The Role of Potassium in the Control of Turgor Pressure in a Gas-Vacuolate Blue-Green Alga

The contribution of K⁺ accumulation to cell turgor pressurewas investigated in the gas-vacuolate blue-green alga Anabaenaflos-aquae. The cell turgor pressure, measured by the gas vesiclemethod, drops in cells suspended in culture medium depletedof K⁺ but rapidly rises again, by 100 kPa or more, when K⁺ isresupplied. A similar though rather slower rise in turgor pressureis supported by an equivalent concentration of Rb⁺. The internalK⁺ concentration rose from 66 to 91 mM when K⁺ was suppliedat an external concentration of 0.4 mM. This rise was light-dependent.Greater increases in internal K⁺ concentration and turgor pressureoccurred when K⁺ was supplied at a higher concentration, 3.6mM. In both cases over 60% of the observed turgor pressure risecould be accounted for by accumulation of K⁺. The turgor pressurerise supported by light-stimulated K⁺ uptake can cause collapseof enough of the alga's gas vesicles to destroy its buoyancy.The effect of K⁺ availability on buoyancy regulation by planktonicblue-green algae is discussed.     

Lamprothamnium, a Euryhaline Charophyte: IV. MEMBRANE POTENTIAL, IONIC FLUXES AND METABOLIC ACTIVITY DURING TURGOR ADJUSTMENT

The early time-course of turgor adjustment following a hyper-or hypo-osomotic shock was examined in the brackish-water charophyteLamprothamnium papulosum. The response to a reduction in turgorwas a five to seven-fold stimulation of the influxes of Cl^–,K⁺ and Na⁺. The distribution of radioactive tracers in the cellsuggested that the ionic composition of the cytoplasm was strictlycontrolled during turgor adjustment. Metabolic activity wasrelatively unaffected by the loss of turgor. high fluxes throughthe cytoplasm, and a cytoplasmic K^– concentration possiblyas high as 280 mol m^–3. Osmotic adjustment to a lower salinity was achieved by largeincreases in the passive effluxes of K⁺ and Cl^– ratherthan by decreases in their influxes. The membrane remained hyperpolarized during hyperosmotic adjustmentbut depolarized after a hypo-osmotic change. This result isdiscussed in relation to changes in the driving forces for ionmovements during osmotic transitions. Key words: Lamprothamnium, Turgor, Osmotic stress     

Red and blue light-stimulated proton efflux by epidermal leaf cells of the Argenteum mutant of Pisum sativum

Light stimulates leaf expansion in dicotyledons by increasingapoplastic acidification, cell wall loosening and solute accumulationfor turgor maintenance. Red and blue light enhance growth viadifferent photo-systems, but the cellular location and modesof action of these systems is not known. Here, the effect of red and blue light was studied on transportprocesses in epidermal cells of expanding leaves of the Argenteummutant of Pisum satlvum. Both red and blue light caused extraceiiuiaracidification by isolated epidermal tissue, which was stimulatedby extracellular K⁺ and inhibited by DCCD at 0.1 mol m^–3.Acidification induced by red compared with blue light showeddifferent saturating kinetics in fluence rate-response curves.Under near saturating light conditions the effects of red andblue light were additive. The red light-induced acidificationwas inhibited by far-red light while the blue light-inducedacidification was not. Light caused a hyperpoianzation of themembrane potential in epidermal strips, and stimulated ⁸⁶Rb⁺uptake by epidermal protoplasts. These results show that phytochromeand an additional blue light-photoreceptor function in isolatedepidermal cells to promote proton efflux, hyperpolarization,and cation uptake. Key words: Pisum sativum, light-induced acidification, ion transport, epidermis, photoreceptor     

The Effects of Temperature on 86Rb Uptake by Two Species of Chlamydomonas (Chlorophyta, Chlorophyceae)

⁸⁶Rb uptake was examined in two species of unicellular greenalgae, Chlamydomonas nivalis isolated from snow, and a cellwall-less mutant of the temperate freshwater Chlamydomonas reinhardii.In C. reinhardii cells grown at 20°C and cooled rapidlyto 0°C, ⁸⁶Rb uptake was abolished. Cells cooled rapidlyto –5°C in the absence of ice accumulated ⁸⁶Rb veryrapidly but the time course of this uptake suggested non-selectiveaccumulation through a damaged plasmalemma. Cells grown at 8°Cwere viable, able to divide and motile; they showed no signsof cold-shock and ⁸⁶Rb uptake, albeit slow, was measurable at–5°C in the absence of extracellular ice. Cells ofC. nivalis grown at 20°C were damaged at sub-zero temperaturesalthough they did show an enhanced ⁸⁶Rb uptake at 0°C. Cellsgrown at 5°C were able to accumulate ⁸⁶Rb from media undercooledto -5°C in the absence of extracellular ice, and again showedenhanced uptake at 0°C. The process of acclimation to lowtemperature appears to differ in the two species. Key words: Chlamydomonas, temperature, ⁸⁶Rb uptake, membrane     

Effects of External Ca2+ on K+ Permeability of the Elongating Region of Mung Bean Roots under High KCl Stress

Simultaneous measurements of the extracellular potential andthe K⁺(⁸⁶Rb) efflux, and of the intracellular and extracellularpotentials of the cortical cells were used to study the effectsof external Ca²⁺ on the plasma membrane K⁺(⁸⁶Rb) permeabilityin two-day-old mung bean (Vigna mungo L. Hepper, ‘Blackmatpe’) roots under high KCl stress. The K⁺ efflux wasenhanced by a high KCl solution (>7.5 mM), and addition of0.5 mM Ca²⁺ could suppress this efflux. The removal of membrane-associatedCa⁺ from the root surface with EDTA led to a recovery of theK⁺ efflux along with a marked decrease in the extracellularpotential. (Received November 19, 1986; Accepted March 6, 1987)     

Membrane Potentials in Excitable Cells of Aldrovanda vesiculosa Trap-Lobes

The resting membrane potential in excitable cells of Aldrovandatrap-lobes is composed of diffusion and electrogenic potentials.The diffusion potential, about –100 mV in artificial pondwater, was determined from the external K⁺ and Na⁺ concentrations.The permeability ratio, P_Na/P_K of the membrane was estimatedto be about 0.3. The electrogenic potential hyperpolarized themembrane to about –140 mV. The peak value of the actionpotential increased by +26 mV with a tenfold increase in theexternal Ca²⁺ concentration. The action potential was blockedby an application of the Ca²⁺ chelater or the Ca channel blocker,LaCl₃. Cells showed additional Ca²⁺ influx (7.8 pmole/cm² impulse)during membrane excitation. These facts suggest that the transientincrease in Ca²⁺ influx causes the action potential presentin cells of Aldrovanda trap-lobes. ¹ Present address: Jerry Lewis Neuromuscular Research Center,School of Medicine, University of California Los Angeles, LosAngeles, CA90024, U.S.A. ² Present address: Biological Laboratory, Kyoritsu Women's University,Hachioji 193, Japan. (Received September 21, 1983; Accepted September 7, 1984)     

Oxidative Damages and Repair in Euglena gracilis Exposed to Ozone II. Membrane Permeability and Uptake of Metabolites

Significant injuries to the plasma membrane were detected inEuglena gracilis cells during ozone exposure (240 µ1.liter¹,delivery rate of l µmol.min^–1), as assessed by measuringthe alterations of vitamin B₁₂ and acetate uptakes and the leakageof intracellular K⁺ (Rb⁺). A rapid decrease in the uptake ofvitamin B₁₂ and acetate was observed within 15 min of treatment,indicating that both transport systems are very sensitive toO₃. On the other hand, the leakage of intracellular K⁺ ions,as measured by the efflux of ⁸⁶Rb⁺ from prelabelled cells, couldonly be detected after 30 min of O₃ exposure. These resultssuggest that the initial metabolic symptoms of injury is atthe level of the two transport systems examined and that thealteration of the membrane permeability to K⁺ ions appears asa second step in the cascade of oxidative events at the plasmamembrane level. When Euglena cells were allowed to recover underautotrophic growth conditions following O₃ treatment, vitaminB₁₂ and ⁸⁶Rb⁺ (K⁺) ions uptakes returned gradually to controllevel within 5 h of the recovery period. Acetate uptake returnedto control level at a slower rate and needed 20 h for completerecovery. These results indicate that the cells were able toactively repair most of the initial oxidative damages inducedby O₃. The metabolic significance of the repair mechanism(s)is discussed. (Received December 25, 1989; Accepted July 23, 1990)     

Measurement of Changes in Cytosolic Ca2+ in Arabidopsis Guard Cells and Mesophyll Cells in Response to Blue Light

Phototropins (phot1 and phot2) are blue light (BL) receptorsthat mediate responses including phototropism, chloroplast movementand stomatal opening, and increased cytosolic Ca²⁺. BL absorbedby phototropins activates plasma membrane H⁺-ATPase in guardcells, resulting in membrane hyperpolarization, and drives K⁺uptake and stomatal opening. However, it is unclear whetherthe phototropin-mediated Ca²⁺ increase activates the H⁺-ATPase.Here, we determined cytosolic Ca²⁺ concentrations in guard cellprotoplasts (GCPs) from Arabidopsis transformed with aequorin.Cytosolic Ca²⁺ increased rapidly in response to BL in GCPs fromboth the wild type and phot1 phot2 double mutants, but was mostlysuppressed by an inhibitor of photosynthetic electron flow (DCMU).With depleted external K⁺, we observed another slower Ca²⁺ increase,which was phototropin- dependent. Fusicoccin, a H⁺-ATPase activator,mimicked the effect of BL. The slow Ca²⁺ increase thus appearsto result from membrane hyperpolarization. The slow Ca²⁺ increasewas suppressed by external K⁺ and was restored by blockers ofinward-rectifying K⁺ channels, CsCl and tetraethylammonium,suggesting the preferential uptake of K⁺ over Ca²⁺. Such efficientK⁺ uptake in response to BL was not found in mesophyll cells.Both the fast and the slow Ca²⁺ increases were inhibited byCa²⁺ channel blockers (CoCl₂ and LaCl₃) and a chelating agent(EGTA). These results indicate that the phototropin-mediatedCa²⁺ increase was not observed prior to H⁺-ATPase activationin guard cells and that Ca²⁺ entered guard cells via Ca²⁺ channelsthrough photosynthesis and phototropin-mediated membrane hyperpolarization.     

Functional characterization of the neuronal-specific K-Cl cotransporter: implications for [K+]o regulation

The neuronal K-Cl cotransporter isoform (KCC2) was functionallyexpressed in human embryonic kidney (HEK-293) cell lines. Two stablytransfected HEK-293 cell lines were prepared: one expressing anepitope-tagged KCC2 (KCC2-22T) and another expressing theunaltered KCC2 (KCC2-9). The KCC2-22T cells produced aglycoprotein of ~150 kDa that was absent from HEK-293 control cells.The ⁸⁶Rb influx in both cell lineswas significantly greater than untransfected control HEK-293 cells. TheKCC2-9 cells displayed a constitutively active⁸⁶Rb influx that could beincreased further by 1 mMN-ethylmaleimide (NEM) but not by cellswelling. Both furosemide [inhibition constant (K_i) ~25µM] and bumetanide (K_i~55 µM) inhibited the NEM-stimulated ⁸⁶Rb influx in the KCC2-9cells. This diuretic-sensitive⁸⁶Rb influx in theKCC2-9 cells, operationally defined as KCC2 mediated, required external Clbut not external Na⁺ and exhibiteda high apparent affinity for externalRb⁺(K⁺)[Michaelis constant(K_m) = 5.2 ± 0.9 (SE) mM; n = 5] but alow apparent affinity for externalCl(K_m >50 mM). Onthe basis of thermodynamic considerations as well as the unique kineticproperties of the KCC2 isoform, it is hypothesized that KCC2 may servea dual function in neurons: 1) themaintenance of low intracellularCl concentration so as toallow Cl influx vialigand-gated Cl channelsand 2) the buffering of externalK⁺ concentration([K⁺]_o) in the brain.

     

Organic Acid Changes in the Epidermis of Vicia faba and Their Implication in Stomatal Movement

Considerable evidence indicates that the increase in guard cell turgor resulting in stomatal opening is brought about by active K⁺ uptake into guard cells. Only a small increase in inorganic anions appears to accompany the increase in K⁺. A plausible explanation is that organic acids are produced within guard cells and act as counterions, whereas the H⁺ produced are exchanged for K⁺.     

Ouabain stimulates protein kinase B (Akt) phosphorylation in opossum kidney proximal tubule cells through an ERK-dependent pathway

Endogenous cardiotonic glycosides bind to the inhibitory binding site of the plasma membrane sodium pump (Na⁺/K⁺-ATPase). Plasma levels of endogenous cardiotonic glycosides increase in several disease states, such as essential hypertension and uremia. Low concentrations of ouabain, which do not inhibit Na⁺/K⁺-ATPase, induce cell proliferation. The mechanisms of ouabain-mediated response remain unclear. Recently, we demonstrated that in opossum kidney (OK) proximal tubular cells, low concentrations of ouabain induce cell proliferation through phosphorylation of protein kinase B (Akt) in a calcium-dependent manner. In the present study, we identified ERK as an upstream kinase regulating Akt activation in ouabain-stimulated cells. Furthermore, we provide evidence that low concentrations of ouabain stimulate Na⁺/K⁺-ATPase-mediated ⁸⁶Rb uptake in an Akt-, ERK-, and Src kinase-dependent manner. Ouabain-mediated ERK phosphorylation was inhibited by blockade of intracellular calcium release, calcium entry, tyrosine kinases, and phospholipase C. Pharmacological inhibition of phosphoinositide-3 kinase and Akt failed to inhibit ouabain-stimulated ERK phosphorylation. Ouabain-mediated Akt phosphorylation was inhibited by U0126, a MEK/ERK inhibitor, suggesting that ouabain-mediated Akt phosphorylation is dependent on ERK. In an in vitro kinase assay, active recombinant ERK phosphorylated recombinant Akt on Ser⁴⁷³. Moreover, transient transfection with constitutively active MEK1, an upstream regulator of ERK, increased Akt phosphorylation and activation, whereas overexpression of constitutively active Akt failed to stimulate ERK phosphorylation. Ouabain at low concentrations also promoted cell proliferation in an ERK-dependent manner. These findings suggest that ouabain-stimulated ERK phosphorylation is required for Akt phosphorylation on Ser⁴⁷³, cell proliferation, and stimulation of Na⁺/K⁺-ATPase-mediated ⁸⁶Rb uptake in OK cells. opossum kidney cells; sodium/potassium adenosine triphosphatase; extracellular signal-regulated kinase; cell proliferation     

Patch-Clamp Study on a Ca2+-Regulated K+ Channel in the Tonoplast of the Brackish Characeae Lamprothamnium succinctum

Cytoplasmic drops were prepared from internodal cells of thebrackish Characeae Lamprothamnium succinctum. Applying the patch-clamptechnique to single drops covered with tonoplast, we demonstratedthe presence of Ca²⁺-regulated K⁺ channels in the tonoplast.In a cell-attached mode, the selectivity of such channels forK⁺ was about 50 times that for Na⁺. This channel showed a tendencyto rectify in an outward direction. In the negative region ofthe pipette voltage, the conductance of this channel was 50pS, while it was 100 pS in the positive voltage region. Whenthe pipette voltage was increased above 50 mV, two conductancelevels were found in the cell-attached mode as well as in theexcised patch (cytoplasmic-side-out patch), which was obtainedby pulling the patch pipette from the cytoplasmic drop underconditions of low levels of Ca²⁺. Using the excised patch, wecontrolled the level of Ca²⁺ on the cytoplasmic side of thechannels. At a low level of Ca²⁺ (pCa=8) on the cytoplasmicside, the open frequency was very low and the opening time wasshort. An increase in Ca²⁺ on the cytoplasmic side (pCa = 5)increased both the frequency and the duration of opening. However,the conductance of the channels did not change. This regulationby Ca²⁺ of the K⁺ channels was reversible, that is, additionof EGTA on the cytoplasmic side inactivated the channels. Thepresent study demonstrates a direct action of Ca²⁺ on the K⁺channels. The physiological role of the K⁺ channel in the regulationof turgor in Lamprothamnium is discussed. (Received January 9, 1989; Accepted March 8, 1989)     

Effect of Sodium on Phosphate Uptake in Unicellular and Filamentous Cyanobacteria

The effect of Na⁺ on phosphate uptake was studied in four strainsof cyanobacteria: Synechococcus PCC 7942, Gloeothece PCC 6501,Phormidium sp. and Chlorogloeopsis PCC 6912. Phosphate uptakewas stimulated by Na⁺ in all cases. Li⁺ and K⁺ acted as partialanalogues for Na⁺. Half-saturation [K_1/2(Na⁺)] of phosphateuptake was reached with Na⁺ concentrations ranging from 317µM in Chlorogloeopsis to 659 µM in Phormidium. Theconcentration of phosphate required to reach half-saturationof phosphate uptake [K_1/2(P_i)]was not changed by the presenceof Na⁺. (Received April 11, 1994; Accepted July 5, 1994)     

Lamprothamnium, a Euryhaline Charophyte: I. OSMOTIC RELATIONS AND MEMBRANE POTENTIAL AT STEADY STATE

The charophyte Lamprothamnium papulosum (Wallr.) J. Gr. is foundat salinities varying from nearly fresh water to twice thatof sea water. It can maintain its turgor constant at 302 mosmolkg^–1 (0.73 MPa) when exposed to external osmotic pressuresof 550 to 1350 mosmol kg^–1 (1.3–3.3 MPa). Turgorshows a tendency to rise slightly at lower osmotic pressure(388 mosmol kg^–1 of turgor at 150 mosmol kg^–1 externalosmolality). K⁺ and Cl^– are the main solutes in the vacuole,and are most important in controlling internal osmotic pressure.Mg²⁺, Ca²⁺, and SO^2–₄ are present in significant amountsbut their concentrations do not change with changes in externalsalinity. Na⁺ is present in lower concentration than K⁺, andplays a minor role in regulating turgor. Sucrose is presentin significant concentrations, but changes little with changesin salinity. Two enzymes involved in sucrose metabolism, sucrosephosphate synthetase (EC 2.4.1.14 [EC] ), and sucrose synthetase (EC2.4.1.13 [EC] ) are active in whole cell extracts of Lamprothamnium.As in the fresh water charophytes, Lamprothamnium membrane potentialmay be depolarized (close to E_K) or hyperpolarized, and presumablyof electrogenic origin. Both types of potential are found atall salinities tested.     

Change in potassium distribution in a Phaseolus pulvinus during circadian movement of the leaf

Phaseolus moves its leaves upward and downward with circadianperiod. This movement of the leaf results from the differentialchange in the turgor on opposite sides of the pulvinus. Concentrations of K⁺, Na⁺, Mg⁺⁺, and Ca⁺⁺ in the upper and lowerhalves of the pulvinus and the water content of cells on bothsides of it were analyzed in relation to the deformation ofthe pulvinus. The results showed that (1) the pulvinus was deformedby expansion and contraction of the cells on its opposite sides;(2) among the four cations, the K⁺ concentration was markedlyhigh in both halves of the pulvinus; (3) the osmotic pressureof the upper and lower halves were nearly equal during the rhythmicdeformation of the pulvinus; (4) the expansion and contractionof the cells on the opposite sides of the pulvinus have a positivecorrelation only with a change in the K+ concentration expressedin terms of µmoles per mg protein; (5) the concentrationsof other cations such as Na⁺, Mg⁺⁺, Ca⁺⁺, expressed in termsof µmoles per mg protein, did not change during the circadiandeformation of the pulvinus. Thus, the rhythmic K⁺ movementseems to be the basis for pulvinar turgor movements. With respectto the mechanism of K⁺ movement, three possibilities are discussed. (Received November 7, 1975; )     

86Rb Influx in Maize Roots at Different External Concentrations of RbCl or KCl

Studies on ⁸⁶Rb influx in root segments of maize at differentexternal concentrations of KC1 or RbCl showed that there wasa preference for K⁺ over Rb⁺ at relatively low external concentrationsor when Fusicoccin was present. Experimental evidence supportsthe hypothesis that discrimination takes place when the ionuptake is energy-dependent. (Received September 6, 1982; Accepted December 7, 1982)     

The high affinity K+ transporter AtHAK5 plays a physiological role in planta at very low K+ concentrations and provides a caesium uptake pathway in Arabidopsis

Caesium (Cs⁺) is a potentially toxic mineral element that isreleased into the environment and taken up by plants. AlthoughCs⁺ is chemically similar to potassium (K⁺), and much is knownabout K⁺ transport mechanisms, it is not clear through whichK⁺ transport mechanisms Cs⁺ is taken up by plant roots. In thisstudy, the role of AtHAK5 in high affinity K⁺ and Cs⁺ uptakewas characterized. It is demonstrated that AtHAK5 is localizedto the plasma membrane under conditions of K⁺ deprivation, whenit is expressed. Growth analysis showed that AtHAK5 plays arole during severe K⁺ deprivation. Under K⁺-deficient conditionsin the presence of Cs⁺, Arabidopsis seedlings lacking AtHAK5had increased inhibition of root growth and lower Cs⁺ accumulation,and significantly higher leaf chlorophyll concentrations thanwild type. These data indicate that, in addition to transportingK⁺ in planta, AtHAK5 also transports Cs⁺. Further experimentsshowed that AtHAK5 mediated Cs⁺ uptake into yeast cells andthat, although the K⁺ deficiency-induced expression of AtHAK5was inhibited by low concentrations of NH     

Osmotic and ionic regulation in Nitella

When the osmotic value of an internodal cell of Nitella flexiliswas modified by the method of transcellular osmosis, the normalosmotic value was chiefly restored by the release or absorptionof K⁺. The release or uptake of Na⁺ was observed only when themodification of osmotic value was significant. Both the uptakeand release of K⁺ were linearly dependent on the degree of modificationof the osmotic value. The effectiveness of alkali metal cationsin restoring the osmotic value in cells of lower osmotic valueswas in the order K⁺>Rb⁺>Na⁺, Cs⁺>Li⁺. The absorptionof K⁺ by cells of lower osmotic values depended strongly ontemperature, while the release of K⁺ from cells of higher osmoticvalues did not. To clarify whether the Nitella cell regulates the osmotic valueor regulates the concentration of K⁺ in the vacuole, the cellsap was exchanged for artificial cell saps whose osmotic valuesand ionic concentrations were varied independent of each other.It was shown that in Nitella two regulating mechanisms are operating,one which regulates the osmotic value of the cell sap irrespectiveof the level of vacuolar K⁺ (0.1–140 mM) and another whichregulates the vacuolar K⁺-level when it is abnormaly high (>160mM). Both mechanisms are assumed to operate in order to keepthe concentration of K⁺ in the cytoplasm at a constant level.The presence of Na⁺ (0–100 mM) and Ca²⁺ (5–40 mM)did not affect the movement of K⁺ during osmoregulation. ¹Present address: Sanki Engineering Limited, Nagaokakyo, Kyoto,Japan. (Received December 19, 1973; )     

Red blood cells do not contribute to removal of K+ released from exhaustively working forearm muscle

K⁺ released from exercisingmuscle via K⁺ channels needs to beremoved from the interstitium into the blood to maintain high musclecell membrane potential and allow normal muscle contractility. Uptakeby red blood cells has been discussed as one mechanism that would alsoserve to regulate red blood cell volume, which was found to be constantdespite increased plasma osmolality and K⁺ concentration([K⁺_pl]). We evaluatedexercise-related changes in[K⁺_pl], pH, osmolality, meancellular Hb concentration, cell water, and red blood cellK⁺ concentration during exhaustivehandgrip exercise. Unidirectional ⁸⁶Rb⁺(K⁺) uptake by red blood cellswas measured in media with elevated extracellularK⁺, osmolarity, andcatecholamines to simulate particularly those exercise-related changesin plasma composition that are known to stimulateK⁺ uptake. During exercise[K⁺_pl] increased from 4.4 ± 0.7 to 7.1 ± 0.5 mmol/l plasma water and red blood cell K⁺ concentration increased from137.2 ± 6.0 to 144.6 ± 4.6 mmol/l cell water(P  0.05), but the intracellularK⁺-to-mean cellularHb concentration ratio did not change.⁸⁶Rb⁺uptake by red blood cells was increased by ~20% on stimulation, caused by activation of theNa⁺-K⁺pump andNa⁺-K⁺-2Clcotransport. Results indicate theK⁺ content of red blood cells didnot change as cells passed the exhaustively exercising forearm muscledespite the elevated [K⁺_pl]. The tendency for an increase in intracellularK⁺ concentration was due to aslight, although statistically not significant, decrease in red bloodcell volume. K⁺ uptake, althoughelevated, was too small to move significant amounts ofK⁺ into red blood cells. Ourresults suggest that red blood cells do not contribute to the removalof K⁺ released from muscle and donot regulate their volume by K⁺uptake during exhaustive forearm exercise.

     

Effects of K$(86Rb) Transport and the Net H$ Efflux on Electrical Properties along Bean (Phaseolus mungo) Roots

The three-phase electric potential distribution along two-day-oldintact Phaseolus roots was investigated in relation to cellgrowth and K^$ and H^$ transports using tracer K^$(⁸⁶Rb) and pHexperiments. The activity of a radial electrogenic componentlocated between the cortical cells and the external solutionwas high in the elongating region and in the completely maturedregion. The activity of another radial electrogenic componentlocated between the cortical cells and the stele was maximalin the elongating region. Both potassium uptake from the externalsolution into the cortical cells and H^$ excretion took placemainly in these regions. (Received November 9, 1983; Accepted June 21, 1984)