a transient but dramatic increase in phloem unloading, and investigated by electron microscopy. After chemical fixation and embedding, extremely thin sections of the root extension zone were examined. Outer, inner, and desmotubule diameters of 830 primary plasmodesmata in transverse walls of cortical cells were measured. Statistical analysis indicated that the majority of plasmodesmata had no neck constriction during osmoregulation. Compared to controls, a highly significant increase in mean plasmodesmata diameter was found, but the desmotubule diameter remained unchanged. Both loss of neck constriction and widening of the cytoplasmic sleeve indicate an increase in effective passage area of plasmodesmata. Spokes between plasma membrane and desmotubule were preserved. Continued exposure of the root tips to mannitol led to a return to control values for plasmodesmal diameters. In contrast to these responses, plasmolysis of cortical cells by 1,000 mM sucrose, diminishing phloem unloading, was accompanied by a reduction in those plasmodesmata classified as open. This is the first report showing a correlation between the ultrastructure of plasmodesmata and the rate of symplasmic transport. The role of the different plasmodesmal components in controlling the passage area of symplasmic transport is discussed.     

Dynamics of plasmodesmal connectivity in successive interfaces of the cambial zone

Frequency, density and branching of plasmodesmata were counted in successive tangential and transverse walls in the cambial zone of tomato stems in order to examine development of the plasmodesmal network in a chronological order. Coincident with progress of cell development, plasmodesmal connectivity increased, both at the xylem- and phloem-side. In transverse walls, the number of secondary plasmodesmata enhanced considerably. The same held for tangential walls, with a superimposed plasmodesmal doubling during the first phase of phloem development. This plasmodesmal doubling was interpreted to result from the deposition of wall material between branched plasmodesmal strands. Structural plasmodesmal development was correlated with production of hydroxyl radicals which control local cell wall alterations. Successive phases of plasmodesmal deployment and modification were distinguished which may coincide with differential functional capacities as documented by intracellular injection of fluorochromes. Diffusion-driven symplasmic transport appeared to be transiently interrupted during cell maturation.     

The shoot apical meristem restores its symplasmic organization during chilling-induced release from dormancy

The shoot apex of overwintering perennials ceases its morphogenetic activity at the end of the growing season and transforms into a bud which is dormant and freezing-tolerant. In birch (Betula pubescens) these events are triggered by short photoperiod, and involve the production of 1,3-beta-D-glucan containing sphincters on the plasmodesmata. As a result, all symplasmic pathways shut down. Here we show that breakage of bud dormancy by chilling involves restoration of the symplasmic organization of the meristem. This restoration is likely to be mediated by 1,3-beta-D-glucanase, which was present in small spherosome-like vacuoles that arose de novo during dormancy induction. During chilling these vacuoles were displaced from the bulk cytoplasm to the cortical cytoplasm where they became aligned with the plasma membrane, often associated with plasmodesmata. At this stage the enzyme also appeared outside the vacuoles. During chilling, 1,3-beta-D-glucan disappeared from the plasmodesmal channels and wall sleeves, and the plasmodesmata regained the capacity for cell-cell transport, as demonstrated by microinjection of Lucifer Yellow CH and Fluorescein-tagged gibberellic acid. Collectively, the present experiments demonstrate that restoration of the symplasmic organization of the meristem is indispensable for the release of buds from dormancy and the assumption of a proliferation-competent state, and implicate 1,3-beta-D-glucanase action at the plasmodesmata. Based on these findings we propose a model for 'dormancy cycling' which depicts the meristem as passing through three sequential states of cellular communication with characteristic sensitivities to distinct environmental cues.     

胞间连丝研究的进展

胞间连丝为多细胞植物有机体提供了一个直接的细胞间物质运输和信息传递的细胞质通道,把一个个独立的“细胞王国”转变成相互连接的共质体,它是当今细胞生物学中十分活跃的研究领域。日益增多的研究结果揭示,胞间连丝协调基因表达和许多的细胞生理生化过程,对细胞的分裂与分化、形态发生、植物体的生长与发育,以及植物对环境的反应与适应等诸方面都起着十分重要的作用。本文仅就胞间连丝结构的多样性;胞间通道的调节因子;大分子蛋白质和核酸的胞间运输;胞间连丝阻断和共质体分区的形成及其与形态发生、休眠和抗逆性的关系等几个方面的新进展做一个简要的综述,借此例证胞间连丝在植物生命活动中的重要意义。     

胞间连丝研究的进展

胞间连丝为多细胞植物有机体提供了一个直接的细胞间物质运输和信息传递的细胞质通道,把一个个独立的“细胞王国”转变成相互连接的共质体,它是当今细胞生物学中十分活跃的研究领域。日益增多的研究结果揭示,胞间连丝协调基因表达和许多的细胞生理生化过程,对细胞的分裂与分化、形态发生、植物体的生长与发育,以及植物对环境的反应与适应等诸方面都起着十分重要的作用。本文仅就胞间连丝结构的多样性;胞间通道的调节因子;大分子蛋白质和核酸的胞间运输;胞间连丝阻断和共质体分区的形成及其与形态发生、休眠和抗逆性的关系等几个方面的新进展做一个简要的综述,借此例证胞间连丝在植物生命活动中的重要意义。     

胞间连丝向胞间通道转化的机理

为了适应衰老器官内大量的降解物质在短期内迅速转移到贮藏器官和生长部位,胞间连丝内部结构在酶的作用下瓦解,其周围的细胞壁物质也被降解,胞间连丝结构拓宽,形成胞间通道。     

胞间连丝与大分子物质的胞间转移

胞间连丝是细胞间细胞器,是细胞间通讯的直接途径。一般认为,胞间连丝允许通过物质的分子量上限(SEL)是800～1000 Da．近年来研究的许多证据表明,胞间连丝的SEL随组织种类及其生理状况而异。在某些情况下,它可以允许大分子物质通过,如病毒运动蛋白与胞间连丝相互作用,使病毒通过胞间连丝转移。玉米突变体 kn1基因异常表达的KN1可使包括表皮在内的各层组织结瘤,KN1是细胞间移动的信息物,P-蛋白可由伴胞通过胞间连丝转移到筛管。某些组织中胞间连丝很高的SEL和发育过程胞间连丝SEL的变化可能在植物发育调控中有重要作用。本文对大分子通过胞间连丝转移的机理进行了讨论。     

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.     

Arabidopsis plasmodesmal proteome

The multicellular nature of plants requires that cells should communicate in order to coordinate essential functions. This is achieved in part by molecular flux through pores in the cell wall, called plasmodesmata. We describe the proteomic analysis of plasmodesmata purified from the walls of Arabidopsis suspension cells. Isolated plasmodesmata were seen as membrane-rich structures largely devoid of immunoreactive markers for the plasma membrane, endoplasmic reticulum and cytoplasmic components. Using nano-liquid chromatography and an Orbitrap ion-trap tandem mass spectrometer, 1341 proteins were identified. We refer to this list as the plasmodesmata- or PD-proteome. Relative to other cell wall proteomes, the PD-proteome is depleted in wall proteins and enriched for membrane proteins, but still has a significant number (35%) of putative cytoplasmic contaminants, probably reflecting the sensitivity of the proteomic detection system. To validate the PD-proteome we searched for known plasmodesmal proteins and used molecular and cell biological techniques to identify novel putative plasmodesmal proteins from a small subset of candidates. The PD-proteome contained known plasmodesmal proteins and some inferred plasmodesmal proteins, based upon sequence or functional homology with examples identified in different plant systems. Many of these had a membrane association reflecting the membranous nature of isolated structures. Exploiting this connection we analysed a sample of the abundant receptor-like class of membrane proteins and a small random selection of other membrane proteins for their ability to target plasmodesmata as fluorescently-tagged fusion proteins. From 15 candidates we identified three receptor-like kinases, a tetraspanin and a protein of unknown function as novel potential plasmodesmal proteins. Together with published work, these data suggest that the membranous elements in plasmodesmata may be rich in receptor-like functions, and they validate the content of the PD-proteome as a valuable resource for the further uncovering of the structure and function of plasmodesmata as key components in cell-to-cell communication in plants.     

Transport of macromolecules through plasmodesmata and the phloem

Cell-to-cell communication is a pivotal process in the determination of cell fate during development and physiological adaptation in response to environmental stimuli. The intercellular trafficking of proteins and RNAs has emerged as a novel mechanism of cell-to-cell signaling in plants. As a strategy for efficient intercellular communication, plants have evolved plant-specific symplasmic communication networks via plasmodesmata (PD) and the phloem. PD are symplasmic channels connecting the cytoplasm of neighboring cells and are responsible for the local exchange of metabolites and signaling molecules. The phloem is the sieve-tube system that allows rapid, long-distance translocation of molecules. Together, PD and phloem conduits have been shown to allow the transport of proteins and RNAs in non-selective or/and selective modes. This review describes the current understanding of macromolecule trafficking through PD and the phloem.     

On the Validity of Plasmodesmograms*

Because the operation of plasmodesmata is of paramount importance for the integrative action of tissues and organs, it is important to quantify the symplastic continuity. An attempt to visualize the intercellular communication pathways in plant tissues is the plasmodesmogram, a two-dimensional diagram of plasmodesmatal frequencies. Plasmodesmograms assume that the greater the frequency of plasmodesmata, the greater is the potential for symplasmic communication. In fact, however, the validity of plasmodesmograms hinges on the premise that plasmodesmata are uniform in structure and functioning. In view of recent findings that plasmodesmata are gatable channels with different functional diameters, a correlation between plasmodesmatal frequency and the rate of intercellular communication - including transport - is disputable and the concept of the plasmodesmogram needs to be re-examined. Its validity appears to vary with the developmental stage and the nature of the plant tissue. Our over-all conclusion is that plasmodesmograms are an acceptable device for coarse (qualitative) assessment of intercellular transport pathways in mature phloem tissues. Pathways identified by plasmodesmograms often correlate with the physiologically determined modes of photosynthate transport. Whether this applies to differentiated tissues, in general, remains to be elucidated. The value of plasmodesmograms for developmental phyisology seems to be limited, as developmental processes coincide with temporary or permanent closure of plasmodesmata.     

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.     

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.     

Identification of symplasmic domains in the embryo and seed of Sedum acre L. (Crassulaceae)

Planta - Our study demonstrated that symplasmic communication between Sedum acre seed compartments and the embryo proper is not uniform. The presence of plasmodesmata (PD) constitutes the...     

Opening up the communication channels: recent insights into plasmodesmal function

The past year has seen significant advances in our understanding of the function and regulation of plasmodesmata. Notably, we have learned that plasmodesmata undergo dynamic changes during development and may participate in long-range communication through the transmission of RNA signals. Biochemical studies have enriched our understanding of a putative plasmodesmal receptor and of plant factors involved in viral cell-to-cell movement.     

Structure and development of cell connections in the phloem ofMetasequoia glyptostroboides needles I. Ultrastructural aspects of modified primary plasmodesmata in Strasburger cells

Summary Symplasmic contacts of Strasburger cells in the mature needle ofMetasequoia glyptostroboides were analysed with special regard to changes of plasmodesmata in fine structure and distribution. In meristematic cells simple primary plasmodesmata are evenly distributed throughout the entire wall, whereas in mature Strasburger cells plasmodesmata are aggregated in defined, dome-shaped wall thickenings. The elongated, often multiple-branched cytoplasmic strands show a distinct neck region besides a considerably dilated sleeve region confluent with cavities, which have formed at branching sites of plasmodesmata in various planes of the wall thickening. Most branches radiating from these cavities connect the protoplasts of the adjacent cells; occasionally some strands are discontinuous. The desmotubules of both, continuous and discontinuous plasmodesmal branches exhibit great variability in structure and number: they may be partially dilated, multiple-stranded and branched within single plasmodesmal branches. Fine structurally, plasmodesmata of Strasburger cells show great resemblance with developing sieve pores of conifers. This characteristic fine structure implicates a special role of the endomembrane system for phloem loading in theMetasequoia leaf.Dedicated to Prof. Dr. Dr. h.c. Eberhard Schnepf on the occasion of his retirement