Phloem-localized, proton-coupled sucrose carrier ZmSUT1 mediates sucrose efflux under the control of the sucrose gradient and the proton motive force

The phloem network is as essential for plants as the vascular system is for humans. This network, assembled by nucleus- and vacuole-free interconnected living cells, represents a long distance transport pathway for nutrients and information. According to the Münch hypothesis, osmolytes such as sucrose generate the hydrostatic pressure that drives nutrient and water flow between the source and the sink phloem (Münch, E. (1930) Die Stoffbewegungen in der Pflanze, Gustav Fischer, Jena, Germany). Although proton-coupled sucrose carriers have been localized to the sieve tube and the companion cell plasma membrane of both source and sink tissues, knowledge of the molecular representatives and the mechanism of the sucrose phloem efflux is still scant. We expressed ZmSUT1, a maize sucrose/proton symporter, in Xenopus oocytes and studied the transport characteristics of the carrier by electrophysiological methods. Using the patch clamp techniques in the giant inside-out patch mode, we altered the chemical and electrochemical gradient across the sucrose carrier and analyzed the currents generated by the proton flux. Thereby we could show that ZmSUT1 is capable of mediating both the sucrose uptake into the phloem in mature leaves (source) as well as the desorption of sugar from the phloem vessels into heterotrophic tissues (sink). As predicted from a perfect molecular machine, the ZmSUT1-mediated sucrose-coupled proton current was reversible and depended on the direction of the sucrose and pH gradient as well as the membrane potential across the transporter.     

Evidence for an essential role of the sucrose transporter in phloem loading and assimilate partitioning.

Sucrose is the principal transport form of assimilates in most plants. In many species, translocation of assimilates from the mesophyll into the phloem for long distance transport is assumed to be carrier mediated. A putative sucrose proton cotransporter cDNA has been isolated from potato and shown to be expressed mainly in the phloem of mature exporting leaves. To study the in vivo role and function of the protein, potato plants were transformed with an antisense construct of the sucrose transporter cDNA under control of the CaMV 35S promoter. Upon maturation of the leaves, five transformants that expressed reduced levels of sucrose transporter mRNA developed local bleaching and curling of leaves. These leaves contained > 20-fold higher concentrations of soluble carbohydrates and showed a 5-fold increase in starch content as compared with wild type plants, as expected from a block in export. Transgenic plants with a reduced amount of sucrose carrier mRNA show a dramatic reduction in root development and tuber yield. Maximal photosynthetic activity was reduced at least in the strongly affected transformants. The effects observed in the antisense plants strongly support an apoplastic model for phloem loading, in which the sucrose transporter located at the phloem plasma membrane represents the primary route for sugar uptake into the long distance distribution network.     

Sucrose carrier RcSCR1 is involved in sucrose retrieval, but not in sucrose unloading in growing hypocotyls of Ricinus communis L

The transport of assimilates from source to sink tissues is mediated by the phloem. Along the vascular system the phloem changes its physiological function from loading phloem to transport and unloading phloem. Sucrose carrier proteins have been identified in the transport phloem, but it is unclear whether the physiological role of these transporters is phloem unloading of sucrose or retrieval of apoplasmic sucrose back into the sieve element/companion cell complex. Here, we describe the dynamic expression of the Ricinus communis sucrose carrier RcSCR1 in the hypocotyl at different sink strengths. Our results indicate that phloem unloading in castor bean is not catalysed by the phloem loader RcSCR1. However, this sucrose carrier represents the molecular basis of the sucrose retrieval mechanism along the transport phloem, which is dynamically adjusted to the sink strength. As a consequence, we assume that other release carrier(s) exist in sink tissues, such as the hypocotyl, in R. communis.     

Phloem loading of sucrose: involvement of membrane ATPase and proton transport

p-Chloromercuribenzenesulfonic acid markedly inhibited sucrose accumulation into sugar beet source leaves without inhibiting hexose accumulation. The site of inhibition is proposed to be the plasmalemma ATPase, since the ATPase-mediated H⁺ efflux was completely inhibited by p-chloromercuribenzenesulfonic acid under conditions where intracellular metabolism, as measured by photosynthesis and hexose accumulation, was unaffected. Fusicoccin, a potent activator of active H⁺/K⁺ exchange, stimulated both active sucrose accumulation and proton efflux in the sugar beet leaf tissue. These data provide strong evidence for the phloem loading of sucrose being coupled to a proton transport mechanism driven by a vectorial plasmalemma ATPase.     

Transport and metabolism of 1'-fluorosucrose, a sucrose analog not subject to invertase hydrolysis

The novel sucrose derivative 1′-fluorosucrose (α-d-glucopyranosyl-β- d-1-deoxy-1-fluorofructofuranoside) was synthesized in order to help define mechanisms of sucrose entry into plant cells. Replacement of the 1′-hydroxyl by fluorine very greatly reduces invertase hydrolysis of the derivative (hydrolysis at 10 millimolar 1′-fluorosucrose is less than 2% that of sucrose) but does not reduce recognition, binding, or transport of 1′-fluorosucrose by a sucrose carrier. Transport characteristics of 1′-fluorosucrose were studied in three different tissues. The derivative is transported by the sucrose carrier in the plasmalemma of developing soybean cotyledon protoplasts with a higher affinity than sucrose (K_m 1′-fluorosucrose 0.9 millimolar, K_m sucrose 2.0 millimolar). 1′-Fluorosucrose is a competitive inhibitor of sucrose uptake with an apparent K_i also of 0.9 millimolar, while the K_i of sucrose competition of 1′-fluorosucrose uptake was 2.0 millimolar. Thus, both sugars are recognized at the same binding site in the plasmalemma. Both sucrose and 1′-fluorosucrose show very similar patterns of phloem translocation from an abraded leaf surface through the petiole indicating that recognition of 1′-fluorosucrose by sucrose carriers involved in phloem loading is likely as well.     

Proton-Coupled Sucrose Transport in Plasmalemma Vesicles Isolated from Sugar Beet (Beta vulgaris L. cv Great Western) Leaves

Sucrose is the predominant form of photosynthetically reduced carbon transported in most plant species. In the experiments reported here, an active, proton-coupled sucrose transport system has been identified and partially characterized in plasmalemma vesicles isolated from mature sugar beet (Beta vulgaris L. cv Great Western) leaves. The isolated vesicles concentrated sucrose fivefold in the presence of an imposed pH gradient (basic interior). The presence of carbonyl cyanide m-chlorophenylhydrazone, a protonophore, prevented sucrose accumulation within the vesicles. ΔpH-dependent sucrose transport exhibited saturation kinetics with an apparent K_m of 1.20 ± 0.40 millimolar, suggesting translocation was carrier-mediated. In support of that conclusion, two protein modifiers, diethyl pyrocarbonate and p-chloromercuribenzenesulfonic acid, were found to be potent inhibitors with 50% inactivation achieved at 750 and 30 micromolar, respectively. ΔpH-Dependent sucrose transport was not inhibited by glucose, fructose, raffinose, or maltose suggesting the transport system was specific for sucrose. Transport activity was associated with the plasmalemma because ΔpH-dependent sucrose transport equilibrated on a linear sucrose gradient at 1.17 grams per cubic centimeter and comigrated with a plasmalemma enzyme marker, vanadate-sensitive K⁺, Mg²⁺-ATPase. Taken together, these results provide the first In vitro evidence in support of a sucrose-proton symport in the plasmalemma of mature leaf tissue.     

Potato sucrose transporter expression in minor veins indicates a role in phloem loading.

The major transport form of assimilates in most plants is sucrose. Translocation from the mesophyll into the phloem for long-distance transport is assumed to be carrier mediated in many species. A sucrose transporter cDNA was isolated from potato by complementation of a yeast strain that is unable to grow on sucrose because of the absence of an endogenous sucrose uptake system and the lack of a secreted invertase. The deduced amino acid sequence of the potato sucrose transporter gene StSUT1 is highly hydrophobic and is 68% identical to the spinach sucrose transporter SoSUT1 (pS21). In yeast, the sensitivity of sucrose transport to protonophores and to an increase in pH is consistent with an active proton cotransport mechanism. Substrate specificity and inhibition by protein modifiers are similar to results obtained for sucrose transport into protoplasts and plasma membrane vesicles and for the spinach transporter, with the exception of a reduction in maltose affinity. RNA gel blot analysis shows that the StSUT1 gene is highly expressed in mature leaves, whereas stem and sink tissues, such as developing leaves, show only low expression. RNA in situ hybridization studies show that the transporter gene is expressed specifically in the phloem. Both the properties and the expression pattern are consistent with a function of the sucrose transporter protein in phloem loading.     

Phloem Transport: The Surface Flow Hypothesis

Various authors have suggested that phloem contains structuralcomponents that provide interfaces at which surface movementcould be the mechanism of transport along phloem. Although surfaceflow at a liquid/gas interface or a liquid/liquid interfacecould be a sufficiently rapid process provided both media canflow with the interface, it is demonstrated that a liquid/solidinterface imposes an excessive viscous resistance. A calculated velocity for surface flow along stationary fibrilsof P-protein under a gradient of surface energy is much lowerthan observed translocation velocities. Moving fibrils wouldcarry little sucrose by the calculated absorption excess ofthe interface layer; moreover free fibrils would tend to movetowards the region of higher sucrose concentration. Similar arguments discount the plasmalemma and the tonoplastas suitable structures. A predicted value of attraction to theendoplasmic reticulum would not provide enough energy for anadequate driving force. Surface diffusion at a liquid/liquidor liquid/solid interface is not a sufficiently rapid process. The sole possibility speculatively requires that there be ahigh affinity between sucrose, or some other molecule, and thesurface of the endoplasmic reticulum, and further that it befree to flow from element to element with a continuous rateof supply of membrane components at a source, of their removalat a sink, and of their recirculation in some way. Since sucha system seems implausible, it is concluded that neither surfaceflow nor surface diffusion can be the mechanism for transportalong phloem.     

Significance of minor-vein anatomy to carbohydrate transport

Plant species which translocate distinct combinations of carbohydrates in the phloem were investigated to assess whether differences in minor-vein anatomy were associated with differences in carbohydrate composition of the phloem sap. In Vicia faba L., a species in which the minor-vein companion cells are modified into transfer cells, sucrose alone was found to be the translocated form of carbohydrate. In Vicia, phloem transport of sucrose was inhibited by pretreatment of leaves with p-chloromercuribenzenesulfonic acid (PCMBS), a known inhibitor of the sucrose carrier. In contrast, in Ocimum basilicum L., a species in which the minor-vein companion cells are of the symplasmically linked intermediary cell type, both sucrose- and raffinose-family oligosaccharides were exported in the phloem. In this species, no PCMBS sensitivity was observed for phloem transport of either sucrose- or raffinose-family oligosaccharides, although a PCMBS-sensitive sucrose carrier was detected in leaf tissues. This carrier did not appear to be involved in phloem loading, rather, it appeared that phloem loading occurred via the symplasm in this species. In the polyoltranslocating species Petroselinum crispum L., the same insensitivity to PCMBS was seen, suggesting that symplasmic phloem loading also occurred. The companion cells were symplasmically connected to the surrounding bundle-sheath cells by numerous H-shaped plasmodesmata but were not intermediary cells, and no raffinose oligosaccharides were exported by Petroselinum. Taken together, the data indicate that apoplasmic transport may be responsible for phloem loading in species in which sucrose alone is exported. However, in those plant species in which a combination of sucrose and any other carbohydrate, including the polyols, is translocated, symplasmic phloem loading may predominate.Abbreviation PCMBS p-chloromercuribenzenesulfonic acid This work was supported by National Science Foundation Grant DCB 8901785 to M.A.M. and by a National Science Foundation Graduate Minority Fellowship to L.L.F. The authors gratefully acknowledge the help of Dr. William W. Thomson in preparing the micrograph.     

A model for sucrose transport in the maize scutellum

A model originally developed for transport of neutral substrates in bacterial systems was tested for its suitability for depicting sucrose transport across the plasmalemma of the maize scutellum cell. The model contains a sucrose—proton symporter, a negatively-charged free carrier and a neutral sucrose—proton—carrier complex. Sucrose transport is driven by the sucrose gradient and by a proton electrochemical gradient set up by a proton-translocating ATPase. The results of experiments on sucrose uptake in scutellum slices are in accord with predictions based on the model. Evidence was obtained for an electrogenic proton pump in the plasmalemma, for sucrose—proton symport and for a sucrose transport mechanism driven by both electrical potential and pH gradients. It was found that treatments (dinitrophenol, N-ethylmaleimide or HCl) causing a net proton influx into the slices also caused an efflux of sucrose. Interpretations of these results compatible with the model are given.     

Hexoses as phloem transport sugars: the end of a dogma?

According to most textbooks, only non-reducing carbohydrate species such as sucrose, sugar alcohols, and raffinose-family sugars function as phloem translocates. Occasional abundance of reducing sugar species (such as hexoses) in sieve-tube sap has been discarded as an experimental artefact. This study, however, discloses a widespread occurrence of hexoses in the sieve-tube sap. Phloem exudation facilitated by EDTA provided evidence that many of the members of two plant families (Ranunculaceae and Papaveraceae) investigated translocate >80% of carbohydrates in the form of hexoses. Representatives of other families also appear to translocate appreciable amounts of hexoses in the sieve tubes. Promoting effects of EDTA, activities of sucrose-degrading enzymes, and sugar uptake by micro-organisms on hexose contents of phloem exudates were checked. The rate of sucrose degradation is far too low to explain the large proportions of hexoses measured in phloem exudates; nor did other factors tested seem to stimulate the occurrence of hexoses. The validity of the approach is further supported by the virtual absence of hexoses in exudates from species that were known as exclusive sucrose transporters. This study urges a rethink of the existing views on carbohydrate transport species in the phloem stream. Hexose translocation is to be regarded as a normal mode of carbohydrate transfer by the phloem equivalent to that of sucrose, raffinose-family sugars, or sugar alcohols.     

Sucrose transport at the tonoplast

Sucrose that leaked from maize scutellum slices upon transfer of slices from a hexose or hexitol solution to water or upon placing the slices in a buffered EDTA solution was considered to be cytoplasmic in origin; residual (after leakage) tissue sucrose was considered to be stored in the vacuoles. This paper presents a study of the movement of sucrose across the tonoplast between the vacuoles and the cytoplasmic compartment. It is concluded that; (a) sucrose transport into the vacuoles is directly linked to sucrose synthesis in such a way that free sucrose is not an intermediate in the coupled process, (b) cytoplasmic sucrose is not (cannot be?) stored, (c) sucrose transport out of the vacuoles is linked to the metabolic demand for sugar, and (d) the transport process removing sucrose from the vacuoles does not release free sucrose into the cytoplasm. The sucrose fluxes at the plasmalemma and at the tonoplast are calculated, and the transport processes at the two membranes are compared.     

Phloem flow and sugar transport in Ricinus communis L. is inhibited under anoxic conditions of shoot or roots

Anoxic conditions should hamper the transport of sugar in the phloem, as this is an active process. The canopy is a carbohydrate source and the roots are carbohydrate sinks. By fumigating the shoot with N₂ or flooding the rhizosphere, anoxic conditions in the source or sink, respectively, were induced. Volume flow, velocity, conducting area and stationary water of the phloem were assessed by non‐invasive magnetic resonance imaging (MRI) flowmetry. Carbohydrates and δ¹³C in leaves, roots and phloem saps were determined. Following flooding, volume flow and conducting area of the phloem declined and sugar concentrations in leaves and in phloem saps slightly increased. Oligosaccharides appeared in phloem saps and after 3 d, carbon transport was reduced to 77%. Additionally, the xylem flow declined and showed finally no daily rhythm. Anoxia of the shoot resulted within minutes in a reduction of volume flow, conductive area and sucrose in the phloem sap decreased. Sugar transport dropped to below 40% by the end of the N₂ treatment. However, volume flow and phloem sap sugar tended to recover during the N₂ treatment. Both anoxia treatments hampered sugar transport. The flow velocity remained about constant, although phloem sap sugar concentration changed during treatments. Apparently, stored starch was remobilized under anoxia.     

Sucrose-metabolizing enzymes in transport tissues and adjacent sink structures in developing citrus fruit

Juice tissues of citrus lack phloem; therefore, photosynthates enroute to juice sacs exit the vascular system on the surface of each segment. Areas of extensive phloem unloading and transport (vascular bundles + segment epidermis) can thus be separated from those of assimilate storage (juice sacs) and adjacent tissues where both processes occur (peel). Sugar composition, dry weight accumulation, and activities of four sucrose-metabolizing enzymes (soluble and cell-wall-bound acid invertase, alkaline invertase, sucrose synthase, and sucrose phosphate synthase) were measured in these transport and sink tissues of grapefruit (Citrus paradisi Macf.) to determine more clearly whether a given enzyme appeared to be more directly associated with assimilate transport versus deposition or utilization. Results were compared at three developmental stages. Activity of sucrose (per gram fresh weight and per milligram protein) extracted from zones of extensive phloem unloading and transport was significantly greater than from adjacent sink tissues during the stages (II and III) when juice sacs grow most rapidly. In stage II fruit, activity of sucrose synthase also significantly surpassed that of all other sucrose-metabolizing enzymes in extracts from the transport tissues (vascular bundles + segment epidermis). In contrast, sucrose phosphate synthase and alkaline invertase at this stage of growth were the most active enzymes from adjacent, rapidly growing, phloem-free sink tissues (juice sacs). Activity of these two enzymes in extracts from juice sacs was significantly greater than that form the transport tissues (vascular bundles + segment epidermis). Soluble acid invertase was the most active enzyme in extracts from all tissues of very young fruit (stage I), including nonvascular regions, but nearly disappeared prior to the onset of juice sac sugar accumulation. The physiological function of high sucrose synthase activity in the transport tissues during rapid sucrose import remains to be determined.     

Bioregulator enhancement of sink activity in sugar beet

The sink mobilizing abillity is partially determined by sugar uptake rates of storage cells. Two synthetic growth regulators (Pix and BAS 106W) were tested for their effect on sucrose uptake in root tissue discs or glucose uptake in cell cultures of sugar beet. In tissue discs, uptake at the plasmalemma was determined by incubating the discs for 1 h in the presence of 5 mM sucrose and at the tonoplast for 4 h in the presence of 40 mM sucrose. Cell cultures were incubated for 1 h in the presence of 1 mM glucose. Pix (10 mg l^–1) caused a 20% stimulation of active sucrose uptake at the plasmalemma. Active sucrose uptake at the tonoplast was increased 67% by 100 mg l^–1 Pix. No effect of BAS 106W was observed on sucrose uptake in tissue discs. In cell cultures, a 65% enhancement of active glucose uptake was observed with both Pix and BAs 106W. When the bioregulators were applied to the root medium of seedlings, Pix but not BAS 106W resulted in increased root/shoot ratio, translocation of ¹⁴C-assimilates, and allocation of more biomass to the root sink. The data suggested that sugar transport and translocation may be used as biochemical criteria for rapid screening of effective yield enhancing bioregulators.     

Transport of primary metabolites across the plant vacuolar membrane

Mesophyll cells and most types of storage cells harbor large central vacuoles representing the main cellular store for sugars and other primary metabolites like carboxylic- or and amino acids. The general biochemical characteristics of sugar transport across the vacuolar membrane are already known since a couple of years but only recently the first tonoplast sugar carriers have been identified on the molecular level. A candidate sucrose carrier has been identified in a proteomic approach. In Arabidopsis, the tonoplast monosaccharide transporters (TMT) represent a small protein family comprising only three members, which reside in the vacuolar membrane. Two of three tmt genes are induced upon cold, drought or salt stress and tmt knock out mutants exhibit altered monosaccharide levels upon cold induction. These observations indicate that TMT proteins represent the first examples of tonoplast sugar carriers involved in the cellular response upon osmotic stress stimuli.     

Isolation and characterization of a sucrose carrier cDNA from spinach by functional expression in yeast.

Active loading of the phloem with sucrose in leaves is an essential part of the process of supplying non-photosynthetic tissues with carbon and energy. The transport is protein mediated and coupled to proton-symport, but so far no sucrose carrier gene has been identified. Using an engineered Saccharomyces cerevisiae strain, a cDNA from spinach encoding a sucrose carrier was identified by functional expression. Yeast strains that allow the phenotypic recognition of a sucrose carrier activity were constructed by expressing a cytoplasmic invertase from yeast, or the potato sucrose synthase gene, in a strain unable to transport or grow on sucrose due to a deletion in the SUC2 gene. A spinach cDNA expression library established from the poly(A)+ RNA from source leaves of spinach and cloned in a yeast expression vector yielded transformed yeast clones which were able to grow on media containing sucrose as the sole carbon source. This ability was strictly linked to the presence of the spinach cDNA clone pS21. Analysis of the sucrose uptake process in yeast strains transformed with this plasmid show a pH-dependent uptake of sucrose with a Km of 1.5 mM, which can be inhibited by maltose, alpha-phenylglucoside, carbonyl cyanide m-chlorophenylhydrazone and p-chloromercuribenzenesulfonic acid. These data are in accordance with measurements using both leaf discs and plasma membrane vesicles from leaves of higher plants. DNA sequence analysis of the pS21 clone reveals the presence of an open reading frame encoding a protein with a molecular mass of 55 kDa. The predicted protein contains several hydrophobic regions which could be assigned to 12 membrane-spanning regions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Involvement of Protons as a Substrate for the Sucrose Carrier during Phloem Loading in Vicia faba Leaves

The effect of pH on uptake of exogenous sucrose by broadbean (Vicia faba L.) leaf discs without the lower epidermis has been investigated at various sucrose concentrations. The concentration dependence of sucrose uptake showed a biphasic saturation response. At high sucrose concentrations (>20 millimolar), sucrose uptake showed no pH dependence. At low sugar concentrations (<5 millimolar), plots of 1/V against 1/H⁺ give straight lines which all intercept at the same point at the left of the ordinal axis. Calculations show that these data agree well with two-substrate kinetics for the carrier, the substrates being the protons and the sucrose molecules. Our results provide further evidence that protonation/deprotonation processes of the carrier are involved in phloem loading, especially for low sucrose concentrations of the apoplast.     

The role of the sucrose transporter, OsSUT1, in germination and early seedling growth and development of rice plants

Using expression analysis, the role of the sucrose transporter OsSUT1 during germination and early growth of rice seedlings has been examined in detail, over a time-course ranging from 1 d to 7 d post-imbibition. Unlike the wheat orthologue, TaSUT1, which is thought to be directly involved in sugar transfer across the scutellar epithelium, OsSUT1 is not expressed in the scutellar epithelial cell layer of germinating rice and is, therefore, not involved in transport of sugars across the symplastic discontinuity between the endosperm and the embryo. OsSUT1 expression was also absent from the aleurone cells, indicating it is not involved in the transport of sucrose in this cell layer during germination. However, by 3 d post-imbibition, OsSUT1 was present in the companion cells and sieve elements of the scutellar vascular bundle, where it may play a role in phloem loading of sucrose for transport to the developing shoot and roots. This sucrose is most likely sourced from hexoses imported from the endosperm. In addition, sucrose may be remobilized from starch granules which are present at a high density in the scutellar ground tissues surrounding the vasculature and at the base of the shoot. OsSUT1 was also present in the coleoptile and the first and second leaf blades, where it was localized to the phloem along the entire length of these tissues, and was also present within the phloem of the primary roots. OsSUT1 may be involved in retrieval of sugars from the apoplasm in these tissues.