P-chloromercuribenzene sulfonate blocks and reverses the effect of amiloride on sodium transport across rabbit colon in vitro.

The addition of 10(-3) M p-chloromercuribenzene sulfonate (PCMBS) to the solution bathing the mucosal surface of rabbit colon has no effect on the rate of active Na transport but blocks or reverses the inhibitory action of amiloride. The tissue must be exposed to PCMBS for 20-30 min for a complete blocking effect, and removal of PCMBS from the mucosal solution after this period of exposure does not restore the sensitivity of the tissue to amiloride. The slow time-courses of the blocking and reversal effects suggest that PCMBS does not irreversibly interact with groups directly involved in the binding of amiloride.     

Parachloromercuribenzenesulfonic Acid : a potential tool for differential labeling of the sucrose transporter

Vicia faba leaf discs without epidermis were pretreated with parachloromercuribenzenesulfonic acid (PCMBS), rinsed and incubated on [¹⁴C]sucrose (1 or 40 millimolar). Those sucrose concentrations were chosen as representative of the apparent uptake system 1 (1 millimolar) and system 2 (40 millimolar) previously characterized. Pretreatment with 0.5 millimolar PCMBS for 20 minutes inhibited system 1 and system 2 by about 70%.

Addition of unlabeled sucrose during PCMBS-pretreatment protected the carrier(s) from the inhibition, whereas glucose, fructose, and sucrose analogs were unable to afford protection. At 1 millimolar [¹⁴C]sucrose, the protection resulted in a small but consistent reduction of normal inhibition (from 63 to 45%) for sucrose concentrations of 50 millimolar and more during pretreatment. Contrarily, at 40 millimolar [¹⁴C]sucrose, the protection increased linearly with the sucrose concentration in the pretreatment medium, and complete prevention of inhibition was reached for 250 millimolar sucrose.

The protection was not due to exchange diffusion and was located in the veins. Michaelian kinetics indicated that PCMBS and sucrose compete with each other at the active site of the carrier.

Among 14 compounds tested (sugars, amino-acids, hormones, ³²P), sucrose uptake was by far the most sensitive to PCMBS. Sucrose preferentially protected its carrier(s) from inhibition. Treatment with 20 millimolar cysteine or 20 millimolar dithioerythreitol reversed inhibition by PCMBS pretreatment.

     

Characteristics of the Amino Acid Transport System in the Mucosal Border of Rabbit Ileum

The specificity of the neutral amino acid transport system in the brush border was examined by studying the ability of amino acid analogues to inhibit the unidirectional influx of phenylalanine from mucosal solution into the cells. Effects were evaluated in terms of the affinity of various substrates for the amino acid site in the transport system. The affinity of amino acids for the site was proportional to the number of carbon atoms in the side chain. Electron-withdrawing substituents in the ring of phenylalanine increased affinity and electron-releasing groups decreased affinity. Removal of the α-amino group from phenylalanine decreased affinity by a factor of approximately 50 and removal of the carboxyl group decreased affinity 12-fold. Effects on affinity of variations in the side chain of the amino acid can be comparable in magnitude to that of the carboxyl group. The effect of sodium ion on the transport system appears to be similar for all compounds tested.     

Turgor regulation of sucrose transport in sugar beet taproot tissue

Sink tissues that store osmotically active compounds must osmoregulate to prevent excessively high turgor. The ability to regulate turgor may be related to membrane transport of solutes and thus sink strength. To study this possibility, the kinetics of sugar uptake were determined in sugar beet (Beta vulgaris L.) taproot tissue discs over a range of cell turgors. Sucrose uptake followed biphasic kinetics with a high affinity saturating component below 20 millimolar and a low affinity linear component at higher concentrations. Glucose uptake exhibited only simple saturation type kinetics. The high affinity saturating component of sucrose and glucose uptake was inhibited by increasing cell turgor (decreasing external mannitol concentrations). The inhibition was evident as a decrease in V_max but no effect on K_m. Sucrose uptake by tissue equilibrated in dilute buffer exhibited no saturating component. Ethylene glycol, a permeant osmoticum, had no effect on uptake kinetics, suggesting that the effect was due to changes in cell turgor and not due to decreased water potential per se. p-(Chloromercuri)benzene sulfonic acid (PCMBS) inhibited sucrose uptake at low but not high cell turgor. High cell turgor caused the tissue to become generally leaky to potassium, sucrose, amino acids, and reducing sugars. PCMBS had no effect on sucrose leakage, an indication that the turgor-induced leakage of sucrose was not via back flow through the carrier. The ability of the tissue to acidify the external media was turgor dependent with an optimum at 300 kilopascals. Acidification was sharply reduced at cell turgors above or below the optimum. The results suggest that the secondary transport of sucrose is reduced at high turgor as a result of inhibition of the plasma membrane ATPase. This inhibition of ATPase activity would explain the reduced V_max and leakiness to low molecular weight solutes. Cell turgor is an important regulator of sucrose uptake in this tissue and thus may be an important determinant of sink strength in tissues that store sucrose.     

Effect of PCMBS on water transfer across biological membranes

P-chloromercuriphenylsulfonate, PCMBS, and 5, 5′ dithiobis-(2-nitrobenzoic acid), DTNB at a concentration of 1 mM are found to inhibit the rate of water transport across human red cell membrane. In addition PCMBS inhibits the rates of transport of small hydrophilic but not hydrophobic nonelectrolytes. Other sulfhydryl reagents such as N-ethylmaleimide and iodoacetamide have no significant effect on the rate of water transfer in these cells. The results suggest that there are at least two populations of membrane bound SH-groups which differ in their topical location which participate in the control of water transfer. One is located closer to the outer surface of the membrane, and thus is readily accessible to PCMBS while the other component is probably located in the membrane interior. These two populations can be dissociated by pH. The effect of PCMBS on water transfer can be greatly influenced by pH and temperature. The main effect of temperature and pH is on the permeability of the membrane to the drug. The same concentration of PCMBS is also found to inhibit to a lesser degree water transfer across other biological membranes.     

Tryptophan and phenylalanine transport in rat cerebral cortex slices as influenced by sodium ions

Tryptophan and phenylalanine transport in rat cerebral cortex slices was studied in sodium-free media and during influx and efflux of sodium ions. Choline as a substitute for sodium in incubation media increased efflux and decreased influx of tryptophan and phenylalanine. Exchange of intracellular [³H]tryptophan and [³H]phenylalanine with extracellular unlabeled histidine, phenylalanine, and tryptophan was sodium-independent. Efflux of sodium ions from the slices had no immediate effects on phenylalanine and tryptophan efflux, but influx decreased. Influx of sodium into the sodium-depleted slices provoked a transient increase in tryptophan and phenylalanine efflux and also enhanced influx. The results are interpreted to indicate that sodium ions may possibly affect the function of the primary transport sites for aromatic amino acids at cerebral membranes by controlling the orientation of their reactive sites towards the intracellular and extracellular sides, rather than by being directly involved in the binding of amino acids to the carriers.     

Plasmalemma Chloride Transport in Chara corallina: Inhibition by 4,4'-Diisothiocyano-2,2'-Disulfonic Acid Stilbene

Chloride transport, presumably via a Cl⁻-2H⁺ co-transport system, was investigated in Chara corallina. At pH 6.5, the control influx (3.1 picomoles per centimeter² per second) was stimulated 4-fold by an 18-hour Cl⁻ starvation. The stimulated influx was inhibited to 4.7 picomoles per centimeter² per second after a 60-minute pre-exposure to 0.5 millimolar 4,4′-diisothiocyano-2,2′-disulfonic acid stilbene (DIDS). This compares with a nonsignificant inhibition of the control under similar conditions. At 2 millimolar DIDS, both stimulated and control influx were inhibited to values of 1.1 and 2.2 picomoles per centimeter² per second, respectively; in all cases, DIDS inhibition was reversible. Over the pH range 4.8 to 8.5, the control and DIDS-inhibited influx showed only slight pH sensitivity; in contrast, the stimulated flux was strongly pH dependent (pH 6.5 optimum). Inasmuch as changes in pH alter membrane potential, N-ethylmaleimide was used to depolarize the membrane; this had no effect on Cl⁻ influx. A transient depolarization of the membrane (about 20 millivolts) was observed on restoration of Cl⁻ to starved cells. The membrane also depolarized transiently when starved cells were exposed to 0.5 millimolar DIDS, but the depolarization associated with Cl⁻ restoration was inhibited by a 40-minute pretreatment with DIDS. Exposure of control cells to DIDS caused only a small hyperpolarization (about 7 millivolts). DIDS may have blocked Cl⁻ influx by inhibiting the putative plasmalemma H⁺-translocating ATPase. Histochemical studies on intact cells revealed no observable effect of DIDS on plasmalemma ATPase activity. However, DIDS application after fixation resulted in complete inhibition of ATPase activity.

The differential sensitivity of the stimulated and control flux to inhibition by DIDS may reflect an alteration of transport upon stimulation, but could also result from differences in pretreatment. The stimulated cells were pretreated with DIDS in the absence of Cl⁻, in contrast to the presence of Cl⁻ during pretreatment of controls. The differential effect could result from competition between Cl⁻ and DIDS for a common binding site. Our histochemical ATPase results indicate that Cl⁻ transport and membrane ATPase are separate systems, and the latter is only inhibited by DIDS from the inside of the cell.

     

Characterization of the uptake of sucrose and glucose by isolated seed coat halves of developing pea seeds. Evidence that a sugar facilitator with diffusional kinetics is involved in seed coat unloading

Uptake of ¹⁴C-labelled sucrose and glucose by isolated seed coat halves of pea (Pisum sativum L. cv. Marzia) seeds was measured in the concentration range <0.1 μM to 100 mM. The initial influx of sucrose was strictly proportional to the external concentration, with a coefficient of proportionality (k) of 6.2 μmol·(g FW)^?1·min^?1·M^?1. Sucrose influx was not affected by 10 μM carbonylcyanide m-chlorophenylhydrazone (CCCP), but it was inhibited by 40% in the presence of 2.5 mM p-chloromercuribenzenesulfonic acid (PCMBS). Influx with diffusional kinetics was also observed for glucose (k = 4.8 μmol·(g FW)^?1·min ^?1·M ^?1) and mannitol (k = 5.1 μmol·(g FW)^?1·min^?1·M^?1). For glucose an additional saturable system was found (K_m = 0.26 mM, V _max = 4.2 nmol·(g FW)^?1·min^?1), which appeared to be completely inhibited by CCCP and partly by PCMBS. In contrast to the diffusional pathway, uptake by this saturable system was slightly pH-dependent, with an optimum at pH 5.5. The influx of sucrose appears to be by the same pathway as the efflux of endogenous sucrose, which was inhibited by 36% in the presence of 2.5 mM PCMBS (De Jong A, Wolswinkel P, 1995, Physiol Plant 94: 78–86). It is argued that passive transport may be the only mechanism for sucrose transport through the plasma membrane of seed coat parenchyma cells. The estimated permeability coefficient of the plasma membrane for sucrose (P = 3.5·10^?7 cm·s^?1) is more than 1 × 10⁶-fold higher than that reported for artificial lipid membranes. This relatively high permeability is hypothesized to result from pore-forming proteins that allow the diffusion of sucrose. Furthermore, it is shown that a sucrose gradient across the plasma membrane of the seed coat parenchyma of only 22 mM will suffice to result in the net efflux of sucrose which is required to feed the embryo.     

Separation of phenylalanine transport events by using selective inhibitors, and identification of a specific uncoupler activity in Yersinia pestis.

Phenylalanine transport in Yersinia pestis TJW was differentially inhibited by sulfhydryl blocking reagents, uncoupling agents, and respiratory inhibitors. Kinetic studies with potassium cyanide and sodium azide showed that these compounds have no immediate effect on the initial rate of phenylalanine transport, but have an immediate and severe inhibitory effect on the rate of oxygen uptake. Identical studies with p-chloromercuribenzoate (pCMB) and 2,4-dinitrophenol (DNP) showed that these compounds have an instantaneous and total inhibitory effect on phenylalanine transport. DNP stimulated oxygen uptake, and pCMB caused only a sluggish inhibiton of oxygen uptake. pCMB acted as a competitive inhibitor of phenylalanine transport, whereas DNP inhibitied noncompetitively. Arrenius plots of the initial rate of phenylalanine transport in pCMB- and DNP-treated cells showed that DNP alters the transition temperature of the phenylalanine transport system from 17 C for control cells to 12 C. DNP did not inhibit transport when cells were treated at temperatures of 2 to 10 C. PCMB did not alter the normal transition temperature and inhibited phenylalanine transport over a 2 to 30 C temperature range. Efflux induced by both pCMB and DNP were blocked by placing cells at low temperatures (2 to 20 C). Inhibition of adenosine 5'-triphosphate synthesis by DNP did not show any temperature sensitivity as did phenylalanine transport. These data indicate that: (i) respiration is not obligatory for active transport of phenylalanine in Y. pestis TJW; and (ii) pCMB inhibits transport activity by reacting with the sulfhydryl group(s) at the carrier binding site. The data show that the uncoupler, DNP, selectively alters a temperature-dependent property of phenylalanine transport, that is not related to uncoupling activity of DNP , and probably involves membrane lipid alterations.     

Amino acid transport in whole cells and membrane vesicles of Arthrobacter pyridinolis

Arginine, and several other amino acids, can only support growth of Arthrobacter pyridinolis if malate is also present in the medium. Arginine is transported by a high affinity lysine-arginine-ornithine-type transport system which is stimulated by malate in both whole cells and vesicles, is respiration-coupled, and appears to depend upon a respiration-generated membrane potential but not on a ΔpH. Arginine is also transported by a low-affinity system which transports canavanine. Studies of an arginine auxotroph suggest that the lysine-arginine-ornithine system may be the system of major physiological significance for arginine transport. Phenylalanine is one of a few amino acids which can act as sole source of carbon for A. pyridinolis. Transport of phenylalanine occurs by two kinetically distinct systems. Both of these transport systems are respiration-coupled, are not appreciably stimulated by malate either in cells or vesicles, but are markedly stimulated by ascorbate-phenazine methosulfate. Studies with inhibitors indicate that the transport systems for phenylalanine utilize both a ΔpH and a membrane potential.     

The Effect of Sugars on the Binding of [Hg]-p-Chloromercuribenzenesulfonic Acid to Leaf Tissues

Replacement of mannitol with sucrose decreases the binding of [²⁰³Hg]-p-chloromercuribenzenesulphonic acid (PCMBS) to Vicia faba leaf discs without epidermis. This decrease is optimal for 20 minutes on incubation, is concentration-dependent, and is also found with maltose and raffinose. In parallel experiments, the addition of sucrose, maltose, and raffinose during PCMBS pretreatment was shown to increase subsequent uptake of [U-¹⁴C]sucrose. In contrast, d- or l-glucose, 3-O-methylglucose, galactose, fructose, palatinose, turanose, or melibiose had no effect either on PCMBS binding or on [¹⁴C]sucrose uptake. The sucrose-induced decrease of PCMBS binding is retained after a cold and ionic shock. Measurements of specific activities of membrane fractions prepared from tissues incubated in labeled PCMBS show that the decrease concerns the 120,000 gravity pellet, but that very mild procedures must be chosen to prevent redistribution of label in the supernatant. Altogether, the data provide new support to the hypothesis that the active site of the sucrose carrier contains a group sensitive to PCMBS.     

Potassium Transport in Corn Roots : II. The Significance of the Root Periphery

The relative transport capabilities of the cells of the root periphery and cortex were investigated using a variety of experimental techniques. Brief (30 seconds to 1 minute) exposures with the penetrating sulfhydryl reagent, N-ethyl maleimide (NEM), and the impermeant reagent, p-chloromercuribenzene sulfonic acid (PCMBS), dramatically reduced ⁸⁶Rb⁺ (0.2 millimolar RbCl) uptake into 2 centimeter corn (Zea mays [A632 × (C3640 × Oh43)]) root segments. Autoradiographic localization studies with [³H]NEM and [²⁰³Hg]PCMBS demonstrated that, during short term exposures with either reagent, sulfhydryl binding occurred almost exclusively in the cells of the root periphery.

Corn root cortical protoplasts were isolated, and exhibited significant K⁺(⁸⁶Rb⁺) influx. The kinetics for K⁺ uptake were studied; the influx isotherms were smooth, nonsaturating curves that approached linearity at higher K⁺(Rb⁺) concentrations (above 1 millimolar K⁺). These kinetics were identical in shape to the complex kinetics previously observed for K⁺ uptake in corn roots (Kochian, Lucas 1982 Plant Physiol 70: 1723-1731), and could be resolved into a saturable and a first order kinetic component.

The existence of a hypodermal apoplastic barrier was investigated. The apoplastic, cell wall binding dye, Calcofluor White M2R, appeared to be excluded from the cortex by the hypodermis. However, experiments with damaged roots indicated that this result may be an artifact resulting from the binding of dye to the epidermal cell walls. Furthermore, [²⁰³Hg] PCMBS autoradiography demonstrated that the hypodermis was not a barrier to apoplastic movement of PCMBS.

These results suggest that although cortical cells possess the capacity to absorb ions, K⁺ influx at low concentrations is limited to the root periphery. Cortical cell uptake appears to be repressed under these conditions. At higher concentrations, cortical cells may function to absorb K⁺. Such a model may involve regulation of cortical cell ion transport capacity.

     

Effect of azetidine 2-carboxylic Acid on ion uptake and ion release to the xylem of excised barley roots

Azetidine 2-carboxylic acid (AZ) was used as an analog of proline to investigate further the relationship between protein synthesis and ion transport. AZ does not inhibit protein assembly, but the proteins formed are ineffective as enzymes. At relatively low concentrations (50 μM) AZ was a potent inhibitor of release of ions to the xylem of excised roots of barley (Hordeum vulgare L.) and intact plants. Uptake to the root was also inhibited but to a lesser degree. A procedure was introduced for estimating unidirectional fluxes from measurements of net tracer uptake, net transport to the xylem, and net efflux from the roots. It was shown that inhibition of release to the xylem was not caused by reduction in influx at the plasmalemma or to stimulation of influx to the vacuoles. It was suggested that AZ was acting on the process of release from symplast to the xylem. The action of AZ is compared with similar effects on ion transport produced by p-fluorophenylalanine, cycloheximide, and abscisic acid.     

Inhibition of sodium-independent amino acid transport by dexamethasone in rat hepatoma cells

We studied the uptake of leucine, phenylalanine, and the amino acid analog, 2-aminonorborane-2-carboxylic acid, by rat hepatoma cells in tissue culture. The uptake of these amino acids was partially mediated by a plasma membrane transport system similar to the L agency described in other cell types in that it does not require extracellular sodium and is subject to trans-stimulation. Initial rates of sodium-independent transport of these amino acids were calculated using mathematical transformations of the uptake time course curves. The glucocorticoid dexamethasone inhibits the activity of this transport system; the initial rates of sodium-independent uptake of leucine, phenylalanine, and 2-aminonorborane-2-carboxylic acid are decreased by approximately one-third (average = 30%, n = 19) after incubation of HTC cells with 0.1 microM dexamethasone. This inhibition requires at least 15 h, reaching a maximum at 24 h of exposure of the cells to the hormone. Dexamethasone has an asymmetrical effect on sodium-independent amino acid transport in that exposure of the cells to the hormone does not inhibit the rates of outflow of leucine or phenylalanine from preloaded cells into medium without sodium. Inhibition of uptake is blocked by 0.1 mM cycloheximide and 4 microM actinomycin D, indicating the need for continuous protein synthesis for dexamethasone action. Insulin, which is known to partially reverse the inhibitory effect of dexamethasone on the A amino acid transport system in HTC cells, does not alter the action of dexamethasone on the L system. Previous investigations have demonstrated inhibition by dexamethasone of at least two distinct sodium-dependent amino acid transport activities in HTC cells. The data presented here, showing inhibition by the glucocorticoid of a sodium-independent transport activity, indicate that the effect of the hormone is independent of the energy source of the amino acid transport systems affected.     

Mercurial perturbation of brush border membrane permeability in rabbit ileum

The sulfhydryl reagents Hg++ and p-chloromercuribenzene sulfonate (PCMBS) at millimolar concentrations reduced the mucosal entry of sugars and amino acids to 80-90% of control levels within several minutes. Based on 50% levels of inhibition, Hg++ proved to be 20 and 10 times as potent as PCMBS in blocking sugar and amino acid transport, respectively; both systems were equally sensitive to Hg++. Concomitant measurements of 203Hg-PCMBS demonstrated a progressive tissue uptake, which, unlike inhibition, did not saturate with increasing times of exposure, thus suggesting appreciable epithelial entry with prolonged exposures (less than 30 min at 1 mM). At similar dose levels, no significant change in mucosal Na+ entry was detected. Inhibition was not reversed by 30-min washes in cholinesalt solutions; however, 10-min exposures to dithiothreitol [10 mM] reversed Hg++ and PCMBS inhibition by 40 and 100%, respectively. Alanine and galactose influx kinetics measured at concentrations of 0-100 mM exhibited a linear or diffusional entry component in addition to the usual saturable component for both control and Hg++-treated ileum. The presence of a diffusional term in the flux equation resulted in two sets of parameters giving nearly equal fits to these measurements. It was shown that this ambiguity could be resolved by determining the change in diffusional entry with Hg++ treatment. A 20-min exposure to 0.5 mM Hg++ caused an increase from 0.050 and 0.045 to 0.064 and 0.070 cm/hr in the coefficient of diffusional entry for alanine and galactose, respectively. On the basis of this increase, it is argued that Hg++ causes a decrease in Jmax and little change in Km for both transport mechanisms. This analysis has a general bearing on kinetic measurements of transport in which passive fluxes are comparable to those mediated by specific pathways. The alanine results are consistent with bimolecular reactions between mercurial and two membrane inhibitory sites, each producing approximately 40% reduction in membrane translocation rate. The estimated reaction rate constants were 5.0 and 0.4 mM min.     

KINETIC ANALYSIS OF PHENYLALANINE-INDUCED INHIBITION IN THE SATURABLE INFLUX OF TYROSINE, TRYPTOPHAN, LEUCINE AND HISTIDINE INTO BRAIN CORTEX SLICES FROM ADULT AND 7-DAY-OLD RATS

—An attempt was made to isolate the saturable uptake from the unidirectional influx of amino acids into tissue slices and to estimate the transport constants and maximal velocities of saturable transport. The method was applied to studies on the inhibition of phenylalanine in the saturable influx of tyrosine, tryptophan, histidine and leucine into brain cortex slices from adult and 7-day-old rats. In both age groups phenylalanine inhibited the influx of the other amino acids, and vice versa. The apparent transport constants of the other amino acids increased in the presence of phenylalanine more noticeably in the slices from 7-day-old rats than in those from adult rats, whereas the concomitant influx of phenylalanine was inhibited less in the slices from 7-day-old rats. In immature animals in vivo competition between amino acids may play a more marked role in the supply of amino acids from plasma to brain, as the transport systems in brain slices from 7-day-old rats become saturated with extracellular amino acids more readily than do the transport systems in brain slices from adult rats.     

Effect of papain treatment on phenylalanine transport in rabbit ileum.

The unidirectional influx of phenylalanine across the mucosal brush border of rabbit ileum is reduced by pretreatment with papain. Phenylalanine influx is reduced to 10–15% of the control value by 60–90 minutes of preincubation with papain. Pretreatment with protease from $\text{Streptomyces griseus}$ has no effect on phenylalanine influx. Kinetic analysis of the effect of papain indicates that the maximum velocity is reduced with little change in the apparent Michaelis-constant for phenylalanine. The data suggest that papain attacks a membrane protein required for transport. This protein is unaffected by protease which indicates the susceptible region of the protein is shielded by the membrane or inaccessible to protease.     

Induction of nitrate transport in maize roots, and kinetics of influx, measured with nitrogen-13

Unlike phosphate or potassium transport, uptake of nitrate by roots is induced, in part, by contact with the substrate ion. Plasmalemma influx of ¹³N-labeled nitrate in maize roots was studied in relation to induction of the uptake system, and the influence of short-term N starvation. Maize (Zea mays) roots not previously exposed to nitrate had a constitutive transport system (state 1), but influx increased 250% during six hours of contact with 100 micromolar nitrate, by which time the transport mechanism appeared to be fully synthesized (state 2). A three-day period of N starvation prior to induction and measurement of nitrate influx resulted in a greater capacity to transport nitrate than in unstarved controls, but this was fully expressed only if roots were kept in contact with nitrate for the six hours needed for full induction (state 2E). A kinetic analysis indicated a 160% increase in maximum influx in N-starved, induced roots with a small decrease in K_m. The inducible component to nitrate influx was induced only by contact with nitrate. Full expression of the nitrate inducible transport system was dependent upon mRNA synthesis. An inhibitor of cytoplasmic protein synthesis (cycloheximide) eliminated the formation of the transport system while inhibition by chloramphenicol of mitochondrial- or plastid-coded protein synthesis had no effect. Poisoning of membrane-bound proteins effectively disabled both the constitutive and induced transport systems.     

Chemical Modification of Membranes : II. Permeation paths for sulfhydryl agents

The amino-reactive reagent, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS),¹ considerably reduces the uptake of the sulfhydryl agent, parachloromercuriphenylsulfonic acid (PCMBS), but does not reduce its effects on cation permeability and on cation transport. These data indicate that PCMBS enters the membrane by at least two channels, one sensitive and the other insensitive to SITS, with only the latter leading to the cation-controlling sulfhydryl groups. Substitution of phosphate or sulfate for chloride results in an inhibition of PCMBS uptake via the SITS-insensitive pathway. These and other data lead to the conclusion that the SITS-sensitive pathway is the predominant one for anion permeation, and the insensitive one for cation permeation. Parachloromercuribenzoate (PCMB), an agent that is more lipid-soluble than PCMBS, penetrates faster but has a smaller effect on cation permeability. Its uptake is less sensitive to SITS. These and other observations suggest that the cation permeation path involves an aqueous channel in the membrane.     

Potassium transport in corn roots : I. Resolution of kinetics into a saturable and linear component

Influx isotherms were obtained for ⁸⁶Rb⁺ uptake into 2-cm corn (Zea mays [A632 × (C3640 × Oh43)] root segments for both low- (0.2 millimolar CaSO₄) and high-salt (0.2 millimolar CaSO₄ + 5 millimolar KCl) grown roots. Unlike the discontinuous curves usually presented for K⁺ influx, our isotherms were smooth, nonsaturating curves that approached linearity at K⁺ (Rb⁺) concentrations above 1 millimolar. The kinetics for K⁺ transport could be resolved into saturable and linear components. The saturable components yielded K_m values of 16 and 86 micromolar for low- and high-salt roots, respectively, while V_max values were 5.62 and 1.85 moles per gram fresh weight per hour. Results of experiments with the penetrating sulfhydryl reagent, N-ethyl maleimide (NEM), and the impermeant reagent, p-chloromercuribenzene sulfonic acid (PCMBS) indicated that the saturable and linear components were independent mechanisms of K⁺ transport.

Short-term NEM exposures (30 seconds to 5 minutes) selectively inhibited the saturable system, but had little effect on the linear component. Increasing NEM exposures resulted in further inhibition and subsequent abolition of the saturable component; the linear component exhibited limited NEM sensitivity. PCMBS elicited the same general inhibitory trends, although it was less effective as a saturable component inhibitor.

The effects of NEM and PCMBS on K⁺ efflux were also studied. Short NEM exposures had no effect on cytoplasmic efflux, while inhibiting vacuolar efflux significantly. From these data, it is unclear at which site(s) NEM is acting. A more complex response was obtained with PCMBS, where a monophasic efflux curve was observed. Analysis indicated that the vacuolar efflux was stimulated, while the cytoplasmic component was abolished.

The nature of the linear component is discussed, and it is proposed that the mechanism may be more complex than simple facilitated diffusion.