Transmembrane electropotential in barley roots as related to cell type, cell location, and cutting and aging effects

Transmembrane electropotential difference (PD) was measured in whole roots of barley (Hordeum vulgare L. cvs. Compana and Himalaya). Seedlings were grown 4 to 5 days in aerated 0.5 mm CaSO(4) or a nutrient solution. Measurements of PD were made with roots bathed in CaSO(4), KCl + CaSO(4), or the nutrient solution. The following results were found. (a) There was a radial PD gradient with epidermal cells being 10 to 58 millivolts less negative than cells in the third layer of the cortex (outside to inside). There was no longitudinal PD gradient in the region 0.5 to 4 cm from the root tip, nor was there any difference between the PD of young root hairs and other epidermal cells. (b) Cell PD in excised whole roots was not detectably different from that found in roots attached to the shoot, and was unchanged for 2 hours from excision. (c) In 1-centimeter sections of root, cell PD at the freshly cut surface was depolarized by 90 millivolts from that in the intact root; cells farther than 1 millimeter from the cut surface were not depolarized. The PD of cells at the cut surface became more negative upon aging the segment in 0.5 mm CaSO(4), eventually becoming greater by -25 millivolts than that in cells of intact roots. Cells in segments to which the root tips were attached had less negative PDs after aging than those in subapical segments, indicating a possible hormonal effect. PDs in aged, excised segments are not equivalent to those in intact roots. (d) Creeping of cytoplasm over electrode tips inserted into the vacuole gave measurements of vacuole-to-cytoplasm PD of + 9 millivolts in 0.5 mm CaSO(4) and + 35 millivolts in 1 mm KCl + 0.5 mm CaSO(4). Most of the cell PD was across the plasmalemma. (e) The reducing sugar content of roots in CaSO(4) solution was greater than that of roots in the nutrient solution in which ion uptake, particularly K(+) occurred.     

Lateral Root Development in Attached and Excised Roots of Zea mays L. Cultivated in the Presence or Absence of Indol-3-yl Acetic Acid

The initiation of lateral root primordia and their subsequentemergence as secondary roots have been examined in attachedand excised roots of Zea mays grown in the presence or absenceof indol-3-yl acetic acid (IAA). Exposure to IAA enhanced anlageinception in both batches of roots. In the attached roots, theIAA-induced stimulation of primordium initiation was followedby a similar increase in lateral emergence. IAA treatment, however,had no effect on the number of laterals produced, per centimetreof root, in the excised primaries. Thus, exposure to IAA didnot directly enhance lateral emergence in the attached rootsnor did it stimulate such emergence in the excised ones. Nocorrelation was found between proliferative activity in themeristem at the apex of the primary or the rate of root elongationon the one hand, and either the number of primordia initiated,or the number of laterals produced, per centimetre of primary,on the other. Zea mays, maize, root, primordium, lateral, indol-3-yl acetic acid, meristematic activity     

Change in Size and Cell Number during the Development of Lateral Root Primordia in Zea mays L.

Increase in cell number, anlage volume and length have beeninvestigated during the overall period of lateral root primordiumdevelopment in excised primaries and in attached roots of Zeamays L. Each of these aspects of anlage growth was found toincrease more or less exponentially during the interval betweenprimordium initiation and subsequent emergence as a lateralin both batches of roots. Values were then determined for celldoubling time (Td), the size of the proliferative fraction (Pf),and for anlage volume (Tv) and length (Tt) doubling times duringthe overall period of primordium development and at intervalsduring this period in both the excised and attached roots. Thepattern of change which took place in Td, Tv, Tl and Pf duringlateral primordium development was found to be similar in bothbatches of roots. However, the overall period of anlage developmentwas shorter in the excised roots than in the attached ones.Moreover, when laterals grew out of the excised roots they didso with fewer cells than comparable laterals emerging from theattached roots. Zea mays L., maize, root primordia, lateral emergence, cell doubling time     

Some Effects of Indol-3-yl Acetic Acid on Lateral Root Development in Attached and Excised Roots of Pisum sativum L.

The effect of continuous exposure to indol-3-yl acetic acid(IAA) on primordium initiation and their subsequent emergenceas lateral roots was determined in excised and attached rootsof Pisum sativum. IAA was found to stimulate the number of primordiainitiated per centimetre of attached or excised primary. Similarly,lateral emergence in terms of the number produced per centimetreof primary was promoted in the presence of IAA. This stimulationof lateral emergence even took place in excised roots whichwere 1 cm in length at the onset of culture and which neverproduced secondary roots over a 6-d culture period when grownin the absence of auxin. These effects of IAA on lateral rootdevelopment have been considered in relation to the concurrentchanges which take place in proliferative activity in the apicalmeristem of the primary root during exposure to auxin. Pisum sativum, garden pea, anlage, primordium, emerged lateral, cell proliferation, indol-3-yl acetic acid     

A Relationship between Phosphate Uptake and Membrane Electrical Potential in Excised Roots of Helianthus annuus

Phosphate uptake by excised roots of sunflower (Helianthus annuus)was determined by the disappearance of phosphate from the externalsolution and by the accumulation of phosphate labelled with³²P. Over a 24 h period it was observed that net phosphate uptakedeclined to zero whilst uptake of ³²P continued unabated. Theelectrical PD of the cortical cell membranes declined in parallelwith net phosphate uptake and it was found that both could berestored by creating a pH gradient across the plasmalemma. Itwas concluded that net phosphate uptake was responsible fora component of the membrane PD of the root cortical cells. Key words: Roots, Phosphate, Membranes     

The Effect of Combined Nitrogen on the Growth and Nodulation of Excised Roots of Phaseolus vulgaris L.

Isolated roots of Phaseolus vulgaris were grown in aseptic cultureusing a modified Raggio technique in which the organic nutrientsare fed to the cut (basal) end of the excised root while theroot tip grows into a mineral-salt solution inoculated withRhizobium. Treatments were applied to investigate the effectsof varying the level of sucrose in the organic medium and ofadding combined nitrogen as nitrate and urea to both media. There was a marked effect of sucrose on the growth and nodulationof the roots. Increasing the concentration increased the numberof nodules both per root and per unit fresh weight of tissue. The growth of the roots was not affected by the level of combinednitrogen. Nitrate in the mineral-salt solution markedly reducednodule numbers but in the agar medium it had only a slight delayingeffect on nodulation. Urea in either the mineral-salt solutionor the organic medium reduced nodule numbers though to a lesserextent than nitrate in the mineral-salt solution. The number of nodules formed was inversely correlated with thelevels of soluble and inorganic nitrogen compounds in the tissues. It is suggested that the adverse effect of combined nitrogenon nodulation is due to the accumulation of unsequestered nitrogencompounds and a depletion of carbohydrates generally withinthe root tissues rather than the local effect of any particularnitrogen compound.     

Unidirectional Ca2+ Fluxes in Roots of Rye (Secale cereale L). A Comparison of Excised Roots with Roots of Intact Plants

The unidirectional Ca²⁺ fluxes across the plasma membrane andtonoplast were determined in both excised roots and roots ofintact seedlings of rye (Secale cereale L. cv. Rheidol). Theunidirectional Ca²⁺ fluxes across the plasma membrane and tonoplastmeasured in excised roots were of a similar order of magnitudeto those determined in roots of intact plants. Influx and effluxof Ca²⁺ across the root plasma membrane were similar (estimatedto be between 0·7 and 3·4 µmol g     

The effect of chloride on nitrate reductase level,on anaerobic nitrite production,and on nitrate content in excisedPisum sativum L. roots

The effect was studied of chloride ions, added in the form of different salts, on nitrate reductase (NR) level in excised pea roots, on anaerobic nitrite production in an assay medium lacking both nitrate and n-propanol, on nitrate content in the roots, and on in vivo NR activity determined in an assay medium containing 5% n-propanol. The presence of Cl in nitrate containing nutrient solutions resulted in lower NR levels, however counterions supplied together with Cl tended to modify slightly this general trend. The negative effect of Cl ions was also apparent, when Cl ions were applied before nitrate ions. Anaerobic nitrite production in the medium lacking both nitrate and n-propanol was not influenced by chloride ions. Nitrate content in the roots was reduced in the presence of chloride both at 3 mM and 15 mM NO₃ in nutrient solutions; however, at 16 mM NO₃, nitrate content in the roots exoeeded even in the presence of 15 mM Cl nitrate content in those root segments which were cultivated in a nutrient solution with 6 mM nitrate, which is the concentration at which NR reaches the level of saturation in excised pea roots. The results obtained suggest that a special induction nitrate pool exists in plant cells besides the storage and metabolic nitrate pools.     

Uptake of Phosphate by White Clover: I. EVIDENCE FOR AN ELECTROGENIC PHOSPHATE PUMP

Uptake of phosphate from flowing solution and cell membraneelectrical potential differences (PD) have been followed simultaneouslyin the roots of Trifolium repens L. Intact plants were usedand it was found that uptake and PD were strongly influencedby the shoot. They were reduced by excision of the root, defoliationof the plant, and lowering the light intensity at the leaf surface.2, 4-Dinitrophenol caused the PD to decline by approximately40 mV. A close correlation between phosphate uptake and PD wasobtained over a wide range of conditions and removal of phosphatefrom the solution resulted in a decline in PD of about 35 mV.It was concluded that there is an electrogenic phosphate pumpin T. repens roots which is closely dependent on the carbohydratesupply from the shoot.     

Root Development and Aerenchyma Formation in Two Wheat Cultivars and One Triticale Cultivar Grown in Stagnant Agar and Aerated Nutrient Solution

Stagnant nutrient solution containing 0.1% agar and with anextremely low oxygen level (‘stagnant agar solution’)was used to simulate the gaseous composition and slow gas diffusionof waterlogged soils. Comparisons were made between the growthof two wheat cultivars(Triticum aestivum,cvs. Gamenya and Kite)and one triticale cultivar(Triticosecale,cv. Muir) grown instagnant relative to aerated solution. For all genotypes tested,immersion of roots in stagnant agar solution resulted in thedeath of the entire seminal root system and led to profuse branchingof the laterals of the nodal roots. In the stagnant agar solutionaerenchyma, as a percentage of the total cross sectional areaof nodal roots, was 18% for Muir, 14% for Kite and 12% for Gamenya;the roots of species with more aerenchyma also attained a longermaximum root length as predicted by the model of Armstrong (in:Woolhouse HW, ed.Advances in botanical research, vol. 7. London:Academic Press, 1979). Muir also had a nodal root/shoot freshweight ratio of 0.5 compared with 0.2–0.3 in Kite andGamenya. The greater number and length of nodal roots of Muirdid not lead to better shoot growth than in the other genotypes;one possible reason for this lack of improvement is a low efficiencyof aerenchymatous roots in wheat.Copyright 1998 Annals of BotanyCompany Root development; aerenchyma; stagnant agar;Triticum aestivumcv. Gamenya;Triticum aestivumcv. Kite;Triticosecalecv. Muir.     

Effect of Auxins (2,4-Dichlorophenoxyacetic acid, Indole-3-Acetic Acid and Naphthaleneacetic Acid) on the Accumulation of {gamma}-Aminobutyric Acid in Excised Rice Root Tips

-Aminobutyric acid (GABA) accumulation occurs in cultured ricecells when ammonium is added to the medium [Kishinami and Ojima(1980) Plant Cell Physiol. 21: 581–589]. Whether thisphenomenon occurs in rice plant tissues was examined with respectto exogenously supplied auxins: 2,4-dichlorophenoxyacetic acid(2,4-D), indole-3-acetic acid (IAA) and naphthalene-acetic acid(NAA). In intact rice plants grown in medium containing ammonium withoutauxin, glutamine first increased, then asparagine graduallyincreased. In both shoots and roots, the asparagine contentbecame the highest among four amino acids after 4 days of cultureperiod. GABA did not increase at all, its level remaining lowin both shoots and roots throughout the culture period. GABA accumulation was observed in excised rice root tips whenthey were incubated in the medium containing ammonium in thepresence of 2,4-D, IAA or NAA. In the absence of auxin, however,excised rice root tips accumulated asparagine and glutamine,but not GABA. Rice root segments obtained from a region in whichroot cells had already developed to maturity did not accumulateGABA but asparagine and glutamine in the presence of both ammoniumand 2,4-D. These results suggest that GABA accumulation occurs in rapidlygrowing and dividing tissue, such as the apical meristem ofrice root in the presence of auxin during ammonium assimilation. (Received June 15, 1987; Accepted March 14, 1988)     

Effect of removal of the root tip on the development of enhanced rb absorption by corn roots

Samples of primary root tissue of corn (Zea mays L.) were aged either in CaSO(4) solution or in humid air, after which they were immersed for 10 minutes in a solution containing 0.1 mm(86)RbCl. Aging in solution, but not in humid air, enhanced the subsequent rate of Rb(+) absorption. Excision of roots before aging was followed by greater enhancement than when exicision followed aging. The time course of aging of 1-cm segments from different portions of the root showed decreasing response with increasing distance from the root cap. The aging response of apical segments (5-15 mm from the root cap) could be detected within 10 minutes and usually reached a maximum within 2 hours. Rb(+) absorption by apical segments (5-15 mm) aged without the tip (0-5 mm) was more than double that by apical segments whose tips were left attached until the end of the aging period. When apical segments without the tip were aged for 2 hours in the CaSO(4) solution in which seedlings had previously been grown for 24 hours, the rate of absorption was only 63% of samples aged in fresh solution. When apical segments were aged for 2 hours in fresh solution containing excised tips floating free in the solution, the rate of Rb(+) absorption was 20% less than in samples aged in solution containing no excised tips. The data presented in this study are interpreted to indicate that a water-soluble metabolite, originating in the root tip and translocated basipetally, inhibits Rb accumulation.     

Waterlogging Tolerance Among a Diverse Range of Trifolium Accessions is Related to Root Porosity, Lateral Root Formation and 'Aerotropic Rooting'

Waterlogging tolerance, root porosity and root anatomy wereevaluated for 20 Trifolium accessions (species and sub-species,all annuals) selected from the eight Sections of the genus.Nine accessions were sensitive [relative growth rate (RGR) reducedby up to 80%] to waterlogging, nine accessions were tolerant(RGR not reduced), and in two accessions RGR increased (up to1.9-fold), when compared to drained controls. Growth of themain (i.e. tap) root axis was severely reduced in all accessionswhen waterlogged. Lateral roots formed the bulk of the rootsystem of tolerant accessions when grown in waterlogged soil.Lengths of the longest lateral roots were up to three-timeslonger than the main root axis. Root porosity varied from 0.7–12%among accessions when grown in aerated solution and from 1.1–15.5%in plants grown in hypoxic (0.031–0.045 mol O₂m^-3) solution.In some accessions aerenchyma formed by cell lysigeny; in othersit formed by schizogenous cell separation, or a combinationof both processes. O₂consumption rates of expanded lateral roottissues varied by up to 1.7-fold (on a mass basis) among thesix accessions tested and was reduced by an average of 24% forroots of plants grown in hypoxic solution prior to measurements.Accessions with the highest root porosity tended to have longerroots when grown in waterlogged soil. Three accessions formed‘aerotropic roots’ and the lateral root lengthsof these plants exceeded those of all other accessions, suggestingenhanced O₂movement to the submerged lateral root axis via theaerotropic roots. Waterlogging-tolerant accessions were identifiedin seven of the eight Sections in Trifolium, and the tolerantaccessions tended to be those with extensive lateral root systemsof relatively high porosity. Copyright 2001 Annals of BotanyCompany Waterlogging, Trifolium, aerenchyma, hypoxia, flooding, root respiration, clover, root anatomy, root porosity, pasture, aerotropic roots     

The regulation of K+ influx into roots of rye (Secale cereale L.) seedlings by negative feedback via the K+ flux from shoot to root in the phloem

The uptake of K⁺ by plant roots is matched to the demand forK⁺ for growth. The growing shoot must communicate its K⁺ requirementto the root. It has been suggested that this might be effectedby varying the amount of K⁺ retranslocated from the shoot tothe root via the phloem. It is predicted that less K⁺ is returnedto the roots in K⁺-deficient plants and that this promotes compensatoryK⁺ uptake from the external medium. These experiments addressthis hypothesis. Rye (Secale cereale L.) was grown hydroponically in completenutrient solutions containing either 100 aM or 400 µMK⁺. Plant development, shoot fresh weight (FW) and plant drymatter accumulation did not differ between seedlings grown atthese K⁺ concentrations. However, root FW was lower in seedlingsgrown in solutions containing 100 µM K⁺, which resultedin a greater shoot/root FW ratio. Seedlings from both treatmentshad similar shoot K⁺ concentrations, but the root K⁺ concentrationof seedlings grown In solutions containing 100 µM K⁺ wasless than their counterparts grown at 400 µM K⁺. When assayed at the same K⁺ concentration, unidirectional K⁺(⁸⁶Rb⁺) influx into 14-d-old seedlings grown with 100 µMK⁺ in the nutrient solution was greater than that into seedlingsgrown with 400 µM K⁺ in the nutrient solution, indicatingan increased K⁺ influx capacity in the former. Furthermore,K⁺ (⁸⁶Rb⁺) influx into seedlings grown and assayed at 100 µMK⁺ was greater than that into seedlings grown and assayed at400 µM K⁺. Since net K⁺ uptake was lower in the seedlingsgrown at 100 µM K⁺, this indicates a greater unidirectionalK⁺ efflux from roots in solutions containing 100 µM K⁺. An empirical model, based on the immobility of calcium in thephloem, was used to describe quantitatively K⁺ fluxes in seedlings14 d after sowing. As primary data, the composition of xylemsap and the accumulation of elements in root and shoot tissueswere determined. Xylem sap was collected either as root-pressureexudate or from excised roots immersed in nutrient solutionand subjected to a pneumatic pressure of 0.4 MPa. The K:Ca ratioin these saps differed, and led to contrasting conclusions concerningthe effect of K⁺ nutrition on the recirculation of K⁺. Basedon the K:Ca ratio in the sap obtained following the applicationof pneumatic pressure, which is thought to resemble that ofintact transpiring plants, it was calculated that the K⁺ fluxfrom the shoot to the root was higher in seedlings maintainedin solutions containing higher K⁺ concentrations. This suggeststhat a negative feedback mechanism based on K⁺ recirculationfrom the shoot to the root via the phloem could be a primarysignal decreasing K⁺ influx. Key words: K⁺ influx, K⁺ recirculation, regulation, root, rye, Secale cereale L     

Gas and Liquids in Intercellular Spaces of Maize Roots

Oils are spontaneously absorbed by gas-filled intercellularspaces (IS) in maize root cortex. The network of these spacesin living root sections was imaged by confocal laser scanningmicroscopy using a fluorescent solution of Nile red in oil.The gas volume fraction (GVF) of root segments was quantifiedby the increase in weight (differentiated zones) or tissue density(2–3 mm root tips) due to complete vacuum infiltration.Cooling to 6 °C or inhibition of oxidative phosphorylationdiminished the GVF of root tips but did not significantly affectthe GVF of differentiated root zones. The threshold pressuredifference for measurable infiltration of isolated root segmentsis lower (10 to 15  kPa) than the threshold for infiltrationof comparable zones of attached roots or of detached roots withthe cut surface sealed (>60 kPa). In the absence of an opencut, pressure-driven infiltration of the root cortex is acceleratedby microscopic fissures within the epidermal/hypodermal barrier.The GVF of the root cortex was reduced after transferring rootsfrom sugar solutions (0.1 to 0.3M ) to water. This points toefficient water transport from the medium to sugar-containingcortical cell walls through epidermal and hypodermal protoplasts.When 2-cm-long primary roots were vacuum infiltrated in situand then allowed to grow on aerated mineral medium for a further5 d, cortical IS of the originally infiltrated root bases remainedfilled with liquid but the subsequently grown apical root zoneshad a normal GVF. Copyright 1999 Annals of Botany Company Apoplastic and protoplasmic route, maize, infiltration, intercellular spaces, oil absorption, confocal laser scanning microscope, water transport, Zea mays L.     

Errors in the Measurement of Root Pressure and Exudation Volume Flow Rate Caused by Damage during the Transfer of Unsupported Roots between Solutions

Plants of Zea mays were grown with their roots confined to growing tubes, consisting of cylindrical or spherical glass tubes fitted at the bottom with a stopcock. Nutrient solution was circulated past the roots, and when a plant was 21 to 25 days old, the stopcock was closed, the root excised from the plant and connected to an apparatus which measured root pressure and exudation volume flow rate. The stopcock was opened and solution was again circulated through the growing tube without dropping the level of the liquid bathing the root in the process. Measurements of pressure and flow rate were made continuously during a period in which the solution was replaced, first by draining and refilling the tube in situ, and second by replacing the growing tube with a beaker of solution. Both these manipulations caused at least temporary and frequently permanent drops in root pressure and flow rate. Plants were also grown in cylindrical tubes with a support medium of either glass beads or Raschig rings which filled the growing tubes. It is shown that the solution bathing these roots could be repeatedly replaced by draining and refilling with no visible effect on the measurements. It is recommended, therefore, that in future, support be provided for the roots of all experimental plants grown by solution culture.     

Relationship Between Root Morphogenesis and Period of Predominant Cell Arrest in Intact and Aseptically-cultured Roots of Helianthus annuus L.

Root morphogenesis and cell cycle kinetics of intact and aseptically-grownexcised roots of Helianthus annuus L. were studied. Intact rootsshow predominant cell arrest in G1 with an absence of polyploidcells coincident with secondary vascularization. Exposure ofthe cut ends of aseptically grown excised roots to known concentrationsof indol-3-yl acetic acid, benzyladenine, and myo-inositol for8 weeks initiated the production of secondary vascular tissuesand predominant cell arrest in G2 concommitant with poiyploidization.Excised roots grown in the absence of these substances producedroots with only primary vascularization and predominant cellarrest in G1 coincident with an absence of polyploidization.These results indicate that (a) root cells of H. annuus havethe ability to undergo polyploidization that may be inducedby exogeneously applied chemicals, (b) a general relationshipbetween predominant cell arrest in G1 coincident with the absenceof secondary vascularization does not hold true and (c) althoughsecondary vascularization occurs in cultured roots exposed toall three additives similar to secondary vascularization inintact roots, the two roots should not be considered identicalin all respects. Helianthus annus L., sunflower, root, morphogenesis, cell cycle kinetics, polyploidy, cell differentiation, vascularization     

The Possible Involvement of Root-cap Mucilage in Gravitropism and Calcium Movement Across Root Tips of Allium cepa L

Roots of Allium cepa L. grown in aerated water elongate rapidly,but are not graviresponsive. These roots (1) possess extensivecolumella tissues comprised of cells containing numerous sedimentedamyloplasts, (2) lack mucilage on their tips, and (3) are characterizedby a weakly polar movement of calcium (Ca) across their tips.Placing roots in humid air correlates positively with the (1)onset of gravicurvature, (2) appearance of mucilage on tipsof the roots, and (3) onset of the ability to transport Ca polarlyto the lower side of the root tip. Gravicurvature of roots previouslysubmerged in aerated water is more rapid when roots are orientedvertically for 1–2 h in humid air prior to being orientedhorizontally. The more rapid gravicurvature of these roots correlatespositively with the accumulation of mucilage at the tips ofroots during the time the roots are oriented vertically. Therefore,the onset of gravicurvature and the ability of roots to transportCa to the lower sides of their tips correlate positively withthe presence of mucilage at their tips. These results suggestthat mucilage may be important for the transport of Ca acrossroot caps. Allium cepa, root gravitropism, root mucilage, calcium, onion     

High pH Causes Disintegration of the Root Surface in Lupinus angustifolius L.

The effect of high pH on the morphology and anatomy of the rootsof lupin (Lupinus angustifolius L. cv. Yandee) and pea (Pisumsativum L. cv. Dundale) was examined in buffered solution. Themorphology and anatomy of lupin roots were markedly altered,and root growth was reduced by increasing solution pH from 5·2to 7·5, whereas pea roots were unaffected. In lupin roots,pH 7·5 caused disintegration of the root surface andimpaired root hair formation. Lupin roots grown at pH 7·5also had decreased cell lengths but increased cell diameterin both the epidermis and the cortex in comparison to rootsgrown at pH 5·2. High pH reduced cell volume greatlyin the epidermis, to a lesser extent in the outer cortex andnot at all in the inner cortex. It appears that in lupins, theprimary detrimental effects of growth at pH 7·5 is reducedlongitudinal growth of cells near the root surface with a consequentreduction in elongation of the cells in inner cortex.Copyright1993, 1999 Academic Press Lupinus angustifolius L., Pisum sativum L., high pH, root morphology, root anatomy     

Localization and Kinetic Properties of {beta}-Glycerophosphatase in Barley Roots

The study of ß-glycerophosphatase activity in cell-wallpreparations and in excised root tips from barley seedlingssupports the view that the former, which constitutes about 20per cent of the activity of the whole homogenate, representsthe fraction located at the surface of the roots in vivo. Theactivities of the cell-wall suspension and intact roots arevirtually identical, and further show identical relations topH, substrate concentration (K_m), and competitive inhibitionby molybdate and inorganic phosphate (K_i). The enzyme must thereforebe freely exposed to the external solution without any permeabilitybarrier separating it from either substrate or inhibitors. Theabsence of any lag phase in the hydrolysis in excised root tipssuggests that the surface enzyme may be limited to the outermostlayers of the root. The solubilization of some of the activityof the cell-wall preparation by treatment with sodium chlorideand ammonium sulphate suggest that surface activity may havebeen lost from these preparations rather than adsorbed duringhomogenization and extraction. The K_m and pH-activity curveof the supernatant activity remaining after centrifugation ofthe cell-wall fraction indicate that only this enzyme and noother detectable glycerophosphatase exists in the roots.