Symplast domains in extrastelar tissues of Egeria densa Planch.

A set of hydrophilic fluorescent dyes of known molecular weight has been used to determine the molecular exclusion limit and the extent of apical, epidermal and cortical symplasts in the root, stem and leaf of Egeria densa. These dyes are unable to pass the plasmalemma, so that any cell-to-cell movement of injected dye must occur via the symplast. The shoot-apex symplast has a high molecular exclusion limit, excluding dyes with a molecular weight of 749 dalton (fluorescein hexaglycine) and greater but allowing dyes of up to 665 dalton (fluorescein diglutamic acid) to pass. The leaf epidermal symplast is similar to that in the apex: fluorescein pentaglycine (674 dalton) moves to a limited extent, but fluorescein hexaglycine is immobile. Stem and root epidermal cells have a lower molecular exclusion limit, only the dye 6-carboxyfluorescein (376 dalton) is able to move from cell-to-cell. Cortical and epidermal tissues in both the stem and the root have similar symplast permeabilities. However, a barrier to dye (6-carboxyfluorescein) movement is found between the epidermis and the cortex in both organs. Barriers are also found at the nodes between expanded internodes. The stem barriers are not found in the unexpanded nodes near the shoot tip; apparently they are formed early during internode expansion. In the root tip, a barrier to the movement of dye is found between the root cap and the remainder of the root. Plasmodesmata are found linking all cell types studied, even cells where barriers to dye movement occur. Thus, the plant, far from being one uniform symplast, consists of a large number of symplast domains, which may or may not differ in molecular exclusion limit.Abbreviations F fluorescein isothiocyanate isomer I - Glu l-glutamic acid - (Glu)₂ l-glutamylglutamic acid - (Gly)₅ l-pentaglycine - (Gly)₆ l-hexaglycine     

Characterisation of the Egeria densa Planch. leaf symplast

The hydrophyllic dyes fluorescein glutamic acid, fluorescein glutamylglutamic acid (F(Glu)₂), fluorescein hexaglycine, fluorescein leucyldiglutamyl-leucine and 6-carboxyfluorescein are unable to pass the plasmalemma in leaves of E. densa. However, when injected into single cells the dye conjugates of molecular weight 665 dalton or less move freely from cell-to-cell. This intercellular movement presumably occurs via the plant symplast. Movement of F(Glu)₂ from the injected cell occurs with greatly reduced frequency when Ca²⁺, Mg²⁺ or Sr²⁺ are injected into the cell immediately prior to the dye. The fraction of dye injections leading to movement declines with increasing group II ion concentration in the electrode tip, up to 10 mM. Sodium and K ions do not affect dye movement. When dye injection is delayed 30 min after Ca²⁺ injection, dye movement is no longer inhibited. Thus the cells recover from the Ca²⁺ injection, indicating that the ion does not cause major cell damage. Recovery from Mg²⁺ injection is not complete within 60 min. Treatment of leaves with chemicals expected to raise the concentration of free intracellular group II ions, notably the mitochondrial uncoupler carbonyl cyanide p-trifluoromethoxyphenyl hydrazone, the inhibitor of mitochondrial Ca²⁺ uptake trifluralin, or the ionophore A23187 also inhibits dye movement, while the calmodulin inhibitor trifluoperazine does not. Cytoplasmic streaming is inhibited by Ca²⁺ or Mg²⁺ injection and by the metabolic inhibitors. However when streaming is stopped by cytochalasin B, dye movement is not inhibited. Hence steaming is not necessary for dye movement. Thus the cytoplasmic concentration of free group II ions may directly regulate the permeability of the plant symplast.     

Characterization of theEgeria densa leaf symplast: Response to plasmolysis,deplasmolysis and to aromatic amino acids

Summary The fluorescent dyes 6-carboxyfluorescein and fluorescein glutamylglutamic acid, which move freely in theEgeria densa leaf symplast, fail to move from cells subjected to plasmolysis, demonstrating that plasmolysis disrupts symplastic continuity. Dye movements begins again within 10 minutes of removal of the osmoticum and becomes more extensive with increasing recovery time. The re-established symplastic links show a number of distinctive features compared to untreated leaves: dyes of up to 1678 dalton can pass, compared to the normal limit of 665 dalton; and Ca²⁺ ions, which completely inhibit dye movement in untreated cells, only reduce the extent of dye movement. Aromatic amino acids and their fluorescein conjugates prevent intercellular movement in untreated cells. In deplasmolysed cells the aromatic conjugates move freely. The increased symplast permeability persists for at least 20 hours. Thus, after plasmolysis followed by deplasmolysis, the symplast shows a marked increase in permeability associated with an increased molecular exclusion limit, indicating an increase in pore size, and symplast permeability becomes relatively insensitive to Ca²⁺ ions or to the aromatic conjugates.     

Uptake and Compartmentation of Fluorescent Probes by Plant Cells

Several fluorescent compounds are now being used as probes forstudying plant transport processes. This review considers thepotential mechanisms of uptake of such probes with particularemphasis on their subsequent compartmentation within the cell.Physico-chemical parameters, such as the dissociation constant(pK_a) and polarity (log k^ow) of the dye molecule provide importantguides as to the likely permeability of the plasmalemma to differentfluorochromes and an ion-trap mechanism may explain the accumulationof many fluorescent probes by plant cells. However, physico-chemicalparameters alone do not always explain the subsequent compartmentationof fluorescent probes within the cell. Evidence is accumulatingthat many anionic fluorescent probes may cross the plasmalemmain the undissociated state, followed by carrier-mediated transportof the anion across the tonoplast. In the specialized case ofthe highly dissociated dye, Lucifer Yellow CH (LYCH), the physico-chemicalproperties of the molecule would predict that it should be unableto cross membranes. Despite this, there have been several reportsof the movement of LYCH from the apoplast to the vacuole ofplant cells. Fluid-phase endocytosis has been implicated inthe vacuolar accumulation of LYCH and also a range of high-molecularweight, purified fluorescent conjugates. This evidence is discussedin the light of some reports that membrane-impermeant dyes,including LYCH, may cross the tonoplast following their microinjectioninto the cytoplasm.     

Uptake of Lucifer Yellow CH into intact barley roots: Evidence for fluid-phase endocytosis

Intact barley (Hordeum vulgare L.) roots have been shown to take up the highly fluorescent dye Lucifer Yellow CH (LYCH) into their cell vacuoles. In the apical 1 cm of root tip, differentiating and dividing cells showed a prolific uptake of LYCH into their provacuoles. The LYCH was retained during fixation, apparently becoming bound to electron-dense material in the vacuoles. The dye freely entered the apoplast of roots in which the Casparian band was not developed, being taken up into the vacuoles of cells in both the cortex and stele. However, when LYCH was applied to a 1-cm zone approx. 6 cm behind the root tip the Casparian band on the radial walls of the endodermis completely prevented the dye from entering the cells of the stele, only the cell walls and vacuoles of the cortical cells taking up the dye. The inability of LYCH to cross the plasmalemma of the endodermal cells and enter the stele via the symplast substantiates previous claims that the dye is unable to cross the plasmalemma of plant cells. The results are discussed in the light of recent demonstrations that LYCH is a particularly effective marker for fluid-phase endocytosis in animal and yeast cells. A calculation of the energetic requirements for LYCH uptake into barley roots supports the contention that LYCH is taken up into the vacuoles of plant cells by fluid-phase endocytosis.Abbreviation LYCH Lucifer Yellow CH     

Cell-cell communication in the leaves of Commelina cyanea and other plants

Abstract. The fluorescent probes 6–carboxyfluorescein and lucifer yellow CH which do not pass the plasmalemma have been used to examine cell-to-cell communication in the leaf of Commelina cyanea. Dye movement from cell-to-cell occurs in epidermal, spongy and palisade mesophyll, and vascular cells. Dye movement between these tissues was also found. Hence, the epidermis, spongy and palisade mesophyll cells, and vascular tissue are all linked in a continuous symplast. However, dye injected into the epidermal cells rarely moves into guard cells, indicating that these cells are relatively isolated from the surrounding cells. In the same way, guard cells in Vicia faba and the C₄ grass Anthephora pubescens also appeared to be isolated from epidermal cells. Thus guard cell isolation from cell-to-cell communication appears to be a common phenomenon. Hence, the ion fluxes required for guard cell function must occur via the apoplast.     

Permeability of the suberized mestome sheath in winter rye

Mestome sheath cells of winter rye (Secale cereale L. cv Puma) deposit suberized lamellae in their secondary cell walls. Histochemical tests including acid digestion and staining with Sudan IV and Chelidonium majus root extract were used to detect the presence of suberin in the primary cell wall. There was no evidence of a Casparian band between adjacent mestome sheath cells. Fluorescent dye techniques were used to trace solute movement through the rye leaf apoplast. Calcofluor white M2R, a fluorescent dye which binds to cell walls as it moves apoplastically, proved to be too limited in its mobility in leaves to test mestome sheath permeability. Trisodium 3-hydroxy-5,8,10 pyrene trisulfonate, a fluorescent dye which is mobile in the apoplast, moved easily up the vascular bundles in the transpiration stream, and diffused outward from the veins to the epidermal cell walls within minutes of reaching a particular level in the leaf. We conclude that the suberized mestome sheath of rye leaves is freely permeable to solutes moving apoplastically through radial primary cell walls.     

Acetylcholine-evoked uncoupling restricts the passage of Lucifer Yellow between pancreatic acinar cells

Summary Direct cell to cell movement of the fluorescent dye Lucifer Yellow CH (457 daltons) in exocrine acinar tissue is demonstrated by direct observation of living mouse pancreatic segments. Electrical uncoupling of pancreatic acinar cells by local application of a high concentration of acetylcholine significantly restricts cell to cell passage of the fluorescent dye. This result shows that a secretagogue can control direct movement of organic molecules between cells through junctional channels.     

Evidence for intercellular cohesion in the septate junction of the protozoon Gregarina

Injection of Lucifer Yellow dye was used to establish whether septate junctions formed a permeability barrier between primite and satellite gamonts in the syzygy of the protozoon Gregarina. The fluorescent dye did not pass from one cell to the other, thus suggesting that the septate junction served only for mechanical adhesion. Later on in development, when the gametocyst had formed, the septate junction vanished and interruptions were observed between opposing cell membranes. At this stage the fluorescent dye was able to pass freely into the conjugated cells.     

Movement of Lucifer Yellow CH in potato tuber storage tissues: A comparison of symplastic and apoplastic transport

The fluorescent dye Lucifer Yellow CH (LYCH) was introduced directly into the symplast of potato (Solanum tuberosum L.) tuber storage parenchyma by microinjection and also into the apoplast through cuts made in the stolon cortex. Microinjected LYCH moved away rapidly from a single storage cell and spread radially via the symplast. When the microinjected tissue was subsequently fixed in glutaraldehyde and sectioned the dye was seen clearly to be localised in the cytoplasm but not in the vacuole. In comparison, when LYCH was introduced into cuts made in the stolon cortex the dye entered the tuber by the xylem and subsequently spread apoplastically. No movement of dye was observed in the phloem. In glutaraldehyde-fixed tissues, in which LYCH was introduced to the apoplast, the dye was found within xylem vessels, in the cell walls and in intercellular spaces. Wall regions, possibly associated with plasmodesmata, became stained by the dye as it moved through the apoplast. Three hours after introduction of the dye to the stolon, intense deposits of LYCH were found in the vacuoles of all cells in the tuber, many aligned along the tonoplast. Differentiating vascular parenchyma elements contained large amounts of dye within enlarging vacuoles. However, with the exception of plasmolysed and-or damaged cells, LYCH was absent from the cytoplasm following its introduction to the plasmalemma it is suggested that the most likely pathway from the cell wall to the vacuole was by endocytosis, the dye being transported across the cytoplasm in membrane-bound vesicles. Clathrin-coated vesicles were abundant in the storage cells, providing a possible endocytotic pathway for dye movement. The significance of these observations is discussed in relation to the movement of LYCH in plant tissues and to the movement of solutes within and between storage cells of the tuber.Abbreviation LYCH Lucifer Yellow CH     

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.     

Galactosyltransferase activity of intact neural retinal cells from the embryonic chicken

Permeability of electrotonic junctions between isolated and reaggregated Fundulus blastomeres was evaluated with a new fluorescent dye, Lucifer yellow CH. The dye is readily shown to pass between coupled cells. It does not enter from the bathing medium, nor does it move between cells via the enlarged extracellular space sometimes seen between them. Thus, we conclude that passage is via a private pathway, presumably provided by the gap junctions described for this tissue. In contrast to previous findings, fluorescein (as the sodium salt, uranine) also passes between coupled Fundulus cells. Although it can enter from the bathing medium, it may be less concentrated in the space between a cell pair than in the uninjected cell. Again, passage via gap junctions is indicated. Molecular models demonstrate that Lucifer yellow and fluorescein are similar in size. Thus, similarity in ability to permeate junctional membranes is to be expected.     

ELECTROPHYSIOLOGICAL INVESTIGATIONS OF THE RED ALGA GRIFFITHSIA PAGIFIG AKYL. 1

The membrane potentials of the plasmalemma and tonoplast in Griffithsia pacifica Kyl were measured and shown to be significantly different. No consistent cell wall potential was discovered. Adjacent cells in the filament were demonstrated to be electrolonically coupled with a mean coupling coefficient of 0.13. Cobaltions did not move between cells. No dye coupling was seen using the fluorescent dye Lucifer yellow CH. These observations provide new information on the electrophysiology of red algae and indicate that there is intercellular continuity between the cells of a filament of Griffithsia pacifica.     

The ultrastructure of the salt gland of Spartina foliosa

Summary The salt gland in Spartina foliosa is composed of two cells, a large basal cell and a smaller, dome-shaped cap cell which is located on a neck-like protrusion of the basal cell. There is no cuticular layer separating the salt gland from the mesophyll tissue. The basal cell has dense cytoplasm which contains numerous mitochondria, rod-like wall protuberances, and infoldings of the plasmalemma which extend into the basal cell and partition the basal cell cytoplasm. The protuberances originate on the wall between the basal and the cap cells and are isolated from the basal-cell cytoplasm by the infoldings of the plasmalemma. While the cap cell has no partitioning membrane system or wall protuberances, it resembles the basal cell by having dense cytoplasm and numerous mitochondria.The basal cell seems to be designed for efficient movement of ions toward the cap cell. The long, dead-end extracellular channels in the basal cell of Spartina appear comparable to surface specializations seen in the secreting epithelium of animal cells which carry out solute-linked water transport. The number of mitochondria and their close association with the plasmalemma extensions suggest that they have an important role in the transfer of ions through the basal cell.The accumulated ions would move into the extracellular spaces along an osomotic gradient where the accompanying passive flow of water would move the ions into the cap-cell wall and from there the solution would pass out through the pores in the cuticle.     

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.     

Lateral electromigration and diffusion of Fc epsilon receptors on rat basophilic leukemia cells: effects of IgE binding

We have used in situ electromigration and post-field relaxation (Poo, M.-m., 1981, Annu. Rev. Biophys. Bioeng., 10:245-276) to assess the effect of immunoglobulin E (IgE) binding on the lateral mobility of IgE- Fc receptors in the plasmalemma of rat basophilic leukemia (RBL) cells. Bound IgE sharply increased the receptor's electrokinetic mobility, whereas removal of cell surface neuraminic acids cut it to near zero. In contrast, we found only a small difference between the lateral diffusion coefficients (D) of vacant and IgE-occupied Fc receptors (D: 4 vs. 3 X 10(-10) cm2/s at 24 degrees C). This is true for monomeric rat IgE; with mouse IgE, the difference in apparent diffusion rates was slightly greater (D: 4.5 vs. 2.3 X 10(-10) cm2/s at 24 degrees C). This range of D values is close to that found in previous photobleaching studies of the IgE-Fc epsilon receptor complex in RBL cells and rat mast cells. Moreover, enzymatic depletion of cell coat components did not measurably alter the diffusion rate of IgE-occupied receptors. Thus, binding of fluorescent macromolecular probes to cell surface proteins need not severely impede lateral diffusion of the probed species. If the glycocalyx of RBL cells does limit lateral diffusion of the Fc epsilon receptor, it must act primarily on the receptor itself, rather than on receptor-bound IgE.     

The Use of Carboxyfluorescein Diacetate Succinimidyl Ester (CFSE) to Monitor Lymphocyte Proliferation

Carboxyfluorescein succinimidyl ester (CFSE) is an effective and popular means to monitor lymphocyte division^1-3. CFSE covalently labels long-lived intracellular molecules with the fluorescent dye, carboxyfluorescein. Thus, when a CFSE-labeled cell divides, its progeny are endowed with half the number of carboxyfluorescein-tagged molecules and thus each cell division can be assessed by measuring the corresponding decrease in cell fluorescence via Flow cytometry. The capacity of CFSE to label lymphocyte populations with a high fluorescent intensity of exceptionally low variance, coupled with its low cell toxicity, make it an ideal dye to measure cell division. Since it is a fluorescein-based dye it is also compatible with a broad range of other fluorochromes making it applicable to multi-color flow cytometry. This article describes the procedures typically used for labeling mouse lymphocytes for the purpose of monitoring up to 8 cell divisions. These labeled cells can be used both for in vitro and in vivo studies.     

Babesia rodhaini, Babesia bovis, and Babesia bigemina: analysis and sorting of red cells from infected mouse or calf blood by flow fluorimetry using 33258 Hoechst.

The DNA of Babesia spp. parasites within host intact red blood cells was labeled using the fluorescent bisbenzimidazole dye 33258 Hoechst. The labeled cells were sorted on a fluorescence activated cell sorter on the basis of cell fluorescence (proportional to DNA content) and the intensity of light scattered from the cells at low angles (related to cell size). The optimal conditions for dye uptake were established for the murine parasite Babesia rodhaini and the bovine parasites B. bovis and B. bigemina. Uninfected cells were nonfluorescent after incubation with the dye and could be completely separated from infected fluorescent cells. The fluorescence of cells infected with B. rodhaini was proportional to the number of parasite nuclei per cell. With saturation levels of dye, samples infected with B. bovis or B. bigemina in which erythrocytes contained one or two parasites, both exhibited only one fluorescent cell peak. Cell sorting did not eliminate the infectivity of B. rodhaini. The method may be used to separate populations of uninfected blood cells and cells infected with Babesia spp. for biochemical and immunochemical experiments.     

Ligands with affinity to specific sequence of DNA base pairs. XII. The synthesis and cytological studies of dimeric Hoechst 33258 molecules

We synthesized dimeric Hoechst dye molecules composed of two moieties of the Hoechst 33258 fluorescent dye phenolic hydroxy groups of which were tethered via pentamethylene, heptamethylene, or triethylene oxide linkers. A characteristic pattern of differential staining of chromosome preparations from human premonocytic leukemia HL60 cells was observed for all the three fluorescent dyes. The most contrast pattern was obtained for the bis-Hoechst analogue with the heptamethylene linker; its quality was comparable with the picture obtained in the case of chromosome staining with 4',6-diamidino-2-phenylindole. The ability to penetrate into the live human fibroblasts was studied for the three bis-Hoechst compounds. The fluorescence intensity of nuclei of live and fixed cells stained with the penta- and heptamethylene-linked bis-Hoechst analogues was found to differ only slightly, whereas the fluorescence of the nuclei of live cells stained with triethylene oxide-linked bis-Hoechst was considerably weaker than that of the fixed cells. The bis-Hoechst molecules are new promising fluorescent dyes that can both differentially stain chromosome preparations and penetrate through cell and nuclear membranes and effectively stain cell nuclei.     

Gap junctional communication in the early Xenopus embryo

In the Xenopus embryo, blastomeres are joined by gap junctions that allow the movement of small molecules between neighboring cells. Previous studies using Lucifer yellow (LY) have reported asymmetries in the patterns of junctional communication suggesting involvement in dorso-ventral patterning. To explore that relationship, we systematically compared the transfer of LY and neurobiotin in embryos containing 16-128 cells. In all cases, the junction-permeable tracer was coinjected with a fluorescent dextran that cannot pass through gap junctions. Surprisingly, while LY appeared to transfer in whole-mount embryos, in no case did we observe junctional transfer of LY in fixed and sectioned embryos. The lack of correspondence between data obtained from whole-mounts and from sections results from two synergistic effects. First, uninjected blastomeres in whole-mounts reflect and scatter light originating from the intensely fluorescent injected cell, creating a diffuse background interpretable as dye transfer. Second, the heavier pigmentation in ventral blastomeres masks this scattered signal, giving the impression of an asymmetry in communication. Thus, inspection of whole-mount embryos is an unreliable method for the assessment of dye transfer between embryonic blastomeres. A rigorous and unambiguous demonstration of gap junctional intercellular communication demands both the coinjection of permeant and impermeant tracers followed by the examination of sectioned specimens. Whereas LY transfer was never observed, neurobiotin was consistently transferred in both ventral and dorsal aspects of the embryo, with no apparent asymmetry. Ventralization of embryos by UV irradiation and dorsalization by Xwnt-8 did not alter the patterns of communication. Thus, our results are not compatible with current models for a role of gap junctional communication in dorso-ventral patterning.