Absence of plasma membrane H+-ATPase in plasmodesmata located in pit-fields of the young reactive pulvinus ofMimosa pudica L.

Summary Immunocytochemical techniques were employed to study the spatial distribution of the plasma membrane H⁺-ATPase within various cell types of the young reactive primary pulvinus ofMimosa pudica L. These cells were interconnected by large numbers of plasmodesmata, being concentrated within pit-fields. Although we could routinely detect evidence of the H⁺-ATPase along the plasma membrane, immunolabelling was rarely, if ever, observed along the plasma membranes of the plasmodesmata. This finding is discussed with respect to the likely specialized supramolecular structure of the plasmodesma.Abbreviations SEL size exclusion limit of plasmodesmata     

The actin cytoskeleton is involved in the regulation of the plasmodesmal size exclusion limit

Plasmodesmata (PD) are the communication channels which allow the trafficking of macromolecules between neighboring cells. Such cell-to-cell movement of macromolecules is regulated during plant growth and development; however, little is known about the regulation mechanism of PD size exclusion limit (SEL). Plant viral movement proteins (MPs) enhance the invasion of viruses from cell to cell by increasing the SEL of the PD and are therefore a powerful means for the study of the plasmodesmal regulation mechanisms. In a recent study, we reported that the actin cytoskeleton is involved in the increase of the PD SEL induced by MPs. Microinjection experiments demonstrated that actin depolymerization was required for the Cucumber mosaic virus (CMV) MP-induced increase in the PD SEL. In vitro experiments showed that CMV MP severs actin filaments (F-actin). Furthermore, through the analyses of two CMV MP mutants, we demonstrated that the F-actin severing ability of CMV MP was required to increase the PD SEL. These results are similar to what has been found in Tobacco mosaic virus MP. Thus, our data suggest that actin dynamics may participate in the regulations of the PD SEL.Key words: plasmodesmata, size exclusion limit, movement protein, actin filaments, F-actin severing     

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。     

Changes in dye coupling of stomatal cells of Allium and Commelina demonstrated by microinjection of Lucifer yellow

Lucifer yellow has been microinjected into stomatal cells of Allium cepa L. epidermal slices and Commelina communis L. epidermal peels and the symplastic spread of dye to neighboring cells monitored by fluorescence microscopy. Dye does not move out of injected mature guard cells, nor does it spread into the guard cells when adjacent epidermal or subsidiary cells are injected. Dye does spread from injected subsidiary cells to other subsidiary cells. These results are consistent with the reported absence of plasmodesmata in the walls of mature guard cells. Microinjection was also used to ascertain when dye coupling ceases during stomatal differentiation in Allium. Dye rapidly moves into and out of guard mother cells and young guard cells. Hovewer, dye movement ceases midway through development as the guard cells begin to swell but well before a pore first opens. Since plasmodesmata are still present at this stage, the loss of symplastic transport may result from changes in these structures well in advance of their actual disappearance from the guard cell wall.Abbreviations DIC differential interference contrast - GMC guard mother cell - LY Lucifer yellow - Pd plasmodesmata You can observe a lot by watching Lawrence Berra, as quoted in Sports Illustrated, vol. 60 (No. 14), p. 94, 2 April 1984     

Inhibition by silver ions of gas space (aerenchyma) formation in adventitious roots of Zea mays L. subjected to exogenous ethylene or to oxygen deficiency

We have studied the role of ethylene in accelerating the lytic formation of gas spaces (aerenchyma) in the cortex of adventitious roots of maize (Zea mays L.) growing in poorly aerated conditions. Such roots had previously been shown to contain increased concentrations of ethylene. Ten day-old maize plants bearing seminal roots and one whorl of emerging adventitious roots were grown in nutrient solution bubbled with air, ethylene in air (0.1 to 5.0 l l^–1), or allowed to become oxygen-deficient in nonaerated (but not completely anaerobic) solution. Additions of 0.1 l l^–1 ethylene or more promoted the formation of aerenchyma, with lysis of up to 47% of the cortical cells. The effects of non-aeration were similar to those of exogenous ethylene. When silver ions, an ethylene antagonist, were present at low, non-toxic concentrations (circa 0.6 M), aerenchyma formation was prevented in ethylene treated roots and in those exposed to oxygen deficiency. Silver ions also blocked the inhibiting effect of exogenous ethylene on root extension. By contrast, the suppression of aerenchyma formation by silver ions under oxygendeficient conditions was associated with a retardation of root extension, indicating the importance of aerenchyma for root growth in poorly aerated media. Rates of production of ethylene by excised roots were stimulated by a previous non-aeration treatment. The effectiveness of Ag⁺ in inhibiting equally the action on cortical cells of exogenous ethylene and of non-aeration, supports the view that gas space (aerenchyma) formation in adventitious roots adpted to oxygendeficient environments is mediated by increased concentrations of endogenous ethylene. The possibility that extra ethylene could arise from increased biosynthesis of a precursor in root tissues with a restricted oxygen supply is discussed.     

Osmotic Stress Decreases the Activity of ATPase Associated with the Root Cap Plasmodesmata in Zea mays

With light and electron microscopy the substructural change and the ATPase activity of corn (Zea mays L. ) root cap cells after short-term osmotic stress were studied. Some spoke-like fine strands originating from the departed periplasm and stretching towards cell wall could be observed even after plasmolysis. By observing the precipitation of ATPase activity product (lead phosphate) at plasma membrane and plasmodesmata, it was found that the fine strands were plasma membrane-lined channels surrounding the cytoplasm and that they still firmly connected to the plasmodesmata during plasmolysis. Compared with the control (unstressed), a sharp decrease of ATPase activity in the plasmodesmata of the stressed cells was observed. Inhibition of energy metabolism in these limited locales would affect the physiological activity, maybe including the regulation of permeability and the change of size exclusion limit (SEL) of plasmodesmata.     

渗透胁迫引起玉米根冠处胞间连丝的ATP酶活性下降

利用光镜和电镜研究了短期渗透胁迫下玉米(Zea mays L.)根冠区超微结构和ATP酶活性变化。经历了质壁分离后,在根冠细胞仍然可以观察到许多从“撤退”的周质出发向细胞壁辐射的纤丝。利用ATP酶活性产物(磷酸铅)在原生质膜和细胞壁处沉积的特点,发现这些纤丝是质膜围绕原生质而形成的管状结构;在质壁分离过程中,这些纤丝依然与胞间连丝相连。与对照(未胁迫)相比,受渗透胁迫细胞胞间连丝处ATP酶活性明显下降。能量代谢在局部区段的抑制会影响胞间连丝的生理活性,可能包括胞间连丝的扩散调节能力和分子扩散上限的改变。     

Influence of the tobacco mosaic virus 30-kDa movement protein on carbon metabolism and photosynthate partitioning in transgenic tobacco plants

Transgenic tobacco (Nicotiana tabacum L.) plants expressing the 30-kDa movement protein of tobacco mosaic virus (TMV-MP) were employed to investigate the influence of a localized change in mesophyll-bundle sheath plasmodesmal size exclusion limit on photosynthetic performance and on carbon metabolism and allocation. Under conditions of saturating irradiance, tobacco plants expressing the TMV-MP were found to have higher photosynthetic CO₂-response curves compared with vector control plants. However, this difference was significant only in the presence of elevated CO₂ levels. Photosynthetic measurements made in the green-house, under endogenous growth conditions, revealed that there was little difference between TMV-MP-expressing and control tobacco plants. However, analysis of carbon metabolites within source leaves where a TMV-MP-induced increase in plasmodesmal size exclusion limit had recently taken place established that the levels of sucrose, glucose, fructose and starch were considerably elevated above those present in equivalent control leaves. Although expression of the TMV-MP did not alter total plant biomass, it reduced carbon allocation to the lower region of the stem and roots. This difference in biomass distribution was clearly evident in the lower root-to-shoot ratios for the TMV-MP transgenic plants. Microinjection (dye-coupling) studies established that the TMV-MP-associated reduction in photosynthate delivery (allocation) to the roots was not due to a direct effect on root cortical plasmodesmata. Rather, this change appeared to result from an alteration in phloem transport from young source leaves in which the TMV-MP had yet to exert its influence over plasmodesmal size exclusion limits. These results are discussed in terms of the rate-limiting steps involved in sucrose movement into the phloem.Abbreviations PFD photon flux density - SEL size exclusion limit - TMV-MP tobacco mosaic virus movement protein This work was supported by National Science Foundation grant No. DCB-9016756 (W.J.L.) and United States-Israel Binational Science Foundation grant No. 90-00070 (S.W. and W.J.L.). Special thanks are due to Bryce Falk for the use of pathogen-free green-house space at the University of California, Davis, Plant Pathology Greenhouse Facility, and to Robert Pearcy, for the use of his gas-exchange system. R.J.H. was on sabbatical leave from the University of Rhode Island, Kingston, RI.     

Identification of a developmental transition in plasmodesmatal function during embryogenesis in Arabidopsis thaliana

Plasmodesmata provide routes for communication and nutrient transfer between plant cells by interconnecting the cytoplasm of adjacent cells. A simple fluorescent tracer loading assay was developed to monitor patterns of cell-to-cell transport via plasmodesmata specifically during embryogenesis. A developmental transition in plasmodesmatal size exclusion limit was found to occur at the torpedo stage of embryogenesis in Arabidopsis; at this time, plasmodesmata are down-regulated, allowing transport of small (approx. 0.5 kDa) but not large (approx. 10 kDa) tracers. This assay system was used to screen for embryo-defective mutants, designated increased size exclusion limit of plasmodesmata (ise), that maintain dilated plasmodesmata at the torpedo stage. The morphology of ise1 and ise2 mutants discussed here resembled that of the wild-type during embryo development, although the rate of their embryogenesis was slower. The ISE1 gene was mapped to position 13 cM on chromosome I using PCR-based biallelic markers. ise2 was found to be allelic to the previously characterized mutant emb25 which maps to position 100 cM on chromosome I. The results presented have implications for intercellular signaling pathways that regulate embryonic development, and furthermore represent the first attempt to screen directly for mutants of Arabidopsis with altered size exclusion limit of plasmodesmata.     

Effects of tissue-preparation-induced callose synthesis on est plasmodesma size exclusion limits

Plasmodesmata are often characterised by their size exclusion limit (SEL), which is the molecular weight of the largest dye, introduced by microinjection, that will move from cell to cell. In this study, we investigated whether commonly used techniques for isolation and manipulation of tissues, and microinjection of fluorescent dyes, affected the SEL, and whether any such effects could be ameliorated by inhibiting callose deposition. We examined young root epidermal cells of Arabidopsis thaliana and staminal hair cells of Tradescantia virginiana, two tissues often used in experiments on symplastic transport. Transport in root tips dissected from the main plant body and in stamen hairs removed from the base of the stamen filament was compared with transport in undissected roots and stamen hairs attached to the base of the filament, respectively. Tissues were microinjected with fluorescent dyes (457 Da to > 3 kDa) with or without prior incubation in the callose deposition inhibitors 2-deoxy-D-glucose or aniline blue fluorochrome. In both tissues, dissection reduced the SEL, which was largely prevented by prior incubation in 2-deoxy-D-glucose but not by incubation in aniline blue fluorochrome. Thus, standard methods for tissue preparation can cause sufficient callose deposition to reduce cell-to-cell transport, and this needs to be considered in studies employing microinjection. Introduction of the dyes by pressure injection rather than iontophoresis decreased the SEL in A. thaliana but increased it in T. virginiana, showing that these two injection techniques do not necessarily give identical results and that plasmodesmata in different tissues may respond differently to similar experimental procedures.     

2-Hydroxyglutaryl-CoA dehydratase from Fusobacterium nucleatum (subsp. nucleatum): an iron-sulfur flavoprotein

Anaerobically prepared cell-free extracts from Fusobacterium nucleatum contain 2-hydroxyglutaryl-CoA dehydratase with a specific activity of 20 nkat mg^-1. The enzyme was purified 24-fold to a specific activity of 480 nkat mg^-1 by anion exchange chromatography, gel filtration and chromatography on Blue-Sepharose. The activity of the purified enzyme was strictly dependent on the reductant Ti(III)citrate and stimulated 25-fold by 0.15 mM ATP and 5 mM MgCl₂. ATP is hydrolysed to ADP during incubation with 2-hydroxyglutaryl-CoA dehydratase in the presence or absence of the substrate. The enzyme is extremely sensitive towards oxygen and is inhibited by 10 M chloramphenicol, 10 M 2,4-dinitrophenol or 0.15 mM hydroxylamine. The pure enzyme consists of three subunits (49 kDa), (39 kDa) and (24 kDa) in approximately equal amounts. In this respect the enzyme differs from the related 2-hydroxy-glutaryl-CoA dehydratase from Acidaminococcus fermentans and lactyl-CoA dehydratase from Clostridium propionicum both of which are composed of only two subunits with sizes comparable to those of and but require an additional protein for activity. The relative molecular mass of the native enzyme of about 100 kDa suggests a trimeric -structure. The homogeneous enzyme contains riboflavin (0.5 mol/112 kDa), iron and sulfur (3.5 mol/112 kDa each). Polyclonal antibodies directed against the 2-hydroxyglutaryl-CoA dehydratase from A. fermentans did not crossreact with cell free extracts or purified dehydratase from F. nucleatum. A comparison of the N-terminal amino acid sequences of the dehydratase subunits from A. fermentans and F. nucleatum, however, showed some similarities in the -subunits.Non-standard abbreviations DTT dithiothreitol - PAGE polyaccrylamide gel electrophoresis - VIS visible     

Expression of GFP-fusions in Arabidopsis companion cells reveals non-specific protein trafficking into sieve elements and identifies a novel post-phloem domain in roots

Transgenic Arabidopsis plants were constructed to express a range of GFP-fusion proteins (36-67 kDa) under the companion cell (CC)-specific AtSUC2 promoter. These plants were used to monitor the trafficking of these GFP-fusion proteins from the CCs into the sieve elements (SEs) and their subsequent translocation within and out of the phloem. The results revealed a large size exclusion limit (SEL) (>67 kDa) for the plasmodesmata connecting SEs and CCs in the loading phloem. Membrane-anchored GFP-fusions and a GFP variant targeted to the endoplasmic reticulum (ER) remained inside the CCs and were used as 'zero trafficking' controls. In contrast, free GFP and all soluble GFP-fusions, moved from the CCs into the SEs and were subsequently translocated through the phloem. Phloem unloading and post-phloem transport of these mobile GFP-fusions were studied in root tips, where post-phloem transport occurred only for the free form of GFP. All of the other soluble GFP-fusion variants were unloaded and restricted to a narrow zone of cells immediately adjacent to the mature protophloem. It appears that this domain of cells, which has a peripheral SEL of about 27-36 kDa, allows protein exchange between protophloem SEs and surrounding cells, but restricts general access of large proteins into the root tip. The presented data provide additional information on phloem development in Arabidopsis in relation to the formation of symplasmic domains.     

Simple, but not branched, plasmodesmata allow the nonspecific trafficking of proteins in developing tobacco leaves.

Leaves undergo a sink-source transition during which a physiological change occurs from carbon import to export. In sink leaves, biolistic bombardment of plasmids encoding GFP-fusion proteins demonstrated that proteins with an Mr up to 50 kDa could move freely through plasmodesmata. During the sink-source transition, the capacity to traffic proteins decreased substantially and was accompanied by a developmental switch from simple to branched forms of plasmodesmata. Inoculation of sink leaves with a movement protein-defective virus showed that virally expressed GFP, but not viral RNA, was capable of trafficking between sink cells during infection. Contrary to dogma that plasmodesmata have a size exclusion limit below 1 kDa, the data demonstrate that nonspecific "macromolecular trafficking" is a general feature of simple plasmodesmata in sink leaves.     

Secondary plasmodesmata are specific sites of localization of the tobacco mosaic virus movement protein in transgenic tobacco plants.

Expression of the tobacco mosaic virus 30-kD movement protein (TMV MP) gene in tobacco plants increases the plasmodesmatal size exclusion limit (SEL) 10-fold between mesophyll cells in mature leaves. In the present study, we examined the structure of plasmodesmata as a function of leaf development. In young leaves of 30-kD TMV MP transgenic (line 274) and vector control (line 306) plants, almost all plasmodesmata were primary in nature. In both plant lines, secondary plasmodesmata were formed, in a basipetal pattern, as the leaves underwent expansion growth. Ultrastructural and immunolabeling studies demonstrated that in line 274 the TMV MP accumulated predominantly in secondary plasmodesmata of nonvascular tissues and was associated with a filamentous material. A developmental progression was detected in terms of the presence of TMV MP; all secondary plasmodesmata in the tip of the fourth leaf contained TMV MP in association with the filamentous material. Dye-coupling experiments demonstrated that the TMV MP-induced increase in plasmodesmatal SEL could be routinely detected in the tip of the fourth leaf, but was restricted to mesophyll and bundle sheath cells. These findings are discussed with respect to the structure and function of plasmodesmata, particularly those aspects related to virus movement.     

Energy metabolism of autotrophically and heterotrophically grown cells of Nitrobacter winogradskyi

The adenine nucleotide pools and the NADH pool were compared in intact Nitrobacter winogradskyi cells grown under different conditions. The NADH pool was highest in nitrite-grown cells (22.0 nmol/mg N), less high in acetategrown cells (15.1 nmol/mg N),and lowest in pyruvate-grown cells (11.9 nmol/mg N).The adenine nucleotide pools and the NADH pool were determined after the transition from anaerobic to aerobic conditions.In both autotrophically and heterotrophically grown cells the ATP pool decreased within the first second after the addition of oxygen and then increased.In cells grown with nitrite or acetate the NADH pool increased the first second after the addition of oxygen then decreased below the initial value. In pyruvate-grown cells the changes in the NADH pool were less obvious.In the presence of rotenone autotrophic cells were able to generate ATP, but the reverse energy-dependent electron transport was inhibited. Consequently, NADH was not synthesized. N,N-dicyclohexylcarbodiimide an inhibitor of ATPase, prevented both ATP and NADH generation.Abbreviations DCCD N,N-dicyclohexylcarbodiimide     

Measurement of the electrical resistance of plasmodesmata and membranes of corn suspension-culture cells

Electrophysiological investigations of intercellular communication and membrane resistance in higher plants have been hampered by the difficulty in measuring these quantities independently. Uncertainty about the position of an electrode inserted into vacuolate tissue has further complicated such measurement. To overcome these problems sister cell pairs of a Zea mays L. Black Mexican Sweet suspension culture were used and dye was injected from the current-injecting electrode to determine the location of the electrode tip in each experiment. Of the impalements, 72% were cytoplasmic. The presence of plasmodesmata was fully incorporated into the electriccircuit model for the cell, and the resistance of the membrane of the current-injected cell was calculated, separate from the plasmodesmata resistance. This avoided some of the confusion resulting from work on multicellular tissue in which the position of the electrode and the extent of intercellular coupling is not determined. Using this technique, plasma-membrane resistivity was measured as 0.65 ·m², the resistivity of the tonoplast and plasma membrane in series was 1.35 ·m², and the resistance of a single plasmodesma was calculated to be 53 ± 11 G.Abbreviations BMS Black Mexican Sweet - PD potential difference - R_j resistance of the plasmodesmata in the junction between cells - R_m resistance of the plasma membrane of the current-injected cell - R_t resistance of the tonoplast - V₁, V₂ membrane PDs of sister cells This work was funded by an Australian Research Council grant to R.L.O. We are grateful to Dr. Maret Vesk (Electron Microscope Unit, The University of Sydney) for assistance with the preparation of EM sections, and to Dr. Richard Brettell (C.S.I.R.O. Division of Plant Industry) for assistance with the BMS culture.     

A Photobacterium-like bacterium able to fix nitrogen

A Photobacterium-like bacterium isolated from the roots of eelgrass (Zostera marina) was shown to fix nitrogen under anaerobic conditions. Nitrogen fixation by Photobacterium spp. has not been reported previous to this.Abbreviation PHB Poly--hydroxybutyrate     

Effect of virus infection on symplastic transport of fluorescent tracers in Nicotiana clevelandii leaf epidermis

The molecular weight exclusion limit of plasmodesmata in subveinal epidermal cells of Nicotiana clevelandii (Gray) leaves was estimated by microinjection and fluorescence microscopy using fluorescein isothiocyanate-peptide conjugates, carboxyfluorescein and Lucifer Yellow CH. The largest fluorochrome which moved symplastically between cells had a molecular weight of 749, although movement did not appear to depend purely on molecular weight parameters. Systemic infection of plants by tobacco rattle tobravirus, tomato black ring nepovirus or potato Y potyvirus did not alter the limits of plasmodesmatal conductance of the fluorochromes. However, carrot mottle umbravirus and groundnut rosette umbravirus diminished the symplastic mobility of some fluorescent tracers. These results imply that intercellular movement of these viruses does not involve a long-lasting increase in the plasmodesmatal molecular size exclusion limit.Abbreviations CMotV carrot mottle umbravirus - GRV groundnut rosette umbravirus - Glu l-glutamate - GluGlu -glutamyl glutamate - FITC fluorescein isothiocyanate - Ala₆ hexa-l-alanine - Gly₆ hexa-l-glycine - PVY potato Y potyvirus - TBRV tomato black ring nepovirus - TRY tobacco rattle tobravirus - TyrGlyGly tyrosylglycylglycine     

Electrical coupling between cells of higher plants: A direct demonstration of intercellular communication

Summary Electrical coupling between adjacent cells of Elodea canadensis has been demonstrated using a microelectrode technique in which the membrane potentials were recorded during the passage of a current pulse from the vacuole of one cell to the external solution. The changes in membrane potential resulting from the passage of the current may be simulated by an equivalent circuit in which the tonoplast:plasmalemma:plasmodesmata resistances are in the ratio 1.0:5.6:2.2. On this basis, the specific resistances are 3.1 k cm² for the plasmalemma, 1.0 k cm² for the tonoplast and 0.051 k cm² for the junction between the cells. Although the plasmodesmata permit the passage of current, it is estimated that they have a resistance about 60 times higher than would be the case if they were completely open channels. Electrical coupling has also been demonstrated between parenchymal cells in oat coleoptiles and between cortical cells in maize roots. The significance of these findings is discussed in relation to the symplastic transport of ions and other small molecules and in relation to the quantitative measurement of membrane resistance in multicellular tissue.