Effect of lanthanum on ion absorption in cucumber seedling leaves

Scanning electron microscope and energy-dispersive X-ray analysis were used to study the tissular distributions of elements Na, Mg, Cl, K, Ca, Mn, and Fe in leaves of cucumber seedlings in the absence or presence of La³⁺. The results showed that the atomic percentages of Na, Mg, Cl, K, and Ca were basically reduced and those of Mn and Fe were increased in the presence of La³⁺; in addition, at 0.02 mM La³⁺, the reduced or increased degrees were higher than those at 2.0 mM La³⁺. The effects of La³⁺ on ion absorption were similar to those of Ca²⁺, suggesting that the rare earth element lanthanum affects the plant physiological mechanism by regulating the Ca²⁺ level in plant cell.     

Calcium inhibition of potassium absorption in corn roots

Calcium (or magnesium) sulfate or chloride was found to inhibit energy dependent potassium transport in excised corn roots. This Ca²⁺ inhibition of K⁺ transport was most pronounced during the initial phases of transport. As the absorption periods were lengthened the effect of Ca²⁺ gradually changed from an inhibition to a typical promotion (after about 30-45 mins) of K⁺ transport. Kinetic analysis indicated the inhibition to be of a non-competitive nature.

Identical experiments with excised barley roots showed that CaSO₄ had no effect on K⁺ absorption whereas CaCl₂ had a typical stimulatory effect on K⁺ absorption. Kinetic analysis indicated that both corn and barley have efficient K⁺ transporting systems but barley roots are approximately 5 times more active (on a fr wt basis) than corn roots.

These results illustrate the hazards involved in applying results obtained with 1 (or even several) plant species to all species.

     

Effects of temperature on orthophosphate absorption by excised corn roots

The uptake of orthophosphate (³²P) by excised corn roots, Zea mays L. was studied using roots grown on 0.2 mm CaSO₄. Nine concentrations of KH₂PO₄ from 1 to 256 μm were used at temperatures of 20°, 30°, and 40°. Enzyme kinetic analysis was applied to the data obtained. Two apparent mechanisms (sites) of phosphate uptake were observed, 1 dominating at high P concentrations and 1 at low P concentrations. A Km of 1.36 × 10⁻⁴ and a Vmax of 177 × 10⁻⁹ moles per gram of roots per hour at 30° was calculated for the mechanism dominating at high P concentrations. Similar calculations gave a Km of 6.09 × 10⁻⁶ and a Vmax of 162 × 10⁻⁹ moles per gram of roots per hour at 30° for the mechanism dominating at low P concentrations. The Q₁₀ for both mechanisms was approximately 2. Calculation of thermodynamic values from the data gave ΔF of − 5200 cal, ΔH of − 950 to − 1400 cal, and a enthalpy of activation (A) of 10,300 to 13,800 cal per mole for the mechanism dominating at high P concentrations. Similar calculations from the data for the mechanism dominating at low P concentrations gave a ΔF of − 7300 cal, ΔH of − 10,700 to − 8200 cal, and a A of 9300 to 18,900 cal per mole. If the dual mechanism interpretation of this kind of data adequately describes this system, then both mechanisms of P absorption by corn roots involve chemical reactions.     

Alkylguanidine inhibition of ion absorption in oat roots

The effect of various alkylguanidines on ion absorption and energy metabolism in oat (Avena sativa cv. Goodfield) roots has been investigated. Of several alkylguanidines tested, octylguanidine was the most effective inhibitor of both K⁺ and Cl⁻ absorption by excised roots. At 225 μm octylguanidine, the transport of both ions was inhibited within 60 seconds and to a similar extent. Octylguanidine inhibited mitochondrial oxidative phosphorylation and mitochondrial adenosine 5′-triphosphatase (ATPase). The plasma membrane ATPase was also inhibited if the membranes were diluted and pretreated with Triton X-100.     

Short Report : Effect of amines and guanidines on Rb+ absorption by excised corn roots

The effect of alkyl-amines and -guanidines on the absorption of rubidium by the excised roots of the corn plant was tested. Inhibition of Rb⁺ absorption was observed with both amines and guanidines, where guanidines were more effective. The effect of alkylamines on Rb⁺ transport depends on their molecular structure.     

Nitrate absorption by corn roots : inhibition by phenylglyoxal

Nitrate transport in excised corn (Zea mays L.) roots was inhibited by phenylglyoxal, but not by 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS) or fluorescein isothiocyanate (FITC). Inhibition of nitrate uptake by a 1-hour treatment with 1 millimolar phenylglyoxal was reversed after 3 hours, which was similar to the time needed for induction of nitrate uptake. If induction of nitrate uptake occurs by de novo synthesis of a nitrate carrier, then the resumption of nitrate uptake in the inhibitor-treated roots may occur because of turnover of phenylglyoxal-inactivated nitrate carrier proteins. All three chemicals inhibited chloride uptake to varying degrees, with FITC being the strongest inhibitor. While inhibition due to DIDS was reversible within 30 minutes, both FITC and phenylglyoxal showed continued inhibition of chloride uptake for up to 3 hours after removal from the uptake solution. Assuming that the anion transporter polypeptide(s) carries a positive charge density at or near the transport site, the results indicate that the nitrate carrier does not carry any lysyl residues that are accessible to DIDS or FITC, whereas the chloride carrier does. Both chloride and nitrate carriers, however, seem to possess arginyl residues that are accessible to phenylglyoxal.     

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.     

Dual mechanisms of ion uptake in relation to vacuolation in corn roots

Absorption isotherms for chloride and rubidium ions have been determined through a wide concentration range for nonvacuolate root tips, and for vacuolate subapical sections of corn root. In the range 0 to 0.5 mm, chloride absorption is hyperbolic with concentration in both tips and proximal sections. At high concentrations, 1 to 50 mm, a second multiple-hyperbolic isotherm for chloride is noted in vacuolate tissue, while the isotherm for nonvacuolate tips rises exponentially. A linear to exponentially rising isotherm is taken to signify diffusive permeation.     

The use of lanthanum to study the functional development of the Casparian strip in corn roots

Summary Lanthanum in combination with electron microscopy was used to study the functional development of the Casparian strip in the primary root of corn (Zea mays L. WF9 X M14). The Casparian strip was first visible between 13 and 16 mm from the root tip, and was first an effective barrier to lanthanum movement through the apoplast from cortex to stele between 14 and 18 mm from the apex. Until the Casparian strip was formed, lanthanum ion freely penetrated the stelar apoplast. By 18 mm from the apex lanthanum was completely restricted to the extracellular spaces of the cortex. Treatment with 0.02 or 0.03% (v/v) Triton X-100 increased the permeability of the plasma membrane, and allowed lanthanum ion to penetrate the cortical symplast. After the detergent treatment, the endodermis no longer functioned as a barrier to La³⁺ movement from cortex to stele. This confirms that an intact plasma membrane is necessary for the primary endodermis to control the passage of solutes into the vascular tissues of the stele.     

Effect of diethylstilbestrol on ion fluxes in oat roots

Effects of diethylstilbestrol (DES) on ion fluxes in oat roots (Avena sativa L.) were investigated by measuring K⁺ and Cl⁻ absorption and K⁺ efflux. DES rapidly decreased the absorption of K⁺ (⁸⁶Rb) and ³⁶Cl⁻ by excised roots; 10⁻⁴ molar DES inhibited Cl⁻ absorption in 1 minute and K⁺ absorption in 1 to 2 minutes. With a 10-minute incubation period, K⁺ and Cl⁻ absorption were inhibited 50% by 1.1×10⁻⁵ molar and 8.4×10⁻⁶ molar DES, respectively. Treatment for 3 minutes with 10⁻⁴ molar DES caused irreversible inhibition of K⁺ absorption. Increasing concentrations of KCl in the absorption media decreased the DES inhibition. Experiments with the DES analogs, DES dipropionate, dienestrol and hexestrol, showed that the steric configuration and the hydroxyl group of the DES molecule are important in determining the inhibitory capacity of the compound.     

Effect of auxin on acropetal auxin transport in roots of corn

Acropetal [¹⁴C]indoleacetic acid (IAA) transport was investigated in roots of corn. At least 40 to 50% of this movement is dependent on activities in the root apex. Selective excision of various populations of cells comprising the root apex, e.g. the root cap, quiescent center, or proximal meristem show that the proximal meristem is the critical region in the apex with regard to influencing IAA movement. The quiescent center has no influence and the root cap has only a minor effect. Excision and replacement of the proximal meristem with an exogenous supply of 10⁻⁸ to 10⁻⁹ molar IAA prevents the reduction in acropetal IAA transport which would normally occur in the absence of this meristem. Substituting 10⁻⁹ molar IAA for the excised root cap brings about a significant increase in the amount of IAA moved acropetally, as compared to intact roots with the root cap still in place. From this and previous work, it is concluded that IAA synthesis occurring in the proximal meristem stimulates the movement of IAA from the basal to apical end of the root.     

Effect of cold on endogenous fucosyl transferase activity in corn roots

Incubation of excised, 1-centimeter long root tips of corn in chilled distilled H₂O increases the activity of extractable GDP fucose: polysaccharide fucosyl transferase. Enhancement of transferase activity is optimal at 10 C and incubation at this temperature for 8 hours causes a 3- to 5-fold stimulation of activity. Transfer of roots from 10 to 30 C reverses the enhancement of enzyme activity although reciprocal transfer of roots from 30 to 10 C does not stimulate the accumulation of transferase activity.     

Induction and development of increased ion absorption in corn root tissue

Washing excised or intact primary roots of corn (Zea mays L., WF9 × M14) in aerated distilled water or dilute salt solutions for 2 hours induced doubling of the rate of accumulation of various nutrient ions and solutes. This response to washing depended upon aerobic metabolism, but involved no increase in aerobic respiration. Excision of root tissue was not required as the effect could be obtained with intact root systems. Increased phosphate absorption followed after a lag period of 30 to 40 minutes and continued for 6 hours before leveling off at about 3.5 times the initial rate. Chloramphenicol was not inhibitory to the development of increased absorption, while inhibitors of RNA and protein synthesis were. Auxins and kinetin were also inhibitory, but so was the antiauxin, 2,4,6-trichlorophenoxyacetic acid.     

Effect of glucose on the induction of nitrate reductase in corn roots

In Zea mays L., addition of glucose to the induction medium has no effect on the induction of nitrate reductase during the initial 3 hours either in root tips (0-10 mm) or mature root sections (25-35 mm). With longer times, higher levels of enzyme activity are recovered from both root segments when glucose is present in the incubation medium. The induction in root tips is saturated by 10 mm NO(3) (-). Higher concentrations of NO(3) (-) are required for saturation in mature root sections. The response to glucose is seen over a wide range of external NO(3) (-) concentrations.Nitrate reductase activity is lost rapidly when nitrate is withdrawn from the induction medium. Additions of glucose do not prevent this loss. Additions of glucose have no effect on total uptake of NO(3) (-) by the root segments but they increase the anaerobic NO(2) (-) production in both root tips and mature root segments. This latter measurement is considered to be an estimate of an active NO(3) (-) pool in the cytoplasm. Thus the results show that glucose alters the distribution of NO(3) (-) within the root sections. This may be an important factor in controlling the in vivo stability of the enzyme or its rate of synthesis.     

Effect of NaCl and mannitol on plasma membrane proteins in corn roots

Summary The short-term effects of NaCl and mannitol stress on plasma membrane (PM) polypeptides from corn roots (Zea mays L.) were determined using two-dimensional gel electrophoresis following radiolabeled amino acid incorporation. After 2.5 hours, both stress treatments altered synthesis of several polypeptides. Changes included up-regulation of some polypeptides with concomitant down-regulation of others. Some changes were unique to the stress treatment while others were common to both NaCl and mannitol. No new polypeptides appeared in either case. Pulse-chase experiments following 0.5-hours and 2.5-hours incubation periods with radiolabeled amino acids did not reveal differences in turnover of PM polypeptides. The results support the contention that altered synthesis of PM proteins under stress may contribute to the alteration of membrane function.Abbreviations ER endoplasmic reticulum: GA Golgi - PM plasma membrane - PVPP polyvinylpolypyrrolidone     

Effect of mineral fertilizers on the microflora of corn roots]

The paper describes studies of the density of microorganisms grown on meat-peptone agar, fungi, nitrifiers, cellulose degraders, actinomycetes and azotobacter in the soil of the radical area of corn grown in field experiments with various doses and ratios of mineral fertilizers. In the forest-steppe zone (leached chernozem) of the Krasnoyarsk region mineral fertilizers activated proliferation of radical microorganisms grown on meat-peptone agar, fungi, nitrifiers and cellulose degraders. The effect of the tested fertilizers was dissimilar during plant vegetation. Under the influence of fertilizers proliferation of actinomycetes increased at the phase of 3--4 leaves. At later phases of the plant development a similar tendency was manifest upon soil application of N120P60K60, N60P120K60 and N120P120K120. The azotobacter density increased only after application of N60P120K60, N60P60K120 and N30P60K30.     

Controls on na influx in corn roots

We have investigated the effects of hyperpolarization and depolarization, and the presence of K⁺ and/or Ca²⁺, on ²²Na⁺ influx into corn (Zea mays L.) root segments. In freshly excised root tissue which is injured, Na⁺ influx is unaffected by hyperpolarization with fusicoccin, or depolarization with uncoupler (protonophore), or by addition of K⁺. However, added Ca²⁺ suppresses Na⁺ influx by 60%. In washed tissue which has recovered, Na⁺ influx is doubled over that of freshly excised tissue, and the influx is increased by fusicoccin and suppressed by uncoupler. This energy-linked component of Na⁺ influx is completely eliminated by low concentrations of K⁺, leaving the same level and kind of Na⁺ influx seen in freshly excised roots. The K⁺-sensitive energy linkage appears to be by the carrier for active K⁺ influx. Calcium is equally inhibitory to Na⁺ influx in washed as in fresh tissue. Other divalent cations are only slightly less effective. Net Na⁺ uptake was about 25% of ²²Na⁺ influx, but proportionately the response to K⁺ and Ca²⁺ was about the same.

The constancy of K⁺-insensitive Na⁺ influx under conditions known to hyperpolarize and depolarize suggests that if Na⁺ transport is by means of a voltage-sensitive channel, the rise or fall of channel resistance must be proportional to the rise or fall in potential difference. The alternative is a passive electroneutral exchange of ²²Na⁺ for endogenous Na⁺. The data suggest that an inwardly directed Na⁺ current is largely offset by an efflux current, giving both a small net uptake and isotopic exchange.

     

Effect of ATPase inhibitors on cell potential and k influx in corn roots

Experiments were performed to determine the effect of plasmalemma ATPase inhibitors on cell potentials (Ψ) and K⁺ (⁸⁶Rb) influx of corn root tissue over a wide range of K⁺ activity. N,N′Dicyclohexylcarbodiimide (DCCD), oligomycin, and diethylstilbestrol (DES) pretreatment greatly reduced active K⁺ influx and depolarized Ψ at low, but not at high, K⁺ activity (K°). More comprehensive studies with DCCD and anoxia showed nearly complete inhibition of the active component of K⁺ influx over a wide range of K°, with no effect on the apparent permeability constant. DCCD had no effect on the electrogenic component of the cell potential (Ψ_p) above 0.2 millimolar K°. Net proton efflux was rapidly reduced 80 to 90% by DCCD. Since tissue ATP content and respiration were only slightly affected by the DCCD-pretreatment, the inhibitions of active K⁺ influx and Ψ_p at low K° can be attributed to inhibition of the plasmalemma ATPase.     

Temperature dependence of the concentration kinetics of absorption of phosphate and potassium in corn roots

The effect of temperature on respiration and kinetics of H₂PO₄⁻ and K⁺ uptake in corn roots was determined in the range of 2 to 42 C. The response of uptake to temperature, determined from Q₁₀ and activation energy (Ea) data, for the anion and the cation differ significantly, especially in the range of uptake mechanism (Mech.) I. At 2.5 micromolar the Ea for K⁺ uptake below the 13 C transition is 29.3 kilocalories per mole. As the K⁺ concentration is increased, Ea declines and at 0.25 millimolar is 21.6 kilocalories per mole. Accompanying this change in Ea is a shifting of the apparent transition temperature from 13 to 17 C. Above the temperature transition the Ea's for K⁺ uptake in the Mech. I range are quite low (3.0) and this value is unchanged by increases of K⁺ concentration to 0.25 millimolar. In the range of Mech. II above 1 millimolar K⁺ the temperature transitions are not seen and plots become linear. The Ea's show an increasing trend from 4.7 at 1 millimolar to 6.1 at 50 millimolar. The uptake of H₂PO₄⁻ is much more temperature sensitive having a constant Ea at concentrations in the Mech. I range below the 13 C temperature transition. The Arrhenius plots reveal a second transition at 22 C and the Ea for this segment is 21.0. Above the second transition the Ea remains high (10.0) and is constant in the range of Mech. I. In the range of Mech. II there is a concentration dependent decline in Ea for H₂PO₄⁻ uptake (22.7 at 1.0 millimolar to 1.0 at 50 millimolar). There is no definable low temperature transition at these concentrations. Ion uptake is found to be much more sensitive to low temperature than respiration in this chill-sensitive species. The data suggest that the low temperature reduction of ion transport is more closely related to restriction of function of active transport systems than to either respiration or membrane permeability.