Gabriele Orlich

Specific proteins in the sieve-tube exudate of Ricinus communis L. seedlings: separation, characterization and in-vivo labelling

Ricinus communis L. seedlings exuded pure phloem sap from the cut hypocotyl for several hours. Throughout the entire exudation period proteins were present in the phloem exudate at a constant concentration ranging from 0.11 to 0.41 mg·ml−1 depending on the culture conditions and the age of the seedlings. Manipulation of the nutrient supply at the cotyledons after removal of the endosperm did not change the protein concentration in the exudate. Comparison of sieve-tube exudate proteins (STEPs) with soluble proteins extracted from the hypocotyl and the cotyledons showed a unique abundance of small proteins in the exudate, with molecular weights ranging from 10 to 25 kDa. Bands at 18, 19 and 20 kDa were especially dominant. The proteins found transiently in the xylem exudate, which might represent proteins secreted at the wound surface, were different in pattern. Two-dimensional separation of STEPs revealed that more than 100 distinct polypeptides occurred in the sieve-tube exudate, most of them slightly acidic with isoelectric points ranging from 4 to 6 and a few basic ones around 8. [35S]Methionine fed to the cotyledons led to labelling of STEPs, demonstrating their rapid synthesis. It is concluded that there is a continuous synthesis and translocation of specific sieve-tube proteins, whose function is unknown.

Sucrose transport into the phloem of ricinus communis l. seedlings as measured by the analysis of sieve-tube sap

Careful cutting of the hypocotyl of Ricinus communis L. seedlings led to the exudation of pure sieve-tube sap for 2–3 h. This offered the possibility of testing the phloem-loading system qualitatively and quantitatively by incubating the cotyledons with different solutes of various concentrations to determine whether or not these solutes were loaded into the sieve tubes. The concentration which was achieved by loading and the time course could also be documented. This study concentrated on the loading of sucrose because it is the major naturally translocated sieve-tube compound. The sucrose concentration of sieve-tube sap was approx. 300 mM when the cotyledons were buried in the endosperm. When the cotyledons were excised from the endosperm and incubated in buffer, the sucrose concentration decreased gradually to 80–100 mM. This sucrose level was maintained for several hours by starch breakdown. Incubation of the excised cotyledons in sucrose caused the sucrose concentration in the sieve tubes to rise from 80 to 400 mM, depending on the sucrose concentration in the medium. Thus the sucrose concentration in the sieve tubes could be manipulated over a wide range. The transfer of labelled sucrose to the sieve-tube sap took 10 min; full isotope equilibration was finally reached after 2 h. An increase of K+ in the medium or in the sieve tubes did not change the sucrose concentration in the sievetube sap. Similarly the experimentally induced change of sucrose concentration in the sieve tubes did not affect the K+ concentration in the exudate. High concentrations of K+, however, strongly reduced the flow rate of exudation. Similar results were obtained with Na+ (data not shown). The minimum translocation speed in the sieve tubes in vivo was calculated from the growth increment of the seedling to be 1.03 m·h-1, a value, which on average was also obtained for the exudation system with the endosperm attached. This comparison of the in-vivo rate of phloem transport and the exudation rate from cut hypocotyls indicates that sink control of phloem transport in the seedlings of that particular age was small, if there was any at all, and that the results from the experimental exudation system were probably not falsified by removal of the sink tissues.

Phloem loading-not metaphysical, only complex: towards a unified model of phloem loading

Phloem loading comprises the entire pathway of phloem-mobile solutes from their place of generation (or delivery) to the sieve tubes in a sequence of transport steps across or passing by several different cell types. Each of these steps can be classified as symplastic or apoplastic. The detailed anatomical-cytological work in the past ten years made clear that the symplastic continuity from mesophyll to sieve tubes may be very different for different plant species or even in different vein orders. Therefore data from one species are not transferable to another species and a well-rounded picture involving different experimental methods has to be aimed at for each species separately. The information obtained with the Ricinus seedling, where phloem loading and sieve tube sap analysis can be achieved relatively easily, is presented. The analysis of the radioactive labelling of sucrose from the sieve tubes of cotyledons, in which external and intracellular sucrose had been differently labelled, revealed that at sucrose concentrations close to the natural one, 50% of sucrose is loaded directly from the external medium. The other 50% is first taken up by mesophyll and then released for uptake into the sieve tubes. No bundle tissue works as obligate, intermediate sucrose storage. The apoplast therefore definitely serves as a transit reservoir for sucrose destined to be loaded into the sieve tubes. The sieve tube sap contains glycolytic metabolites at concentrations higher than found in the hypocotyl tissue, whereas the corresponding glycolytic enzymes are missing. It is concluded that the enzymes are sequestered in the companion cell or by parietal membrane stacks. Not only the sieve tubes but nearly all cotyledonary cells are equipped with a sucrose-H(+) symporter able to achieve sucrose accumulation and sensitive to inhibition by high salt concentrations or SH reagents. A cDNA clone coding for a sucrose carrier was isolated. It is transcribed at approximately the same level in most organs of the seedling and throughout the germination period. Leaves of adult Ricinus have significantly lower levels of this transcript. Recirculation of excess, phloem-delivered solutes from the sink back to the source is shown not only to be a common feature of long-distance transport, but the only way that an imbalance between supply to and consumption of nutrients in the sink can be adjusted in the source. It is a pathway by which sink activity regulates phloem loading. Non-invasive NMR imaging revealed the flow rates and flow speeds in phloem and xylem in the intact seedling and proved directly the existence of an internal circulating solution flow. A unified model of phloem loading is proposed, based on a pump-and-leak model, where active sucrose carriers (and other carriers) accumulate solutes in the sieve tubes with a concomitant build-up of pressure resulting in mass flow. Plasmodesmata are leaks (as are the transport carriers, too), slowing down the transport rate, but they also serve as diffusion channels for substances which are produced in the neighbouring cell. Therefore, compounds, which are not made in the sieve tubes themselves are translocated together with the bulk solution of sieve tube sap.

Phloem loading in Ricinus cotyledons: sucrose pathways via the mesophyll and the apoplasm

Ricinus communis cv. Carmencita seedlings with their cotyledons incubated in sucrose solution and their hypocotyls cut to induce exudation of phloem sap, constitute a system of sucrose fluxes into and out of the cotyledons. This system was characterized with respect to quasi-steady-state conditions of sucrose uptake and export and then used to investigate the pathways of sucrose during phloem loading. The redistribution of 14C-labelled internal sucrose between the three “compartments”, cotyledons (mesophyll), exudate (sieve tubes) and incubation medium (cell-wall space), was measured in the presence or absence of external nonlabelled sucrose. It was found that mesophyll-derived labelled and external sucrose compete at uptake sites in the apoplasm. On the basis of the specific radioactivity of sucrose which reflects the proportionate intermixture of mesophyll-derived and external sucrose in the three “compartments”, it was determined that about 50% of the sucrose exported is loaded directly from the apoplasm, while the other half takes the route via the mesophyll. It was confirmed that mesophyll-derived sucrose is released into the apoplasm, so that the existence of an indirect apoplasmic loading pathway is established. Calculations depending on the concentration gradients of labelled and non-labelled sucrose in the cell-wall space are presented to quantify tentatively the proportions of direct and indirect apoplasmic as well as symplasmic loading.

A symplasmic flow of sucrose contributes to phloem loading in Ricinus cotyledons

Abstract. External sucrose, supplied by the endosperm in vivo, is the physiological source of sucrose for Ricinus communis L. seedlings. It is taken up by the cotyledons and exported via the sieve tubes to the growing hypocotyl and root. Two parallel pathways of external sucrose to the sieve tubes, directly via the apoplasm and indirectly after transit through the mesophyll, have already been established (G. Orlich and E. Komor, 1992). In this study, we analysed whether a symplasmic flow of sucrose contributes to phloem loading. Uptake of external sucrose into the mesophyll and into the sieve tubes, and export of total sucrose were measured with intact and exuding seedlings in the presence of p-chloromercuribenzenesulfonic acid (PCMBS). Sucrose uptake into the mesophyll and into the sieve tubes was inhibited by 80–90%. Consequently, export of total sucrose slowed down. However, after the addition of PCMBS, sucrose was transiently exported in such a high amount that could not be accounted for by the residual uptake activity nor by the amount of sucrose confined to the sieve element-companion cell complex (seccc). From the results, we conclude that most of the sucrose exported transiently had moved to the sieve tubes from a symplasmic domain larger than the seccc, comprising at least all the cells of the bundle including the bundle sheath. We suggest that the symplasmic flow of sucrose observed is a mass flow driven by a turgor pressure. As a structural prerequisite for a symplasmic flow, plasmodesmata interconnect all the cells from the bundle sheath to the sieve tubes and also occur between the bundle sheath and the mesophyll. The phloem loading pathway of Ricinus cotyledons can thus be classified as a combination of three different routes.

Microautoradiographic studies of the role of mesophyll and bundle tissues of the Ricinus cotyledon in sucrose uptake

The aim of the study was to show which tissues and cell types of the cotyledon of Ricinus communis L. are responsible for uptake of sucrose by H+-sucrose symport. The cotyledons were incubated in labelled sucrose for up to 20 min and then the amount of radioactivity in each cell type of the cotyledon was assessed by microautoradiography. It was found that 50% of the label was present in the spongy mesophyll, and 10–15% was in the bundles, the epidermal layers and the palisade parenchyma. The sieve tubes contained only 2–3% of the label. The addition of sucrose to cotyledons depolarized the membrane of spongy-mesophyll cells by 33 mV. Therefore, it was concluded that the previously found H+-sucrose symport is at least partly located at the spongy mesophyll. No precursor-like behaviour of the label in mesophyll or bundle-sheath cells was observed in pulse-chase experiments, which indicates a direct uptake of sucrose by the sieve tube-companion cell complex from the apoplast.

Analysis of the driving forces of phloem transport in Ricinus seedlings: sucrose export and volume flow are determined by the source

Abstract. The aim of this study was to reveal the factors determining sucrose export and volume flow through the sieve tubes in Ricinus communis L. seedlings. The cotyledons take up sucrose from the apoplasm in vivo, and export most of it to the growing sinks, hypocotyl and root. This simple source-sink system allowed sucrose uptake and export to be studied under controlled conditions with respect to apoplasmic sucrose concentrations. From the additional knowledge of the sucrose concentrations in the mesophyll and the sieve tubes, transmembrane concentration differences were calculated. The volume flow rate along the sieve tubes could be calculated from the export rate and the sucrose concentration in the sieve tubes. While the export rate exhibited saturation kinetics, the volume flow rate decreased at high external sucrose concentrations. The export rate correlated with the sucrose uptake rate, the volume flow rate correlated with the sucrose concentration (osmotic pressure) difference across the sieve-tube plasma membrane, the driving force for transmembrane water flux. From these data it can be concluded that sucrose export and the volume flow through the sieve tubes are determined by activities of the source. Export out of Ricinus cotyledons was considerably higher than export out of green source leaves of different species. The concomitant comparatively low sucrose concentration in the sieve-tube sap of the seedlings can thus be attributed to a very high water flux into and along the sieve tubes associated with the high sucrose flux.

[21] Phloem transport

Publisher Summary The term phloem transport refers to the flow of assimilates from their site of synthesis or storage to their site of consumption for methodological reasons and may be separated into three phases: phloem loading, long-distance transport, and phloem unloading. To gain a better understanding of phloem transport, a close relationship between structural and functional information is necessary. Therefore, methods for studying phloem transport should include anatomical, histological, and physiological approaches. This chapter presents a selection of techniques with special emphasis on their methodological value, and open questions are briefly discussed on occasion. The different techniques are introduced by those who are working in the respective field to provide firsthand information. The development of legume seeds is characterized by a continuous transfer of assimilates from the tissues of maternal origin (seed coat) to the embryonic tissues. Photosynthetic imported from the pod wall must pass the seed coat before it is available for uptake by the embryo.

Relationship between apoplastic nutrient concentrations and the long-distance transport of nutrients in the Ricinus communis L. seedling

The seedling of Ricinus communis was used to study the fluxes of nutrients from the apoplastic space into the symplast of the cotyledons, from the apoplast and the symplast of the cotyledons into the phloem, and the recirculation of nutrients into the cotyledons via the xylem. Cotyledons of the intact seedling were incubated in media of defined nutrient concentrations till a steady-state of fluxes was reached, then a small cut of two to three bundles at the hypocotyl hook was made and the exudates from phloem and xylem were sampled and analysed. Together with the information obtained for nutrient concentrations in the medium (apoplast) and in the leaf (symplast) a quantitative scheme of nutrient fluxes at different apoplastic concentrations was designed. All tested nutrients (sucrose, glutamine, potassium ion) were found in higher concentrations in the symplast and in the phloem sap than in the apoplast, but sucrose was the only substrate which was clearly enriched in the phloem sap compared to the symplast. Recirculation (i.e. export via the phloem and re-import via the xylem) of sucrose was negligible at all tested sucrose concentrations, whereas recirculation of glutamine and potassium ions was up to 80{%} in case of high supply at the cotyledon apoplast. The recirculation of these nutrients enables the apoplastic space of the cotyledons to function as a storage space for homeostatic nutrient supply to the phloem for up to 1h. The concentrations of all tested nutrients in phloem and in xylem were determined by the high accumulation capacity of the cotyledons’ symplast and the high phloem loading activity. Therefore, the concentrations of nitrogenous compounds and of potassium reached in the xylem by providing these nutrients to the roots were not higher than obtained through recirculation of phloem-derived nutrients. This situation may be typical for the seedling stage with low transpirational water flux and high nutrient resources in the cotyledons.