Seed-specific overexpression of a potato sucrose transporter increases sucrose uptake and growth rates of developing pea cotyledons

During the storage phase, cotyledons of developing pea seeds are nourished by nutrients released to the seed apoplasm by their maternal seed coats. Sucrose is transported into pea cotyledons by sucrose/H+ symport mediated by PsSUT1 and possibly other sucrose symporters. PsSUT1 is principally localised to plasma membranes of cotyledon epidermal and subepidermal transfer cells abutting the seed coat. We tested the hypothesis that endogenous sucrose/H+ symporter(s) regulate sucrose import into developing pea cotyledons. This was done by supplementing their transport activity with a potato sucrose symporter (StSUT1), selectively expressed in cotyledon storage parenchyma cells under control of a vicilin promoter. In segregating transgenic lines, enhanced [(14)C]sucrose influx into cotyledons above wild-type levels was found to be dependent on StSUT1 expression. The transgene significantly increased (approximately 2-fold) transport activity of cotyledon storage parenchyma tissues where it was selectively expressed. In contrast, sucrose influx into whole cotyledons through the endogenous epidermal transfer cell pathway was increased by only 23% in cotyledons expressing the transgene. A similar response was found for rates of biomass gain by intact cotyledons and by excised cotyledons cultured on a sucrose medium. These observations demonstrate that transport activities of sucrose symporters influence cotyledon growth rates. The attenuated effect of StSUT1 overexpression on sucrose and dry matter fluxes by whole cotyledons is consistent with a large proportion of sucrose being taken up at the cotyledonary surface. This indicates that the cellular location of sucrose transporter activity plays a key role in determining rates of sucrose import into cotyledons.     

Cell specific expression of three genes involved in plasma membrane sucrose transport in developingVicia faba seed

Summary In developing seeds ofVicia faba, transfer cells line the inner surface of the seed coat and the juxtaposed epidermal surface of the cotyledons. Circumstantial evidence, derived from anatomical and physiological studies, indicates that these cells are the likely sites of sucrose efflux to, and influx from, the seed apoplasm, respectively. In this study, expression of an H⁺/sucrose symporter-gene was found to be localised to the epidermal-transfer cell complexes of the cotyledons. The sucrose binding protein (SBP) gene was expressed in these cells as well as in the thin-walled parenchyma transfer cells of the seed coat. SBP was immunolocalised exclusively to the plasma membranes located in the wall ingrowth regions of the transfer cells. In addition, a plasma membrane H⁺-ATPase was most abundant in the wall ingrowth regions with decreasing levels of expression at increasing distance from the transfer cell layers. The observed co-localisation of high densities of a plasma membrane H⁺-ATPase and sucrose transport proteins to the wall ingrowths of the seed coat and cotyledon transfer cells provides strong evidence that these regions are the principal sites of facilitated membrane transport of sucrose to and from the seed apoplasm.Abbreviations BCIP 5-bromo-4-chloro-3-indolyl phosphate - DIG digoxigenin - H⁺-ATPase plasma membrane H⁺-translocating adenosine triphosphatase - Ig immunoglobulin - LeSUT1 tomato H⁺/sucrose symporter - SBP sucrose binding protein     

Differentiation of legume cotyledons as related to metabolic gradients and assimilate transport into seeds

Legume seed development is closely related to metabolism and nutrient transport. To analyse this relationship, a combination of biochemical, histological and transgenic approaches was used. Sugars within tissue sections have been quantitatively measured by metabolic imaging. During cotyledon differentiation glucose gradients emerge related to a particular cell type, with higher concentrations in non-differentiated premature regions. Sucrose in creases at the beginning of maturation in a layer underneath the outer epidermis expressing a sucrose transporter. Sucrose distribution is initially controlled by uptake activity and the permeability within the parenchyma and, later on, also by differences in growth and starch accumulation. Increased sucrose levels are accompanied by increased levels of sucrose synthase and ADP-Glc pyrophosphorylase mRNAs, but carbon flux into starch is initially still low. Rates increase at a stage when hexose concentrations become low, allowing increased flux through the sucrose synthase pathway. Transfer cell formation represents a regional specification of the cotyledonary epidermis for embryo nutrition characterized by increased transport-active cell surfaces and up-regulated expression of transport-related genes. The E2748 pea seed mutation blocks epidermal differentiation into transfer cells and leads to the loss of epidermal cell identity. Embryos with impaired epidermis cannot tolerate elevated levels of sucrose and respond with disorganized growth. The E2748 gene product is required for transfer cell formation in developing cotyledons with no other function during plant growth. Seed coat permeability provides a hypoxic environment for embryo development. However, at maturity, seed energy supply is not limited indicating fundamental developmental and metabolic adaptations. Results from transgenic seeds show that altered expression of single genes induces complex and unexpected changes. In AGP-antisense seeds the block in starch synthesis leads to pleiotropic effects of water and nitrogen content and induces temporal changes in seed development.     

Structure of the developing pea seed coat and the post-phloem transport pathway of nutrients

An important function of the seed coat is to deliver nutrients to the embryo. To relate this function to anatomical characteristics, the developing seed coat of pea (Pisum sativum L.) was examined by light- and cryo-scanning electron microscopy (cryo-SEM) from the late pre-storage phase until the end of seed filling. During this time the apparently undifferentiated seed coat tissues evolve into the epidermal macrosclereids, the hypodermal hourglass cells, chlorenchyma, ground parenchyma and branched parenchyma. Using the fluorescent symplast tracer 8-hydroxypyrene-1,3,6-trisulfonic acid, it could be demonstrated that solutes imported by the phloem move into the chlorenchyma and ground parenchyma, but not into the branched parenchyma. From a comparison with literature data of common bean (Phaseolus vulgaris L.) and broad bean (Vicia faba L.), it is concluded that in the three species different parenchyma layers, but not the branched parenchyma, may be involved in the post-phloem symplasmic transport of nutrients in the seed coat. In pea, the branched parenchyma dies during the storage phase, and its cell wall remnants then form the boundary layer between the living seed coat parenchyma cells and the cotyledons. Using cryo-SEM, clear images were obtained of this boundary layer which showed that many intracellular spaces in the seed coat parenchyma are filled with an aqueous solution. This is suggested to facilitate the diffusion of nutrients from the site of unloading towards the cotyledons.     

A pea seed mutant affected in the differentiation of the embryonic epidermis is impaired in embryo growth and seed maturation

During legume seed development the epidermis of the embryos differentiates into a transfer cell layer which mediates nutrient uptake during the storage phase. This specific function of the epidermal cells is acquired at the onset of embryo maturation. We investigated this process in the pea seed mutant E2748. The epidermal cells of the mutant embryo, instead of turning into transfer cells, enlarge considerably and become vacuolated and tightly associated with adjacent seed tissues. Expression of a sucrose transporter gene that is upregulated in wild-type transfer cells decreases in the mutant and changes its spatial pattern. This indicates that the outermost cell layer of mutant cotyledons cannot acquire transfer cell morphology but loses epidermal cell identity and does not function as a sucrose uptake system. Seed coat growth as well as composition, concentration and dynamics of sugars within the endospermal vacuole are unchanged. The loss of epidermal identity has severe consequences for further embryo development and is followed by disruption of the symplast within the parenchyma, the breach of the developmental gradient, lower sucrose and starch levels and initiation of callus-like growth. It is concluded that the E2748 gene controls differentiation of the cotyledonary epidermis into transfer cells and thus is required for the regional specialisation with a function in embryo nutrition.     

Transfer cell induction in cotyledons ofVicia faba L.

Summary Immediately prior to seed fill, a dermal transfer cell complex, comprised of epidermal and subepidermal cells, differentiates on the abaxial surface of the cotyledons in seed ofVicia faba. Over the period of differentiation of this complex in vivo, the principal sugars of the seed apoplasmic sap change from hexoses, glucose and fructose, to sucrose. Cotyledons were removed from seeds before differentiation of the transfer cell complex and cultured for 6 days on an agar-based medium in the dark with their abaxial surface in contact with a medium containing either 100 mM hexoses (glucose and fructose in equimolar concentrations) or 100 mM sucrose. On both media, cotyledon growth rate was maintained throughout the culture period at, or above, that of in vivo grown cotyledons of equivalent developmental age. When cotyledons were cultured on a medium containing glucose and fructose, epidermal cells of both the ab- and adaxial surfaces developed wall ingrowths on their outer periclinal walls and their cytoplasm became dense, vesicular, and rich in mitochondria. Extensive ingrowth deposition also occurred on walls of the subepidermal cells and several rows of underlying storage cells where they abutted intercellular spaces. This latter ingrowth development was apparent on both cotyledon surfaces, but extended into more of the underlying cell layers on the abaxial surface at the funicular end of the cotyledon. In in vivo grown cotyledons, such ingrowth development is restricted to the subepidermal cells of the abaxial surface. Ingrowth morphology was commensurate with that of transfer cells of in vivo grown cotyledons. In contrast to the observed induction on a medium containing glucose and fructose, cotyledons cultured with sucrose as the sole sugar source exhibited no ingrowth deposition or small wall ingrowths in some abaxial epidermal cells. While the potential sugar signalling mechanism is unknown, this culture system offers an exciting opportunity to explore the molecular biology of transfer cell development.Abbreviations DAA days after anthesis - GC-MS gas chromatography and mass spectrometry - PAR photosynthetically active radiation - RGR relative growth rate - SCM standard culture medium     

The cellular pathway of sucrose transport in developing cotyledons ofVicia faba L. andPhaseolus vulgaris L.: a physiological assessment

The cellular pathway of sugar uptake in developing cotyledons of Vicia faba L. and Phaseolus vulgaris L. seed was evaluated using a physiological approach. The cotyledon interface with the seed coat is characterised by a specialised dermal cell complex. In the case of Vicia faba cotyledons, the epidermal component of the dermal cell complex is composed of transfer cells. Sucrose is the major sugar presented to the outer surface of both cotyledons and it is taken up from the apoplasm unaltered. Estimated sucrose concentrations within the apparent free space of Vicia and Phaseolus cotyledons were 105 and 113 mM respectively. Rates of in-vitro uptake of [¹⁴C]sucrose by cotyledon segments or by whole cotyledons following physical removal or porter inactivation of the outer cells demonstrated that, for both Vicia and Phaseolus cotyledons, the dermal cell complexes are the most intense sites of sucrose uptake. Accumulation of [¹⁴C]sucrose in the storage parenchyma of whole cotyledons was directly affected by experimental manipulation of uptake by the outer cell layers and plasmolytic disruption of the interconnecting plasmodesmata. These findings indicated that sucrose accumulated by the dermal cell complexes is transported symplasmically to the storage parenchyma. Overall, it is concluded that the dermal cell complexes of the developing legume embryo, irrespective of the presence or absence of wall ingrowths, are the major sites for the uptake of sucrose released from the maternal tissues to the seed apoplasm. Thereafter, the accumulated sucrose is transported radially inward through the symplast to the storage parenchyma.Abbreviations AFS apparent free space - CF 5-(6)-carboxyfluorescein - CFDA 5-(6)-carboxyfluorescein diacetate - Mes 2-(N-morpholino)ethanesulfonic acid - PCMBS p-chloromercuribenzenesulfonic acid - SRG sulphorhodamine G The investigation was supported by funds from the Research Management Committee, The University of Newcastle and the Australian Research Council. One of us, R. McDonald, gratefully acknowledges the support of an Australian Postgraduate Research Award. We are grateful to Stella Savoury for preparing the photomicrographs.     

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     

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.     

Compartmentation of transport and transfer events in developing seeds

Developing seeds are net importers of organic and inorganic nutrients. Nutrients enter seeds through the maternal vascular system at relatively high concentrations in the phloem. They exit importing sieve elements via interconnecting plasmodesmata and, during subsequent symplasmic passage, are sequestered into labile storage pools (vacuoles; starch). Transporters function to retrieve nutrients leaked to the seed apoplasm during symplasmic passage. Maternal cells responsible for nutrient release to the seed apoplasm are characteristically located at the maternal/filial interface. Their plasma membranes are enriched in transport proteins and, in some species, these cells are modified to a transfer cell morphology. Apoplasmic volumes of seeds are relatively small, but contain high concentrations of sugars, potassium and a range of amino acids. Sucrose and amino acids are taken up from the seed apoplasm by one to two cell layers of filial tissues that juxtapose the maternal tissues. The plasma membranes of the uptake cells are enriched in sucrose and amino acid/H(+) transporters which co-localize with H(+)-ATPASES: In some species, these cells are modified to a transfer cell morphology. High densities of plasmodesmata support symplasmic delivery of accumulated nutrients to underlying storage cells where polymer formation (starch, protein) takes place. Hexoses, resulting from sucrose hydrolysis and leakage to the seed apoplasm, are retrieved by hexose/H(+) symporters.     

Improvement of pea biomass and seed productivity by simultaneous increase of phloem and embryo loading with amino acids

The development of sink organs such as fruits and seeds strongly depends on the amount of nitrogen that is moved within the phloem from photosynthetic‐active source leaves to the reproductive sinks. In many plant species nitrogen is transported as amino acids. In pea (Pisum sativum L.), source to sink partitioning of amino acids requires at least two active transport events mediated by plasma membrane‐localized proteins, and these are: (i) amino acid phloem loading; and (ii) import of amino acids into the seed cotyledons via epidermal transfer cells. As each of these transport steps might potentially be limiting to efficient nitrogen delivery to the pea embryo, we manipulated both simultaneously. Additional copies of the pea amino acid permease PsAAP1 were introduced into the pea genome and expression of the transporter was targeted to the sieve element‐companion cell complexes of the leaf phloem and to the epidermis of the seed cotyledons. The transgenic pea plants showed increased phloem loading and embryo loading of amino acids resulting in improved long distance transport of nitrogen, sink development and seed protein accumulation. Analyses of root and leaf tissues further revealed that genetic manipulation positively affected root nitrogen uptake, as well as primary source and sink metabolism. Overall, the results suggest that amino acid phloem loading exerts regulatory control over pea biomass production and seed yield, and that import of amino acids into the cotyledons limits seed protein levels.     

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     

Relationship of endogenous abscisic Acid to sucrose level and seed growth rate of soybeans

It has been proposed that abscisic acid (ABA) may stimulate sucrose transport into filling seeds of legumes, potentially regulating seed growth rate. The objective of this study was to determine whether the rate of dry matter accumulation in seeds of soybeans (Glycine max L.) is correlated with the endogenous levels of ABA and sucrose in those sinks. The levels of ABA and sucrose in seed tissues were compared in nine diverse Plant Introduction lines having seed growth rates ranging from 2.5 to 10.0 milligrams dry weight per seed per day. At 14 days after anthesis (DAA), seeds of all genotypes contained less than 2 micrograms of ABA per gram fresh weight. Levels of ABA increased rapidly, however, reaching maxima at 20 to 30 DAA, depending upon tissue type and genotype. ABA accumulated first in seed coats and then in embryos, and ABA maxima were higher in seed coats (8 to 20 micrograms per gram fresh weight) than in embryos (4 to 9 micrograms per gram fresh weight. From 30 to 50 DAA, ABA levels in both tissues decreased to less than 2 micrograms per gram fresh weight. Levels of sucrose were also low early in development, less than 10 milligrams per gram fresh weight at 14 DAA. However, by 30 DAA, sucrose levels in seed coats had increased to 20 milligrams per gram fresh weight and remained fairly constant for the remainder of the filling period. In contrast, sucrose accumulated in embryos throughout the filling period, reaching levels greater than 40 milligrams per gram fresh weight by 50 DAA. Correlation analyses indicated that the level of ABA in seed coats and embryos was not directly correlated to the level of sucrose measured in those tissues or to the rate of seed dry matter accumulation during the linear filling period. Rather, the ubiquitous pattern of ABA accumulation early in development appeared to coincide with water uptake and the rapid expansion of cotyledons occurring at that time. Whole tissue sucrose levels in embryos and seed coats, as well as sucrose levels in the embryo apoplast, were generally not correlated with the rate of dry matter accumulation. Thus, it appears that, in this set of diverse soybean genotypes, seed growth rate was not limited by endogenous concentrations of ABA or sucrose in reproductive tissues.     

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     

Turgor-dependent unloading of photosynthates from coats of developing seed of Phaseolus vulgaris and Vicia faba. Turgor homeostasis and set points

Key physiological characteristics of turgor-dependent efflux of photosynthates were examined using excised coats and cotyledons of developing Phaseolus vulgaris (cv. Redland Poineer) and Vicia faba (cv. Coles Prolific) seed during the linear phase of seed fill. Exposure to solutions of high osmotic potential inhibited net uptake of [¹⁴C]sucrose by cotyledons at developmental stages less than 60% of their final dry weight. The effect could not be fully reversed by transferring cotyledons to solutions set at lower osmotic potentials. The inhibition became apparent at osmotic potentials that were higher than those that caused stimulation of efflux from seed coats. Net [¹⁴C]sucrose uptake by cotyledons at more advanced stages of development was unaffected by external osmotic potential. Specified tissue layers were removed from seed coats by pretreatment with pectinase. Efflux studies with the pectinase-modified coats of Phaseolus and Vicia seed demonstrated that the cellular site of turgordependent efflux was the ground parenchyma and thin-wall parenchyma transfer cells, respectively. Coats subjected to long-term (hours) incubations, under hypo-osmotic conditions, exhibited the capacity for turgor regulation. This was mediated by turgor-dependent efflux of solutes. The solutes exchanged were of nutritional significance to the developing embryo. The relationship between efflux and coat turgor was characterised by a turgor-independent phase at low turgors. Once turgor exceeded a minimal value (set point), efflux increased in proportion to the magnitude of the turgor deviation (error signal) from the set point. For coats of sink-limited seed of Vicia and Phaseolus, efflux exhibited apparent saturation at turgors above 0.25 and 0.5 MPa respectively. The putative turgor set point and slope of the turgor-dependent component of efflux varied with seed development, the prevailing source/sink ratio and genetic differences in seed growth rate. The nature of these kinetic variations was compatible with the competitive ability of the seed. A turgor homeostat model is proposed that incorporates the observed functional attributes of turgor-dependent efflux. Operationally, the model provides a mechanistic basis for the integration of assimilate demand by the cotyledons with assimilate import into and unloading from the seed coat.