Primary effect of bromoxynil to induce plant cell death may be cytosol acidification

Bromoxynil, 3,5-dibromo-4-hydroxybenzonitrile, is a commonly used herbicide and is also used as a tool to trigger rapid cell death in basic botany. However, the primary effect inducing cell death is not known. Bromoxynil inhibited the cytoplasmic streaming and killed cells in Chara corallina when it was applied in the acidic external medium. At higher pH, bromoxynil was inert even at high concentrations. It was speculated that bromoxynil in the protonated form enters the cell and acidifies the cytosol by releasing H⁺. Experiments using analogues of bromoxynil supported this possibility. Acidification of the cytosol by bromoxynil was confirmed by experiments using pollen tubes. Based on the acidity of the apoplast, the herbicide action of bromoxynil in higher plants was discussed.     

A New Turgor/Membrane Potential Probe Simultaneously Measures Turgor and Electrical Membrane Potential

Abstract: A new combined turgor/membrane potential probe (T-EP probe) monitored cell turgor and membrane potential simultaneously in single giant cells. The new probe consisted of a silicone oil-filled micropipette (oil-microelectrode), which conducted electric current. Measurements of turgor and hydraulic conductivity were performed as with the conventional cell pressure probe besides the membrane potential. In internodal cells of Chara corallina, steady state turgor (0.5-0.7 MPa) and resting potentials (-200 to ?220 mV) in APW, and hydraulic conductivity (0.07 to 0.21 × 10～⁵ m s^?1 MPa^?1) were measured with the new probe, and cells exhibited healthy cytoplasmic streaming for at least 24 h during measurements. When internodal cells of Chara corallina were treated with 30, 20, 10, and 5 mM KCI, turgor responded immediately to all concentrations, and the osmotic changes in the medium were measured. Action potentials, which brought the membrane potential to a steady depolarization that measured the concentration difference of K⁺ in the medium, were induced in a concentration — dependent delay and occurred only 30, 20, and 10 mM of KCl. When the solution was changed back to APW, the repolarization of membrane potential consisted of a quick and a following slow phase. During the quick phase, which took place immediately and lasted 1 to 3 min, the plasma membrane remained activated. The membrane was gradually deactivated in the slow phase, and entirely deactivated when the membrane potential recovered to the resting potential in APW. Although the activated plasma membrane was permeable to K⁺, no major ion channels were activated on the tonoplast, and therefore, internodal cells of Chara corallina did not regulate turgor when osmotic potential changed in the surrounding medium.     

Interaction ofStreptomyces felleus with bromoxynil during growth on laboratory media

Streptomyces felleus resistant to the herbicide bromoxynil (BX) took up 95 % of the initial amount of BX from the solid or liquid medium containing 100 μg of the herbicide per mL during a 5-d incubation. 50 % of the amount taken up was degraded and 45 % deposited in the cell (90 % in the cytoplasm, 10 % in the cell wall). A prolonged incubation time did not result in any further decrease of BX concentration. The addition of KC1 (the effect of NaCl was less pronounced) increased the affinity of BX for the cell wall and slowed down both the uptake and degradation of BX. Though P-14 was capable of growing at 5- to 10 times higher concentrations of BX in comparison with sensitiveStreptomyces strains, the herbicide caused its physiological (growth rate decrease, antibacterial antibiotic production, pigmentation, dehydrogenase activities), morphological and ultrastructural changes. Second paper of a series onStreptomyces felleus resistance to bromoxynil.     

p-CMBS Modifies Extrafacial Sulfhydryl Groups at the Chara Plasma Membrane: Activation of Ca2+ Influx and Inhibition of Two Different K+ Currents

The effect of the membrane impermeant sulfhydryl group (SH) reagent, p-chloromercuribenzenesulfonic acid (p-CMBS), on electrical membrane transport properties of the giant alga, Chara corallina, was determined. In an external medium with a high K⁺ concentration (5 mM) cells typically exhibited stable membrane potentials close to the K⁺equilibrium potential. The steady-state current-voltage (I-V) relation could be dissected into two distinct components: an almost linear ohmic leak current and a voltage-dependent K⁺ current. Adding 0.5 mM p-CMBS to the external medium resulted in an immediate, short depolarization transient (resembling the time course of an action potential) and was associated with a slow down of the cytoplasmic streaming velocity. The depolarization, as well as the streaming inhibition, could be abolished by pretreating cells with the Ca²⁺ channel inhibitor, LaCl₃. This suggests that the depolarization transient reflected a p-CMBS induced Ca²⁺ influx, a scenario known to trigger membrane excitation and slow down of cytoplasmic streaming. From the I-V analysis it appeared that p-CMBS also caused a reversible inhibition of two additional transmembrane currents: (1) a reduction of a leak current and (2) a modification of the deactivation kinetics of the voltage-dependent K⁺ channels. From the I-V difference analysis, the inhibited leak current was identified as a K⁺ current, because the reversal potential was close to the estimated K⁺ equilibrium potential. Control experiments have furthermore shown that the mercapto reagent, dithiothreitol, partly reversed the effect of p-CMBS. This strengthens the view that the action of the mercurial is related to a specific and direct modification of SH groups. The p-CMBS-evoked inhibition of K⁺ currents was not abolished by the LaCl₃ pretreatment, which suggests that the effect of the SH reagent is not induced indirectly by p-CMBS-triggered Ca²⁺ influx. Therefore, it is suggested that the mercurial interacts direcly with the K⁺ transport protein.     

The effect of divalent cations on Na+ tolerance in Charophytes. II: Chara corallina

Abstract The freshwater Charophyte Chora corallina dies when subjected to 70 molm^?3 NaCl if the Ca²⁺ concentration is 0.1 mol m ^?3. This stress is accompanied by a depolarization of the cell to a membrane potential more positive than E_K, a net influx of Na⁺ into the vacuole, and a net loss of K⁺ from the vacuole. Raising the Ca²⁺ concentration to 7 mol m ^?3 in the presence of elevated Na⁺ restores the Na⁺ to Ca²⁺ ratio to 10: 1 as in the control solution, and results in enhanced survival even though turgor is not regulated. Mg²⁺ is not a good substitute for Ca²⁺. It is suggested that the main reason that C. corallina fails to occupy saline habitats is its failure to regulate turgor, not sensitivity to Na ⁺, since the latter is similar to that seen in C. buckellii, which is found in saline habitats.     

Susceptibility of the eggs of the field slug Deroceras reticulatum to contact with pesticides and substances of biological origin on artificial soil

The toxicity of 14 substances, including a number of pesticides, to the eggs of the pest slug Deroceras reticulatum was determined in laboratory experiments. Eggs were kept in contact with a precisely defined artificial soil to which a range of concentrations of the test substances had been applied. Mortality of the eggs was assessed every 24 h and the median lethal doses (LD₅₀) were determined. The herbicides bromoxynil, ioxynil and pyridate + bromoxynil, the insecticides thiocyclam, diflubenzuron and azadirachtin, the molluscicides metaldehyde and methiocarb, and other compounds such as carvone, iron‐EDDHA, saponin, and an extract of Pongamia pinnata, killed the eggs after periods of exposure ranging from 2 to 14 days, depending on the compound and the dose. Only two compounds, the insecticides imidacloprid and teflubenzuron, failed to kill the eggs of D. reticulatum at any of the doses tested. Values of LD₅₀ below 0.01 mg a.i. cm^?2 were obtained for the herbicides bromoxynil, ioxynil and pyridate + bromoxynil, and for the biological pesticide azadirachtin. The feasibility of slug egg control in different contexts is discussed.     

Transduction of pressure signal to electrical signal upon sudden increase in turgor pressure in Chara corallina

By taking advantage of large cell size of Chara corallina, we analyzed the membrane depolarization induced by decreased turgor pressure (Shimmen in J Plant Res 124:639–644, 2011). In the present study, the response to increased turgor pressure was analyzed. When internodes were incubated in media containing 200 mM dimethyl sulfoxide, their intracellular osmolality gradually increased and reached a steady level after about 3 h. Upon removal of dimethyl sulfoxide, turgor pressure quickly increased. In response to the increase in turgor pressure, the internodes generated a transient membrane depolarization at its nodal end. The refractory period was very long and it took about 2 h for full recovery after the depolarizing response. Involvement of protein synthesis in recovery from refractoriness was suggested, based on experiments using inhibitors.     

Mechanisms of cation permeation across apical cell membrane ofNecturus gallbladder: Effects of luminal pH and divalent cations on K+ and Na+ permeability

Summary Conventional microelectrode techniques were combined with unilateral mucosal ionic substitutions to determine the effects of luminal pH and luminal alkali-earth cation concentrations on apical membrane cation permeability inNecturus gallbladder epithelium. Acidification of the mucosal solution caused reversible depolarization of both cell membranes and increase of transepithelial resistance. Low pH media also caused: (a) reduction of the apical membrane depolarization induced by high K, and (b) increase of the apical membrane hyperpolarization produced by Na replacement with Li or N-Methyl-d-glucamine. These results, in conjunction with estimates of cell membrane conductances, indicate that acidification of the luminal solution produces a reduction of apical membrane K permeability (P _K). Addition of alkali earth cations (Mg²⁺, Ca²⁺, Sr²⁺, or Ba²⁺) produced cell membrane depolarization, increase of relative resistance of the luminal membrane and reduction of the apical membrane potential change produced by a high-K mucosal medium. These results, as those produced by low pH, can be explained by a reduction of apical membraneP _K. The effects of Ba²⁺ on membrane potential and relative apical membraneP _K were larger than those of all other four cations at all concentrations tested (1–10mm). The effect of Sr²⁺ was significantly larger than those of Mg²⁺ and Ca²⁺ at 10mm, but not different at 5mm. The reduction ofP _K produced by mucosal acidification appears to be mediated by: (a) nonspecific titration of membrane fixed negative charges, and (b) an effect of luminal proton activity on the apical K channel. Divalent cations reduce apical membraneP _K probably by screening negative surface charges. The larger magnitude of the effects of Ba²⁺ and Sr²⁺ can be explained by binding to membrane sites, in the surface or in the K channel, in addition to their screening effect. We suggest that the action of luminal pH on K secretion in some segments of the renal tubule could be mediated in part by this pH-dependent K permeability of the luminal membrane.     

Inactivation of plasmalemma conductance in alkaline zones of <Emphasis Type="Italic">Chara corallina</Emphasis> after generation of action potential

A microelectrode study with Chara corallina cells has shown that post-excitation changes of membrane potential and plasmalemma resistance, induced by the action potential (AP) generation, differ substantially for cell areas producing zones of high and low external pH. In cell regions producing alkaline zones, the AP generation was followed by post-excitation hyperpolarization by about 50 mV, concomitant with four- to eightfold increase in plasmalemma resistance and a considerable drop of pericellular pH. In the acidic areas the post-excitation hyperpolarization was weak or absent, and the membrane resistance showed no significant increase within 1–2 min after AP. The membrane excitation in the acidic zones was accompanied by a noticeable pH increase near the cell surface, indicative of the inhibition of plasma membrane H⁺ pump. The results suggest that the high local conductance of the plasmalemma is closely related to alkaline zone formation and the depolarized state of illuminated cell under resting conditions. Excitation-induced changes of membrane potential and pH in the cell vicinity were fully reversible, with the recovery period of ∼15 min at a photon flux density of ∼100 μE/(m² s). At shorter intervals between excitatory stimuli, differential membrane properties of nonuniform regions turned smoothed and could be overlooked. It is concluded that the origin of alkaline zones in illuminated Chara cells cannot be ascribed to hypothetical operation of H⁺/HCO₃⁻ symport or OH⁻/HCO₃⁻ antiport.     

Resistance ofStreptomyces felleus to the herbicide bromoxynil

A soil strain ofStreptomyces felleus resistant to the herbicide bromoxynil (BX) and capable of supporting growth of sensitive streptomycetes on a BX-containing medium, was found to decrease the concentration of BX in the medium to one half after 10 d of incubation. Physicochemical methods showed that a co-metabolic process without any accumulation of the degradation products similar to BX was involved. Mutation experiments carried out with the strain suggest a nonchromasomal control of the resistance to BX.     

The degradation of the herbicide bromoxynil and its impact on bacterial diversity in a top soil

Aims: To study how repeated applications of an herbicide bromoxynil to a soil, mimicking the regime used in the field, affected the degradation of the compound and whether such affects were reflected by changes in the indigenous bacterial community present. Methods and Results: Bromoxynil degradation was monitored in soil microcosms using HPLC. Its impact on the bacterial community was determined using denaturing gradient gel electrophoresis (DGGE) and quantitative PCR of five bacterial taxa (Pseudomonads, Actinobacteria, α‐Proteobacteria, Acidobacteria and nitrifying bacteria). Three applications of 10 mg kg^?1 of bromoxynil at 28‐day intervals resulted in rapid degradation, the time for removal of 50% of the compound decreasing from 6·4 days on the first application to 4·9 days by the third. Bacterial population profiles showed significant similarity throughout the experiment. With the addition of 50 mg kg^?1 bromoxynil to soil, the degradation was preceded by a lag phase and the time for 50% of the compound to be degraded increased from 7 days to 28 days by the third application. The bacterial population showed significant differences 7 days after the final application of bromoxynil that correlated with an inhibition of degradation during the same period. Conclusions: These analyses highlighted that the addition of bromoxynil gave rise to significant shifts in the community diversity and its structure as measured by four abundant taxa, when compared with the control microcosm. These changes persisted even after bromoxynil had been degraded. Significance and Impact of the Study: Here we show that bromoxynil can exert an inhibitory effect on the bacterial population that results in decreased rates of degradation and increased persistence of the compound. In addition, we demonstrate that molecular approaches can identify statistically significant changes in microbial communities that occur in conjunction with changes in the rate of degradation of the compound in the soil.     

ATP-driven proton pumping in two species of Chara differing in salt tolerance

Chara corallina is an obligate freshwater alga, while C. buckellii can be grown in salt and freshwater culture. When grown in fresh water, C. buckellii has electrophysiological properties similar to C. corallina, but when cultured in salt water, it has a less negative membrane potential and has a higher conductance. We show in internally perfused, tonoplast-free cells that the ATP-dependence of the two species cultured in fresh water is similar, although C. buckellii hyperpolarizes at lower ATP concentrations. We determined the pump parameters in perfused and intact cells. Using both techniques, C. corallina and C. buckellii cultured in fresh water show similar values of E_p, G_p and I_p. However, there is a significant difference between the two techniques: E_p is more negative (–400 to –700 mV) in perfused cells than in intact cells (–220 to –260mV); G_p is lower (0·1–0·2 versus 0·3–0·9 S m^?2); and I_p is higher (40–60 versus 10–18 mA m^?2). Salt-cultured C. buckellii was compared with freshwater C. buckellii using intact cells; G_p and E_p were similar, but I_p was much higher in salt-cultured cells (60 versus 15mA m^?2). This higher pump rate is due to the depolarization of the membrane of salt-cultured algae, which is caused by a higher passive conductance. The significance of the less negative membrane potential and the higher rate of proton pumping is discussed with respect to the banding pattern and salt stress.     

Dual effects of proctolin on the rhythmic burst activity of the cardiac ganglion

The neuropeptide proctolin has distinguishable excitatory effects upon premotor cells and motorneurons of Homarus cardiac ganglion. Proctolin's excitation of the small, premotor, posterior cells is rapid in onset (5–10 s) and readily reversible (< 3 min). Prolonged bursts in small cells often produce a “doublet” ganglionic burst mode via interactions with large motorneuron burst-generating driver potentials. In contrast to small cell response, proctolin's direct excitatory effects upon motorneuron are slow in onset (60–90 s to peak) and long-lasting (10–20 min). The latter include: (a) a concentration-dependent (10^?9–10^?7M) depolarization of the somatic membrane potential; (b) increases in burst frequency and (c) enhancement of the rate of depolarization of the interburst pacemaker potential. Experiments on isolated large cells indicate: (a) the slow depolarization is produced by a decrease in the resting G_K and (b) proctolin can produce or enhance motorneuron autorhythmicity. A two-tiered non-hierarchical network model is proposed. The differential pharmacodynamics exhibited by the two cell types accounts for the sequential modes of ganglionic burst activity produced by proctolin.     

Polyamines inhibit NADPH oxidase-mediated superoxide generation and putrescine prevents programmed cell death induced by polyamine oxidase-generated hydrogen peroxide

Our previous results indicate that during protoplast isolation an oxidative burst occurs [A.K. Papadakis and KA Roubelakis-Angelakis (1999) Plant Physiol 127:197–205] and that suppression of totipotency is correlated with reduced antioxidant activity and low redox state [A.K. Papadakis et al. (2001b) Plant Physiol 126:434–444]. Polyamines are known to affect cell development and to act as antioxidants. Polyamines applied during isolation of tobacco (Nicotiana tabacum L.) protoplasts reduced the accumulation of O₂^·– but not that of H₂O₂. This antioxidant effect is probably due to the inhibition of microsomal membrane NADPH oxidase, which occurred in a concentration-dependent manner, with spermine exerting the highest inhibitory effect. However, during protoplast culture, polyamine oxidase activity increased severalfold in spermidine- and spermine-treated protoplasts, concomitant with H₂O₂ titers. A cell death program was executed in untreated protoplasts, as documented by membrane malfunction, induced DNase activity, DNA fragmentation and a positive TUNEL reaction. Protoplast cell death was prevented in protoplasts treated with putrescine, but not by treatment with spermidine or spermine, which rather had the opposite effect. The data presented suggest that PAs may be implicated in the expression of plant protoplast totipotency.     

Effect of Neural Stimulation on Acinar Cell Membrane Potentials in Isolated Pancreas and Salivary Gland Segments

The effect of cholinergic neural excitation by field stimulation on the acinar cell membrane potential was investigated in superfused segments of mouse pancreas and salivary glands (sublingual, submaxillary, and parotid glands).

Responses of acinar cells in both exocrine pancreas and salivary glands to the neural excitation obtained by field stimulation were similar to responses previously described in each gland to the externally applied acetylcholine.

In the pancreatic acinar cell, electrical field stimulation induced depolarization with a latency of 0.3 to 1.2 sec. This depolarization was accompanied by a marked decrease in membrane resistance. The equilibrium potential of the depolarization induced by stimulation was between -10 and -20 mV. In the sublingual gland, field stimulation induced depolarization of the acinar cell with a latency of 0.2 to 0.3 sec. The stimulus induced depolarization was blocked by the addition of atropine. In the submaxillary and parotid glands, field stimulation induced depolarization in some acinar cell and hyper-polarization in other cells.

The results support evidence previously presented by Petersen and his colleagues that acetylcholine acts to increase Na⁺ and K⁺ or Na⁺, K⁺, and Cl^- permeabilities in the pancreatic acinar cell and to increase K⁺ and Na⁺ permeabilities in the salivary gland [11,24].     

Machine vision based stochastic analysis of cancer cell mitochondrial dysfunction induced by a BH3 domain

We have developed a versatile and rapid method for the quantitative estimation of cell death kinetics, following direct single-shot activation of the mitochondrial death pathway by a cell permeable BH3 activator peptide (D-R₈BH3^BID). This approach employs timelapse epifluorescent imaging of live cells and a machine- vision based feature extraction algorithm, to measure unidirectional stochastic transitions associated with mitochondrial inner membrane potential depolarization and/or permeability transition, at single cell resolution. This data is transformed to enable construction of a right step-wise survival function using the product limit estimator, and estimation of a median latency parameter (λ), defined for the entire imaged cell population. Estimates of λ computed for cells exhibiting two-colour fluorescence can be compared statistically using the Mantel-Hansel test. This general method has been applied to measure the kinetics and temporal ordering of BH3 domain induced mitochondrial depolarization and inner membrane permeabilization in cancer cells, and demonstrates the robustness of this technique in resolving temporally distinct intracellular events within individual cells.     

Further electrophysiological studies on cellular effect of herbicide, bromoxynil, using characean cells

In the previous paper, I reported that 3,5-dibromo-4-hydroxybenzonitrile (bromoxynil) depolarizes the plasma membrane by inhibiting the electrogenic proton pump and discussed that the inhibition is caused by cytosol acidification due to influx of protonated bromoxynil and following release of proton (Shimmen in J Plant Res 123:715–722, 2010). However, a possibility of direct inhibition of the proton pump by bromoxynil flowed into the cell could not be excluded. In the present study, the direct effect of bromoxynil on the proton pump was unequivocally excluded.     

Effect of cell membrane-active antimicrobial agents on membrane potential and viability of mycoplasmas

The membrane potential ofMycoplasma mycoides subsp.capri has been determined to beE _M=−48 mV±10%, inside negative. In this study we investigated the influence of cell membrane-active antimicrobial agents, viz., valinomycin, gramicidin, polymyxin, and clotrimazole, on membrane potential and viability ofM. mycoides subsp.capri. Valinomycin, an ionophore with extreme potassium selectivity, induced a membrane hyperpolarization,E _M=−110 mV. Valinomycin was not cidal, but static to mycoplasmas. Obviously the potassium drain induced by valinomycin can be compensated for by the organisms. Gramicidin is an antibiotic forming cation conduction channels across membranes. It induced a rapid depolarization,E _M=+23 mV, of mycoplasma membranes. At low concentrations, gramicidin had a static effect, whereas at high concentrations it was cidal to mycoplasmas. The rapid permeation of cations through the stationary ion channels formed by gramicidin obviously exerts an inhibitory or even lethal effect on mycoplasma metabolism and growth. Polymyxin B induced a depolarization,E _M=−35 mV, of mycoplasma membranes only when the organisms had been pretreated and hyperpolarized with valinomycin. After treatment with both valinomycin and polymyxin B, a slight inhibition of mycoplasma growth was observed. Clotrimazole, a synthetic imidazole antimycotic, hyperpolarized mycoplasma membranes (E _M=−80 mV). At high concentrations clotrimazole was cidal, whereas at low concentrations it was static to mycoplasmas.     

ATP-sensitive K+ channels in an insulin-secreting cell line are inhibited byd-glyceraldehyde and activated by membrane permeabilization

Summary The control of K⁺ channels in the insulin-secreting cell line RINm5F has been investigated by patch-clamp singlechannel current recording experiments. The unitary current events recorded from cell-attached patches are due to large and small inwardly rectifying ATP-sensitive K⁺ channels with conductance properties similar to the two channels previously identified in primary cultured rat islet cells (Findlay, I., Dunne, M.J., & Petersen, O. H.J. Membrane Biol. 88:165–172, 1985). Cell permeabilization through brief exposure to 10 m digitonin or 0.05% saponin (outside the isolated membrane patch area) results in a dramatic increase in current through the cell-attached patch due to opening of many large and small K⁺-selective channels. These channels are inhibited in a dose-dependent manner by ATP applied to the bath (near-complete inhibition by 5mm ATP). During prolonged ATP exposure (1–5 min) the initial inhibition is followed by partial recovery of channel activity, although further activation does occur when ATP is subsequently removed. From the maximal number of coincident channel openings in the permeabilized cells (in the absence of ATP), it is estimated that there are on average 12 large ATP-sensitive K⁺ channels per membrane patch, but in the intact cells less than 5% of the membrane patches exhibited three or more coincident K⁺ channel openings, indicating the degree to which the channels are inhibited in the resting condition by endogenous ATP. Stimulation of RINm5F cells to secrete insulin was carried out by challenging intact cells with 10mm d-glyceraldehyde.d-glyceraldehyde induced depolarization of the membrane from about –70 to –20 mV and evoked a marked reduction in the open-state probability of both the large and small ATP-sensitive channels.d-glyceraldehyde also induced action potentials in a number of cases. All effects of stimulation were largely transient, lasting about 100 sec. The two ATP-sensitive K⁺ channels are probably responsible for the resting potential and play a crucial role in coupling metabolism to membrane depolarization.     

Effects of microtubule agents on the spatial and electrical properties of the plasma membrane inChara corallina

The freshwater algaChara corallina Klein ex Willd., em. R.D.W. (=C. australis R.Br.) develops alternating outward (acid) and inward (alkaline) current areas on its surface when illuminated. Exposure of cells to vinblastine, colchicine, or oryzalin caused a reduction in and a shifting of this extracellular current pattern. Removal of these agents from the bathing media resulted in regeneration of the initial current profile. Because these agents all affect tubulin, microtubules may be responsible for orchestrating the transmembrane currents responsible for the acid and alkaline banding phenomenon. Analysis of the membrane potential showed a fast depolarization after vinblastine exposure; however, analysis of the current-voltage curve did not show a change in membrane conductance. A 30-min colchicine treatment decreased the conductance of the plasma membrane with either an hyperor a depolarization in the membrane potential. In contrast, although a 9-h exposure to oryzalin caused a major reduction in the extra-cellular current pattern, only minor changes were observed in the membrane potential and conductance. However, in the presence of oryzalin, the time constants in the light response of the membrane potential increased over this 9-h period. Collectively, these results implicate an involvement of microtubules in spatial control of plasma-membrane transport events inC. corallina. This research was supported by National Science Foundation grant DCB-88-16077.