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.

Cell-to-cell communication via plant endomembranes.

Cell-to-cell communication was investigated in epidermal cells cut from stem internodal tissue of Nicotiana tabacum and Torenia fournieri. Fluorescently labelled peptides and dextrans were microinjected using iontophoresis into the cytoplasm andcortical endomembrane network of these cells. The microinjected endomembrane network was similar in location and structure to the endoplasmic reticulum (ER) as revealed by staining with 3, 3'-dihexyloxacarbocyanine iodide (DiOC(6)). No cell-to-cell movement of dextrans was observed following cytoplasmic injections but injection of dextrans into the endomembrane network resulted in rapid diffusion of the probes to neighbouring cells. It is proposed that the ER acts as a pathway for intercellular communication via the desmotubule through plasmodesmata.

Compartmentation of fluorescent tracers injected into the epidermal cells of Egeria densa leaves.

We have compared the movement of a series of fluorescent tracers of increasing molecular weight injected into the cytoplasm in the epidermal cells of leaves of Egeria densa Planch. In general, the tracers showed major movement into three cellular compartments: first, to the cytoplasm of adjacent cells; secondly, from the cytoplasm, to the vacuole (irreversible); and thirdly, from the cytoplasm to the nucleus (reversible). No visible accumulation in chloroplasts or mitochondria, or loss across the plasmalemma was observed. No evidence for metabolic breakdown was found in extracts from injected leaves. The time course of accumulation of the dye in the three major compartments (cytoplasm, nucleus, vacuole) was monitored using fluorescence microscopy. The rate measurements and the quantified geometry of the cells were used to generate a model of compartmentation during intercellular transport. Permeability coefficients were calculated and related to the molecular sizes of the tracers. The coefficients for the tonoplast and nuclear envelope were independent of the molecular sizes of the tracers, and were in the range 2.4·10(-6)-4.1· 10(-6) cm·s(-1) for the tonoplast, and 2.6·10(-5)-9.4.10(-5) cm· s(-1) for the nuclear envelope. For intercellular movement, permeabilities were strongly dependent on molecular size, and ranged from 1.1·10(-4) cm·s(-1) for 6-carboxyfluorescein (376 daltons (Da)) to 9·10(-9) cm·s(-1) for fluorescein leucyldiglutamylleucine (874 Da). Thus, the differences in cell-to-cell movement of these tracers are based upon their differing ability to cross the intercellular walls, not upon differences in their intracellular compartmentation.

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.

Molecular size limit for movement in the symplast of the Elodea leaf.

A range of water-soluble fluorescent dyes and dye conjugates have been injected into cells in Elodea canadensis Michx. leaves. All compounds are unable to cross the plasmalemma between living cells and the external solution, are not degraded to other fluorescent compounds by tissue homogenates, and do not affect cytoplasmic streaming. Despite being unable to cross the plasmalemma, molecules up to 874 dalton pass from cell to cell, smaller molecules showing greater mobility. The conjugate of fluorescein isothiocyanate and leucyl-diglutamylleucine (874 dalton) appears to be close to the limit for movement: in only three out of 17 injections was any movement visible; this movement was only to adjacent cells and was close to the limit of detection. Dye molecules of 1678 dalton and larger did not pass from cell to cell. From the relationship between the size of the dye molecules, measured using molecular models, and their intercellular mobility, the equivalent pore diameter of the Elodea leaf plasmodesmata has been estimated to lie within the range 3.0-5.0 nm.

Characterisation of the Egeria densa Planch. leaf symplast : Inhibition of the intercellular movement of fluorescent probes by group II ions.

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 Ca(2+), Mg(2+) or Sr(2+) 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 Ca(2+) injection, dye movement is no longer inhibited. Thus the cells recover from the Ca(2+) injection, indicating that the ion does not cause major cell damage. Recovery from Mg(2+) 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 Ca(2+) uptake trifluralin, or the ionophore A23187 also inhibits dye movement, while the calmodulin inhibitor trifluoperazine does not. Cytoplasmic streaming is inhibited by Ca(2+) or Mg(2+) 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.

Actinomycin D and the hormonal induction of amylase synthesis in barley aleurone layers.

The induction of amylase synthesis in barley aleurone layers by gibberellic acid is most sensitive to Actinomycin D (AM) over a short interval late in the lag phase. The duration of the lag phase may be extended as much as 3 fold by lower temperatures over the range 30° to 15° C. At each temperature the AM sensitive period remains close to the end of the lag phase, the period we have previously determined as the stage less sensitive to temperature.Lack of sensitivity to the inhibitor at other periods is not due to failure to penetrate, or to degradation. AM has no effect on tissue respiration, leucine, uridine or uracil uptake, leucine incorporation, or leucine pool size. At all stages it inhibits uracil and uridine incorporation into RNA. Thus AM probably acts by inhibiting RNA synthesis.