Symplastic Transport in Ipomea tricolor Source Leaves : Demonstration of Functional Symplastic Connections from Mesophyll to Minor Veins by a Novel Dye-Tracer Method

A novel method for the delivery of the fluorescent dye Lucifer Yellow CH to the cytosol of a source leaf mesophyll cell was devised which utilized a preencapsulation of the dye in phospholipid vesicles (liposomes). The liposomes were easily injected into the vacuoles of leaf cells of Beta vulgaris or Ipomea tricolor, where fusion with the tonoplast resulted in the release of the dye into the cytosol. Subsequent cell-to-cell movement of the dye was readily followed by fluorescence microscopy. Using this liposome technique symplastic continuity from the the mesophyll to the minor veins of the source leaf of Ipomea tricolor was demonstrated. This agreed with ultrastructural studies which demonstrated the presence of plasmodesmata between all cells from the mesophyll to the minor veins. The symplastic movement of dye from the injected mesophyll cell to the minor veins was unaffected by pretreatment of the leaf tissues with 2 millimolar p-chloromercuribenzenesulfonic acid. Pretreatment of the leaf tissues at alkaline pH (3-[N-morpholino] propanesulfonic acid-KOH, pH 8.0) had no apparent effect on dye movement between adjacent mesophyll cells but inhibited the movement of dye into and along the minor veins. Thus, although there were no apparent barriers to symplastic solute movement in this leaf, symplastic barriers could be imposed by the experimental conditions used.     

Cell-to-cell movement of green fluorescent protein reveals post-phloem transport in the outer integument and identifies symplastic domains in Arabidopsis seeds and embryos

Developing Arabidopsis (Arabidopsis thaliana) seeds and embryos represent a complex set of cell layers and tissues that mediate the transport and partitioning of carbohydrates, amino acids, hormones, and signaling molecules from the terminal end of the funicular phloem to and between these seed tissues and eventually to the growing embryo. This article provides a detailed analysis of the symplastic domains and the cell-to-cell connectivity from the end of the funiculus to the embryo, and within the embryo during its maturation. The cell-to-cell movement of the green fluorescent protein or of mobile and nonmobile green fluorescent protein fusions was monitored in seeds and embryos of plants expressing the corresponding cDNAs under the control of various promoters (SUC2, SUC3, TT12, and GL2) shown to be active in defined seed or embryo cell layers (SUC3, TT12, and GL2) or only outside the developing Arabidopsis seed (AtSUC2). Cell-to-cell movement was also analyzed with the low-molecular-weight fluorescent dye 8-hydroxypyrene-1,3,6-trisulfonate. The analyses presented identify a phloem-unloading domain at the end of the funicular phloem, characterize the entire outer integument as a symplastic extension of the phloem, and describe the inner integument and the globular stage embryo plus the suspensor as symplastic domains. The results also show that, at the time of hypophysis specification, the symplastic connectivity between suspensor and embryo is reduced or interrupted and that the embryo develops from a single symplast (globular and heart stage) to a mature embryo with new symplastic domains.     

Symplastic continuity in Agrobacterium tumefaciens-induced tumours

The Agrobacterium tumefaciens-induced plant tumour is regarded as a strong sink, containing a well-developed vascular system that guarantees an efficient supply of water and nutrients from the host plant into the tumour. The phloem transport and unloading of the fluorescent dye carboxyfluorescein (CF) was studied to examine the potential pathways for unloading of a low-molecular-mass solute, and was compared with the symplastic movement of potato virus X expressing a green fluorescent protein-coat protein fusion (PVX.GFP-CP). The distribution of both CF and PVX.GFP-CP in the host plant, Nicotiana benthamiana, demonstrated a clear symplastic pathway between the phloem of the host stem and the cells of the tumour, and also a considerable capacity for subsequent cell-to-cell transport between tumour cells. This same pattern of CF transport was also demonstrated independently for the host species Cucurbita maxima and Ricinus communis. In addition to entering the tumour, CF and PVX both moved through the vascular rays of the host stem towards the stele. The results confirm that host and tumour tissues in the Agrobacterium gall are in direct symplastic continuity and emphasize an important symplastic pathway for radial solute transport in stems.Key words: Agrobacterium tumefaciens, carboxyfluorescein, GFP, symplastic phloem unloading, plant tumour, vascular rays      

O-antigen from Bradyrhizobium japonicum lipopolysaccharide inhibits intercellular (symplast) communication between soybean (Glycine max) cells

The technique of fluorescence redistribution after photobleaching was utilized to measure intercellular movement of low molecular weight fluorescent hydrophilic substances across the cell wall/membrane interface between contiguous soybean (Glycine max (L.) Merr. cv. Mandarin) root cells (SB-1 cell line) in tissue culture. Lipopolysaccharide (LPS) purified from Bradyrhizobium japonicum R110d, a Gram-negative bacterium that normally infects and induces nodulation in soybean roots in vivo, inhibits intercellular communication between the soybean cells in a dose-dependent manner. In contrast, LPS from noninfecting strains failed to yield the same effect. The inhibitory activity of the LPS was localized to the O-antigen region of the LPS.     

Endoplasmic Reticulum Forms a Dynamic Continuum for Lipid Diffusion between Contiguous Soybean Root Cells

Intercellular communication between plant cells for low molecular weight hydrophilic molecules occurs through plasmodesmata. These tubular structures are embedded in the plant cell wall in association with the plasmalemma and endoplasmic reticulum (ER). Transmission electron microscopy has provided strong evidence to support the view that both the ER and plasmalemma are structurally continuous across the wall at these sites. In experiments to be described, the technique of fluorescence redistribution after photobleaching was used to examine the lateral mobility and intercellular transport capability of a number of fluorescent lipid and phospholipid analogs. These probes were shown by confocal fluorescence microscopy to partition in either the ER or plasmalemma. Results from these measurements provide evidence for cell communication between contiguous cells for probes localized predominantly in the ER. In contrast, no detectable intercellular communication was observed for probes residing exclusively in the plasmalemma. It was of particular interest to note that when 1-acyl-2-(N-4-nitrobenzo-2-oxa-l,3-diazole)aminoacylphosphatidylcholine was utilized as a potential reporter molecule for phospholipids in the plasmalemma, it was quickly degraded to 1-acyl-2-(N-4-nitrobenzo-2-oxa-1,3-diazole)aminoacyldiglyceride (NBD-DAG), which then appeared predominantly localized to the ER and nuclear envelope. This endogenously synthesized NBD-DAG was found to be capable of transfer between cells, as was exogenously incorporated NBD-DAG. Results from these investigations provide support for the following conclusions: (1) ER, but apparently not the plasmalemma, can form dynamic communication pathways for lipids across the cell wall between connecting plant cells; (2) the plasmodesmata appear to form a barrier for lipid diffusion through the plasmalemma; and (3) lipid signaling molecules such as diacylglycerol are capable of transfer between contiguous plant cells through the ER. These observations speak to issues of plant cell autonomy for lipid synthesis and mechanisms of intercellular signaling and communication.     

Metabolic inhibitors induce symplastic movement of solutes from the transport phloem of Arabidopsis roots

The distribution of the phloem-mobile fluorescent probe carboxyfluorescein(CF) within the primary root of Arabidopsis thaliana was imagedusing a confocal laser scanning microscope (CLSM) and the tissueand subcellular distribution of the probe was shown to be influencedby treatment with a number of metabolic inhibitors. Sodium azidecompletely inhibited the phloem transport of CF into the treatedregion of root. Treatment with both CCCP and probenecid inducedthe lateral movement of CF from the transport phloem to theadjacent cell layers, and the probe accumulated in the cytoplasmof the pericycle, endodermis, cortex, and epidermis. This lateraltransfer of CF was restricted to the pericycle in the presenceof plasmolysing concentrations of sorbitol. Ultrastructuralinvestigations demonstrated the presence of a plasm odesmatalpathway leading from the sieve elementcompanion cell complex(SE-CC) out into the cortex. The results are consistent withthe operation of this symplastic pathway under conditions ofmetabolic energy reduction and are discussed in relation tothe regulation of plasmodesmatal conductance in the transportphloem. Key words: Arabidopsis, confocal laser scanning microscopy (CLSM), metabolic inhibitors, phloem transport, symplastic phloem unloading     

Non-targeted and targeted protein movement through plasmodesmata in leaves in different developmental and physiological states

Plant cells rely on plasmodesmata for intercellular transport of small signaling molecules as well as larger informational macromolecules such as proteins. A green fluorescent protein (GFP) reporter and low-pressure microprojectile bombardment were used to quantify the degree of symplastic continuity between cells of the leaf at different developmental stages and under different growth conditions. Plasmodesmata were observed to be closed to the transport of GFP or dilated to allow the traffic of GFP. In sink leaves, between 34% and 67% of the cells transport GFP (27 kD), and between 30% and 46% of the cells transport double GFP (54 kD). In leaves in transition transport was reduced; between 21% and 46% and between 2% and 9% of cells transport single and double GFP, respectively. Thus, leaf age dramatically affects the ability of cells to exchange proteins nonselectively. Further, the number of cells allowing GFP or double GFP movement was sensitive to growth conditions because greenhouse-grown plants exhibited higher diffusion rates than culture-grown plants. These studies reveal that leaf cell plasmodesmata are dynamic and do not have a set size exclusion limit. We also examined targeted movement of the movement protein of tobacco mosaic virus fused to GFP, P30::GFP. This 58-kD fusion protein localizes to plasmodesmata, consistently transits from up to 78% of transfected cells, and was not sensitive to developmental age or growth conditions. The relative number of cells containing dilated plasmodesmata varies between different species of tobacco, with Nicotiana clevelandii exhibiting greater diffusion of proteins than Nicotiana tabacum.     

Evidence for symplastic phloem unloading in sink leaves of barley

The pathway of phloem unloading in sink barley (Hordeum vulgare) leaves was studied using a combination of electron microscopy, carboxyfluorescein transport, and systemic movement of barley stripe mosaic virus expressing the green fluorescent protein. Studies of plasmodesmatal frequencies between the phloem and mesophyll indicated a symplastic sieve element- (SE) unloading pathway involving thick-walled and thin-walled SEs. Phloem-translocated carboxyfluorescein was unloaded rapidly from major longitudinal veins and entered the mesophyll cells of sink leaves. Unloading was "patchy" along the length of a vein, indicating that sieve element unloading may be discontinuous along a single vascular bundle. This pattern was mirrored precisely by the unloading of barley stripe mosaic virus expressing the green fluorescent protein. Transverse veins were not utilized in the unloading process. The data collectively indicate a symplastic mechanism of SE unloading in the sink barley leaf.     

Signalling via plasmodesmata—the neglected pathway

This review considers recent studies on the role of plasmodesmata in the conduction of small solutes and signalling molecules between plant cells. The substructure of plasmodesmata is described in relation to the potential pathways available for symplastic signalling between cells. At least two discrete pathways are available for transport through plasmodesmata, the cytoplasmic sleeve between the desmotubule and the plasmalemma, and the endoplasmic reticulum which connects contiguous cells via the central desmotubule. This latter pathway has been shown recently to function as a dynamic continuum for the movement of lipids and lipid-signalling molecules between plant cells. The role of plasmodesmata in the conduction of hormones and electrical signals is also considered, as is the potential for movement of macromolecular signalling molecules via the symplast. The factors which regulate plasmodesmatal conductance and the significance of symplast 'domains' are discussed in relation to the control of movement of signalling molecules in the symplast.     

The Use of Fluorescent Tracers to Characterize the Post-Phloem Transport Pathway in Maternal Tissues of Developing Wheat Grains

Various polar fluorescent tracers were used to characterize the pathways for apoplastic and symplastic transport in the "crease tissues" (i.e. the vascular strand, chalaza, nucellus, and adjacent pericarp) of developing wheat (Triticum aestivum L.) grains. With mostly minor exceptions, the results strongly support existing views of phloem unloading and post-phloem transport pathways in the crease. Apoplastic movement of Lucifer yellow CH (LYCH) from the endosperm cavity into the crease was virtually blocked in the chalazal cell walls before reaching the vascular tissue. However, LYCH could move slowly along the cell wall pathway from the chalaza into the vascular parenchyma. Slow uptake of LYCH into nucellar cell cytoplasm was observed, but no subsequent symplastic movement occurred. Carboxyfluorescein (CF) imported into attached grains moved symplastically from the phloem across the chalaza and into the nucellus, but was not released from the nucellus. In addition, CF moved in the opposite direction (nucellus to vascular parenchyma) in attached grains. Thus, the post-phloem symplastic pathway can accommodate bidirectional transport even when there is an intense net assimilate flux in one direction. When fresh sections of the crease were placed in fluorochrome solutions (e.g. LYCH or pyrene trisulfonate), dye was rapidly absorbed into intact cells, apparently via unsealed plasmodesmata. Uptake was not visibly reduced by cold or by respiratory inhibitors, but was greatly reduced by plasmolysis. Once absorbed, the dye moved intercellularly via the symplast. Based on this finding, a size-graded series of fluorescein-labeled dextrans was used to estimate the size-exclusion limits (SEL) for the post-phloem symplastic pathway. In most, and perhaps all, cells of the crease tissues except for the pericarp, the molecular diameter for the SEL was about 6.2 nm. The SEL in much of the vascular parenchyma may be smaller, but it is still at least 3.6 nm. Channel diameters would likely be about 1 nm larger, or about 4.5 to 7.0 nm in the vascular parenchyma and 7.0 nm elsewhere. These dimensions are substantially larger than those for "conventional" symplastic connections (about 3 nm), and would have a greater than proportionate effect on the per channel diffusive and hydraulic conductivities of the pathway. Thus, relatively small and probably ultrastructurally undetectable adjustments in plasmodesmatal structure may be sufficient to account for assimilate flux through the crease symplast.     

STUDIES ON THE ROOT OF HORDEUM VULGARE L.– ULTRASTRUCTURE OF THE SEMINAL ROOT WITH SPECIAL REFERENCE TO THE PHLOEM

Seminal root tissue of Hordeum vulgare L. var. Barsoy was fixed in glutaraldehyde and osmium tetroxide and studied with the light and electron microscopes. The roots consist of an epidermis, 6–7 layers of cortical cells, a uniseriate endodermis and a central vascular cylinder. Cytologically, the cortical and endodermal cells are similar except for the presence of tubular-like invaginations of the plasmalemma, especially near the plasmodesmata, in the former. The vascular cylinder consists of a uniseriate pericycle surrounding 6–9 phloem strands occurring on alternating radii with an equal number of xylem bundles. The center of the root contains a single, late maturing metaxylem vessel element. Each phloem strand consists of one protophloem sieve element, two companion cells and 1–3 metaphloem sieve elements. The protophloem element and companion cells are contiguous with the pericycle. Metaphloem sieve elements are contiguous with companion cells and are separated from tracheary elements by xylem parenchyma cells. The protoplasts of contiguous cells of the root are joined by various numbers of cytoplasmic connections. With the exception of the pore-plasmodesmata connections between sieve-tube members and parenchymatic elements, the plasmodesmata between various cell types are similar in structure. The distribution of plasmodesmata supports a symplastic pathway for organic solute unloading and transport from the phloem to the cortex. Based on the arrangement of cell types and plasmodesmatal frequencies between various cell types of the root, the major symplastic pathway from sieve elements to cortex appears to be via the companion and xylem parenchyma cells.     

A morphometric analysis of the phloem-unloading pathway in developing tobacco leaves

A morphometric analysis of developing leaves of Nicotiana tabacum L. was conducted to determine whether imported photoassimilates could be unloaded by symplastic transport and whether interruption of symplastic transport could account for termination of import. Five classes of veins were recognized, based on numbers of cells in transverse section. Photoassimilate is unloaded primarily from Class III veins in tissue nearing the end of the sink phase of development. Smaller veins (Class IV and V) do not transport or unload photoassimilate in sink tissue because the sieve elements of these veins are immature until after the tissue stops importing. In Class III veins the sieve element-companion cell (SE-CC) complexes are surrounded by phloem parenchyma which abuts the bundle sheath. Along the most obvious unloading route, from SE-CC complex to phloem parenchyma to bundle sheath to mesophyll cells, the frequency of plasmodesmata at each interface increases. To determine whether this pattern of plasmodesmatal contact is consistent with symplastic unloading we first demonstrated, by derivation from Fick's law that the rate of diffusion from a compartment is proportional to a number N which is equal to the ratio of surface area to volume of the compartment multiplied by the frequency of pores (plasmodesmata) which connect it to the next compartment. N was calculated for each compartment within the vein which has the SE-CC complex as its center, and was shown to be statistically the same in all cases except one. These observations are consistent with a symplastic unloading route. As the leaf tissue matures and stops importing, plasmodesmatal frequency along the unloading route decreases and contact area between cells also decreases as intercellular spaces enlarge. As a result, the number of plasmodesmata between the SE-CC complex and the first layer of mesophyll cells declines in nonimporting tissue to 34% of the number found in importing tissue, indicating that loss of symplastic continuity between the phloem and surrounding cells plays a role in termination of photoassimilate unloading.Abbreviation SE-CC sieve element-companion cell     

Changes in symplastic permeability during adventitious shoot regeneration in tobacco thin cell layers

Thin cell layer (TCL) explants of tobacco (Nicotiana tabacum L.) were cultured in either a regeneration medium that resulted in formation of adventitious vegetative shoots or a non-regeneration (control) medium that maintained the TCLs but did not promote shoot formation. Microinjections were conducted on epidermal cells at 1- or 2-day intervals during the culture period (14 days) and also on meristematic regions as they appeared in regenerating TCLs. A fluorescein isothiocyanate-labelled peptide (F(Glu)₃ MW 799) was used to assess the permeability of the symplast during adventitious shoot regeneration. A period of increased symplastic movement of F(Glu)₃ was detected during day 2 of culture and was significantly greater in regenerating TCLs than in non-regenerating TCLs. This corresponded to the period of the first cell divisions and represents the re-initiation of a meristematic type of symplastic linkage between epidermal cells. A smaller increase in cell-to-cell movement within non-regenerating TCLs indicated a possible stress response as a factor in these changes. Movement of F(Glu)₃ throughout the epidermal symplast of regenerating TCLs returned to pre-culture levels by the time of shoot primordia formation. F(Glu)₃ movement was further down-regulated in non-regenerating TCLs, with a high degree of cell isolation observed. Within newly formed shoots, symplastic movement of F(Glu)₃ cycled between high and low levels.     

Characterization of a connexin homologue in cultured soybean cells and diverse plant organs

Antibodies were prepared against ratliver connexin (27-kDa polypeptide subunit of cell gap junctions found between contacting animal cells) and a putative soybean (Glycine max (L.) Merr.) connexin (29-kDa polypeptide) previously isolated from cultured soybean root cells (SB-1 cell line). The antibodies were utilized to examine the intracellular localization of soybean connexin in these cultured soybean cells and to probe for the presence of a soybean-type connexin in petals, fruits, and leaves from a variety of plants. As judged by specific reactivity on immunoblots, both antibodies against the 27-kDa polypeptide (ratliver connexin) and against the 29-kDa polypeptide (operationally termed soybean connexin) were utilized to demonstrate immunological relatedness of the 27-kDa (rat liver) and the 29-kDa (soybean) polypeptide. Immunofluorescent localization of the putative soybean connexin in cultured soybean cells utilizing these probes demonstrated a peripherally localized punctate pattern of labeling at areas of contact between cells. Use of antibody to the soybean connexin as a probe on immunoblots of extracts from petals, fruits and leaves demonstrated that the soybean-type connexin is present in a large number of different plants.Abbreviations kDa kilodalton - IgG immunoglobulin G - NEPHGE non-equilibrium pH gradient electrophoresis - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis     

Long-distance trafficking of macromolecules in the phloem

The fact that macromolecules such as proteins and mRNAs overcome the symplastic barriers between various tissue domains was first evidenced by the movement of plant viruses. We have recently demonstrated that viral infection disengages the symplastic restriction present between the sieve element-companion cell complex and neighboring cells in tobacco plants. As a result, green fluorescent protein, which was produced in mesophyll and bundle sheath cells, could traffic into the sieve tube and travel long distances within the vascular system. In this addendum we discuss the likely existence of a novel plant communication network in which macromolecules also act as long-distance trafficking signals. Plasmodesmata interconnecting sieve elements and companion cells as well as plasmodesmata connecting the sieve tube with neighboring cells may play a central role in establishing this communication network.Key words: companion cells, cucumber mosaic virus, Cucumis melo, plasmodesmata, movement protein, sieve-elementsTranslocation of photoassimilates from the source (site of synthesis) to various sink organs is governed, in part, by short-distance intercellular transfer of assimilates to the loading region of the phloem and long-distance transport within the plant vascular system. Sucrose, which is synthesized in the leaf mesophyll, moves cell-to-cell symplastically through plasmodesmata until it reaches the boundary of the sieve element (SE)-companion cell (CC) complex. In many plant species, the connection between phloem parenchyma (PP)/bundle sheath (BS) cells and CCs is characterized by a sparseness of plasmodesmata (e.g., Solanaceae), and sucrose is exported out of the cells to the apoplast. This type of plants (apoplastic loaders) uses sucrose proton symporters to load the sucrose into the vasculature.¹ Cucurbits are considered one of the model plants for symplastic phloem loading.² This type of plant is characterized by abundant plasmodesmata interconnecting the intermediary cells, which are specialized CCs, with the neighboring BS cells. It is generally accepted that in these plants, phloem loading includes intercellular movement of sucrose through the plasmodesmata, along the entire pathway from the mesophyll cell to the SE-CC complex.Interestingly, the existence of plasmodesmata interconnecting the SE-CC complex and neighboring cells is evident in all plant species that are characterized by an apoplastic phloem-loading mechanism. Moreover, microinjection experiments have indicated that plasmodesmata interconnecting the PP-CC are functional, in that they allow the exchange of small membrane-impermeable fluorescent probes.³ Virus movement through plasmodesmata from the mesophyll into the SEs further supports the notion that the symplastic communication between the CC-SE complex and the neighboring cells is functional.⁴One can assume that in apoplastic-loading plants, it would be an advantage to maintain the SE-CC complex as an isolated domain, with no functional plasmodesmata interconnecting it to the neighboring tissue. Symplastic continuity between the two domains could result in leakage of sucrose out of the vasculature and a significant reduction in the efficacy of sucrose loading. The fact that the two domains are interconnected suggests that any back-leakage of sucrose that might occur is insignificant relative to the likely efficacy of this communication route.What might the advantage be for symplastic communication between the SE-CC complex and the neighboring tissue? Accumulated evidence suggests that at the tissue/organ level, cell-to-cell trafficking of information molecules allows for noncell-autonomous control over a range of processes, whereas at the organismal level, the phloem serves as an information superhighway, delivering a wide range of macromolecules to enable the plant to function as a whole organism.^5–8 We advanced the hypothesis that plasmodesmata interconnecting the CCs and PP/BS cells play a pivotal role in controlling the long-distance trafficking of putative signaling molecules.     

The cellular pathway of photosynthate transfer in the developing wheat grain. I. Delineation of a potential transfer pathway using fluorescent dyes

A potential cellular pathway for photosynthate transfer between the crease phloem and the starchy endosperm of the developing wheat grain has been delineated using fluorescent dyes. Membrane permeable and impermeable dyes have been introduced into the grain through the crease phloem, the endosperm cavity or the dorsal surface of the starchy endosperm. The movement of the symplastic tracer 5-(6)-6-carboxyfluorescein (CF) derived from 5-(6)-6-carboxyfluorescein diacetate (CFDA), from either direction between the crease phloem and the endosperm cavity, indicated that the symplastic pathway was operative from the crease phloem to the nucellar projection. Furthermore, the inward movement of apoplastic tracer trisodium, 3-hydroxy-5,8,10-pyrentrisulphonate (PTS) from the endosperm cavity and that of CF following plasmolysis showed that there was a high resistance to solute transfer within the apoplast of the pigment strand. All dyes entered the modified aleurone and adjacent sub-aleurone bordering the endosperm cavity. Subsequent movement of the symplastic tracers CF and sulphorhodamine G (SRG) into and through the endosperm was rapid. However, the movement of apoplastic tracers PTS and Calcofluor White (CFW) was relatively slow and with tissue plasmolysis, CF was confined to the cytoplasm of the modified aleurone and subaleurone cells. Together, these results demonstrate that there is a high resistance to solute movement within the apoplast of the cells bordering the endosperm cavity. We propose that photosynthate transfer is via the symplast to the nucellar projection where membrane exchange to the endosperm cavity occurs. Uptake from the cavity is by the modified aleurone and small endosperm cells prior to transfer through the symplast to and through the starchy endosperm.     

Cell-to-cell and long-distance trafficking of the green fluorescent protein in the phloem and symplastic unloading of the protein into sink tissues

Macromolecular trafficking within the sieve element-companion cell complex, phloem unloading, and post-phloem transport were studied using the jellyfish green fluorescent protein (GFP). The GFP gene was expressed in Arabidopsis and tobacco under the control of the AtSUC2 promoter. In wild-type Arabidopsis plants, this promoter regulates expression of the companion cell-specific AtSUC2 sucrose-H+ symporter gene. Analyses of the AtSUC2 promoter-GFP plants demonstrated that the 27-kD GFP protein can traffic through plasmodesmata from companion cells into sieve elements and migrate within the phloem. With the stream of assimilates, the GFP is partitioned between different sinks, such as petals, root tips, anthers, funiculi, or young rosette leaves. Eventually, the GFP can be unloaded symplastically from the phloem into sink tissues, such as the seed coat, the anther connective tissue, cells of the root tip, and sink leaf mesophyll cells. In all of these tissues, the GFP can traffic cell to cell by symplastic post-phloem transport. The presented data show that plasmodesmata of the sieve element-companion cell complex, as well as plasmodesmata into and within the analyzed sinks, allow trafficking of the 27-kD nonphloem GFP protein. The data also show that the size exclusion limit of plasmodesmata can change during organ development. The results are also discussed in terms of the phloem mobility of assimilates and of small, low molecular weight companion cell proteins.     

A dual switch in phloem unloading during ovule development in <Emphasis Type="Italic">Arabidopsis</Emphasis>

Developing flowers are important sinks in Arabidopsis thaliana. Their energy demand is covered by assimilates which are synthesized in source leaves and transported via the vasculature. Assimilates are unloaded either symplastically through plasmodesmata or apoplastically by specific transport proteins. Here we studied the pathway of phloem unloading and post-phloem transport in developing gynoecia. Using phloem-mobile fluorescent tracers, we show that phloem unloading into cells of ovule primordia followed a symplastic pathway. Subsequently, the same tracers could not move out of phloem cells into mature ovules anymore. A further change in the mode of phloem unloading occurred after anthesis. In open flowers as well as in outgrowing siliques, the phloem was again unloaded via the symplast. This observed onset of symplastic phloem unloading was accompanied by a change in frequency of MP17-GFP-labeled plasmodesmata. We could also show that the change in cell–cell connectivity was independent of fertilization and increasing sink demand. The presented results indicate that symplastic connectivity is highly regulated and varies not only between different sink tissues but also between different developmental stages.     

Changes in macromolecular movement accompany organogenesis in thin cell layers of <Emphasis Type="Italic">Torenia fournieri</Emphasis>

A range of fluorescently labelled probes of increasing molecular weight was used to monitor diffusion via the symplast in regenerating thin cell layer (TCL) explants of Torenia fournieri. An increase in intercellular movement of these molecules was associated with the earliest stages of vegetative shoot regeneration, with the movement of a 10 kDa dextran (FD 10000) observed between epidermal cells prior to the appearance of the first cell divisions. A low frequency of dextran movement in thin cell layers maintained under non-regenerating conditions was also observed, indicating a possible wound induced increase in intercellular movement. Dextran movement between epidermal cells reached a peak by day 4 of culture and then declined as cell division centres (CDCs) formed, became meristematic regions and finally emerged as adventitious shoots. Within CDCs, testing with small fluorescent probes (CF: carboxyfluorescein, mw 376 Da and F(Glu)₃: fluorescein-triglutamic acid, mw 799 Da) revealed a mosaic of cell isolation and regions of maintained symplastic linkage. Within shoots, surface cells of the presumptive apical meristem permitted the intercellular movement of 10 kDa dextrans but epidermal cells of the surrounding leaf primordia did not permit dextran movement. In some cases, intercellular movement of CF was maintained within leaf primordia. Symplastic movement of labelled dextrans during regeneration in Torenia thin cell layers represents a significant increase in the basal size exclusion limit (SEL) of this tissue and reveals the potential for intercellular trafficking of developmentally related endogenous macromolecules.