The cellular pathway of photosynthate transfer in the developing wheat grain. II. A structural analysis and histochemical studies of the pathway from the crease phloem to the endosperm cavity

In the developing wheat grain, photosynthate is transferred longitudinally along the crease phloem and then laterally into the endosperm cavity through the crease vascular parenchyma, pigment strand and nucellar projection. In order to clarify this cellular pathway of photosynthate unloading, and hence the controlling mechanism of grain filling, the potential for symplastic and apoplastic transfer was examined through structural and histochemical studies on these tissue types. It was found that cells in the crease region from the phloem to the nucellar projection are interconnected by numerous plasmodesmata and have dense cytoplasm with abundant mitochondria. Histochemical studies confirmed that, at the stage of grain development studied, an apoplastic barrier exists in the cell walls of the pigment strand. This barrier is composed of lignin, phenolics and suberin. The potential capacity for symplastic transfer, determined by measuring plasmodesmatal frequencies and computing potential sucrose fluxes through these plasmodesmata, indicated that there is sufficient plasmodesmatal cross-sectional area to support symplastic unloading of photosynthate at the rate required for normal grain growth. The potential capacity for membrane transport of sucrose to the apoplast was assessed by measuring plasma membrane surface areas of the various cell types and computing potential plasma membrane fluxes of sucrose. These fluxes indicated that the combined plasma membrane surface areas of the sieve element–companion cell (se–cc) complexes, vascular parenchyma and pigment strand are not sufficient to allow sucrose transfer to the apoplast at the observed rates. In contrast, the wall ingrowths of the transfer cells in the nucellar projection amplify the membrane surface area up to 22-fold, supporting the observed rates of sucrose transfer into the endosperm cavity. We conclude that photosynthate moves via the symplast from the se–cc complexes to the nucellar projection transfer cells, from where it is transferred across the plasma membrane into the endosperm cavity. The apoplastic barrier in the pigment strand is considered to restrict solute movement to the symplast and block apoplastic solute exchange between maternal and embryonic tissues. The implications of this cellular pathway in relation to the control of photosynthate transfer in the developing grain are discussed.     

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.     

The cellular pathway of photosynthate transfer in the developing wheat grain. III. A structural analysis and physiological studies of the pathway from the endosperm cavity to the starchy endosperm

The cellular pathway of sucrose transfer from the endosperm cavity to the starchy endosperm of developing grains of wheat (Triticum turgidum) has been elucidated. The modified aleurone and sub-aleurone cells exhibit a dense cytoplasm enriched in mitochondria and endoplasmic relicilium. Significantly, the sub-aleurone cells are characterized by secondary wall ingrowths. Numerous plasmodesmata interconnect all cells between the modified aleurone and starchy endosperm. The pro-tonophore carbonylcyanide-m-chlorophenyl hydrazone (CCCP) slowed [¹⁴C]sucrose uptake by grain tissue slices enriched in modified aleurone and sub-aleurone cells but had no effect on uptake by the starchy endosperm. The fluorescent weak acid sulphorhodamine G (SRG) was preferentially accumulated by the modified aleurone and sub-aleurone cells, and this uptake was sensitive to CCCP. The combined plasma membrane surface areas of the modified aleurone and sub-aleurone cells appeared to be sufficient to support the in vivo rates of sucrose transfer to the starchy endosperm. Plasmolysis of intact excised grain inhibited [¹⁴C]sucrose transfer from the endosperm cavity to the starchy endosperm. The sulphydryl group modifier p-chloromercuribenzenesulphonie acid (PCMBS) decreased [¹⁴C]sucrose uptake by the modified aleurone and sub-aleurone cells but had little effect on uptake by the starchy endosperm. In contrast, when PCMBS and [¹⁴C]sucrose were supplied to the endosperm cavity of intact excised grain, PCMBS slowed accumulation by all tissues equally. Estimates of potential sucrose fluxes through the interconnecting plasmodesmata were found to be within the published range. It is concluded that the bulk of sucrose is accumulated from the endosperm cavity by the modified aleurone and sub-aleurone cells and subsequently transferred through the symplast to the starchy endosperm.     

Movement of fluorescein into isolated caryopses of wheat and barley

Abstract. The movement of fluorescein, a symplastic fluorescent tracer, into isolated caryopses of wheat and barley is described. The dye followed the pathway to the endosperm which has been proposed previously from anatomical studies, namely a movement from the phloem, through cells of the pigment strand and nucellar projection, followed by a radial spread of the dye from the endosperm cavity into the starchy endosperm. By contrast, the fluorochromes calcofluor white M2R and ANS remained confined to the apoplast and failed to cross the 'xylem discontinuity' at the base of the caryopses.     

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.     

What Is Phloem Unloading?

Several studies of phloem unloading have failed to distinguish between transport events occurring at the sieve element/companion cell boundary and subsequent short-distance transport through parenchyma cells. Indirect evidence has been obtained for symplastic unloading in storage and utilization sinks. In other sinks transfer to the apoplast may occur, but not necessarily at the sieve element/companion cell complex, and the evidence for apoplastic phloem unloading is equivocal, as is the role of apoplastic acid invertase in this process. The ability of several types of sink cells to accumulate sugars from the apoplast is discussed in the conflicting light of functional symplastic continuity between sink cells. Attention is drawn to the complexity of the postunloading pathway in many sinks and the difficulty of determining the exact sites of symplast/apoplast solute exchange. Potential future areas for study in the field are highlighted.     

Cellular Structures, Plasma Membrane Surface Areas and Plasmodesmatal Frequencies of the Stem of Phaseolus vulgaris L. in Relation to Radial Photosynthate Transfer

At an early stage of secondary development, the metaphloem sieveelements appeared to be the only functional axial transportconduit in fully elongated stems of P. vulgaris plants. Thereis no apparent barrier to the radial transfer of solutes inthe stem apoplast. However, radial transfer through the stemsymplast could be limited by discontinuities resulting fromprotoplast degeneration of the protophloem fibres and developingsecondary xylem fibres. Estimates of possible sucrose fluxesthrough the apoplastic and symplastic routes indicated thatradial photosynthate transfer from the sieve element-companioncell (se-cc) complexes of the stem metaphloem could follow eithercellular route. In the case of apoplastic transfer, the plasmamembrane surface area of the se-cc complexes is only sufficientto support some form of facilitated movement of sucrose. Incontrast, the plasma membrane surface area of the phloem parenchymais sufficient to permit passive diffusion of sucrose to theapoplast. Plasmodesmatal frequencies suggest that any symplastictransfer to the phloem parenchyma from the sieve elements wouldbe via the companion cells. Phaseolus vulgaris, french bean, stem, photosynthate, radial transfer (photosynthates), cellular pathway     

Contrast observation and investigation of wheat endosperm transfer cells and nucellar projection transfer cells

In cereal seed, there are no symplastic connections between the maternal tissues and the endosperm. In order to facilitate solute transport, both the nucellar projection and its opposite endosperm epithelial cells in wheat caryopsis differentiate into transfer cells. In this paper, we did contrast observation and investigation of wheat endosperm transfer cells (ETC) and nucellar projection transfer cells (NPTC). The experimental results showed that there were some similarities and differences between ETC and NPTC. ETC and NPTC almost developed synchronously. Wall ingrowths of ETC and NPTC formed firstly in the first layer nearest to the endosperm cavity, and formed later in the inner layer further from the endosperm cavity. The mature ETC were mainly three layers and the mature NPTC were mainly four layers. Wall ingrowths of ETC were flange type and wall ingrowths of NPTC were reticulate type. NPTC were not nutrient-storing cells, but the first layer of ETC had aleurone cell features, and the second layer and third layer of ETC accumulated starch granules and protein bodies.     

Phloem loading. A reevaluation of the relationship between plasmodesmatal frequencies and loading strategies

The incidence of plasmodesmata in the minor vein phloem of leaves varies widely between species. On this basis, two pathways of phloem loading have been proposed: symplastic where frequencies are high, and apoplastic where they are low. However, putative symplastic-loading species fall into at least two categories. In one, the plants translocate raffinose-family oligosaccharides (RFOs). In the other, the primary sugar in the phloem sap is sucrose (Suc). While a thermodynamically feasible mechanism of symplastic loading has been postulated for species that transport RFOs, no such mechanism is known for Suc transporters. We used p-chloromercuribenzenesulfonic acid inhibition of apoplastic loading to distinguish between the two pathways in three species that have abundant minor vein plasmodesmata and are therefore putative symplastic loaders. Clethra barbinervis and Liquidambar styraciflua transport Suc, while Catalpa speciosa transports RFOs. The results indicate that, contrary to the hypothesis that all species with abundant minor vein plasmodesmata load symplastically, C. barbinervis and L. styraciflua load from the apoplast. C. speciosa, being an RFO transporter, loads from the symplast, as expected. Data from these three species, and from the literature, also indicate that plants with abundant plasmodesmata in the minor vein phloem have abundant plasmodesmata between mesophyll cells. Thus, plasmodesmatal frequencies in the minor veins may be a reflection of overall frequencies in the lamina and may have limited relevance to phloem loading. We suggest that symplastic loading is restricted to plants that translocate oligosaccharides larger than Suc, such as RFOs, and that other plants, no matter how many plasmodesmata they have in the minor vein phloem, load via the apoplast.     

Energized Uptake of Sugars from the Apoplast of Leaves: A Study of Some Plants Possessing Different Minor Vein Anatomy

Solutions of sucrose, glucose, raffinose, and stachyose were fed via the petiole to detached leaves of plant species known to transfer sugars during photosynthesis into the phloem using either the apoplastic or the symplastic pathway of phloem loading. Symplastic phloem loaders, which translocate raffinose-type oligosaccharides and sucrose in the phloem, and apoplastic plants, translocating exclusively sucrose, were selected for this study. As the sugars arrived with the transpiration stream in the leaf blade within little more than a minute, dark respiration increased. Almost simultaneously, fluorescence of a potential-indicating dye, which had been infiltrated into the leaves, indicated membrane depolarization. Another fluorescent dye used to record the apoplastic pH revealed apoplastic alkalinization that occurred with a slight lag phase after respiration and membrane depolarization responses. Occasionally, alkalinization was preceded by transient apoplastic acidification. Whereas membrane depolarization and apoplastic acidification are interpreted as initial responses of the proton motive force across the plasma membrane to the advent of sugars in the leaf apoplast, the following apoplastic alkalinization showed that sugars were taken up from the apoplast into the symplast in cotransport with protons. This was true not only for glucose and sucrose, but also for raffinose and stachyose. Similar observations were made for sugar uptake not only in leaves of plants known to export sugars by symplastic phloem loading but also of plants using the apoplastic pathway. Increased respiration during sugar uptake revealed tight coupling between respiratory ATP production and ATP consumption by proton-translocating ATPase of the plasma membrane, which exports protons into the apoplast, thereby compensating for the proton loss in the apoplast when protons are transported together with sugars into the symplast. The extent of stimulation of respiration by sugars indicated that sugar uptake was not limited to phloem tissue. Ratios of the extra CO₂ released during sugar uptake to the amounts of sugars taken up were variable, but lowest values were lower than 0.2. When a ratio of 0.2 is taken as a basis to calculate rates of sugar uptake from observed maxima of sugar-dependent increases in respiration, rates of sugar uptake approached 350 nmol/(m² leaf surface s). Sugar uptake rates were half-saturated at sugar concentrations in the feeding solutions of about 10–25 mM indicating a low in vivo affinity of sugar uptake systems for sugars.     

菜豆茎韧皮部卸出的细胞途径以及激素的促进作用(英文)

通过缩小叶面积和去茎尖改变源库比率,以调节韧皮部卸出的途径,证明了韧皮部卸出的共质体与质外体途径的季节变化,和由对氯高汞苯磺酸所诱发的从质外体向共质体途径的转变,是与光合产物的输入有关。缩小叶面积而降低源库比率,能增加夏季生长植株茎韧皮部的质外体卸出,但对冬季生长植株无影响。去尖而增加源库比率,则促进共质体卸出。赤霉酸和激动素能促进共质体的横向转运,但对质外体转运无作用。当质外体为主要运输途径时,赤霉酸和激动素开启共质体途径。赤霉酸和激动素刺激光合产物,通过共质体从筛管一伴胞复合体向韧皮部薄壁纽胞输送,并可能在韧皮部薄壁细胞被动扩散到自由空间。由此可进一步说明蔗糖在激素处理部位自由空间的增加。     

Guard cell apoplastic photosynthate accumulation corresponds to a phloem-loading mechanism

Apoplastic phloem loaders have an apoplastic step in the movement of the translocated sugar, prototypically sucrose, from the mesophyll to the companion cell-sieve tube element complex. In these plants, leaf apoplastic sucrose becomes concentrated in the guard cell wall to nominally 150 mM by transpiration during the photoperiod. This concentration of external sucrose is sufficient to diminish stomatal aperture size in an isolated system and to regulate expression of certain genes. In contrast to apoplastic phloem loaders and at the other extreme, strict symplastic phloem loaders lack an apoplastic step in phloem loading and mostly transport raffinose family oligosaccharides (RFOs), which are at low concentrations in the leaf apoplast. Here, the effects of the phloem-loading mechanism and associated phenomena on the immediate environment of guard cells are reported. As a first step, carbohydrate analyses of phloem exudates confirmed basil (Ocimum basilicum L. cv. Minimum) as a symplastic phloem-loading species. Then, aspects of stomatal physiology of basil were characterized to establish this plant as a symplastic phloem-loading model species for guard cell research. [(14)C]Mannitol fed via the cut petiole accumulated around guard cells, indicating a continuous leaf apoplast. The (RFO+sucrose+hexoses) concentrations in the leaf apoplast were low, <0.3 mM. Neither RFOs (<10 mM), sucrose, nor hexoses (all, P >0.2) were detectable in the guard cell wall. Thus, differences in phloem-loading mechanisms predict differences in the in planta regulatory environment of guard cells.     

Sink anatomy in relation to solute movement in rice (Oryza sativa L.): A summary of findings

The results of studies on assimilate and water transport in the developing caryopsis of rice are summarised. Evidence is presented for a symplastic movement of solutes as far as the aleurone layer. However, transport into the apoplast at the nucellus/aleurone interface appears to be a necessary step due to the absence of plasmodesmata at this site. It is suggested that water leaves the caryopsis during grain filling by the isolated cell walls of the pigment strand, the suberised walls of these cells functioning to isolate the apoplast from the symplast and thereby allowing opposing fluxes of water and assimilates to occur in the dorsal region of the grain.     

Sieve element unloading: cellular pathway, mechanism and control

The transport and distribution of phloem – mobile solutes is predominantly determined by transport processes located at the sink end of the source – transport – sink system. Transport across the sieve element boundary, sieve element unloading, is the first of a series of sink transport processes. Unloading of solutes from the sieve elements may follow an apo- or symplastic route. It is speculated that the unloading pathway is integrated with sink function and that apoplastic unloading is restricted to situations in which movement through the symplast is not compatible with sink function. These situations include axial transport and storage of osmotically active solutes against concentration and turgor gradients between the sieve elements and sink cells. Coupled with alteration in sink function, the cellular pathway of unloading can switch in stems and possibly other sinks. Experimental systems and approaches used to elucidate the mechanism of sieve element unloading are reviewed. Unloading fluxes to the apoplast can largely be accounted for by membrane diffusion in axial sinks. However, the higher fluxes in storage sinks suggests dependence on some form of facilitated transport. Proton sucrose symport is assessed to be a possible mechanism for facilitated efflux of solutes across the sieve element plasma membrane to the sink apoplast. Unloading through the symplast may occur by diffusion or mass flow. The latter mechanism serves to dissipate phloem water and hence prevent the potential elevation of sieve element turgor that would otherwise slow phloem import into the sink. The possibility of energised plasmodesmatal transport is raised. Sieve element unloading must be integrated with subsequent compartmentation and metabolism of the unloaded solute. Solute levels are an obvious basis for control of sieve element unloading, but are found to offer limited scope for a mass action mechanism. Apoplastic, cellular pathway, sieve element, solute transport, symplastic. Translated into a turgor signal, solute levels could regulate the rate of unloading, metabolism and compartmentation forming part of a turgor homeostat irrespective of the pathway of unloading.     

Subcellular localization of cadmium in roots and leaves of Arabidopsis thaliana

We examined the subcellular cadmium (Cd) localization in roots and leaves of wild-type Arabidopsis thaliana (ecotype Columbia) exposed to environmentally relevant Cd concentrations. Energy-dispersive X-ray microanalysis (EDXMA) was performed on high-pressure frozen and freeze-substituted tissues. In the root cortex, Cd was associated with phosphorus (Cd/P) in the apoplast and sulfur (Cd/S) in the symplast, suggesting phosphate and phytochelatin sequestration, respectively. In the endodermis, sequestration of Cd/S was present as fine granular deposits in the vacuole and as large granular deposits in the cytoplasm. In the central cylinder, symplastic accumulation followed a distinct pattern illustrating the importance of passage cells for the uptake of Cd. In the apoplast, a shift of Cd/S granular deposits from the middle lamella towards the plasmalemma was observed. Large amounts of precipitated Cd in the phloem suggest retranslocation from the shoot. In leaves, Cd was detected in tracheids but not in the mesophyll tissue. Extensive symplastic and apoplastic sequestration in the root parenchyma combined with retranslocation via the phloem confirms the excluder strategy of Arabidopsis thaliana.     

Phloem loading and its development related to plant evolution from trees to herbs

Summary Minor vein structure in various taxonomic groups was described in a previous paper (Gamalei 1989). Here, these results are used to correlate minor vein structure with plant evolutionary, ecological and growth form schemes. The following pattern emerges: reductive evolution from evergreen trees to annual herbs is accompanied by gradually increasing symplastic isolation of the mesophyll and the phloem. This evolutionary tendency is confirmed by the ecological spreading and life-form distribution of modern plants with different types of minor vein structure. The meaning of this phenomenon is discussed. Chilling sensitivity of plasmodesmal translocation is considered to be the main reason. It is suggested that phloem loading for assimilate transport is double-routed. The symplastic route is more ancient and more economical for loading. The apoplastic pathway becomes the main or the only route under unfavorable conditions. The existence of a symplast/apoplast regulatory loading mechanism is suggested. The two loading routes differ in their selectivity for products of photosynthesis which changes their symplast/apoplast ratio which, in turn, determines the composition of the sieve tube exudate. The latter will influence growth and morphogenesis. Correlated changes of structure and function related to photosynthesis, loading, translocation and growth, are analysed with respect to life-form evolution. The influence of the pathway of loading on other processes is discussed.     

Cellular pathway of photosynthate transport in coats of developing seed of Vicia faba L. and Phaseolus vulgaris L. I. Extent of transport through the coat symplast

The extent of post-phloem solute transport through the coatsymplasts of developing seeds of Vicia faba L. and Phaseolusvulgaris L. was evaluated. For Vicia seed coats, the membrane-impermeantfluorochrome, CF, moved radially from the chalazal vein to reachthe chlorenchyma and thin-walled parenchyma transfer cell layers.Thereafter, the fluorochrome moved laterally in these two celllayers around the entire circumference of the seed coat. Transferof CF from the chalazal vein was inhibited by plasmolysis ofattached ‘empty’ seed coats. In contrast, the spreadof phloem imported CF was restricted to the ground parenchymaof Phaseolus seed coats. Fluorochrome loaded into the outermostground parenchyma cell layer was rendered immobile followingplasmolysis of excised seed-coat halves. Phloem-imported [¹⁴C]sucroseand the slowly membrane permeable sugar, L-[¹⁴C]glucose, werepartitioned identically between the vascular and non-vascularregions of intact Vicia seed coats. For ¹⁴C-photosynthates,these partitioning patterns in attached ‘empty’Vicia seed coats were unaffected by PCMBS, but inhibited byplasmolysis. Tissue autoradiographs of intact Phaseolus seedcoats demonstrated that a pulse of ¹⁴C-photosynthate moved fromthe veins to the grounds tissues. In excised Vicia seed coats,preloaded with ¹⁴C-photosynthates, the cellular distributionof residual ¹⁴C-label was unaffected by PCMBS. In contrast,PCMBS caused the ¹⁴C-photosynthate levels to be elevated inthe veins and ground parenchyma relative to the branch parenchymaof Phaseolusseed coat halves. Based on the above findings, itis concluded that the phloem of Vicia seed coats is interconnectedto two major symplastic domains; one comprises the chlorenchyma,the other the thin-walled parenchyma plus thin-walled parenchymatransfer cells. For Phaseolusseed coats, the phloem forms amajor symplastic domain with the ground parenchyma. Key words: Phaseolus vulgaris L, phloem unloading, photosynthate transport, seed coat, symplast, Vicia faba L     

Changes in Photosynthate Unloading from Perfused Seed Coats of Phaseolus vulgaris L. Induced by Osmoticum and Ethylenediaminetetraacetate (EDTA)

Photosynthate unloading in Phaseolus vulgaris L. seed coatswas studied by treating perfused seed coats with differing concentrationsof an osmoticum and ethylenediaminetetraacetate (EDTA). Largechanges in osmoticum concentration typically produced rapidchanges in efflux of unlabelled sugar and steady-state-labelled¹⁴C-photosynthate. Osmoticum-induced changes in photosynthateefflux were caused by phloem import stimulation at low cellturgor and net efflux stimulation by high cell turgor. Eventhough rapid changes in sugar and tracer efflux were often inducedby osmoticum treatments, the specific activity of sugar releasedfrom seed coats was not greatly affected by these treatmentsand was similar to the specific activity of sugar remainingin the seed coat after perfusion. Thus, tracer was transportedfrom the phloem throughout the seed coat sugar pool before itwas released to the apoplast. This result is most consistentwith symplastic phloem unloading throughout perfused seed coats,because apoplastic transport between cells within the seed coatwas blocked by perfusion. Photosynthate efflux was stimulatedby simultaneous treatment of seed coats with EDTA and differentconcentrations of an osmoticum; loss of photosynthate from seedcoats did not appear to be tissue-specific. Key words: Phaseolus vulgaris, seed coat, photosynthate unloading, turgor, EDTA     

Ion distribution measured by electron probe X-ray microanalysis in apoplastic and symplastic pathways in root cells in sunflower plants grown in saline medium

Little is known about how salinity affects ions distribution in root apoplast and symplast. Using x-ray microanalysis, ions distribution and the relative contribution of apoplastic and symplastic pathways for delivery of ions to root xylem were studied in sunflower plants exposed to moderate salinity (EC=6). Cortical cells provided a considerably extended Na+ and Cl- storage facility. Their contents are greater in cytoplasm (root symplast) as compared to those in intercellular spaces (root apoplast). Hence, in this level of salinity, salt damage in sunflower is not dehydration due to extracellular accumulation of sodium and chloride ions, as suggested in the Oertli hypothesis. On the other hand, reduction in calcium content due to salinity in intercellular space is less than reduction in the cytoplasm of cortical cells. It seems that sodium inhibits the radial movement of calcium in symplastic pathway more than in the apoplastic pathway. The cell wall seems to have an important role in providing calcium for the apoplastic pathway. Redistribution of calcium from the cell wall to intercellular space is because of its tendency towards xylem through the apoplastic pathway. This might be a strategy to enhance loading of calcium to xylem elements and to reduce calcium deficiency in young leaves under salinity. This phenomenon may be able to increase salt tolerance in sunflower plants. Supplemental calcium has been found to be effective in reducing radial transport of Na+ across the root cells and their loading into the xylem, but not sodium absorption. Supplemental calcium enhanced Ca2+ uptake and influx into roots and transport to stele.     

灵武长枣果实ATPase超微细胞化学定位和功能研究

采用ATPase超微细胞化学定位技术,研究灵武长枣果实不同发育阶段韧皮部和果肉库薄壁细胞ATPase分布特征,以明确灵武长枣果实ATPase超微细胞化学定位特征和功能。结果显示:(1)第一次快速生长期SE/CC复合体与周围的薄壁细胞有丰富的胞间连丝,形成共质体连续,韧皮部薄壁细胞之间有丰富的胞间连丝,ATPase反应物在韧皮部各细胞分布较少。(2)缓慢生长期ATPase反应物在韧皮部各细胞分布逐渐增加。(3)第二次快速生长期SE/CC复合体与周围的薄壁细胞缺乏胞间连丝,形成共质体隔离,韧皮薄壁细胞及果肉库薄壁细胞的胞间连丝较少,囊泡和膜泡在筛管、韧皮薄壁细胞和库薄壁细胞中很丰富,质膜、液泡膜、囊泡膜、细胞壁和胞间隙的ATPase活性较高。研究表明,果实在第一次快速生长期同化物从筛分子的卸出主要采取共质体途径,缓慢生长期同化物卸出时可能为共质体和质外体途径共存,第二次快速生长期则主要以质外体途径为主,证明果实不同发育阶段韧皮部同化物卸出路径存在差异。