Glycinergic nerve endings in hippocampus and spinal cord release glycine by different mechanisms in response to identical depolarizing stimuli

Studies on hippocampal glycine release are extremely rare. We here investigated release from mouse hippocampus glycinergic terminals selectively pre-labelled with [³H]glycine through transporters of the GLYT2 type. Purified synaptosomes were incubated with [³H]glycine in the presence of the GLYT1 blocker NFPS to abolish uptake (∼ 30%) through GLYT1. The non-GLYT1-mediated uptake was entirely sensitive to the GLYT2 blocker Org25543. Depolarization during superfusion with high-K⁺ (15–50 mmol/L) provoked overflows totally dependent on external Ca²⁺, whereas in the spinal cord the 35 or 50 mmol/L KCl-evoked overflow (higher than that in hippocampus) was only partly dependent on extraterminal Ca²⁺. In the hippocampus, the Ca²⁺-dependent 4-aminopyridine (1 mmol/L)-evoked overflow was five-fold lower than that in spinal cord. The component of the 10 μmol/L veratridine-induced overflow dependent on external Ca²⁺ was higher in the hippocampus than that in spinal cord, although the total overflow in the hippocampus was only half of that in the spinal cord. Part of the veratridine-evoked hippocampal overflow occurred by GLYT2 reversal and part by bafilomycin A₁-sensitive exocytosis dependent on cytosolic Ca²⁺ generated through the mitochondrial Na⁺/Ca²⁺ exchanger. As glycine sites on NMDA receptors are normally not saturated, understanding mechanisms of glycine release should facilitate pharmacological modulation of NMDA receptor function.     

Identification of a System N-Like Na+-Dependent Glutamine Transport Activity in Rat Brain Neurons

Abstract: Glutamine is a primary precursor for the biosynthesis of the neurotransmitters glutamate and γ-aminobutyric acid. It is proposed that glutamine, synthesized and released by astrocytes, is transported into the neuron for subsequent conversion to neurotransmitters. To provide a more complete characterization of this process, we have delineated the transport systems for glutamine uptake in primary cultures of brain neuronal cells from 1-day-old rats. The Na⁺-dependent glutamine entry is mediated by system A, system ASC, and a third, previously unidentified, activity that has been tentatively designated as system N^b. System N^b activity can be monitored by assaying Na⁺-dependent [³H]glutamine uptake in the presence of 2 m M concentrations of both 2-(methylamino)isobutyric acid and threonine to block uptake by systems A and ASC, respectively. The newly identified transport activity exhibits an apparent substrate specificity that is unique compared with the hepatic system N, because it is inhibited by glutamine and asparagine, but not by histidine. Also, the affinity of system N^b for glutamine, as estimated from K _m values, is significantly greater than that observed for the hepatic and muscle Na⁺-dependent glutamine transporters, systems N and N^m. In sharp contrast to the hepatic system N transporter, system N^b exhibits a relative insensitivity to pH and does not permit Li⁺ substitution for Na⁺ as the cosubstrate. The substrate specificity, kinetic analysis, pH sensitivity, and cation dependence of this transport activity indicate that it represents a glutamine transport system not previously identified.     

Heterogeneous Na+ Sensitivity of Na+,K+-ATPase Isoenzymes in Whole Brain Membranes

Abstract: The Na⁺ sensitivity of whole brain membrane Na⁺,K⁺-ATPase isoenzymes was studied using the differential inhibitory effect of ouabain (α1, low affinity for ouabain; α2, high affinity; and α3, very high affinity). At 100 m M Na⁺, we found that the proportion of isoforms with low, high, and very high ouabain affinity was 21, 38, and 41%, respectively. Using two ouabain concentrations (10⁻⁵ and 10⁻⁷ M ), we were able to discriminate Na⁺ sensitivity of Na⁺, K⁺-ATPase isoenzymes using nonlinear regression. The ouabain low-affinity isoform, α1, exhibited high Na⁺ sensitivity [ K _a of 3.88 ± 0.25 m M Na⁺ and a Hill coefficient ( n ) of 1.98 ± 0.13]; the ouabain high-affinity isoform, α2, had two Na⁺ sensitivities, a high ( K _a of 4.98 ± 0.2 m M Na⁺ and n of 1.34 ± 0.10) and a low ( K _a of 28 ± 0.5 m M Na⁺ and an n of 1.92 ± 0.18) Na⁺ sensitivity activated above a thresh old (22 ± 0.3 m M Na⁺); and the ouabain very-high-affinity isoform, α3, was resolved by two processes and appears to have two Na⁺ sensitivities (apparent K _a values of 3.5 and 20 m M Na⁺). We show that Na⁺ dependence in the absence of ouabain is the result of at least of five Na⁺ reactivities. This molecular functional characteristic of isoenzymes in membranes could explain the diversity of physiological roles attributed to isoenzymes.     

Glutamine Transport in Mouse Cerebral Astrocytes

Abstract: We measured initial influx and exchange of [¹⁴C]glutamine in primary astrocyte cultures in the presence and absence of Na⁺. Kinetic analysis of transport in Na⁺-free solution indicated two saturable Na⁺-independent components, one of which was identifiable functionally as system L₁ transport. In the presence of Na⁺, multiple hyperbolic components were not resolvable from the kinetic data. Nevertheless, other evidence supported participation by at least three Na⁺-dependent neutral amino acid transporters (systems A, ASC, and N). System A transport of glutamine was usually absent or minimal, based on lack of inhibition by α-(methylamino)isobutyric acid. However, vigorous system A-mediated transport emerged after derepression by substrate deprivation. Participation by system ASC was indicated by trans-acceleration of Na⁺-dependent uptake, preferential inhibition of an Li⁺-intolerant component of uptake by cysteine, and inhibition by cysteine of a component resistant to inhibition by histidine and α-(methylamino)isobutyric acid. Because nonsaturable transport of glutamine appeared negligible, and system L transport of glutamine was suppressed in the presence of Na⁺, low-affinity system ASC transport may be the major route of export of glutamine from astrocytes. At 700 µ M glutamine, the primary uptake route was system N transport, identified on the basis of selective inhibition by histidine and asparagine, pH sensitivity, and tolerance of Li⁺ in place of Na⁺.     

Modulation of Human Glutamate Transporter Activity by Phorbol Ester

Abstract: Termination of synaptic glutamate transmission depends on rapid removal of glutamate by neuronal and glial high-affinity transporters. Molecular biological and pharmacological studies have demonstrated that at least five subtypes of Na⁺-dependent mammalian glutamate transporters exist. Our study demonstrates that Y-79 human retinoblastoma cells express a single Na⁺-dependent glutamate uptake system with a K _m of 1.7 ± 0.42 µ M that is inhibited by dihydrokainate and dl - threo -β-hydroxyaspartate (IC₅₀ = 0.29 ± 0.17 µ M and 2.0 ± 0.43 µ M , respectively). The protein kinase C activator phorbol 12-myristate 13-acetate caused a concentration-dependent inhibition of glutamate uptake (IC₅₀ = 0.56 ± 0.05 n M ), but did not affect Na⁺-dependent glycine uptake significantly. This inhibition of glutamate uptake resulted from a fivefold decrease in the transporter's affinity for glutamate, without significantly altering the V _max. 4α-Phorbol 12,13-didecanoate, a phorbol ester that does not activate protein kinase C, did not alter glutamate uptake significantly. The phorbol 12-myristate 13-acetate-induced inhibition of glutamate uptake was reversed by preincubation with staurosporine. The biophysical and pharmacological profile of the human glutamate transporter expressed by the Y-79 cell line indicates that it belongs to the dihydrokainate-sensitive EAAT2/GLT-1 subtype. This conclusion was confirmed by western blot analysis. Protein kinase C modulation of glutamate transporter activity may represent a mechanism to modulate extracellular glutamate and shape postsynaptic responses.     

Glycine transporter isoforms show differential subcellular localization in PC12 cells

The subcellular localization of glycine transporters one (GLYT1) and two (GLYT2) stably expressed in PC12 cells has been studied. To facilitate visualization, enhanced green fluorescent protein (GFP) was fused to the amino terminus of both glycine transporters. Functional analysis of the GFP-GLYT1 and GFP-GLYT2 stable cell lines demonstrated that they exhibited high affinity for glycine and the characteristic properties of both glycine transporter subtypes. The GFP-coupled transporters were differently distributed throughout the cell. GFP-GLYT1 was mainly localized on the plasma membrane, whereas most of GFP-GLYT2 was present on large dense-core vesicles and endosomes. Both transporters were absent from the synaptic vesicle population in PC12 cells.     

Modulation of a Recombinant Glycine Transporter (GLYT1b) by Activation of Protein Kinase C

Abstract: Treatment of human embryonic kidney cells (HEK 293 cells) expressing the mouse glycine transporter 1 (GLYT1b) with the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA) decreased specific [³H]glycine uptake. This down-regulation resulted from a reduction of the maximal transport rate and was blocked by the PKC inhibitors 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine (H7) and staurosporine. The inhibitory effect of PMA treatment was also observed after removing all five predicted phosphorylation sites for PKC in GLYT1b by site-directed mutagenesis. These data indicate that glycine transport by GLYT1b is modulated by PKC activation; however, this regulation may involve indirect phosphorylation mechanisms.     

N-System Amino Acid Transport at the Blood-CSF Barrier

Abstract: Despite l -glutamine being the most abundant amino acid in CSF, the mechanisms of its transport at the choroid plexus have not been fully elucidated. This study examines the role of L-, A-, ASC-, and N-system amino acid transporters in l -[¹⁴C]glutamine uptake into isolated rat choroid plexus. In the absence of competing amino acids, approximately half the glutamine uptake was via a Na⁺-dependent mechanism. The Na⁺-independent uptake was inhibited by 2-amino-2-norbornane carboxylic acid, indicating that it is probably via an L-system transporter. Na⁺-dependent uptake was inhibited neither by the A-system substrate α-(methylamino)isobutyric acid nor by the ASC-system substrate cysteine. It was inhibited by histidine, asparagine, and l -glutamate γ-hydroxamate, three N-system substrates. Replacement of Na⁺ with Li⁺ had little effect on uptake, another feature of N-system amino acid transport. These data therefore indicate that N-system amino acid transport is present at the choroid plexus. The V _max and K _max for glutamine transport by this system were 8.1 ± 0.3 nmol/mg/min and 3.3 ± 0.4 m M , respectively. This system may play an important role in the control of CSF glutamine, particularly when the CSF glutamine level is elevated as in hepatic encephalopathy.     

Glutamate Uptake Stimulates Na+,K+-ATPase Activity in Astrocytes via Activation of a Distinct Subunit Highly Sensitive to Ouabain

Abstract: The excitatory amino acid glutamate was previously shown to stimulate aerobic glycolysis in astrocytes by a mechanism involving its uptake through an Na⁺-dependent transporter. Evidence had been provided that Na⁺,K⁺-ATPase might be involved in this process. We have now measured the activity of Na⁺,K⁺-ATPase in cultured astrocytes, using ouabain-sensitive ⁸⁶Rb uptake as an index. l -Glutamate increases glial Na⁺,K⁺-ATPase activity in a concentration-dependent manner with an EC₅₀ = 67 µ M . Both l - and d -aspartate, but not d -glutamate, produce a similar response, an observation that is consistent with an uptake-related effect rather than a receptor-mediated one. Under basal conditions, concentration-dependent inhibition of Na⁺,K⁺-ATPase activity in astrocytes by ouabain indicates the presence of a single catalytic site with a low affinity for ouabain ( K _0.5 = 113 µ M ), compatible with the presence of an α₁ isozyme. On stimulation with glutamate, however, most of the increased activity is inhibited by low concentrations of ouabain ( K _0.5 = 20 n M ), thus revealing a high-affinity site akin to the α₂ isozyme. These results suggest that astrocytes possess a glutamate-sensitive isoform of Na⁺,K⁺-ATPase that can be mobilized in response to increased neuronal activity.     

Environmental induction of Na+ transporter affinity in Atlantic salmon embryos

Atlantic salmon ( Salmo salar L.) alevins hatched from eggs transferred from high- to low-Na water at 250° days, before the onset of the phase of increasing whole egg sodium content (at ∼380°days), showed a significantly reduced K _m for Na⁺ transport, whereas transfer at 400° days did not produce any change in K _m . Alevins hatched from eggs given acid shocks of 1, 3, 7 or 14 days duration initiated at 250 or 400° days showed no significant changes in Na⁺ transporter K _m . Extended acid exposure (38 days) from 250°days to hatching resulted in a slight lowering of K _m (P<0.05). A 24-day acid exposure from 400°days to hatching had no effect on Na⁺ transporter K _m . Alevins hatched from eggs incubated throughout in acidified water had a significantly reduced K _m compared to controls (P<0.01).
The timing and duration of periods of Na depletion of eggs is considered with respect to environmental induction of increased Na transporter affinity in teleost embryos as a mechanism of long-term physiological adaptation to the gradual acidification of natural waters.     

Oxidative Stress, Hypoxia, and Ischemia-Like Conditions Increase the Release of Endogenous Amino Acids by Distinct Mechanisms in Cultured Retinal Cells

Abstract: The aim of this study was to elucidate the mechanisms by which retinal cells release endogenous amino acids in response to ascorbate/Fe²⁺-induced oxidative stress, as compared with chemical hypoxia or ischemia. In the absence of stimulation, oxidative stress increased the release of aspartate, glutamate, taurine, and GABA only when Ca²⁺ was present. Under hypoxia or ischemia, the release of aspartate, glutamate, glycine, alanine, taurine, and GABA increased mainly by a Ca²⁺-independent mechanism. The increased release observed in N -methyl- d -glucamine⁺ medium suggested the reversal of the Na⁺-dependent amino acid transporters. Upon oxidative stress, the release of aspartate, glutamate, and GABA, occurring through the reversal of the Na⁺-dependent transporters, was reduced by about 30%, although the release of taurine was enhanced. An increased release of [³H]arachidonic acid and free radicals seems to affect the Na⁺-dependent transporters for glutamate and GABA in oxidized cells. All cell treatments increased [Ca²⁺]_i (1.5 to twofold), although no differences were observed in membrane depolarization. The energy charge of cells submitted to hypoxia or oxidative stress was not changed. However, ischemia highly potentiated the reduction of the energy charge, as compared with hypoglycemia or hypoxia alone. The present work is important for understanding the mechanisms of amino acid release that occur in vivo upon oxidative stress, hypoxia, or ischemia, frequently associated with the impairment of energy metabolism.     

Substrate-induced conformational changes of extracellular loop 1 in the glycine transporter GLYT2

The neurotransmitter glycine is removed from the synaptic cleft by two Na(+)-and Cl(-)-dependent transporters, the glial (GLYT1) and neuronal (GLYT2) glycine transporters. GLYT2 lacks a conserved cysteine in the first hydrophilic loop (EL1) that is reactive to [2-(trimethylammonium)ethyl] methanethiosulfonate (MTSET) in related transporters. A chimeric GLYT2 (GLYT2a-EL1) that contains GLYT1 sequences in this region, including the relevant cysteine, was sensitive to the reagent, and its sensitivity was decreased by co-substrates. We combined cysteine-specific biotinylation to detect transporter-reagent interactions with MTSET inactivation assays and temperature dependence analysis to study the mechanism by which Cl(-), Na(+), and glycine reduce methanethiosulfonate reagent inhibition. We demonstrate a Na(+) protective effect rather than an increased susceptibility to the reagent exerted by Li(+), as reported for the serotonin transporter. The different inhibition, protection, and reactivation properties between GLYT2a-EL1 and serotonin transporter suggest that EL1 is a source of structural heterogeneity involved in the specific effect of lithium on serotonin transport. The protection by Na(+) or Cl(-) on GLYT2a-EL1 was clearly dependent on temperature, suggesting that EL1 is not involved in ion binding but is subjected to ion-induced conformational changes. Na(+) and Cl(-) were required for glycine protection, indicating the necessity of prior ion interaction with the transporter for the binding of glycine. We conclude that EL1 acts as a fluctuating hinge undergoing sequential conformational changes during the transport cycle.     

Cationic and Anionic Requirements for the Binding of 2β-Carbomethoxy-3β-(4-Fluorophenyl)[3H]tropane to the Dopamine Uptake Carrier

Abstract: The present study reports the ion dependency of 2β-carbomethoxy-3β-(4-fluorophenyl)[³H]tropane ([³H]- CFT) binding to the dopamine transporter in the rat striaturn. The results indicate that [³H]CFT binding to synaptosomal P₂ membranes requires low concentrations of Na⁺ (peak binding between 20 and 50 m M Na⁺), is stimulated by phosphate anion or l^-, but is unaffected or only slightly affected by F^-, Cl^-, Br^-, NO₃^-, or SO₄^2-, Concentrations of Na⁺ of >50 m M become inhibitory except in the presence of l^-, which shifts peak binding levels toward higher Na⁺ concentrations and also elevates the peak binding level. K⁺ strongly decreased [³H]CFT binding with a shallow inhibition curve, and Na⁺ could not overcome this effect. Saturation analysis of [³H]CFT binding revealed a single binding site changing its affinity for CFT depending on the concentration of sodium phosphate buffer (6, 10, 30, 50, 130, or 200 m M ; 1 mM plus 49 mM NaCIversus 10 m M plus 40 m M NaCI; or 1 mM plus 129 m M Nal versus 10 m M plus 120 m M Nal). No differences were observed in the density of CFT binding sites between any of the conditions examined.     

The HAL1 function on Na+ homeostasis is maintained over time in salt-treated transgenic tomato plants, but the high reduction of Na+ in leaf is not associated with salt tolerance

To achieve a deeper knowledge on the function of HAL1 gene in tomato ( Solanum lycopersicum ) plants submitted to salt stress, in this study, we studied the growth and physiological responses to high salt stress of T3 transgenic plants (an azygous line without transgene and both homozygous and hemizygous lines for HAL1 ) proceeding from a primary transformant with a very high expression level of HAL1 gene. The homozygous plants for HAL1 gene did not increase their salt tolerance in spite of an earlier and higher reduction of the Na⁺ accumulation in leaves, being moreover the Na⁺ homeostasis maintained throughout the growth cycle. The greater ability of the homozygous line to regulate the Na⁺ transport to the shoot to long term was even shown in low accumulation of Na⁺ in fruits. By comparing the homozygous and hemizygous lines, a higher salt tolerance in the hemizygous line, with respect to the homozygous line, was observed on the basis of fruit yield. The Na⁺ homeostasis and osmotic homeostasis were also different in homozygous and hemizygous lines. Indeed, the Na⁺ accumulation rate in leaves was greater in hemizygous than in homozygous line after 35 days of 100 m M NaCl treatment and only at the end of growth cycle did the hemizygous line show leaf Na⁺ levels similar to those found in the homozygous line. With respect to the osmotic homeostasis, the main difference between lines was the different contribution of inorganic and organic solutes to the leaf osmotic balance. Taken together, these results suggest that the greater Na⁺ exclusion ability of the homozygous line overexpressing HAL1 induces a greater use of organic solutes for osmotic balance, which seems to have an energy cost and hence a growth penalty that reverts negatively on fruit yield.     

Agents that Promote Protein Phosphorylation Inhibit the Activity of the Na+/Ca2+ Exchanger and Prolong Ca2+ Transients in Bovine Chromaffin Cells

Abstract: The Na⁺/Ca²⁺ exchanger is an important element in the maintenance of calcium homeostasis in bovine chromaffin cells. The Na⁺/Ca²⁺ exchanger from other cell types has been extensively studied, but little is known about its regulation in the cell. We have investigated the role of reversible protein phosphorylation in the activity of the Na⁺/Ca²⁺ exchanger of these cells. Cells treated with 1 m M dibutyryl cyclic AMP (dbcAMP), 1 µ M phorbol 12,13-dibutyrate, 1 µ M okadaic acid, or 100 n M calyculin A showed lowered Na⁺/Ca²⁺ exchange activity and prolonged cytosolic Ca²⁺ transients caused by depolarization. A combination of 10 n M okadaic acid and 1 µ M dbcAMP synergistically inhibited Na⁺/Ca²⁺ exchange activity. Conversely, 50 µ M 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine, a protein kinase inhibitor, enhanced Na⁺/Ca²⁺ exchange activity. Moreover, we used cyclic AMP-dependent protein kinase and calcium phospholipid-dependent protein kinase catalytic subunits to phosphorylate isolated membrane vesicles and found that the Na⁺/Ca²⁺ exchange activity was inhibited by this treatment. These results indicate that reversible protein phosphorylation modulates the activity of the Na⁺/Ca²⁺ exchanger and suggest that modulation of the exchanger may play a role in the regulation of secretion.     

Na+-Dependent Uptake and Release of Taurine by Neuroblastoma × Glioma Hybrid Cells

Abstract In neuroblastoma × glioma hybrid cells, a cell line of neuronal character, a saturable uptake system for taurine is found which displays high affinity and high capacity ( K _m= 38 μ m , V = 1.25 nmol mg⁻¹ min⁻¹)- Only the closely related structural analogues hypotaurine and β-alanine are able to inhibit the transport of radioactively labeled taurine. Imipramine or haloperidol at 100 μ m effectively blocks taurine uptake. High-affinity taurine uptake shows an absolute and highly specific requirement for Na⁺. The hybrid cells internalize taurine very slowly and, with 1 m m extracellular taurine, attain a plateau only after more than 20 h, at which time approximately 34 m m labeled taurine has accumulated in the cytosol. Generally there is hardly any spontaneous release of accumulated taurine. Efflux can, however, be induced by increasing the intracellular Na⁺ content and is then accelerated by lowering the extracellular Na⁺ concentration. The hypothesis is forwarded that taurine may exert its function by driving the extrusion of Na⁺ in emergency situations.     

Zn2+ inhibits glycine transport by glycine transporter subtype 1b

In the central nervous system, glycine is a co-agonist with glutamate at the N-methyl-D-aspartate subtype of glutamate receptors and also an agonist at inhibitory, strychnine-sensitive glycine receptors. The GLYT1 subtypes of glycine transporters (GLYTs) are responsible for regulation of glycine at excitatory synapses, whereas a combination of GLYT1 and GLYT2 subtypes of glycine transporters are used at inhibitory glycinergic synapses. Zn2+ is stored in synaptic vesicles with glutamate in a number of regions of the brain and is believed to play a role in modulation of excitatory neurotransmission. In this study we have investigated the actions of Zn2+ on the glycine transporters, GLYT1b and GLYT2a, expressed in Xenopus laevis oocytes and we demonstrate that Zn2+ is a noncompetitive inhibitor of GLYT1 but has no effect on GLYT2. We have also investigated the molecular basis for these differences and the relationship between the Zn2+ and proton binding sites on GLYT1. Using site-directed mutagenesis, we identified 2 histidine residues, His-243 in the large second extracellular loop (ECL2) and His-410 in the fourth extracellular loop (ECL4), as two coordinates in the Zn2+ binding site of GLYT1b. In addition, our study suggests that the molecular determinants of proton regulation of GLYT1b are localized to the 2 histidine residues (His-410 and His-421) of ECL4. The ability of Zn2+ and protons to regulate the rate of glycine transport by interacting with residues situated in ECL4 of GLYT1b suggests that this region may influence the substrate translocation mechanism.     

Limiting cytosolic Na+ confers salt tolerance to rice cells in culture: a two-photon microscopy study of SBFI-loaded cells

Rice ( Oryza sativa L.), a staple food in Asia, is very sensitive to soil salinity. However, intraspecific variations exist, with the coastal cultivar Pokkali tolerating even brackish water. This study explores cellular mechanisms that contribute to salt tolerance in rice. It is widely accepted that limiting cytosolic Na⁺ should improve the survival of plants subjected to saline stress. However, an understanding of the mechanisms by which Na⁺ levels are controlled in relatively tolerant cultivars requires monitoring cytosolic Na⁺ non-invasively and in real time, which is technically challenging. We have used two-photon excitation for the ratiometric estimation of cytosolic Na⁺ in cultured cells using sodium-binding benzofuran isophthalate. Pokkali cells maintained low cytosolic Na⁺ (approximately 25 m M ), and a viability of over 85% under high salinity , while Jaya cells were unable to maintain low cytosolic Na⁺ and suffered decreased viability even at moderate saline stress. Here we show that the permeability of the Pokkali plasma membrane to Na⁺ is significantly lower than that of Jaya, to the extent that it is comparable with permeabilities reported for halophytes. Pokkali effectively sequesters Na⁺ in intracellular compartments utilizing a Ca²⁺-regulated transport system(s). Together these cellular mechanisms allow Pokkali to maintain low cytosolic Na⁺ up to a stress of 250 m M NaCl. The findings demonstrate that differences in survival between these contrasting varieties of rice are mainly because of differences in membrane transport mechanisms and thus have significance in crop improvement.