A Novel Experimental System for Studies of Photosynthate Transfer in the Developing Wheat Grain

The aim of this study was to develop a valid and convenientexperimental system for exploring photosynthate transfer inthe developing wheat grain. Structural characteristics relatingto photosynthate transfer and the composition of the endospermcavity sap were examined during the linear stage of grain developmentat 25±3 d after anthesis. Based on the results of thesestudies, an experimental system was devised to permit the directmonitoring and manipulation of photosynthate transfer from theendosperm cavity to the storage endosperm. A novel approachwas used whereby insertions were made into the endosperm cavityby a needle at the embryo end and a piece of microcapillarytubing at the stigma end of the detached grain. By this means,the experimental solution was delivered into and flowed longitudinallyunder gravity through the endosperm cavity to exit at the stigmaend. The composition of the experimental solution reflected the principalsolute concentrations and osmolality of the in vivo endospermcavity contents. With the introduction of the solution intothe cavity, it was found that the viability of grain tissueswas maintained for up to 30 h. During a 24 h period both therate of sucrose uptake and subsequent incorporation into ethanolinsolublecomponents were shown to reproduce the rate of starch biosynthesisand in vivo grain growth. Moreover, the experimental systemeffectively reproduced the in vivo pathway of photosynthatetransfer from the endosperm cavity via the modified aleuronecells into the endosperm. As a result, this system providesa new approach to study photosynthate transfer in the developingwheat grain. Key words: Wheat grain, endosperm cavity, experimental system, photosynthate transport     

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.     

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     

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.     

Pathway of Photosynthate Transfer in the Developing Seed of Vicia faba L. Transfer in Relation to Seed Anatomy

The seed coat vascular system of the developing seed of Viciafaba consists of a chalazal and two lateral veins. The veinsare embedded in parenchymatous tissue which lies beneath thehypodermis and is divided into chlorenchyma, ground parenchymaand thin-walled parenchyma. The thin-walled parenchyma cellsand, in old seed coats, the vascular parenchyma of the veinsundergo additional secondary wall development to form transfercells. Thus, transfer cells line the entire inner surface ofthe seed coat. Initial distribution of ¹⁴C-photosynthates andsodium fluorescein within the seed coat was in the vascularsystem. Subsequent transfer towards the embryo was either radiallythrough vascular parenchyma and thin-walled parenchyma to thin-walledparenchyma/transfer cells, or by lateral spread within the groundand thin-walled parenchyma/transfer cells of the non-vascularregion of the seed coat prior to radial transfer. One-thirdof the ¹⁴C-photosynthate delivered to the enclosed embryo wasestimated to be transferred via the non-vascular region of theseed coat. The cotyledons consist of a single-layered epidermisenclosing storage parenchyma in which a differentiating reticulatevascular system is embedded. Epidermal cells juxtaposed to theseed coat develop wall ingrowths characteristic of transfercells. Initial distribution of ¹⁴C-photosynthate within thecotyledons reflected the unequal delivery to the seed apoplastfrom the vascular and non-vascular regions of the seed coat.Subsequent even distribution of photosynthate within the cotyledonspossibly occurred by transfer within their vascular system. Key words: Cellular pathway, photosynthate transfer, seed anatomy, transfer cell     

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.     

The Cellular Pathway of Radial Transfer of Photosynthates in Stems of Phaseolus vulgaris L.: Effects of Cellular Plasmolysis and p-Chloromercuribenzene Sulphonic Acid

Cellular plasmolysis with l M solutions of mannitol appearedto sever plasmodesmatal interconnections between all cells ofthe stems of Phaseolus vulgaris plants except the sieve element-companioncell (se—cc) complexes. Phloem loading and uptake of [¹⁴C]sucroseby the storage cells of the stems was unimpaired by cellularplasmolysis followed by rehydration of the stem tissues. Accumulationof phloem-transported ¹⁴C-photosynthates of the treated stemswas inhibited in summer-grown plants and unaffected in winter-grownplants indicating that phloem unloading follows a symplasticand a free-space route respectively depending on growth season.At a concentration that did not interfere with cellular metabolism,p-chloromercuribenzene sulphonic acid (PCMBS) applied to thestems blocked [¹⁴C]sucrose loading into the phloem and storagecells of the stem, but had no effect on the pool size of free-spacesugars. This latter response is consistent with a facilitatedmechanism of sugar unloading to the stem free-space. Accumulationof phloem-transported ¹⁴C-photosynthates was stimulated by PCMBSand this effect was most pronounced in winter-grown plants.Cellular plasmolysis followed by rehydration abolished the PCMBSaction on ¹⁴C-photosynthate accumulation. This effect is consistentwith a PCMBS induction of phloem unloading through the stemsymplast. It is proposed that phloem unloading in bean stemsmay follow either a free-space or symplastic route and thatthe latter route is entrained under sink-limited conditions. Phaseolus vulgaris, french bean, stem, phioem unloading, free-space, symplast     

Pathway of Photosynthate Transfer in the Developing Seed of Vicia faba L: A Structural Assessment of the Role of Transfer Cells in Unloading from the Seed Coat

Photosynthate movement within the coat of the developing seedof Vicia faba occurs radially inward from the restricted vascularsystem and laterally through the non-vascularized region ofthe seed coat prior to exchange to the seed apoplast. Thin-walledparenchyma/transfer cells line the entire inner surface of theseed coat and thus are located at the terminus of the photosynthatetransfer pathway. The principal cellular route of transfer withinthe seed coat and the role of the thin-walled parenchyma/transfercells in membrane exchange to the seed apoplast has been investigated.Sucrose fluxes, computed from estimates of the plasma membranesurface areas of the cell types of the pathway, the plasmodesmatalcross-sectional areas interconnecting contiguous cells and theobserved rate of sucrose delivery to the embryo indicate thatsieve element unloading and subsequent transfer to the thin-walledparenchyma/transfer cells is through the symplast. For the cellsof the ground tissue, plasmodesmatal density is consistentlyhigher on their anticlinal walls. This observation supportsthe reported pattern of lateral transfer through these tissuesin the non-vascular regions of the seed coat. Wall ingrowthsare initiated sequentially in the thin-walled parenchyma cellsto maintain 1–3 rows of thin-walled parenchyma/transfercells. The development of these wall ingrowths results in a58% increase in the plasma membrane surface area of these cellsand provides them with the capacity to act as the principalcellular site for membrane exchange of sucrose to the seed apoplast.This cellular route of symplastic transfer from the sieve elementsto the ground tissues where membrane exchange to the seed apoplastoccurs is consistent with that reported for Phaseolus vulgaris Key words: Cellular pathway, photosynthate transfer, transfer cell, Vicia seed coat     

The Cellular Pathway of Short-distance Transfer of Photosynthates and Potassium in the Elongating Stem of Phaseolus vulgaris L. A Structural Assessment

The potential cellular pathway of radial transfer of photosynthateand potassium delivered in the phloem to the elongation zone(apical 0.5–2.5 cm) of internode 2 ofPhaseolus vulgarisL. seedlings was elucidated. This was achieved using ultrastructuralobservations of the cell types that constitute the radial pathwayand estimates of potential sucrose and potassium fluxes throughthe cross-sectional area of interconnecting plasmodesmata andacross the plasma membrane surface areas of selected cell types.The investigation relied on predicting the relative roles ofthe mature and developing sieve elements as conduits for theaxial delivery of solutes to the elongation zone. In turn, thesepredictions led to formulation of two transport models whichwere subsequently evaluated. It was found that unloading ofsucrose and potassium from the protophloem sieve elements cannotbe through the symplast due to the absence of plasmodesmata.On the other hand, mature metaphloem sieve element-companioncell complexes have the potential capacity to unload eitherthrough the stem symplast or apoplast. The potential symplasticroute is proposed to be via the companion cells to the adjacentlarge phloem parenchyma cells. Continued radial transfer couldoccur either by exchange to the stem apoplast from the largephloem parenchyma cells or continue in the symplast to the groundtissues. It was further predicted that sucrose utilized forthe development of the procambial/small phloem parenchyma cellscould be delivered axially by them and not by the mature sieveelements. Phaseolus vulgaris ; apoplast; elongating stem; photosynthates; potassium; transport; symplast     

Photosynthate Unloading from Seed Coats of Phaseolus vulgaris L.--Nature and Cellular Location of Turgor-Sensitive Unloading

Patrick, J. W., Jacobs, E., Offler, C. E. and Cram, W. J. 1986.Photosynthate unloading from seed coats of Phaseolus vulgarisL.—Nature and cellular location of turgor-sensitive unloading—J.exp. Bot. 37: 1006–1019. Unloading rates of ¹⁴C-Photosynthates from excised seed-coathalves of Phaseolus vulgaris L. plants were sharply increasedat cell turgor potentials in excess of 5 ? 10⁵ Pa. Turgor-sensitiveunloading occurred in the absence of any change in the passivepermeability of, and active sucrose influx across, the plasmalemmaand tonoplast membranes. The proton ionophore CCCP, and lowtemperature significantly slowed turgor-sensitive unloadingwhile PCMBS, a non-permeating sulphydryl-modifying compound,was without effect. Turgor-sensitive unloading significantlydepressed the ¹⁴C-Photosynthate content of the ground and branchparenchyma, but had no effect on the ¹⁴C-Photosynthate levelsin the vascular tissues. Cycling of cell turgor potentials aboveand below 5 ? 10⁵ Pa elicited reproducible responses in theunloading rate of ¹⁴C-Photosynthates. Increasing turgor above5 ? 10⁵ Pa resulted in a burst of ¹⁴C-Photosynthate unloading.Reversal to turgors less than 5 ? 10⁵ Pa caused a rapid depressionin unloading rate. It is proposed that turgor-sensitive unloadingis facilitated by a specific turgor-sensitive porter locatedon the plasmalemma of the ground and/or branch parenchyma cellsof bean seed coats. Key words: Bean, seed coat, turgor-sensitive unloading, phloem