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     

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     

Cellular pathway of photosynthate transport in coats of developing seed of Vicia faba L. and Phaseolus vulgaris L. II. Principal cellular site(s) of efflux

The cells responsible for the photosynthate efflux from coatsof developing seed of Vicia faba L. and Phaseolus vulgaris L.were elucidated using known properties of the efflux mechanism.Sensitivity of sucrose efflux to NEM and high potassium concentrationswas retained by seed-coat halves of Phaseolus following pectinaseremoval of the branch parenchyma cell layer. In contrast, removalof the thin-walled parenchyma transfer cell layer from Viciaseed-coat halves abolished this sensitivity. The membrane-impermeantthiol-binding fluorochrome, qBBr, selectively stained the surfaceof the thin-walled parenchyma transfer cells. This phenomenonwas inhibited by the slowly permeable sul-phydryl agent, PCMBS,indicating that the plasma membranes of these cells are enrichedin sulphydryl groups characteristic of membrance porter proteins.On the basis that carrier-mediated sucrose efflux from seedcoats appears to be proton coupled, the putative plasma membraneH+-ATPase was used as a marker for the cells responsible forcarrier-mediated photosynthate efflux. When seed-coat halveswere exposed briefly at pH 8.5 to the weak acid fluorochrome,SRG, the ground parenchyma and thin-walled parenchyma transfercell layers selectively accumulated the dye. The apparent lowpH environment in the walls of these cells that renders SRGmembrane permeant appeared to be maintained by a VAN-sensitiveproton pump. The findings with SRG were corroborated by thecyto-chemical localization of plasma membrane ATPase activityto the ground parenchyma and thin-walled parenchyma transfercells using precipitation of cerium phosphate. Together, ourobservations provide qualified support for the conclusion thatcarrier-mediated photosynthate efflux from coats of Phaseolusand Vicia seed is primarily restricted to the ground parenchymaand thin-walled parenchyma transfer cell layers, respectively. Key words: Ground parenchyma, Phaseolus vulgaris L., photosynthate efflux, seed coat, transfer cell, 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     

Mechanisms of solute efflux from seed coats: whole-cell K+ currents in transfer cell protoplasts derived from coats of developing seeds of Vicia faba L.

In developing seed ofVicia faba L., solutes imported throughthe phloem of the coats move symplastically from the sieve elementsto a specialized set of cells (the thin-walled parenchyma transfercells) for release to the seed apoplast. Potassium (K⁺) is thepredominant cation released from the seed coats. To elucidatethe mechanisms of K⁺ efflux from seed coat to seed apoplast,whole-cell currents across the plasma membranes of protoplastsof thin-walled parenchyma transfer cells were measured usingthe whole-cell patch-clamp technique. Membrane depolarizationelicited a time-dependent and an instantaneous outward current.The reversal potential (E_R of the time-dependent outward currentwas close to the potassium equilibrium potential (E_K and itshifted in the same direction as E_K upon changing the externalK⁺ concentration, indicating that this current was largely carriedby an efflux of K⁺. The activation of the time-dependent outwardK⁺ current could be well fitted by two exponential componentsplus a constant. The instantaneous outward current could alsobe carried by K⁺ efflux as suggested by ion substitution experiments.These K⁺ outward rectifier currents elicited by membrane depolarizationare probably too small to represent the mechanism for the normalK⁺ efflux from seed coat cells. Membrane hyperpolarization morenegative than –80 mV activated a time-dependent inwardcurrent. K⁺ influx was responsible for the inward current asthe current reversed at membrane voltage close to E_K and shiftedin the same direction as E_K when external [K⁺] was varied. Activationof this K⁺inward rectifier current was well fitted with twoexponential components plus a constant. A regulating functionfor this current is suggested. Key words: Potassium outward rectifier, potassium inward rectifier, transfer cell protoplast, seed coat, Vicia faba L     

Early Development of the Seed Coat of Soybean (Glycine max)

Although the development of the soybean ovule has been fairlywell studied, knowledge of the sequence of events in the seedcoat during the first 3 weeks after flowering is incomplete.The goal of the present study was to document, using light microscopy,the early development of the soybean seed coat with respectto changes in structure and histochemistry. At anthesis, theseed coat consists of an outer layer of cuboidal epidermal cellssurrounding several layers of undifferentiated parenchyma (whichtogether constitute the outer integument), and an inner layerof cuboidal endothelial cells (the inner integument). At 3 dpost anthesis (dpa), the inner integument has expanded to includethree to five layers of relatively large cells with thick, heavily-stainingcell walls immediately adjacent to the endothelium. By 18 dpa,the outer integument has developed into a complex of tissuescomprised of an inner layer of thick-walled parenchyma, an outerlayer of thin-walled parenchyma containing vascular tissue whichhas grown down from the lateral vascular bundles in the hilumregion, a hypodermis of hourglass cells, and palisade layer(epidermis). The thick-walled parenchyma of the inner integumenthas become completely stretched and compressed, leaving a single,deeply staining wall layer directly above the endothelium. At21 dpa, the outermost cells of the endosperm have begun to compressthe endothelium. At 45 dpa (physiological maturity) the seedcoat retains only the palisade layer, hourglass cells, and afew layers of thin-walled parenchyma. The innermost layer ofthe endosperm, the aleurone layer, adheres to the inside ofthe seed coat. This knowledge will be invaluable in future studiesof manipulation of gene expression in the seed coat to modifyseed or seed coat characteristics. Copyright 1999 Annals ofBotany Company Soybean, Glycine max, seed coat, development, aleurone.     

Effect of Potassium on Sucrose and Amino Acid Release from the Seed Coat of Developing Seeds of Pisum sativum

After removal of the embryo from developing seeds of Pisum sativum,the ‘empty’ ovules (seed coats without enclosedembryo) were filled with a solution (pH 5.5) containing mannitol(usually 400 mM) to which various salts were added. A solutioncontaining two isotopes ((a) [²H]-sucrose/[–¹⁴C]aminoisobutyricacid (AIB) or (b) [³H]valine/[₁₄C]asparagine mixture) was administeredto the plant via the petiole subtending the fruiting node, and[²H]solute and [¹⁴C]solute unloading from the seed coat wasmeasured, in pulse-labelling experiments of about 5 h. The presenceof 25 or 50 mM K⁺ in the ‘empty’ ovule enhancedthe release of sucrose from the seed coat particularly duringthe first hours of the experiment, but the stimulating effectof K⁺ on the release of labelled solutes derived from aminoacids was much smaller. The presence of 25 mM CaCl₂ did notaffect the release of sucrose or amino acids from the seed coat.The effect of K⁺ on sucrose and amino acid release is explainedas an inhibition of sucrose and amino acid resorption from theseed coat apoplast into seed coat cells, after unloading fromthe seed coat unloading sites. It is suggested that amino acidrelease is much less affected by K⁺ than sucrose release, becausefar less resorption of amino acids by seed coat parenchyma cellstakes place during amino acid transport into the seed coat cavity. Pisum sativum, pea, assimilate transport, assimilate unloading, seed-coat exudate, seed development, sucrose resorption, surgical treatment     

Mechanism of Photosynthate Efflux from Vicia faba L. Seed Coats

In order to develop a tentative model of the mechanism of photosynthateefflux from the vascular region of Vicia faba L. seed coats,wash-out experiments were performed after removal of the embryo. The sulphydryl group modifiers, pCMBS and NEM, reduced ¹⁴C-photosynthateefflux by 40% and 50%, respectively. Their inhibitory effectcould be prevented or reduced (in the latter case) by includingDTT in the bathing solution. Maltose competed with sucrose forefflux; a concentration of 300 mol m^–3 inhibited ₁₄C-photosynthaterelease by 35%. The cations K⁺ , Na⁺ Mg²⁺ and TPP⁺ enhancedefflux significantly, whereas the countenon Cl^– had noeffect. The presence of the protonophore CCCP (0·1 molm^–3) led to a reduction of efflux by 50% net proton extrusiondropped by 34%. To a lesser extent, an efflux inhibition wasalso achieved by decreasing the cytoplasmic pH with the weakacid DM0. In contrast, alterations in the external pH causedonly a feeble response. The ATPase inhibitor, EB, decreasedphotosynthate efflux and H⁺ extrusion. DES reduced efflux slightly,presumably by affecting ATPase activity as well as energy metabolism. Based on these findings, it is proposed that a sucrose/protonantiport mechanism could be responsible for photosynthate effluxfrom Vicia faba seed coats. Key words: Photosynthate efflux, proton extrusion, proton/sucrose antiport, seed coat, Vicia faba L.     

Carpology, Seed Anatomy and Taxonomic Relationships ofGalbulimima(Himantandraceae)

The fruit and seed anatomy and morphology ofGalbulimima belgraveana(F.Muell.) Sprague, a solitary species of the monotypic genus inthe Himantandraceae, have been studied in an effort to clarifyits systematic position. The indehiscent fleshy multicarpellary,two- or three-ranked capsetum ofGalbulimimaconsists of follicles(capseoles) with lignified fibrous five- or six-layered endocarp.Such construction of the himantandraceous capsetum suggestsderivation from free cone-like fruits similar to those of Annonaceaeand Magnoliaceae. Seeds ofGalbulimimaare relatively large, flattened,winged, with a solitary vascular bundle extending to the micropyle,and a cup of hypostase. They are abundantly albuminous and havea small dicotyledonous embryo. The seed coat ofGalbulimimaismesotestal with testal-tegmic ruminations and unspecializedtwo- or three-layered tegmen; a single-layered exotesta representedby thin-walled tanniniferous cells; a two (–three)-layeredmesotesta, composed of thick-walled lignified longitudinal fibres;and an endotesta composed of two or three layers of unspecializedaerenchymatous parenchyma. Evidence, mainly from seed morphologyand anatomy of seed coats, emphasizes the anomaly of the traditionalaffiliation of Himantandraceae with MagnolialessensuTakhtajan,being quite distinct in spermoderm structure and origin fromboth Magnoliaceae and Degeneriaceae in particular. Furthermore,seed anatomy does not confirm any relationships with Myristicaceaeor Canellaceae. Among all Magnoliidae, the structure of theseed coats ofGalbulimimais similar to that of some advancedAnnonaceae and Eupomatiaceae. It is suggested that Himantandraceaetogether with Eupomatiaceae and Annonaceae constitute a distinctrelic blind branch of magnoliid ancestry. On the basis of availabledata of seed coat anatomy, it is appropriate to remove Himantandralesfrom the order Magnolialessensu stricto, and to place it intoits own monotypic order, Himantandralesord. nov.,grouping togetherwith orders Eupomatiales and Annonales in Magnoliidae.Copyright1998 Annals of Botany Company Galbulimima belgraveana(F. Muell.) Sprague; carpology; pericarp; seed anatomy; systematics; phylogenetic relationships; Himantandraceae; Magnoliaceae; Eupomatiaceae; Degeneriaceae; Annonaceae; Liriodendraceae; Myristicaceae; Canellaceae.     

Effect of Potassium on Photosynthate Unloading from Seed Coats of Phaseolus vulgaris L. Specificity and Membrane Location

Rates of ¹⁴C-photosynthate unloading from excised seed-coathalves of Phaseolus vulgaris L. plants were stimulated by externalKCI concentrations in excess of 10 mM with an optimal responseat 100–150 mM KCI. The cellular pattern of ¹⁴C-photosynthatemetabolism was not altered by KCI but the treatment preferentiallystimulated the release of sucrose from the seed-coats. Photosynthateunloading was insensitive to Cl^– and was stimulated bya range of membrane-permeable cations (Na⁺, Mg²⁺ and tetraphenylphosphoniumion) in addition to K⁺. The K⁺ ionophore, valinomycin, abolishedthe K⁺ stimulation of ¹⁴C-photosynthate unloading. A switchto a wash solution containing K⁺ elicited a rapid burst of ¹⁴C-photosynthateunloading; the rate constant for the final phase of ¹⁴C-efflux(probably across the tonoplast) was unaffected by K⁺. The KCItreatment did not change the passive permeability of eitherthe plasmalemma or tonoplast. While sucrose influx across theplasmalemma was insensitive to K⁺, sucrose transfer to the vacuolewas slowed. The results obtained support the postulate thatK⁺ (and other membrane permeable cations) preferentially stimulatesucrose efflux across the plasmalemma of the unloading cellsby serving to carry positive charge in the opposite direction. Phaseolus vulgaris, bean, photosynthate unloading, potassium stimulation, seed-coat     

Structural and Histochemical Changes in Palisade Cells of Prosopis juliflora Seed Coat in Relation to its Water Permeability

Histochemical investigations on the Prosopis juliflora seedcoat indicate the occurrence of a hydrophobic ‘strip’as the primary water barrier. Its position and the structureand histochemistry of the palisade cells of the seed coat differaccording to their location on the seed. These differences maybe responsible for differences in the water permeability ofvarious parts of the seed coat. In particular, parts of theseed coat in which the hydrophobic ‘strip’ is locatedmore superficially tend to be more water impermeable than partslike the chalaza, in which the ‘strip’ is more deeplylocated within the palisade cells. Prosopis juliflora, seed coat impermeability, palisade cells, hydrophobic ‘strip’     

Carbon Import into Developing Ovules of Pisum sativum: The Role of the Water Relations of the Seed Coat

We tested the hypothesis that the transport of carbon to developingpea ovules is controlled by the water potential of the seedcoat, in both the short-term (minutes to hours) and long-term(days). At 14 d after anthesis, when the embryo just fills theseed coat, the osmotic pressure of seed coat apoplast solutionwas about 1 MPa (equivalent to 400 mOsmol kg^–1). Transportof carbon into perfused attached seed coats at this stage ofdevelopment was monitored with radioactive carbon-11. Aftera small (50 mOsmol kg^–1) increment in the osmotic pressureof the bathing solution, transport of carbon increased abruptly,but after about 100 min it returned towards pretreatment values.Therefore, although osmotic pressure in the sink apoplast initiallyaffected carbon import, as expected from the M     

Seed Coat Dormancy in Two Species of Grevillea(Proteaceae)

The role played by the seed coat in seed dormancy of Grevillealinearifolia(Cav.) Druce and G. wilsonii(A. Cunn.) was testedby a series of manipulations in which the seed coat was dissectedand removed, dissected and returned to the decoated seed, ordissected, removed and given a heat shock, and returned to thedecoated seed. Germination of intact seeds of both species wasalso examined after exposure to heat shock, smoke, or heat shockand smoke combined. Water permeability of the seed coat wasinvestigated by examining imbibition. For intact seeds, virtuallyno germination occurred under any treatment (G. wilsonii), orgermination was increased by exposure to either heat or smoke(G. linearifolia). Removal of the seed coat led to germinationof all decoated seeds for G. linearifolia, or a proportion ofdecoated seeds for G. wilsonii. Inclusion of smoked water inthe incubation medium led to a higher proportion of decoatedseeds germinating for G. wilsonii. Returning the seed coat,either with or without heat shock to the seed coat, did notsignificantly affect germination in either species. Seed coatswere permeable to water in both species. For the two Grevilleaspecies, there were different dormancy mechanisms that werecontrolled by the seed coat (G. linearifolia) or by both theseed coat and embryo (G. wilsonii). Copyright 2000 Annals ofBotany Company Grevillea linearifolia, Grevillea wilsonii, dormancy, seed coat dormancy, seed coat permeability, smoke, heat shock, germination     

Seed Coat Unloading in Pisum sativum--Osmotic Effects in Attached versus Excised Empty Ovules

Experiments were undertaken with embryo-less ovules of Pisumsativum to study the influence of apoplastic osmolality on seedcoat import and seed coat unloading.¹¹CO₂ pulse labelling alongwith collimated monitoring of plant tissues were used with attachedovules to measure continuously and simultaneously total podimport, import into a modified ovule and photo-assimilate washoutfrom the seed coat of the ovule into a flow-through bathingsolution.Our results indicated that seed coat import was immediatelyaffected by a change in the applied bathing solution osmolality,with a decrease in osmolality lowering seed coat import andan increase in osmolality increasing import. ¹¹C-photo-assimilatewashout from attached ovules was found to respond in a similarmanner to the apoplastic osmolality. However, the osmotic effecton ¹¹C-washout was a delayed response and it appears that themajority of this observed response was due to the alterationin seed coat tracer import. Further experiments with ¹⁴C-labelled,excised seed coat halves (i.e. no further import) supportedthis hypothesis by demonstrating that seed coat unloading (measuredas ¹⁴C-photo-assimilate washout) was actually enhanced at alow solution osmolality. PCMBS had no effect on seed coat importor washout in attached, modified ovules, suggesting that photo-assimilateunloading from seed coats of Pisum does not involve a carrierprotein. Studies of the spatial distribution of imported ¹⁴Cin Pisum seed coats further suggest that this unloading, intothe apoplast, occurs from non-phloem cell types, and that themovement of photo-assimilates from the sieve elements to theterminal unloading site occurs via symplastic transport. Key words: Pisum sativum, seed coat, seed coat unloading, phloem unloading     

Auxin-Promoted Transport of Metabolites in Stems of Phaseolus vulgaris L.: Auxin Dose-Response Curves and Effects of Inhibitors of Polar Auxin Transport

Transport of ¹⁴C-photosynthate in decapitated stems of Phaseolusvulgaris explants was dependent on the concentration of indole-3-aceticacid (IAA) applied to the cut surfaces of the stem stumps. Thephysiological age of the stem influenced the nature of the transportresponse to IAA with stems that had ceased elongation exhibitinga more pronounced response with a distinct optimum. Increasednutrient status of the explants had little influence on theshape of the IAA dose-response curve but increased, by two ordersof magnitude, the IAA concentration that elicited the optimalresponse. Applications of the inhibitor of polar auxin transport,1-(2-carboxyphenyl)-3-phenylpropane-1, 3-dione (CPD), affectedIAA-promoted transport of ¹⁴C-photosynthates. At sub-optimalIAA concentrations, CPD inhibited transport, whereas at supra-optimalIAA concentrations, ¹⁴C-photosynthate transport was marginallystimulated by CPD. Treatment with CPD resulted in a significantreduction in stem levels of [¹⁴C]IAA below the site of inhibitorapplication, while above this point, levels of [¹⁴C]1AA remainedunaltered. The divergent responses of auxin-promoted transportto CPD treatment are most consistent with a remote action ofIAA on photosynthate transport in the decapitated stems. Key words: Auxin, photosynthate, transport     

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     

Differentiation of a Functional Aleurone Layer Within the Seed Coat of Sinapis alba L.

The hitherto unresolved ontogenetic origin of the aleurone layerin mustard (Sinapis alba L.) seeds was investigated with lightand electron microscopy. Contrary to previous views, this layerof storage cells is neither derived from the endosperm nor fromthe nucellus, but from a particular cell layer within the innerintegument of the seed coat. These cells differentiate and becomefilled with storage protein and fat concurrently with the maturationof the embryo. They survive seed desiccation and become depletedof storage materials during seed germination. Temporally correlatedwith the germinating embryo, the aleurone cells produce microbodyenzymes, which are controlled by light in a similar fashionin both tissues. Sinapis alba L., mustard, aleurone layer, seed coat, seed formation, germination     

Control of Seed Growth in Soya Beans [Glycine max (L.) Merrill]

The seed is the primary sink for photosynthate during reproductivegrowth and an understanding of the mechanisms controlling therate of seed growth is necessary to understand completely theyield production process. The growth rate of individual seedsof seven soya bean [Glycine max (L.) Merrill] cultivars withgenetic differences in seed size varied from 10.8 to 3.9 mgseed^–1 day^–1. The growth rates were highly correlatedwith final seed size. The growth rate of cotyledons culturedin a complete nutrient medium was highly correlated with thegrowth rate of seeds developing on the plant and with finalseed size. The number of cells per seed in the cotyledons variedfrom 10.2 to 5.7 x 10⁶ across the seven cultivars. The numberof cells per seed in the cotyledons was significantly correlatedwith final seed size and the seed growth rate both on the plantand in the culture medium. The data suggest that genetic differencesin seed growth rates are controlled by the cotyledons and thenumber of cells in the cotyledons may be the mechanism of control. Glycine max L., soya bean, seed size, growth rate, cell number, sink activity     

The Pathway of Radial Transfer of Photosynthate in Decapitated Stems of Phaseolus vulgaris L.

[¹⁴C]Sucrose was found to be the predominant component of the¹⁴C-photosynthates that accumulated in the free space of decapitatedstems of P. vulgaris plants. The ¹⁴C-photosynthates appearedto occupy the entire free-space volume of the stems at totalsugar concentrations in the range of 3–12 mM. The free-spacesugar levels were found to rapidly decline once photosynthatetransfer to the stems was halted. Moreover, it was found thatestimates of the rate of in vitro sucrose uptake by the stemscould account fully for the decline in free-space sugar levels.Overall, the evidence indicated that at least part of the radialpathway of photosynthate transfer in bean stems involved thestem apoplast. It is tentatively proposed that, based on celland tissue distribution of ¹⁴C-photosynthates, the apoplasticpathway extends from the membrane boundary of the sieve element/companion-cellcomplex to all other cells of the stem. Apoplast, Phaseolus vulgaris L., bean, phloem unloading, photosynthates, symplast     

The Morphology and Anatomy of Ovule and Fruit Development in Arachis hypogaea L

The vascular system of the monocarpellary gynoecium with tenwell differentiated traces and a few cross links probably representsa precocious development of the post-fertilization vasculatureof the fruit wall. The restriction of the two integuments ofthe ovule to the micropylar half, and the endothecial natureof the chalazal cells adjoining the embryo sac appear to indicatea pathway of derivation of the unitegmic tenumucellate ovulefrom the bitegmic crassinucellate one. During double fertilization,a dark staining refractive body appears in the nucleolus ofthe egg as well as the fusion product of the polar nuclei. The peg that carries the ovary into the soil after fertilizationgrows by the activity of a rib meristem at the basal solid partof the gynoecium. During sub-soil fruit development, the ovarywall develops a prominent spongy inner zone which finally disappears,and a peripheral zone that forms the mature fruit wall. Theabinitio nuclear endosperm is much reduced and degenerates afterproducing a few cell layers in the chalazal half alone. Seeddevelopment is pachychalazal. The main vascular supply of theseed branches at the chalaza into eight to ten strands in theseed coat. All seeds that have a vascular ramification in theseed coat are probably pachychalazal. In the variety Valencia, diminutive fruits with viable seedmay develop aerially from pegs that fail to grow long enoughto reach the soil from the higher nodes. Arachis hypogaea L., groundnut, fruit development, seed development, carpel vasculature, seed vasculature, pachychalaza