The Contribution of an Apoplastic Pathway to Sodium Uptake by Rice Roots in Saline Conditions

An apoplastic pathway, the so-called bypass-flow, across riceroots to the xylem has been investigated and approximately quantifiedusing the apoplastic tracer dye 8-hydroxy-l,3,6-pyrenetrisulphonicacid (PTS); former nomenclature 3-hydroxy-5,8,10-pyrenetrisulphonicacid. It was confirmed that PTS was confined to a compartmentno greater than the apparent free space in living rice roots.Experimental handling did not contribute to bypass-flow. Riceroots recovered rapidly from severe damage: following root pruning,sodium and calcium uptake returned to steady values in about6 h. Apoplastic flow declined after damage as a first-orderkinetic with a half time of 75 min. Analysis of the pattern of elution of PTS from preloaded roots(intact, excised and heat-killed), and from cellulose, was followedto compare PTS movement in the extracellular compartment withthat of water and small hydrated ions. Consideration is givento the factor by which the bypass-flow estimated with the dyewould need to be corrected to reflect the proportion of thetranspiration stream flowing in the apoplastic pathway. Thedata suggest that this factor would be at least 10 for transpiringrice plants. There was large individual variation in the transport both ofsodium and of the apoplastic tracer PTS to the shoot. Plantswith high sodium transport also had high PTS transport and itis concluded that some proportion of the sodium reaching thexylem in rice does so by a pathway which is also available toPTS, presumably direct apoplastic contact across the endodermis.A median value for the bypass-flow of water (corrected fromPTS) would be 0.5 to 1.0 percent of the transpirational volumeflow, but individuals with the highest sodium transport wouldhave bypass-flow values of several percent. Evidence is discussedwhich suggests that apoplastic transport may increase in stressconditions, and it is argued that bypass-flow is a major contributionto sodium uptake in rice in saline conditions. Key words: Oryza saliva, salinity, roots, radial ion transport, apoplast, bypass-flow     

A Comparison of the Methods of X-ray Microanalysis, Compartmental Analysis and Longitudional Ion Profiles to Estimate Cytoplasmic Ion Concentrations in Two Maize Varieties

Hajibagheri, M. A., Flowers, T. J., Collins, J. C. and Yeo,A. R. 1988. A comparison of the methods of X-ray microanalysis,compartmental analysis and longitudinal ion profiles to estimatecytoplasnuc ion concentrations in two maize varieties.—J.exp. Bot. 39: 279-290. The ion content of compartments within plant root cells hasbeen studied by three different methods; flux analysis usingradioactive isotopes, longitudinal ion profiles and X-ray microanalysis.The data provide estimates of the concentrations of K⁺ and CI^–in the cytoplasm of roots of culture solution and salt grownmaize by three independent methods. In the cultivar LG₁₁ grown in 50 mol m^–3 NaCl X-ray microanalysis,compartmental analysis and longitudinal profiles yielded approximatelyagreeing values for cytoplasmic K⁺ of 90, 70 and 62 mol m^–33of tissue volume respectively. However, the methods disagreedon cytoplasmic Cl^– where the value obtained by compartmentalanalysis was about four times that from X-ray microanalysisand longitudinal profiles. Possible reasons for this are discussed. Key words: X-ray microanalysis, longitudinal ion profiles, compartmental analysis, salt-tolerance.     

Ion accumulation in the cell walls of rice plants growing under saline conditions: evidence for the Oertli hypothesis

Abstract. When plants of rice ( Oryza saliva L.) are subjected to mildly saline (50mol m⁻³ NaCl) conditions, the leaves show symptoms of water deficit, even though ion accumulation has been more than sufficient to adjust to the decrease in external water potential. After a few days of exposure to salt, there is a negative correlation, in a population of leaves, between the leaf water concentration (g water per g dry weight) and their sodium concentration (mmol Na per g dry weight). Ion concentrations in the cell walls and the cytoplasm of cells of plants grown in low salinity were measured by X-ray microanalysis. The NaCl concentration in solution in the apoplast was calculated to be around 600mol m⁻³ in leaves of plants whose roots were exposed to only 50 mol m⁻³ NaCl. This constitutes strong evidence that an important factor in salt damage in rice is dehydration due to the extracellular accumulation of salt as suggested in the Oertli hypothesis. The implication, that changes in tissue ion concentration and solute potentials equivalent to the external medium is not evidence of plant osmotic adjustment to salinity, is discussed.     

Sodium Chloride Compartmentation in Leaf Vacuoles of the Halophyte Suaeda maritima (L.) Dum. and its Relation to Tonoplast Permeability

Single channel properties, whole vacuole currents and protonpumping capacity were investigated in the intact vacuoles andmembrane patches of leaf tonoplast from the halophyte Suaedamaritima. ATP-dependent proton pumping capacity was similarto non-halophytes whether the plants were or were not grownwith added sodium chloride (200 mM). The most abundant ion channelwas inward rectifying and had a single channel conductance of58 pS in symmetrical KCl solutions (100 mM) to 170 pS usingphysiological conditions (50/150 mM KCl/NaCl cytoplasmic side,50/450 mM KCl/NaCl vacuolar side). The channel showed all thecharacteristics of the SV type channel described in many otherspecies. In the open state these channels caused tonoplast conductancesin excess of 0.5 nS m²– but conductances were much lowerusing physiological ion concentrations and membrane potentials.In spite of the poor selectivity and the potentially large tonoplastconductance it is calculated that compartmentation of NaCl inleaf vacuoles can be sustained by about 30% of ATP-dependentproton pumping capacity. The results do not indicate any specialadaptation of the tonoplast ion channels in the halophyte. Key words: Ion-channels, patch-clamp, salt-tolerance, vacuole     

Changes in ant communities along an age gradient of cocoa cultivation in the Oumé region,central Côte d'Ivoire

We identified the extent to which ant diversity occurs despite conversion of forests into cocoa plantations by examining the communities across four age classes of plantations (classes I–IV with increasing age from 0–5 to 21–40 years) and in their original forests. An extensive sampling protocol consisting of pitfall trapping, leaf litter sampling, soil sampling and hand sampling was used to characterize ant species richness and composition in three replicates of each age class and in the remaining forest patches. A total of one hundred ant species was found in all habitats combined. While the forest was the richest habitat (73 species), species richness in the different plantation age classes varied as follows (sorted in descending order): class IV (69 species) > class III (57 species) > class I (52 species) > class II (43 species). Age gradient was thus significantly positively correlated with mean species richness and with the relative abundance of some subfamilies. The species composition differed greatly between some plantation age classes and the forest. The two youngest cocoa age classes (I and II) were most dissimilar to the forest. In contrast, forest ants were well represented in the old cocoa age classes (III and IV). Three functional guilds (generalist predators, specialist predators and territorially dominant arboreal species) were in their relative abundance significantly correlated to the age gradient. Overall, cocoa cultivations retaining a floristically diverse and structurally complex forest structure are a suitable management system for the conservation of ant species of the formerly forested habitats.     

Molecular Markers for Ion Compartmentation in Cells of Higher Plants

The tonoplast plays a crucial role in ion compartmentation,which is a central feature of the salt tolerance of halophytes,but we do not know the properties of the membrane that conferthis ability. A method was, therefore, developed for the isolationof vacuoles from Suaeda maritima (L.) Dum. of sufficiently highpurity to enable biochemical characterization of their lipidand protein composition. Tonoplast fractions produced by densitygradient centrifugation, as well as vacuoles isolated by a varietyof methods (including DEAE dextran lysis, digitonin lysis, andmechanical shear forces) were unacceptably contaminated. A highlypure vacuole preparation was obtained when protoplasts werelysed by a mild hypotonic shock in alkaline buffer, in the presenceof the compatible cytosolute glycine-betaine, followed by shearforce during ultracentrifugation; cytoplasmic contaminationwas prevented by the addition of the zwitterionic detergent3-([3-cholamidopropyl]dimethylammonio)-l-propanesulphonate (CHAPS).Light microscopy of this preparation revealed no intact protoplastsand no contamination by chlorophyll could be detected. Electronmicroscopy showed the vacuoles to be single-membrane-bound structures,and was the only criterion upon which vacuoles could be separatedreliably from vacuoplasts, in which the plasmalemma is collapsedon to the tonoplast. Analysis by SDS-PAGE showed that a totalof 15 polypeptides were enriched in the tonoplast and 27 inthe soluble fraction from vacuole preparations, with a patternsimilar to that reported for glycophytic species. The pure tonoplastexhibited both vanadate-insensitive ATPase and pyrophosphataseactivities, but the properties of these enzymes were broadlysimilar to those of glycophytes. Analysis of membrane fattyacids showed that the degree of saturation of the putative tonoplastpreparation increased as the assessment of the purity of thepreparation (made by microscopy) increased. The ATPase couldbe substantially purified by ion-exchange FPLC. The resultsare discussed in relation to the degree of purity needed inmembrane preparations in order to be suitable for biochemicalanalysis. Key words: ATPase, membrane lipids, tonoplast, salinity, Suaeda maritima     

Ion Transport in Suaeda maritima: Its Relation to Growth and Implications for the Pathway of Radial Transport of Ions across the Root

The ion relations of the halophytc Suaeda maritima are described.When plants grew in 340 mol m^–3 sodium chloride (—1•76MPa) leaf solute potentials decreased, and were sustained around—2•5 MPa Inorganic ion concentration (mostly of sodiumchloride) accounted for this. Comparable shoot ion concentrationsof potassium, nitrate and sulphate occurred when plants grewon different salinity types characterized by these ions. Netsodium transport and shoot sodium concentration increased dramaticallywith increases in external sodium chloride concentration upto 85 mol m^–3; thereafter, further increases in externalsodium chloride concentration had relatively little effect uponeither shoot sodium concentration or upon net transport of sodiumto the shoot. The net transport of sodium plus potassium onlydoubled when the external concentration of sodium plus potassiumincreased from 24 to 687 mol m^–3 Shoot ion concentrationswere remarkably constant with time, external concentration andsalinity type. The membrane flux rates and symplasmic ion concentrations neededto sustain the observed net transport of sodium (of some 10mmol g^–1 dry wt. of roots d^–1) are calculated fromanatomical and stereological data for the root system of thisspecies. The minimum net sodium chloride flux to load the symplasmwould be 260 nmol m^–2s^–1 if the whole cortical andepidermal plasmalemmal surface area were used uniformly, butthe flux rate required would be 3000 nmol m^–2s^–1if uptake took place only at the root surface. A flux rate ofat least 1000 nmol m^–2s^–1 is needed between symplasmand xylem. The symplasmic concentration of NaCl would be atleast 80 mol m^–3. It is argued (1), that both symplasmicand xylem loading are likely to be passive processes mediatedby ion channels rather than active carriers, (2), that net iontransport at 340 mol m^–3 sodium chloride is close to themaximum which is physiologically sustainable and (3), that growthof this halophyte is limited by NaCl supply from the root. Key words: Suaeda maritima, halophyte, salinity, roots, radial ion transport