A tracer method to study unidirectional fluxes of lithium: Application to frog skin

We describe a new tracer method to measure unidirectional fluxes of Li⁺, despite the lack of any utilizable radioisotope of lithium. This method uses the purified stable isotopes, ⁶Li and ⁷Li, detected with an ion-probe microanalyser. The accuracy is comparable to that obtained for other ions (e.g., Na⁺) with radiotracers.The method has been applied to frog skin with both faces bathed in a 20% lithium/80% sodium medium. Sodium and lithium unidirectional fluxes have been measured simultaneously. The results are consistent with lithium being actively pumped, the outflux of lithium being, however, much larger than that of sodium.     

Water deficit during root development: effects on the growth of roots and osmotic water permeability of isolated root protoplasts

The effect of low water potentials on root growth of flax (Linum usitatissimum L. cv. Ariane), rape (Brassica napus L. de Candolle, cv. Bristol), hard wheat (Triticum turgidum L. cv. Cham1) and soft wheat (Triticum aestivum L. cv. Ritmo) was studied by measuring the osmotic water permeability (Pos) of root protoplasts and the protein abundance of PIP1 and PIP2 aquaporins. These different species require more or less water, the most sensitive to water deficit being flax and rape. Ritmo, is a cultivar of wheat adapted to temperate zones, while the other cultivar Cham1 is adapted to low-rainfall areas. The seedlings were germinated and grown in water, salt or sugar solutions at different water potentials. The values of Pos for flax, rape and Chaml wheat were normally distributed and could be characterized by mean +/- SD. Root protoplasts from water-grown seedlings had Pos values of 485+/-159 microm s(-1) (flax), 582+/-100 microm s(-1) (rape), and 6.3+/-3.5 microm s(-1) (Cham1). At the same age, the protoplasts from Ritmo exhibited a much wider range of values than the protoplasts of Cham1. When seedlings were grown under conditions of osmotic or salt stress, the mass of the roots was reduced for all species. With 0.25 mol kg(-1) sorbitol or 0.125 M NaCl, the Pos for flax, rape and Cham1 remained constant or slightly increased, while for Ritmo the reduction in the mass of the roots was paralleled by a reduction in Pos. Only Cham1 and Ritmo were able to germinate at a lower potential (0.5 mol kg(-1) sorbitol). For Ritmo the reduction in the mass of the roots was paralleled by a reduction in Pos when grown in this stress condition and both wheats exhibited low Pos values. The expression of the PIP1 and PIP2 aquaporins families was also studied by immunoblotting. We did not observe any difference in protein expression for any of the species, whatever the growing conditions. We suggest that the high Pos values for flax and rape could play a role in the sensitivity of these plants at low water potential. The low native Pos for Cham1 in spite of the expression of both families of aquaporins may reflect its adaptation to low-rainfall conditions by a functional regulation of the water channels. For a similar reason, the low-water-potential-induced Pos of Ritmo may also correspond to a down-regulation of the aquaporins, reflecting adaptation of this wheat to water-deficit conditions.     

Electrical noise measurements on red beet vacuoles : another way to detect the ATPase activity

The vacuolar potential (V_vac) and its fluctuations were recorded in red beet vacuoles (Beta vulgaris L.). Measurements with vacuoles in their suspension medium gave V_vac = 10 ± 2 millivolts (referred to the external medium) when 3 molar KCl microelectrodes were used. Buffering the microelectrode filling solution at pH 7.7 reversed the sign of the potential: V_vac = −7 ± 2 millivolts. The magnitude of the potential fluctuations was lowered by dilution (5-1000 times) with the suspension medium containing components released by the cells during the mechanical preparation. Fluctuations were decreased by 50 millimolar KNO₃ while they were enhanced by 5 millimolar ATP-Mg. No noticeable change in membrane resistance was detected. The presence of an ATPase bound to the tonoplast may explain the recorded noise spectra. These spectra imply a close connection between the rate of ATPase functioning and the magnitude of ionic fluxes across the tonoplast. It is suggested that noise analysis could be used to detect ATPase (or related enzyme) activity in vacuoles. Possible use of H⁺ diffusion through a buffered microelectrode, to modify intravacuolar pH, is also suggested.     

Hydrostatic and osmotic pressure activated channel in plant vacuole

The vacuolar membrane of red beet vacuoles contains a channel which was not gated by voltage or Ca²⁺ ions. Its unit conductance was 20 pS in 200 mM symmetrical KCl solutions. It was stretch activated: the conductance remained constant but the probability of opening was increased by suction or pressure applied to a membrane patch. A 1.5-kNm^-2 suction applied to isolated patches or a 0.08-kNm^-2 pressure applied to a 45-μm diameter vacuole induced an e-fold change in the mean current. A 75% inhibition of the channel current was obtained with 10 μM Gd³⁺ on the cytoplasmic side. The channel was more permeable for K⁺ than for Cl^- (P_K/P_Cl ~ 3). A possible clustering for this channel was suggested by the recordings of the patch current. The channel properties were not significantly affected by a change in sorbitol osmolality in the solutions under isoosmotic conditions, between 0.6 and 1 mol/kg sorbitol. However, the channel was very sensitive to an osmotic gradient. A 0.2-mol/kg sorbitol gradient induced a two-fold increase in unit conductance and a thirty-fold increase in the mean patch current of the channel. A current was measured, when the osmotic gradient was the only driving force applied to the vacuolar membrane. The hydrostatic and osmotic pressure (HOP) activated channel described in this paper could be gated in vivo condition by a change in osmolality, without the need of a change in the turgor pressure in the cell. The HOP channel represents a possible example of an osmoreceptor for plant cells.     

Osmotic water permeability of isolated vacuoles

We measured the osmotic water permeability (P _os) of vacuoles isolated from onion (Allium cepa L.), rape (Brassica napus L.), petunia (Petunia hybrida Hook.) and red beet (Beta vulgaris L.). For all the vacuolar types investigated, P _os values were in the range 200–1000 μm s⁻¹. The change in membrane surface area induced by an osmotic gradient was smaller than 2–6%. The vacuolar P _os values for red beet and onion were reduced by 1 mM HgCl₂, to 14% and 30% of the control values, respectively, but were partially restored to 51% and 76% by 5 mM β-mercaptoethanol. These results suggest that aquaporins were present in all the vacuoles tested. In HgCl₂-treated onion vacuoles, the reduced P _os (56 μm s⁻¹) had a low activation energy (approx. 6 kJ mol⁻¹), indicating that water permeation was still occurring mainly via aquaporins, and that the water permeability of the lipid part of the vacuolar membrane is probably very low. Received: 18 February 1999 / Accepted: 21 June 1999     

Quasi-periodic behaviour in a model for the lithium-induced,electrical oscillations of frog skin

The fact that oscillations can be induced in studies of the maintenance of the electrical potential of frog skin by addition of lithium allowed evaluation of several parameters fundamental to the functioning of the system in vivo (e.g. relative volumes of internal compartments, characteristic times of ionic exchanges between compartments). A realistic model was thus proposed under the form of a set of ordinary differential equations. In the past, numerical simulations using such a model reproduced the periodic experimental oscillations and was able to provide an explanation for the global synchronised oscillations of the whole skin. In that paper, new numerical simulations reproduce the non-periodic oscillations which were observed two decades ago, but not reproduced by the model. Moreover, the dynamical process under which all the local oscillators are synchronised is explained in terms of a tangent bifurcation.     

Brassinolide may control aquaporin activities in Arabidopsis thaliana

 It is usually assumed that aquaporins present in the cellular membranes could be an important route in the control of water flux in plants, but evidence for this hypothesis is scarce. In this paper, we report measurements of the osmotic permeability (P _os ) of protoplasts isolated from hypocotyls of wild-type and mutant Arabidopsis thaliana (L.) Heynh. Mutants were affected in their growth and exhibited different sensitivities to the phytohormone, brassinolide. For the two mutants studied (cpd: constitutive photomorphogenesis and dwarfism; bri1: brassinosteroid insensitive), hypocotyl length was correlated to P _os for the protoplasts. Under experimental conditions where hypocotyl growth had ceased, restoration of root, hypocotyl and petiole growth by brassinolide was correlated with an increase in P _os of the hypocotyl protoplasts. We consider that the increase in P _os of the hypocotyl cells was needed because these cells were part of the transcellular water pathway of the plant. This is the first time, to our knowledge, that brassinolide has been shown to be involved in the modification of the water-transport properties of cell membranes. Our results also emphasize the importance of aquaporins and the transcellular pathway in water transport under normal growth conditions. Received: 15 January 2000 / Accepted: 18 May 2000     

Voltage Noise in Acer pseudoplatanus Cells : Basic Cellular Noise and Gramicidin a Induced Noise

The present contribution is devoted to studying the electrical noise of Acer pseudoplatanus cells in culture suspensions. Spontaneous voltage noise of the cells was recorded by means of a microelectrode inserted in the vacuole. The small signal impedance of the cell was measured so that it was possible to study the intensity spectra of the noise. We recorded intensity spectra with cells incubated in 10⁻³ molar gramicidin A. Difference spectra showed characteristics of a channel noise. By using the calculated conductance of gramicidin A in an artificial membrane, and by simplifying assumptions for the ionic transports through plasmalemma and tonoplast, we were able to estimate the electrochemical potential difference for K⁺ ions across the plasmalemma (3.2 ± 1 millivolt).     

Microelectrode Measurements on Red Beet Vacuole : Biological Effect of Na OR NO(3) Ions, Diffusing from the Microelectrode

Glass microelectrodes filled with 3 molar KCl are widely used to measure intracellular potentials and it is usual to try to minimize their electrolyte loss. In these experiments we have used the ionic leak of our microelectrodes, filled with various salt solutions, to introduce a given ion into the red beet vacuole. This allowed us to show that NO₃⁻ ions reduce the magnitude of the current spectral density while they do not change the resistance of the tonoplast. This is true when NO₃⁻ is either added to the external medium or used as the microelectrode filling solution. This can be interpreted by a NO₃⁻ effect on the vacuolar side of the tonoplast, resulting in an inhibition of the ion transporting ATPase. Replacing K⁺ by Na⁺ ions in the medium has no effect on tonoplast resistance (R_s). On the contrary, when ions leaking from the microelectrode are H⁺, Li⁺ or K⁺, R_s is close to 4 kilohm square centimeter, whereas R_s is of the order of 30KΩ square centimeter when Na⁺ are the leaking ions. We also found a possible correlation between the presence of a Lorentzian in the current spectral density (cut-off frequency = 2 hertz) and a Cl⁻ efflux from the vacuole. This could be explained by the existence of Cl⁻ channels on the tonoplast.