Water Flow Across the Sieve-Tube Boundary: Estimating Turgor and Some Implications For Phloem Loading and Unloading. I. Theory

A mathematical model of water and sucrose transport across thesieve tube boundary is presented, based on conservation of matterand the phenomenological equations for plasmodesmatal transportbetween the sieve elements and their associated cells. Plasmodesmataltransport coefficients are discussed. In parts II–IV,the equations developed here are used to assess: (i) the estimationof phloem turgor gradients from osmotic pressure gradients;(ii) plasmodesmatal transport of water and sucrose between thesieve elements and adjacent cells; and (iii) the plausibilityof symplastic and apoplastic phloem loading and unloading insome primary sources and sinks. A list of symbols is given inAppendix 1 of this paper Phloem, turgor, osmotic pressure, loading, unloading, plasmodesmata, Munch hypothesis     

Water Flow Across the Sieve Tube Boundary: Estimating Turgor and Some Implications for Phloem Loading and Unloading. IV. Root Tips and Seed Coats

In the present paper, the theory developed in Part I of thisseries is applied to seed coats of Phaseolus vulgaris and somecombined data on root tips of Hordeum distichum and Hordeumvulgare. Because of the large back-pressures implied, it isconcluded that phloem transport into these primary sinks wouldbe physiologically impossible in the absence of a symplasticpathway for the unloading of water from sieve elements. In thiscase, unloading of water and sucrose will occur predominantlyas a pressure-driven flow of solution through plasmodesmata,although diffusion can contribute significantly to the plasmodesmatalsucrose flux. At least 20% of the plasmodesmata connecting sieveelements and adjacent cells must be unobstructed if large changesin turgor and osmotic pressure are to be avoided. Dependingon the membrane area available for water fluxes, it is possiblethat the difference in water potential across the sieve-tubeplasmalemma can lead to significant errors when axial turgorgradients are estimated from gradients of osmotic pressure andexternal water potential. The magnitude and even the sign ofthese errors is uncertain, but it is possible that sieve-tubeturgor pressures will be significantly underestimated in primarysinks Phloem, turgor, osmotic pressure, plasmodesmata, Munch hypothesis, Phloem unloading     

Pathways of Uptake and Accumulation of Sugars in Tomato Fruit

The route of sucrose unloading from the conducting tissue, theregulation of sucrose hydrolysis and the uptake and subsequentmetabolism of sugars were investigated in the rapidly growingtomato fruit. During the first two weeks of fruit enlargement, the vacuoleaccounted for more than 85% of the protoplast volume and theintercellular space accounted for 20% of the fruit placentaltissue. The plasmodesmatal frequency was highest between phloemparenchyma cells and lowest between phloem sieve cells and phloemparenchyma. The total invertase activity was about 8 µmolglucose g^–1 d. wt min^–1 during the rapid growingperiod and increased six-fold at ripening. The wall-bound invertaseaccounted for less than 11% of the total activity. Invertaseactivity increased with increasing sucrose concentrations (upto 50 mM) in the incubation medium, but decreased at higherconcentrations. Sucrose synthase activity could only be detectedwhen fruit was older than 19 d. The uptake and metabolism of sugars by fruit cells were investigatedby incubation of fruit slices with ¹⁴C-sugars for 3 h. The uptakeof sucrose increased with the sucrose concentration up to 200mM. The rate of glucose uptake and its conversion to the ethanol-insolublefraction were higher than those of sucrose. The uptake of sucrosedid not compete with that of glucose or vice versa, providedthe osmotic potential of the incubation solution was maintainedconstant. The uptake of sucrose was not inhibited by metabolicinhibitors such as PCMBS, CCCP, sodium azide or vanadate. TheATPase activity in the fruit tissue was low. These findings did not identify conclusively the mode of sucroseunloading. However, the uptake of sugars by fruit cells is non-specificand does not appear to require a membrane carrier or plasmalemmaATPase to provide energy for sucrose uptake. Fruit, invertase, Lycopersicon esculentum, phloem unloading, plasmodesmata, sucrose     

Water Flow Across the Sieve-Tube Boundary: Estimating Turgor and Some Implications for Phloem Loading and Unloading. III. Phloem in the Leaf

The theory described in Part I of this series is applied hereto the loading of water and sucrose into the sieve-element-companion-cell(se-cc) complexes of minor veins. It is concluded that symplasticphloem loading cannot account for large increases in osmoticpressure from mesophyll to se-cc complex or the dilution ofsieve tube sap which is evident in leaves. By contrast, loadingfrom the free space into a symplastically isolated se-cc complexcan account for both these observations. Within the se-cc complex,sucrose and water will be transported from the companion cellsto the sieve elements by a pressure-driven flow of solutionthrough the cytoplasmic annuli of plasmodesmata. The associatedchanges in turgor and osmotic pressure are small, and so these-cc complex can be regarded as a single compartment with respectto water potential. The assumption that this compartment isat water flux equilibrium will lead to significant overestimatesof turgor gradients. However, if the trans-membrane water potentialdifference and the external water potential are taken into account,the correlation of such gradients with sieve-element dimensionsand / or transport velocities provides one means of testingthe Munch hypothesis of phloem transport Phloem, turgor, osmotic pressure, plasmodesmata, Münch hypothesis, Phloem loading     

Measurement of turgor pressure and its gradient in the Phloem of oak

A direct method is described for measuring the pressure in secondary phloem sieve tubes of oak trees. One end of a 26-gauge stainless steel tube was shaped such that when it penetrated the outer bark and transected a few sieve elements, it was stopped by the xylem so that small openings in the end allowed phloem sap to enter the tube. The other end of the stainless tube (phloem needle) was joined to a long glass capillary sealed at its other end to form a manometer for measuring phloem sap pressure. A method for measuring the average osmotic and turgor pressures in cells of leaves is also described. Phloem turgor pressures varied greatly in a series of phloem punctures around the trunk at 1.5 and at 6.3 meters. The variation in turgor pressure was always greater than the variation in osmotic pressure. In a series of turgor pressures arranged in descending order, the values in a sequence for the upper level was usually a little (0-3 atm) larger than the values for the lower level. These results may suggest that translocation of assimilate is favored by a small turgor pressure gradient, but they do more to emphasize the complications in measuring gradients in an elastic low resistance distribution system composed of contiguous longitudinal conduits. The results also imply that the sieve tubes are inflated with assimilate fluid under high pressure which can readily move longitudinally and with less pressure drop than would be necessary if the sieve tubes were rigid.     

Turgor, Growth and Rheological Gradients of Wheat Roots Following Osmotic Stress

The growth rate of hydroponically grown wheat roots was reducedby mannitol solutions of various osmotic pressures. For example,following 24 h exposure to 0·96 MPa mannitol root elongationwas reduced from 1· mm h^–1 to 0·1 mm h^–1 Mature cell length was reduced from 290 µm in unstressedroots to 100 µm in 0·96 MPa mannitol. This indicatesa reduction in cell production rate from about 4 per h in theunstressed roots to 1 per h in the highest stress treatment. The growing zone extended over the apical 4·5 mm in unstressedroots but became shorter as growth ceased in the proximal regionsat higher levels of osmotic stress. The turgor pressure along the apical 5·0 mm of unstressedroots was between 0·5 and 0·6 MPa but declinedto 0·41 MPa over the next 50 mm. Following 24 h in 0·48(200 mol m^–3) or 0·72 MPa (300 mol m^–) mannitol,turgor along the apical 50 mm was indistinguishable from thatof unstressed roots but turgor declined more steeply in theregion 5·10 mm from the tip. At the highest level ofstress (0·96 MPa or 400 mol m^–3 mannitol) turgordeclined steeply within the apical 20 mm. Key words: Growth, turgor pressure, wall rheology, osmotic stress, osmotic adjustment     

An Investigation of the Relay Hypothesis of Phloem Transport in Ricinus communis L.

To test for the existence of an apoplastic unloading/reloadingstep in phloem translocation, as envisaged in the relay hypothesisof phloem transport, isotopic trapping experiments were performedon Ricinus comunis L. var. Gibsonii. A CO₂ buffer system wasused to supply ¹⁴CO₂ at constant partial pressure and constantspecific activity to a photosynthesizing leaf. The subtendinginternode was perfused with solutions of sugars or of mannitoland transolation of ¹⁴C past the perfused zone was monitoredby the collection of phloem exudate. Trapping of activity inthe perfusate was enhanced by the presence of sugars as wouldbe expected with an unloading/reloading process. However, therewas no evidence that introduction of the unlabelled sugars tothe apoplast also reduced activity in the phloem exudate. Moreover,the rate of loss of activity to the perfusing solutions representedonly 1% of the rate of appearance in the exudation. It is suggestedthat the trapping results may reflect an unloading of tracerfrom the phloem associated with a subsequent reloading by adjacenttissues rather than by the sieve tubes. To investigate the length of sieve tube continuity in Ricinus,a horizontal incision was made to the bark and the rate of exudationof phloem sap was monitored. Successive circumferential cutswere made above the exuding incision and progressively closerto it. In general, a girdling incision produced a transientdecrease in the rate of change of exudation rate (i.e. the firstderivative became more negative/less positive). The magnitudeof this response rose with exudation rate and fell with thedistance at which a girdling cut was made. Fitting an appropriatemodel yielded an estimate for contributory length of 69 ±6 cm. This was comparable with the distance of the initial tangentialincision from the stem apex, suggesting a continuous sieve tubesystem in Ricinus. A similar investigation on the petiole yieldedan estimate of around 7.0 cm. This lower estimate for contributorylength is believed to reflect a rapid sealing process that limitsthe distance of propagation of turgor-release rather than alimited length of sieve tube continuity. The results of this investigation do not support the relay hypothesisof phloem transport. Rather they suggest a continuous sievetube system which has a distributed capacity to load and unloadsolutes, and which may exhibit a sealing response when injured. Key words: Ricinus communis L, phloem transport, phleom unloading     

Sieve element unloading: cellular pathway, mechanism and control

The transport and distribution of phloem – mobile solutes is predominantly determined by transport processes located at the sink end of the source – transport – sink system. Transport across the sieve element boundary, sieve element unloading, is the first of a series of sink transport processes. Unloading of solutes from the sieve elements may follow an apo- or symplastic route. It is speculated that the unloading pathway is integrated with sink function and that apoplastic unloading is restricted to situations in which movement through the symplast is not compatible with sink function. These situations include axial transport and storage of osmotically active solutes against concentration and turgor gradients between the sieve elements and sink cells. Coupled with alteration in sink function, the cellular pathway of unloading can switch in stems and possibly other sinks. Experimental systems and approaches used to elucidate the mechanism of sieve element unloading are reviewed. Unloading fluxes to the apoplast can largely be accounted for by membrane diffusion in axial sinks. However, the higher fluxes in storage sinks suggests dependence on some form of facilitated transport. Proton sucrose symport is assessed to be a possible mechanism for facilitated efflux of solutes across the sieve element plasma membrane to the sink apoplast. Unloading through the symplast may occur by diffusion or mass flow. The latter mechanism serves to dissipate phloem water and hence prevent the potential elevation of sieve element turgor that would otherwise slow phloem import into the sink. The possibility of energised plasmodesmatal transport is raised. Sieve element unloading must be integrated with subsequent compartmentation and metabolism of the unloaded solute. Solute levels are an obvious basis for control of sieve element unloading, but are found to offer limited scope for a mass action mechanism. Apoplastic, cellular pathway, sieve element, solute transport, symplastic. Translated into a turgor signal, solute levels could regulate the rate of unloading, metabolism and compartmentation forming part of a turgor homeostat irrespective of the pathway of unloading.     

Phloem water relations and translocation

Satisfactory measurements of phloem water potential of trees can be obtained with the Richards and Ogata psychrometer and the vapor equilibration techniques, although corrections for loss of dry weight and for heating by respiration are required for the vapor equilibrium values. The psychrometer technique is the more satisfactory of the 2 because it requires less time for equilibration, less tissue, and less handling of tissue. Phloem water potential of a yellow-poplar tree followed a diurnal pattern quite similar to that of leaves, except that the values were higher (less negative) and changed less than in the leaves.

The psychrometer technique permits a different approach to the study of translocation in trees. Measurements of water potential of phloem discs followed by freezing of samples and determination of osmotic potential allows estimation of turgor pressure in various parts of trees as the difference between osmotic potential and total water potential. This technique was used in evaluating gradients in water potential, osmotic potential, and turgor pressure in red maple trees. The expected gradients in osmotic potential were observed in the phloem, osmotic potential of the cell sap increasing (sap becoming more dilute) down the trunk. However, values of water potential were such that a gradient in turgor pressure apparently did not exist at a time when rate of translocation was expected to be high. These results do not support the mass flow theory of translocation favored by many workers.

     

Concentrations and Transport of Solutes in Xylem and Phloem along the Leaf Axis of NaCl-treated Hordeum vulgare

Hordeum vulgare cv. California Mariout was established in sandculture at two different NaCl concentrations (0.5 mol m^–3‘control’ and 100 mol m^–3) in the presenceof 6.5 mol m^–3 K ⁺. Between 16 and 31 d after germination,before stem elongation started, xylem sap was collected by useof a pressure chamber. Collections were made at three differentsites on leaves 1 and 3: at the base of the sheath, at the baseof the blade, i.e. above the ligule, and at the tip of the blade.Phloem sap was collected from leaf 3 at similar sites throughaphid stylets. The concentrations of K ⁺, Na⁺, Mg2⁺ and Ca²⁺were measured. Ion concentrations in xylem sap collected at the base of leaves1 and 3 were identical, indicating there was no preferentialdelivery of specific ions to older leaves. All ion concentrationsin the xylem decreased from the base of the leaf towards thetip; these gradients were remarkably steep for young leaves,indicating high rates of ion uptake from the xylem. The gradientsdecreased with leaf age, but did not disappear completely. In phloem sap, concentrations of K⁺ and total osmolality declinedslightly from the tip to the base of leaves of both controland salt-treated plants. By contrast, Na⁺ concentrations inphloem sap collected from salt-treated plants decreased drasticallyfrom 21 mol m^–3 at the tip to 7.5 mol m^–3 at thebase. Data of K/Na ratios in xylem and phloem sap were used to constructan empirical model of Na⁺ and K⁺ flows within xylem and phloemduring the life cycle of a leaf, indicating recirculation ofNa⁺ within the leaf. Key words: Hordeum vulgare, xylem transport, phloem transport, NaCl-stress     

Phloem unloading in the potato tuber. Pathways and sites of ATPase

Summary Potential pathways for sucrose unloading in the potato tuber were examined by light and electron microscopy. Abundant plasmodesmata connected sieve elements with surrounding parenchyma elements and also sieve elements with companion cells. Plasmodesmata were rarer, however, between companion cells and parenchyma elements. These observations suggest that sucrose may leave the sieve elements and enter the storage parenchyma cells directly via the symplast and that transport through the companion cell may not be a prerequisite for unloading. Plasmodesmata, grouped together in primary pit fields, were also abundant between storage cells, and isolated storage cells, separated enzymically, showed considerable variation in plasmodesmatal distribution between cells and also on different faces of a single cell. Deposition of starch was found to occur in the tuber cortex while an endodermis with Casparian strip was present external to the phloem, suggesting that assimilates initially enter the cortical storage cells by an entirely symplastic pathway. The possible involvement of ATPase in the unloading process was examined cytochemically, using a lead-salt precipitation method. By contrast with previous findings for phloem no evidence was found for ATPase activity that was unique to the sieve element-companion cell complex. The present observations favour the view that phloem unloading in the potato tuber is a symplastic and passive process.     

Regulation of Turgor Pressure by Suspension-Cultured Tobacco Cells

Turgor regulation and effects of high NaCl and water deficiton growth and internal solutes were studied after transferringtobacco cells from control culture medium (osmotic pressure= 0.13–0.15 MPa at time of transfer) to culture mediumcontaining either 82 mol m^–3 NaCl or 150 mol m^–3melibiose (osmotic pressure of media = 0.62 MPa). Followingtransfer to media with higher osmotic pressure, expansion rateand turgor pressure were reduced. Within 24 h of imposing thewater deficit, expansion rate had returned to that of cellsin control culture medium. However, by 24 h, turgor pressurehad only risen from 0.2 MPa to 0.65 MPa in the NaCl treatmentand to 0.53 MPa in the melibiose treatment, while it was 0.73MPa in the control treatment. Furthermore, turgor pressure remainedwithin 0.05 MPa of these respective values for the rest of the(75 h) experiment. These results suggest differences in bothcell wall properties (extensibility and/or threshold turgor)and the level at which turgor is maintained for cells in thevarious treatments. Solutes contributing nearly all (82–97%) of the osmoticpressure in cells were identified. The initial (up to 24 h)increases in turgor pressure were mainly due to increases insolute concentrations caused by relatively slow expansion rates.However, increased Na⁺ and Cl ^– uptake contributed toincreased turgor pressure in the NaCl treatment and caused turgorpressure of cells in this treatment to increase faster thanin the melibiose treatment. Likewise, expansion rate rose morequickly in the NaCl than in the melibiose treatment. After 24h, maximum expansion rate was reached and concentrations ofmost internal solutes began to decrease. Nevertheless, turgorpressure remained relatively constant. The constancy of turgorpressure was due to increased glucose uptake rates relativeto controls, with consequent increases in concentrations ofsucrose, glucose and fructose and, in cells in the melibiosetreatment, of organic acids. Glucose uptake was slower in theNaCl than in the melibiose treatment but higher turgor pressurewas maintained in the NaCl treatment due to high uptake of Na⁺and Cl^–. Glucose uptake appears to respond to a systemof turgor regulation, but further experiments are required toconfirm this and to determine whether Na⁺ and Cl^– uptakealso respond to a system of turgor regulation. Key words: Salinity, water deficit, growth     

Radial Turgor Pressure Profiles in Growing and Mature Zones of Wheat Roots--A Modification of the Pressure Probe

A modification of the pressure probe is described which allowsaccurate routine recording of the turgor pressure of singlecells at measured depth within a tissue. Measurements of radial profiles of turgor pressure in wheatroots grown in some simple salt solutions (0.5 mol m^–3CaCl₂, 0.5 mol m^–3 CaCI₂ plus 10 mol m^–3 NaCl, and0.5 mol m^–3 CaCl₂ plus 10 mol m^–3 KCI), are described.Turgor pressure was constant (approximately, 0.65 MPa) alonga radius within the elongation zone irrespective of the natureof the bathing solution. In mature root tissue turgor pressurein the cortex was lower than that of the growing zone in alltreatments and the pressure of the stele was on average 0.22MPa higher than that of the cortex. Potassium in the mediumbathing the root increased the turgor pressure in mature root(both cortex and stele) relative to low salt and sodium treatments. The results are discussed in relation to both root growth andion accumulation. Key words: Pressure probe, wheat roots, salt solution     

The Cellular Pathway of Radial Transfer of Photosynthates in Stems of Phaseolus vulgaris L.: Effects of Cellular Plasmolysis and p-Chloromercuribenzene Sulphonic Acid

Cellular plasmolysis with l M solutions of mannitol appearedto sever plasmodesmatal interconnections between all cells ofthe stems of Phaseolus vulgaris plants except the sieve element-companioncell (se—cc) complexes. Phloem loading and uptake of [¹⁴C]sucroseby the storage cells of the stems was unimpaired by cellularplasmolysis followed by rehydration of the stem tissues. Accumulationof phloem-transported ¹⁴C-photosynthates of the treated stemswas inhibited in summer-grown plants and unaffected in winter-grownplants indicating that phloem unloading follows a symplasticand a free-space route respectively depending on growth season.At a concentration that did not interfere with cellular metabolism,p-chloromercuribenzene sulphonic acid (PCMBS) applied to thestems blocked [¹⁴C]sucrose loading into the phloem and storagecells of the stem, but had no effect on the pool size of free-spacesugars. This latter response is consistent with a facilitatedmechanism of sugar unloading to the stem free-space. Accumulationof phloem-transported ¹⁴C-photosynthates was stimulated by PCMBSand this effect was most pronounced in winter-grown plants.Cellular plasmolysis followed by rehydration abolished the PCMBSaction on ¹⁴C-photosynthate accumulation. This effect is consistentwith a PCMBS induction of phloem unloading through the stemsymplast. It is proposed that phloem unloading in bean stemsmay follow either a free-space or symplastic route and thatthe latter route is entrained under sink-limited conditions. Phaseolus vulgaris, french bean, stem, phioem unloading, free-space, symplast     

Turgor Regulation in a Brackish Charophyte, Lamprothamnium succinctum II. Changes in K$, Na$ and Cl- Concentrations, Membrane Potential and Membrane Resistance during Turgor Regulation

A brackish Characeae, Lamprothamnium succinctum, regulates intracellularosmotic pressure in response to changes in the external salinityand keeps the turgor pressure constant. The osmotic pressureof the vacuole was found to be mostly due to K^$, Na^$ and Cl^–.But in the cytoplasm, the sum of their concentrations was muchlower than the cellular osmotic pressure. Electroneutralitywas maintained among the analyzed inorganic ions in the vacuolebut a strong anion deficiency was detected in the cytoplasm,supporting the existence of organic anions to balance excesspositive charges. During turgor regulation, concentrations of inorganic ions inthe vacuole changed just enough to accommodate the osmotic pressurechange, while those in the cytoplasm remained almost constant.Since the cytoplasmic volume was almost constant during turgorregulation, some organic molecule(s) may have contributed tothe osmoregulation of the cytoplasm. The membrane potential and resistance at steady state underdifferent salinities were almost constant. Hypotonic treatmentcaused a sudden depolarization of the membrane potential anda drastic decrease in membrane resistance. Hypertonic treatmentcaused a slow hyperpolization of membrane potential but didnot significantly affect the membrane resistance. The energeticsof K^$ and Cl^– movements across the plasma membrane isdiscussed based upon the electrochemical potential gradients. (Received November 28, 1983; Accepted March 14, 1984)     

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     

Xyloglucan Endotransglycosylase Activity, Microfibril Orientation and the Profiles of Cell Wall Properties Along Growing Regions of Maize Roots

A series of physical and chemical analyses were made on theexpanding zone of maize seedling roots grown in hydroponics.Comparison of longitudinal profiles of local relative elementalgrowth rate and turgor pressure indicated that cell walls becomelooser in the apical 5 mm and then tighten 5–10 mm fromthe root tip. Immersion of roots in 200 mol m^–3 mannitol(an osmotic stress of 0·48 MPa) rapidly and evenly reducedturgor pressure along the whole growing region. Growth was reducedto a greater extent in the region 5–10 mm from the roottip than in the apical region. This indicated rapid wall-looseningin the root tip, but not in the more basal regions. Following 24 h immersion in 400 mol m^–3 mannitol (an osmoticstress of 0·96 MPa) turgor had recovered to pre-stressedvalues. Under this stress treatment, growth was reduced in theregion 4–10 mm from the root tip, despite the recoveryof turgor, indicating a tightening of the wall. In the rootapex, local relative elemental growth rate was unchanged incomparison to control tissue, showing that wall properties herewere similar to the control values. Cellulose microfibrils on the inner face of cortical cell wallsbecame increasingly more parallel to the root axis along thegrowth profile of both unstressed and stressed roots. Orientationdid not correlate with the wall loosening in the apical regionof unstressed roots, or with the tightening in the region 5–10mm from the root tip following 24 h of osmotic stress. Longitudinal profiles of the possible wall-loosening enzymexyloglucan endotransglycosylase (XET) had good correspondencewith an increase in wall loosening during development. In thezone of wall tightening following osmotic stress, XET activitywas decreased per unit dry weight (compared with the unstressedcontrol), but not per unit fresh weight. Key words: Osmotic stress, turgor, growth, cell wall properties, microfibrils, XET     

Measurement of Yield Threshold and Cell Wal Extensibility of Intact Wheat Roots under Different Ionic, Osmotic and Temperature Treatments

Yield stress threshold (Y) and volumetric extensibility () arethe rheological properties that appear to control root growth.In this study they were measured in wheat roots by means ofparallel measurement of the growth rate (r) of intact wheatroots and of the turgor pressures (P) of individual cells withinthe expansion zone. Growth and turgor pressure were manipulatedby immersion in graded osmoticum (mannitol) solutions. Turgorwas measured with a pressure probe and growth rate by visualobservation. The influence of various growth conditions on Yand was investigated; (a) At 27 °C.In 0.5 mol m^–3 CaCl₂ r, P, Y and were20.7±4.6 µm min^–1, 0.77±0.05 MPa,0.07±0.03 MPa and 26±1.9 µm min^–1MPa^–1 (expressed as increase in length), respectively.Following 24 h growth in 10 mol m^–3 KC1 these parametersbecame 12.3±3.5 µm min^–1, 0.72±0.04MPa, 0.13±0.01 MPa and 21±0.7 µm min^–1MPa^–1. After 24 h osmotic adjustment in 150 mol m^–3mannitol/0.5 mol m^–3 CaCl₂ r= 19.6±4.2 µmmin^–1, P = 0.68±0.05 MPa and Y and were 0.07±0.04MPa and 30±0.2 µm min^–1 MPa^–01, respectively.After 24 h growth in 350 mol m^–3 mannitol/0.5 mol m^–3CaCl₂ r= 13.3±4.1 µm min^–1, P= 0.58±0.07MPa, Y=0.12±0.01 MPa and ø 32±0.2 tim min^–1MPa^–1. During osmotic adjustment in 200 mol m^–3mannitol/0.5 mol m^–3 CaCl₂, with or without KCl, the recoveryof growth rate corresponded to turgor pressure recovery (t1/2approximately 3 h). (b) At 15 °C. Lowered temperature dramatically influencedthe growth parameters which became r= 8.3±2.8 um min^–1,P=0.78 MPa, r=<0.2 MPa and =15±0.1 µm min^–1MPa^–1. Therefore, Y and are influenced by 10 mol m^–3 K⁺ ionsand low temperature. In each case the effective pressure forgrowth (P-Y) was large indicating that small fluctuations ofsoil water potential will not stop root elongation. Key words: Yield threshold, cell wall extensibility, wheat root growth, temperature, turgor pressur     

Manometric Measurement of Turgor Pressures in Laticiferous Phloem Tissues2

A manometric technique for the determination of turgor pressuresin laticiferous phloem tissues has given reproducible resultsin Hevea brasiliensis and a few other tree species. In Hevea,early morning pressures are in the range 7.9–15.0 atmospheres,falling during the day and recovering at night. These diurnalpressure changes are positively correlated with atmosphericrelative humidity and negatively correlated with changes intemperature, evaporation, leaf water deficit, and stomatal opening.They are not displayed by trees devoid of leaves. Thus the lossin turgor is probably the result of withdrawal of water fromthe phloem tissues under transpirational stress. Pressures at the base of the trunk normally exceed those atthe top, the gradient usually approximating to 1 atmosphere/10metres at night and rising up to six times this figure duringthe day. This increase probably reflects the development oftension gradients in the xylem during transpiration. A generalturgor gradient from base to crown does not preclude mass flowin sieve-tubes in the opposite direction provided that ratesof loading and unloading are such that a sufficient osmoticgradient is maintained in them in the required direction. No marked long-term effects of regular tapping on turgor pressurehave been noted in Hevea trees and there is no evidence forseasonal changes in turgor under our conditions.     

Respiration and Phloem Translocation in the Roots of Chickpea (Cicer arietinum)

Root growth in chickpea (Cicer arietinum) has been studied fromthe early vegetative phase to the reproductive stage in orderto elucidate its growth and maintenance respiration and to quantifythe translocation of assimilates from shoot to root. A carbonbalance has been drawn for this purpose using the growth andrespiration data. The increase in the sieve tube cross-sectionalarea was also followed simultaneously. Plants growing in a nutrient culture medium were studied todetermine the relative growth rate (RGR) 5–60 d aftergermination. RGR declined from 113 to 41 mg d^–1 g^–1during the measurement period. Simultaneous with the RGR analysis,respiration rate was also measured using an oxygen electrode.The respiration rate declined as the plants aged and a drasticreduction was recorded following anthesis. The relationshipbetween RGR and respiration rate was used to extrapolate themaintenance respiration (m) and growth respiration (1/Y_EG).The respiration quotient (r.q.) of the roots was 1.2 and theQ₁₀ in the range 20–25 °C was 2·2. A carbon balance for the roots was constructed by subtractingthe carbon lost during respiration from that gained during growth.The roots were found to respire no less than 80% of the carbontranslocated. The increase in the cross-sectional area composed of sieve tubeswas measured near the root-shoot junction as the plants grew.Chickpea has storied sieve plates which simplifies these measurements.Their cross-sectional area increased during growth mainly becauseof an increase in sieve tube number. The diameter of individualsieve tubes remained constant. Specific mass transfer (SMT) values for seive tubes into theroots have been computed during various stages of growth. SMTvalues were relatively constant before anthesis (approx. 6·5g h^–1 cm^–2), but decreased following anthesis. Wedid not evaluate possible retranslocation from roots: any suchretranslocation would have the effect of increasing our SMTvalues. Chickpea, Cicer arietinum, legume, root, respiration, phloem, translocation, carbon balance, specific mass transfer, sieve-tube dimensions