Further studies on the charge-related alterations of methotrexate transport in Ehrlich ascites tumor cells by ionic liposomes: Correlation with liposome-cell association

Summary Interaction of positively (phosphatidylcholine/stearylamine 51) or negatively (phosphatidylcholine/stearic acid 51) charged liposomes with Ehrlich ascites tumor cells for 1–5 min increases or decreases, respectively, the bidirectional fluxes of the folic acid analog, methotrexate. These effects on influx and efflux appear to be symmetrical since the liposomes do not change the intracellular level of methotrexate at the steady state. Influx kinetics show that these alterations result from an increase or decrease in theV _max with no change in theK _m ⁱⁿ . These effects appear to be specific for the methotrexate-tetrahydrofolate carrier system since the transport of other compounds which utilize this carrier, aminopterin, 5-methyltetrahydrofolate, and 5-formyltetrahydrofolate, is affected similarly to methotrexate, whereas, the transport of folic acid, a compound similar in structure and charge but not significantly transported by this carrier is unaffected by liposomes. Once cells are exposed to charged liposomes, the effects on methotrexate transport cannot be reversed by washing the cells free of the extracellular liposomes. If, however, cells are exposed to liposomes of one charge, washed and then exposed to liposomes of the opposite charge, methotrexate influx is reversed to control rates. The effects of charged liposomes on methotrexate influx were not abolished by treating the cells with neuraminidase, metabolic inhibitors or lowering the temperature to 4°C. Studies on the uptake of [¹⁴C] liposomes show that these effects are not proportional to the total amount of lipid associated with the cell but result from an initial rapid liposome-cell association that is not dependent on temperature or energy metabolism nor related to cell surface charge.     

Characterization of the multiple transport routes for methotrexate in L1210 cells using phthalate as a model anion substrate

Summary o-Phthalate is actively transported into L1210 cells and the primary route for cell entry is the same transport system which mediates the influx of methotrexate and other folate compounds. The identity of the influx route has been established by the following observations: (A) Phthalate influx is competitively inhibited by methotrexate and the inhibition constant (K _i ) is comparable to theK _i for half-maximal influx of methotrexate; (B) Various anions inhibit the influx of phthalate and methotrexate with comparableK _i values; (C) The influx of phthalate and methotrexate both fluctuate in parallel with changes in the anionic composition of the external medium; and (D) A specific covalent inhibitor of the methotrexate transport system (NHS-methotrexate) also blocks the transport of phthalate. In contrast, the efflux of phthalate does not occur via the methotrexate influx carrier, but rather by two separate processes which can be distinguished by their sensitivities to bromosulfophthalein. Efflux via the bromosulfophthalein-sensitive route constitutes 75% of total efflux and is enhanced by glucose and inhibited by oligomycin. The inability of phthalate to exit via the methotrexate influx carrier is due to competing intracellular anions which prevent phthalate from interacting with the methotrexate binding site at the inner membrane surface.     

Effects of metabolic deprivation on methotrexate transport in L1210 leukemia cells: Further evidence for separate influx and efflux systems with different energetic requirements

Summary Measurements of methotrexate transport in L1210 cells in the presence and absence ofd-glucose reveal that both influx and efflux are depressed in the absence ofd-glucose, whereas the steady-state accumulation of drug is enhanced. The reason for the increase in steady state is that the relative decline in efflux is greater than the decline in influx. Analysis of the concentration dependence of steady-state methotrexate accumulation ind-glucose-deprived cells indicates a linear relationship consistent with a one-carrier active transport model. Similar data in nondeprived cells is highly nonlinear and strongly supports the postulate that under physiological conditions influx and efflux of methotrexate are mediated by separate carrier systems. These results indicate that the efflux system, preferentially transporting methotrexate under normal conditions, cannot operate in the absence ofd-glucose, whereas the influx system is only partially inhibited under conditions of glucose deprivation.     

A model system for the study of heteroexchange diffusion: Methotrexate-folate interactions in L1210 leukemia and Ehrlich ascites tumor cells

A unique interaction between the folate analog, methotrexate (4-amino-4-deoxy-10-methylpteroylglutamic acid), and the naturally occurring folates in L1210 leukemia and Ehrlich ascites tumor cells provides a useful model for the study of heteroexchange diffusion. The presence of intracellular binding sites with a high affinity for methotrexate but a low affinity for folic acid and its tetrahydrofolate derivatives permit the measurement of true unidirectional influx rates for methotrexate and assure that the trans-stimulation of methotrexate uptake by the intracellular presence of the other folates is due solely to a primary augmentation of this carrier influx mechanism. Further, since free methotrexate does not appear prior to saturation of the binding sites, the reaction between the folates and carrier at the inner cell membrane is undisturbed by methotrexate released from carrier as the complex enters the cell during heteroexchange, facilitating quantitation of the kinetic alterations which occur for methotrexate influx during trans-stimulation.     

Leukotriene D4-induced Ca2+ Mobilization in Ehrlich Ascites Tumor Cells

Stimulation of Ehrlich ascites tumor cells with leukotriene D₄ (LTD₄) within the concentration range 1–100 nm leads to a concentration-dependent, transient increase in the intracellular, free Ca²⁺ concentration, [Ca²⁺] _i . The Ca²⁺ peak time, i.e., the time between addition of LTD₄ and the highest measured [Ca²⁺] _i value, is in the range 0.20 to 0.21 min in ten out of fourteen independent experiments. After addition of a saturating concentration of LTD₄ (100 nm), the highest measured increase in [Ca²⁺] _i in Ehrlich cells suspended in Ca²⁺-containing medium is 260 ± 14 nm and the EC₅₀ value for LTD₄-induced Ca²⁺ mobilization is estimated at 10 nm. Neither the peptido-leukotrienes LTC₄ and LTE₄ nor LTB₄ are able to mimic or block the LTD₄-induced Ca²⁺ mobilization, hence the receptor is specific for LTD₄. Removal of Ca²⁺ from the experimental buffer significantly reduces the size of the LTD₄-induced increase in [Ca²⁺] _i . Furthermore, depletion of the intracellular Ins(1,4,5)P₃-sensitive Ca²⁺ stores by addition of the ER-Ca²⁺-ATPase inhibitor thapsigargin also reduces the size of the LTD₄-induced increase in [Ca²⁺] _i in Ehrlich cells suspended in Ca²⁺-containing medium, and completely abolishes the LTD₄-induced increase in [Ca²⁺] _i in Ehrlich cells suspended in Ca²⁺-free medium containing EGTA. Thus, the LTD₄-induced increase in [Ca²⁺] _i in Ehrlich cells involves an influx of Ca²⁺ from the extracellular compartment as well as a release of Ca²⁺ from intracellular Ins(1,4,5)P₃-sensitive stores. The Ca²⁺ peak times for the LTD₄-induced Ca²⁺ influx and for the LTD₄-induced Ca²⁺ release are recorded in the time range 0.20 to 0.21 min in four out of five experiments and in the time range 0.34 to 0.35 min in six out of eight experiments, respectively. Stimulation with LTD₄ also induces a transient increase in Ins(1,4,5)P₃ generation in the Ehrlich cells, and the Ins(1,4,5)P₃ peak time is recorded in the time range 0.27 to 0.30 min. Thus, the Ins(1,4,5)P₃ content seems to increase before the LTD₄-induced Ca²⁺ release from the intracellular stores but after the LTD₄-induced Ca²⁺ influx. Inhibition of phospholipase C by preincubation with U73122 abolishes the LTD₄-induced increase in Ins(1,4,5)P₃ as well as the LTD₄-induced increase in [Ca²⁺] _i , indicating that a U73122-sensitive phospholipase C is involved in the LTD₄-induced Ca²⁺ mobilization in Ehrlich cells. The LTD₄-induced Ca²⁺ influx is insensitive to verapamil, gadolinium and SK&F 96365, suggesting that the LTD₄-activated Ca²⁺ channel in Ehrlich cells is neither voltage gated nor stretch activated and most probably not receptor operated. In conclusion, LTD₄ acts in the Ehrlich cells via a specific receptor for LTD₄, which upon stimulation initiates an influx of Ca²⁺, through yet unidentified Ca²⁺ channels, and an activation of a U73122-sensitive phospholipase C, Ins(1,4,5)P₃ formation and finally release of Ca²⁺ from the intracellular Ins(1,4,5)P₃-sensitive stores. Received: 9 February 1996/Revised: 15 August 1996     

Regulation of taurine transport in Ehrlich ascites tumor cells

Summary Taurine influx is inhibited and taurine efflux accelerated when the cell membrane of Ehrlich ascites tumor cells is depolarized. Taurine influx is inhibited at acid pH partly due to the concomitant depolarization of the cell membrane partly due to a reduced availability of negatively charged free carrier. These results are in agreement with a 2Na, 1Cl, 1taurine cotransport system which is sensitive to the membrane potential due to a negatively charged empty carrier. Taurine efflux from Ehrlich cells is stimulated by addition of LTD4 and by swelling in hypotonic medium. Cell swelling in hypotonic medium is known to result in stimulation of the leukotriene synthesis and depolarization of the cell membrane. The taurine efflux, activated by cell swelling, is dramatically reduced when the phospholipase A₂ is inhibited indirectly by addition of the anti-calmodulin drug pimozide, or directly by addition of RO 31-4639. The inhibition is in both cases lifted by addition of LTD₄. The swelling-induced taurine efflux is also inhibited by addition of the 5-lipoxygenase inhibitors ETH 615-139 and NDGA. It is concluded that the swelling-induced activation of the taurine leak pathway involves a release of arachidonic acid from the membrane phospholipids and an increased oxidation of arachidonic acid into leukotrienes via the 5-lipoxygenase pathway. LTD₄ seems to act as a second messenger for the swelling induced activation of the taurine leak pathway either directly or indirectly via its activation of the Cl^– channels, i.e., via a depolarization of the cell membrane.     

Evidence for a specific fructose carrier inRhodotorula glutinis based on kinetic studies with a mutant defective in glucose transport

The mutant R₃₃ of the obligatory aerobic yeastRhodotorula glutinis exhibited a defect ind-glucose uptake. Detailed kinetic studies ofd-glucose andd-fructose transport in wild-type and mutant strains provided evidence for the existence in the plasma membrane of a carrier specific for fructose. The transport ofd-fructose in the mutant exhibited saturation kinetics up to 1 mmol/Ld-fructose; at higher concentrations the rate ofd-fructose uptake decreased. In the wild-type strain biphasicd-fructose uptake kinetics were observed; the low-affinity component was not found in the mutant, but the high-affinity transport system persisted. During the exponential phase of growth (ond-glucose) the high-affinityd-fructose system was repressed in the wild-type strain. Mutual competition betweend-fructose andd-glucose as well as the pH dependence of transport of the two hexoses further supported the following conclusion: In the wild-type strain,d-fructose is taken up both by the specific fructose carrier (K _T=0.22 mmol/L) and the glucose carrier (K _T=9.13 mmol/L). The former does not translocated-glucose, the latter is damaged by the mutation. Finally H⁺ co-transport and plasma membrane depolarization induced by the onset ofd-fructose transport indicated that the fructose carrier is an H⁺ symporter.     

Modulation of apical Na permeability of the toad urinary bladder by intracellular Na,Ca, and H

Summary The Na conductance of the apical membrane of the toad urinary bladder was measured at different concentrations of Na both in the external medium and in the cell. Bladders were bathed in high K-sucrose medium to reduce basal-lateral resistance and voltage, and the transepithelial currents measured under voltage-clamp conditions. Amiloride was used as a specific blocker of the apical Na channel. At constant external Na, the internal Na concentration was increased by blocking the basallateral Na pump with ouabain. With high Na activity in the mucosal medium (86mm), increases in intracellular Na activity from 10 to over 40mm increased the amiloride-sensitive slope conductance at zero voltage while apical Na permeability, estimated from current-voltage plots using the constant field equation, decreased by less than 20%. Lowering the serosal Ca concentration from 1 to 0.1mm had no effect on the change inP _Na with increasing Na_c, but increasing serosal Ca to 5mm enhanced the reduction inP _Na with increasing Na _c , presumably by increasing Ca influx into the cell.P _Na was also reduced by serosal vanadate (0.5mm), a putative blocker of ATP-dependent Ca extrusion from the cell, and by acute exposure to CO₂, which presumably acidifies the cytoplasm. Current-voltage relationships of the amiloridesensitive transport pathway were also measured in the absence of a Na gradient across the apical membrane. These plots show that outward current passes through the channels somewhat less easily than does inward current. The shape of theI-V relationships was not significantly altered by changes in cellular Na, Ca or H, indicating that the effects of these ions onP _Na are voltage independent.     

A mathematical model for membrane transport of amino acid and Na+ in vesicles

Summary A model with a carrier having sites for both amino acid and Na⁺ can account for AIB (-aminoisobutyric acid) transport kinetics observed in membrane vesicles from SV3T3 (simian virus 40-tranformed Balb/c3T3 cells) and 3T3 (the parent cell line). The main feature of this cotransport model is that Na⁺ binding to carrier decreases the effectiveK _m for AIB transport, Na⁺ transport kinetics observed in both vesicle systems can be described by passive (possibly facilitated) diffusion. The lag of Na⁺ transport across the membrane compared to that for AIB, coupled to the Na⁺-dependent decrease in theK _m for AIB, accounts for the overshoot in intravesicular AIB observed for SV3T3 in the presence of an initial Na⁺ gradient. Extra-vesicular Na⁺ maintains a derease in theK _m for AIB influx before intra-vesicular Na⁺ has accumulated to balance it with a comparable decrease in theK _m for AIB efflux. 3T3 vesicles display little overshoot, and this finding can be explained mostly by a lower carrier affinity for Na⁺.     

Effect of sodium on cellular calcium transport in rat kidney

Summary The influence of extracellular Na (Na _o ) on cellular Ca transport and distribution was studied in rat kidney slices. Calcium efflux from prelabeled slices was depressed when Na _o was completely replaced by choline or tetraethylammonium (TEA) ions and it was markedly stimulated when Na was reintroduced in a Na-free medium. However, reducing Na _o (with choline or TEA as substituting ions) did not increase the total slice⁴⁰Ca, their total exchangeable Ca pool, or the⁴⁰Ca or⁴⁵Ca of mitochondria isolated from these slices. Kinetic analyses of steady-state⁴⁵Ca desaturation curves showed that reducing Na _o depressed the exchange of Ca across the plasma membrane, slightly decreased the cytosolic Ca pool, but did not significantly affect the mitochondrial Ca pool and Ca cycling. Ouabain (10^–3 m) which should reduce the Na gradient across the plasma membrane had no effect on calcium distribution and transport. These results suggest that in kidney cells low Na _o depresses Ca influx as well as Ca efflux; there may be an interaction between Na and Ca at a possible carrier located in the plasma membrane, but there is no Na/Ca exchange as described in several excitable tissues.     

Two-compartment behavior during transport of folate compounds in L1210 cell plasma membrane vesicles

Summary The transport of [³H] 1,l 5-formyltetrahydrofolate, [³H] folic acid, and [³H]methotrexate by L1210 cell plasma membrane vesicles exhibited multicompartmental behavior. Two separate vesicular compartments (parallel relationship) of approximately equal volume were revealed during measurements of influx and efflux. Flux in one compartment was rapid, saturable, highly temperature-sensitive, and inhibited by pCMBS. Flux in the other compartment exhibited all of the characteristics of passive diffusion. These results imply that our plasma membrane vesicle preparations consist of a mixture of two functional species. Transport of folate into one of these species occurs by passive diffusion alone, whereas transport into the other kind of vesicle occurs by both passive diffusion and carrier-facilitated transport.     

Lack of stereospecificity at carbon 6 of methyltetrahydrofolate transport in Ehrlich ascites tumor cells. Carrier-mediated transport of both stereoisomers

Nonlabeled and tritiated stereoisomers of 5-methyltetrahydrofolate were prepared and were both shown to be substrates for the high affinity H4 folate cofactor membrane transport carrier in Ehrlich ascites tumor cells. Both the enzymically active form and the isomer having the opposite configuration at carbon 6 inhibited the influx of enzymically synthesized (+)-5-methyltetrahydrofolate, methotrexate, and aminopterin. When added to the media of cells preloaded with methotrexate, both isomers stimulated a net efflux of the antifolate from the cell. Influx of the natural and unnatural isomers followed Michaelis-Menten kinetics with comparable Km values. Each isomer competitively inhibited influx of the other.     

Substrate and inhibitor specificity of the lactate carrier of human neutrophils

Summary The substrate and inhibitor specificity of the lactic acid (Lac) transport system of human neutrophils was investigated. The ability of a variety of compounds to inhibit the influx of [¹⁴C]lactate, presumably reflecting competition by substrate analogues for binding at the external translocation site, was taken as an index of affinity for the Lac carrier. pH-stat techniques were utilized to assess transportability. Results indicate a relatively low order of selectivity, the neutrophil H⁺ + lactate^– cotransport system demonstrating a broad acceptance of short-chain unsubstituted and substituted alkyl monocarboxylates as well as aromatic monocarboxylates. There was a slight preference for oxo, Cl, and OH substituents over other groups at the two-position of short chain alkyl fatty acids: all were readily transported across the plasma membrane at rates approaching that ofl-lactate itself. Aromatic acids were not transported inward by the carrier although these compounds did permeate via simple nonionic diffusion. The neutrophil Lac carrier can be blocked by a number of cyanocinnamate derivatives, the classical inhibitors of monocarboxylate transport in mitochondria, and by dithiol compounds and sulfhydryl-reactive agents. This constellation of biochemical properties is similar to the features that characterize other well described H⁺ + lactate^– cotransport systems in red blood cells, Ehrlich ascites tumor cells, hepatocytes, and cardiac sarcolemmal vesicles, although significant differences exist when comparisons are made to the Na⁺-dependent lactate transporter of the kidney proximal tubule.     

pH Modulation of the kinetics of rabbit jejunal,brush-border folate transport

Summary In jejunal brush-border membrane vesicles, an out-wardly directed OH^– gradient (in>out) stimulates DIDS-sensitive, saturable folate (F) uptake (Schron, C.M., 1985).J. Clin. Invest. 76:2030–2033), suggesting carrier-mediated folate: OH^– exchange (or phenomenologically indistiguishable H⁺: folate cotransport). In the present study, the precise role of pH in the transport process was elucidated by examinin F uptake at varying pH. For pH gradients of identical magnitude, F uptake (0.1 M) was geater at lower (pH_int/pH_ext:5.5/4.5) compared with higher (6.5/5.5) pH ranges. In the absence of a pH gradient, internal Ftrans stimulated DIDS-sensitive³H-folate uptake only at pH6.0. Since setepwise increments ininternal pH (4.57.5; pH_ext=4.5) stimulated F uptake, an inhibitory effect of higherinternal pH was excluded. In contrast, with increasing external pH(4.356.5; pH_int=7.8), a 50-fold decrement in F uptake was observed (H⁺ K _m =12.8±1.2m). Hill plots of these data suggest involvement of at least one H⁺ (OH^–) at high pH (divalent F^–2 predominates). Since an inside-negative electrical potential did not affect F uptake at either pH_ext 4.55 or 5.8, transport of F^– and F^–2 is electroneutral. Kinetic parameters for F^– and F^–2 were calculated from uptake data at pH_ext 4.55 and 5.0. Comparision of predictedvs. experimentally determined kinetic parameters at pH_ext 5.8 (K _m =1.33vs. 1.70 m;V _max=12.8vs. 58.0 pmol/mg prot min) suggest that increasing external pH lowers theV _max, but does not affect thatK _m, for carrier-mediated F transport. These data are consistent with similarK _i's for sulfasalazine (competitive inhibitor) at pH_ext 5.35 and 5.8 (64.7 and 58.5 m, respectively). In summary, the jejunal F carrier mediates electroneutral transport of mono- and divalen F and is sensitive to extermal pH with a H⁺ K _m (or OH^– IC₅₀) corresponding to pH 4.89. External pH affects theV _max, but not theK _m for carriermediated F uptake suggesting a reaction mechanism involving a ternary complex between the outward-facing conformation of the carrier and the transported ions (F and either OH^– or H⁺) rather than competitive binding that is mutually exclusive.     

Effects of starvation on valine and alanine transport across the intestinal mucosal border in sea bass,Dicentrarchus labrax

Summary kinetics of intestinal transport of l-alanine and l-valine (substrates of the A-system and the L-system, respectively, in mammals) across the brush-border membrane in sea bass, Dicentrarchus labrax, were studied on intact mucosa using a short-term uptake technique. When fish were starved for 4–8 weeks, total influx (mucosa-to-cell) of valine fell owing to disappearance or modification of the diffusion component. The maximum influx rate of saturable component increased but its affinity (reflected by the Michaelis constant) decreased. Alanine transport by Na⁺-dependent and diffusion pathways was unchanged after starvation Fasting also induced an almost 20% decrease in the length of intestinal microvilli.Abbreviations K _d diffusional constant - K _m Michaelis constant - V _max maximum influx rate     

pH modulation of the kinetics of rabbit jejunal,brush-border folate transport

Summary In jejunal brush-border membrane vesicles, an outwardly directed OH^– gradient (in>out) stimulates DIDS-sensitive, saturable folate (F) uptake (Schron, C.M. 1985.J. Clin. Invest. 76:2030–2033), suggesting carrier-mediated folate: OH^– exchange (or phenomenologically indistinguishable H⁺: folate cotransport). In the present study, the precise role of pH in the transport process was elucidated by examining F uptake at varying pH. For pH gradients of identical magnitude, F uptake (0.1 M) was greater at lower (pH_int/pH_ext: 5.5/4.5) compared with higher (6.5/5.5) pH ranges. In the absence of a pH gradient, internal Ftrans stimulated DIDS-sensitive³H-folate uptake only at pH6.0. Since stepwise increments ininternal pH (4.57.5; pH_ext=4.5) stimulated F uptake, an inhibitory effect of higherinternal pH was excluded. In contrast, with increasing external pH (4.356.5; pH_int=7.8), a 50-fold decrement in F uptake was observed (H⁺ K _m =12.8±1.2 M). Hill plots of these data suggest involvement of at least one H⁺ (OH^–) at low pH (monovalent F^– predominates) and at least 2 H⁺ (OH^–) at high pH (divalent F^–2 predominates). Since an inside-negative electrical potential did not affect F uptake at either pH_ext 4.55 or 5.8, transport of F^– and F^–2 is electroneutral. Kinetic parameters for F^– and F^–2 were calculated from uptake data at pH_ext 4.55 and 5.0. Comparison of predictedvs. experimentally determined kinetic parameters at pH_ext5.8 (K _m =1.33vs. 1.70 M;V _max=123.8vs. 58.0 pmol/mg prot min) suggest that increasing external pH lowers theV _max, but does not affect theK _m for carrier-mediated F transport. These data are consistent with similarK _i ^' s for sulfasalazine (competitive inhibitor) at pH_ext 5.35 and 5.8 (64.7 and 58.5 M, respectively). In summary, the jejunal F carrier mediates electroneutral transport of mono- and divalent F and is sensitive to external pH with a H⁺ K _m (or OH^– lC₅₀) corresponding to pH 4.89. External pH effects theV _max, but not theK _m for carriermediated F uptake suggesting a reaction mechanism involving a ternary complex between the outward-facing conformation of the carrier and the transported ions (F and either OH^– or H⁺),rather than competitive binding that is mutually exclusive.     

Influence of membrane structure on ion transport through lipid bilayer membranes

Summary Charge-pulse relaxation studies with the positively charged PV-K⁺ complex (cyclo-(d-Val-l-Pro-l-Val-d-Pro)₃) and the negatively charged lipophilic ion dipicrylamine (DPA^–) have been performed in order to study the influence of structural properties on ion transport through lipid bilayer membranes. First, the thickness of monoolein membranes was varied over a wide range using differentn-alkanes and slovent-free membranes. The thickness (d) of the hydrocarbon core of these membranes varied between 4.9 and 2.5 nm. For both transport systems the partition coefficient was found to be rather insensitive to variations ind. The same was valid for the translocation rate constantk _MS of PV-K⁺, whereas a strong increase of the translocation rate constantk _i of DPA-with decreasingd was observed. In a further set of experimental conditions the structure of the lipids, such as number and position of the double bonds in the hydrocarbon chain and its chain length as well as the nature of the polar head group, was varied. The translocation constantk _MS of PV-K⁺ transport was found to be much more sensitive to these variations thank _i of DPA-.Much larger variations ink _i andk _MS were observed in membranes made from lipids with ether instead of ester linkages between glycerol backbone and hydrocarbon chain. The results are in qualitative agreement with the surface potentials of monolayers made from corresponding lipids. Increasing amounts of cholesterol in membranes of dioleoylphosphatidylcholine caused a strong decrease ofk _MS (PV-K⁺), whereask _i was found to be rather insensitive to this variation.In monoolein membranes cholesterol causes a decrease ofk _MS up to sixfold and a increase ofk _i up to eightfold. The partition coefficient of DPA^– was insensitive to cholesterol, whereas of PV-K⁺ was found to decrease about eightfold in these membranes. The influence of cholesterol onk _MS is discussed on the basis of viscosity changes in the membrane and the change ink _i of DPA^– and of PV-K⁺ on the basis of a possible change of the dipole potential of the membranes. The other sterols, epicholesterol and ergosterol cause no change in the kinetics of the two probes.The different influence of membrane properties like thickness, viscosity, and dipole potential on the two transport systems is discussed under the assumption that the adsorption planes of the two probes have different positions in a membrane. Possibly because of a larger hydrophobic interaction, the adsorption plane of PV-K⁺ is located more towards the hydrocarbon side and that of DPA^– more towards the aqueous side of the dipole layer.     

The complete rate equation,including the explicit dependence on Na+ ions,for the influx of α-aminoisobutyric acid into mouse brain slices

Summary The rate equation, including dependence on Na⁺-ion concentration for the influx of -aminoisobutyric acid into mouse brain slices incubated in isotonic glucose medium at 37°C, isv=0.402S/{1.02(1+788/[Na⁺]²)+S}+0.0477S, wherev=influx in mol/min, g final wet wt of slices; [Na⁺]=concentration of Na⁺ ions in medium, inmm; andS=concentration of -aminoisobutyric acid in medium, inmm. This equation shows two kinetically independent, parallel pathways of concentrative uptake: one, saturable and dependent on Na⁺; the other, unsaturable and independent of Na⁺. Influx is independent of ionic strength, Cl^– ionper se, and a moderate increase in tonicity. The binding of substrate to the saturable carrier depends on the Na⁺ concentration; the maximum capacity of this carrier does not. For transport, 2 Na⁺ ions must interact with each saturable transport site. This does not imply coupling between the flux of Na⁺ and the flux of -aminoisobutyric acid.     

Kinetics of sodiumd-glucose cotransport in bovine intestinal brush border vesicles

Summary Brush border membrane vesicles (BBMV) purified from steer jejunum were used to study the kinetics of sodiumd-glucose cotransport under voltage clamped, zero-trans conditions. When the initial rate of glucose transport (J _gluc) was measured over a wide range of glucose concentrations ([S]=0.01–20mm), curvature of the Woolf-Augustinsson-Hofstee plots was seen, compatible with a diffusional and one major, high capacity (maximal transport rateJ _max=5.8–8.8 nmol/mg·min) saturable system. Further studies indicated that changes incis [Na] altered theK _t , but not theJ _max, suggesting the presence of a rapid-equilibrium, ordered bireactant system with sodium adding first.Trans sodium inhibitedJ _gluc hyperbolically. KCl-valinomycin diffusion potentials, inner membrane face positive, loweredJ _gluc, while potentials of the opposite polarity raiseJ _gluc. At low glucose concentrations ([S]<0.05mm), a second, minor, high affinity transport system was indicated. Further evidence for this second saturable system was provided by sodium activation curves, which were hyperbolic when [S]=0.5mm, but were sigmoidal when [S]=.0.01mm. Simultaneous fluxes of²²Na and [³H]glucose at 1mm glucose and 30mm NaCl yielded a cotransport-dependent flux ratio of 21 sodium/glucose, suggestive of 11 (Na/glucose) high capacity, low affinity system and a 31 (Na/glucose) high affinity, low capacity system. Kinetic experiments with rabbit jejunal brush borders revealed two major Na-dependent saturable systems. Extravesicular (cis) Na changed theK _t , but not theJ _max of the major system.     

Mechanisms of arsenic hyperaccumulation in<Emphasis Type="Italic"> Pteris</Emphasis> species: root As influx and translocation

Several species of fern from the Pteris genus are able to accumulate extremely high concentrations of arsenic (As) in the fronds. We have conducted short-term unidirectional As influx and translocation experiments with ⁷³As-radiolabeled arsenate, and found that the concentration-dependent influx of arsenate into roots was significantly larger in two of these As-hyperaccumulating species, Pteris vittata (L.) and Pteris cretica cv. Mayii (L.), than in Nephrolepis exaltata (L.), a non-accumulating fern. The arsenate influx could be described by Michaelis-Menten kinetics and the kinetic parameter K _m was found to be lower in the Pteris species, indicating higher affinity of the transport protein for arsenate. Quantitative analysis of kinetic parameters showed that phosphate inhibited arsenate influx in a directly competitive manner, consistent with the hypothesis that arsenate enters plant roots on a phosphate-transport protein. The significantly augmented translocation of arsenic to the shoots that was seen in these As hyperaccumulator species is proposed to be due to a combination of the increased root influx and also decreased sequestration of As in the roots, as a larger fraction of As could be extracted from roots of the Pteris species than from roots of N. exaltata. This leaves a larger pool of mobile As available for translocation to the shoot, probably predominantly as arsenite.Abbreviations As ^V Arsenate - As ^III Arsenite - K _m Michaelis-Menten constant - P _i Phosphate - V _max Maximum rate of an enzyme-catalyzed reaction