L-Proline and L-Pipecolate Induce Enkephalin-Sensitive Currents in Human Embryonic Kidney 293 Cells Transfected with the High-Affinity Mammalian Brain L-Proline Transporter

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The Journal of Neuroscience, August 1, 1999, 19(15):6290-6297

L-Proline and L-Pipecolate Induce Enkephalin-Sensitive Currents in Human Embryonic Kidney 293 Cells Transfected with the High-Affinity Mammalian Brain L-Proline Transporter
Aurelio Galli², Lankupalle D. Jayanthi¹, I. Scott Ramsey¹, Joshua W. Miller³, Robert T. Fremeau Jr³, and Louis J. DeFelice¹
¹ Department of Pharmacology and Center for Molecular Neuroscience, Vanderbilt University Medical Center, Nashville, Tennessee 37232-6600, ² Department of Pharmacology, University of Texas, Health Science Center, San Antonio, Texas 78284-7764, and ³ Department of Pharmacology and Cancer Biology and Neurobiology, Duke University Medical Center, Durham, North Carolina 27710

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The high-affinity mammalian brain L-proline transporter (PROT) belongs to the GAT1 gene family, which includes Na- and Cl-dependentplasma membrane carriers for neurotransmitters, osmolites, andmetabolites. These transporters couple substrate flux to transmembraneelectrochemical gradients, particularly the Na gradient. In thenervous system, transporters clear synapses and help to replenishtransmitters in nerve terminals. The localization of PROT to specificexcitatory terminals in rat forebrain suggests a role for thiscarrier in excitatory transmission (Renick et al., 1999). We investigatedthe voltage regulation and electrogenicity of this novel transporter,using human embryonic kidney (HEK) 293 cells stably transfectedwith rat PROT cDNA. In physiological solutions between $-$ 140 and $-$ 40 mV, L-proline (PRO) and its six-member ring congener L-pipecolate(PIP) induced inward current. The current-voltage relationshipand the variance of current fluctuations were similar for PRO-and PIP-induced current, and the ratio of induced variance tothe mean current ranged from 20 to 60 fA. Des-Tyr-Leu-enkephalin(GGFL), a competitive peptide inhibitor of PROT, reduced the ratPROT-associated current to control levels. GGFL alone did notelicit currents, and the GGFL-sensitive substrate-induced currentwas absent in nontransfected cells. Finally, GGFL inhibited PROT-mediatedtransport only when applied to the extracellular face of PROT.These data suggest that (1) PROT uptake is electrogenic, (2) individualtransporter currents are voltage-independent, and (3) GGFL isa nonsubstrate inhibitor that interacts either with an extracellulardomain of PROT or in an externally accessiblepore.

Key words: proline; pipecolic acid; transporter; enkephalin; voltage-clamp; uptake; current; HEK-293 cells

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A mammalian brain high-affinity L-proline transporter (PROT) was cloned from a rat forebrain cDNA library on the basis ofamino acid sequence conservation between GABA and norepinephrinetransporters (Fremeau et al., 1992). The PROT cDNA encodes a 68kDa glycosylated protein that exhibits 42-50% amino acid sequenceidentity with a gene family of Na- and Cl-dependent plasma membranetransports proteins that mediate high-affinity uptake of neurotransmitters(norepinephrine, dopamine, serotonin, GABA, glycine), osmolites(taurine, betaine), and the metabolite creatine (Shafqat et al.,1993; Velaz-Faircloth et al., 1995; Miller et al., 1997a,b). Thesetransporters use transmembrane electrochemical gradients to transportsubstrates across the plasma membrane. They are also criticaltargets for therapeutic and pathological alterations of synapticfunction (for review, see Kanner, 1989; Amara and Kuhar, 1993;Rudnick and Clark, 1993; Blakely et al., 1994; Lester et al.,1994). The brain-specific expression of PROT in human (Shafqatet al., 1995) and rat (Velaz-Faircloth et al., 1995) tissues isconsistent with a unique physiological role for this transporterin the mammalianCNS.

The pharmacological specificity, ion dependence, and kinetics of the cloned transporter expressed in non-neural cells (Fremeauet al., 1992, 1996; Shafqat et al., 1995) are similar to the correspondingproperties of the high-affinity component of synaptosomal L-prolineuptake (Bennett et al., 1972; Peterson and Raghupathy, 1972; Balcaret al., 1976; Nadler, 1987). These properties distinguish PROTfrom the other widely expressed Na-dependent plasma membrane carriersthat transport L-proline (PRO), including the intestinal brushborder "imino" carrier (Stevens et al., 1984) and the system "A"and system "ASC" neutral amino acid carriers (Christensen, 1990).In situ hybridization of rat brain sections and cultured hippocampalneurons demonstrated that PROT mRNA is expressed by subpopulationsof putative glutamatergic neurons in rat brain (Fremeau et al.,1992; Velaz-Faircloth et al., 1995). Recently, Crump et al. (1999)observed that the PROT protein is localized to a subset of excitatoryterminals in cultured rat hippocampal neurons. Furthermore, ultrastructuralstudies showed that PROT is localized selectively to a subsetof presynaptic axon terminals, forming asymmetric excitatory-typesynapses typical of glutamatergic synapses (Renick et al., 1999).These findings raise the possibility of a specialized role forPROT and its presumed natural substrate, L-proline, in the modulationof excitatory synaptic transmission in specific excitatory pathwayswithin the CNS. High-affinity L-proline uptake may regulate theability of extracellular proline to potentiate excitatory transmissionat those synapses that express PROT (Cohen and Nadler, 1997).

To gain biophysical insight into the nature of PROT-mediated transport processes, we established the cell line HP-21 by stablytransfecting human embryonic kidney 293 (HEK-293) cells with ratPROT cDNA (Fremeau et al., 1992). The HP-21 cell line is suitablefor biochemical analysis, radiolabeled flux studies, and patch-clamprecording techniques. Electrophysiological measurements revealthat rat PROT (rPROT) is electrogenic; however, individual transporterevents are not voltage-dependent. We also suggest that severalpreviously identified inhibitors of high-affinity L-proline uptake,including L-pipecolate (PIP), an endogenous brain L-lysine metabolite(for review, see Giacobini et al., 1980), are likely PROT substrates,and we propose a Na- and Cl-dependent stoichiometric mechanismfor PRO and PIP transport. Finally, we demonstrate that the competitivepeptide inhibitor Des-Tyr-Leu-enkephalin (GGFL) inhibits PROT-mediatedtransport processes only from theoutside.

  MATERIALS AND METHODS

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rPROT stable cell lines and tissue culture. An EcoRI/XbaI fragment of the rat PROT cDNA containing the entire protein codingsequence was released from pBluescript KSII() (Fremeau et al., 1992) and subcloned into EcoRI/XbaI-digestedpcDNA3 (Invitrogen, San Diego, CA) such that PROT expression wasunder the control of enhancer-promoter sequences from the immediate-earlygene of the human cytomegalovirus (CMV). To generate stably transfectedcell lines, we transfected the pcDNA3-PROT mammalian expressionconstruct by calcium phosphate coprecipitation (Invitrogen) intoHEK-293 cells at ~50% confluence. The cells were cultured in DMEMsupplemented with 10% heat-inactivated fetal bovine serum and50 µg/ml gentamycin. After 3 d the transfected cells were switchedto medium containing 250 µg/ml Geneticin (G418; Life Technologies,Gaithersburg, MD). Resistant colonies were isolated 2 weeks laterby using sterile cloning rings, and individual resistant cellswere used to generate clonal lines. Multiple lines exhibited GGFL-sensitive[³H]-PRO uptake and immunoreactive PROT protein. Clonal line HP-21was used in all of the experiments reported here. The cultureof HEK-293 cells stably transfected with rat PROT cDNA (HP-21cells) was as follows: HP-21 cells were cultured in DMEM supplementedwith 10% fetal bovine serum, 2 mM L-glutamine, penicillin (100U/ml), and streptomycin (100 mg/ml). Trypsin-released cells wereseeded in 24-well cell culture plates at 1-1.5 × 10⁵ cells/well and allowed to grow for 48 hr before the transportmeasurements weredone.

Transport assays. Measurements were performed in triplicate by incubating the HP-21 cells for 10 min at 37°C, with [³H]-PRO in 0.5 ml of Krebs-Ringer's-HEPES-Tris (KRHT) buffer, pH7.4, containing (in mM) 120 NaCl, 4.7 KCl, 2.2 CaCl₂, and 10 D-glucose.The concentration of HEPES was 10 mM, and the concentration ofTris was 5 mM. For the time course of uptake, we used 50 nM [³H]-PRO to determine the incubation period for uptake (10 min).This introduces an approximation, because higher concentrationswill fall off faster from their initial velocities. The consequenceis to underestimate V_max by as much as 20%. Thus we underestimatedthe coupledcurrent.

Assays were terminated by removing the radiolabeled PRO and by washing the cells rapidly three times with 1 ml of ice-coldKRHT buffer. Cells were solubilized with 1 ml of Optiphase scintillant(Wallac, Gaithersburg, MD), and accumulated radioactivity wasquantified by direct scintillation spectrometry with a Microbetamicroplate scintillation counter (Wallac). Inhibitors were added10 min before the addition of labeled substrates in the inhibitionstudies, whereas unlabeled substrates were added simultaneouslywith labeled substrates in the kinetic studies. The cells werecounted each time just before the assay. Substrate K_m and V_maxwere determined by nonlinear least-square fits (Kaleidagraph,Synergy Software, Reading, PA) with the generalized Hill equation:V = V_max [S]ⁿ/(K_mⁿ + [S]ⁿ), where V is the transport velocity, [S] is the substrate concentration,and n is the Hill coefficient. Inhibitor K_i values were determinedby nonlinear least-squares fits, using two-parameter logisticequations: the percentage of specific PRO transport remaining= 100/[1 + (IC₅₀/[I])ⁿ]. The IC₅₀ is the concentration of inhibitor giving 50% inhibition,[I] is the inhibitor concentration, and n is the slope (Hill coefficient).To determine K_i values, we adjusted IC₅₀ values to account forsubstrate concentration (Cheng and Prusoff, 1973). Data are representedas the means ± SEM of six independent measurements on three separatebatches of cells. The dependence of [³H]-PRO on Na and Cl concentration was determined by the methodof Clark and Amara (1994). The ionic concentrations in KRHT bufferswere varied by mixing the NaCl-containing buffer with those thatlacked Na or Cl. After 15 min preincubation, [³H]-PRO (0.05 ml) was added to each well (50 nM final concentration).Transport in each well was stopped after 10 min by three 1 mlwashes with ice-cold KRHT solutions (without glucose) that containedthe same Na and Cl concentration as during preincubation and transport.After the last wash, 1% SDS was added to each well. After solubilizationa small aliquot of each solubilized cell mixture was set asidefor protein determination (Bio-Rad DC Protein Assay Kit, Richmond,CA). The rest was mixed with scintillation fluid for scintillationcounting. We defined uptake into nontransfected HEK cells as background.Each assay was performed in triplicate, and mean specific uptake± SEM was determined and expressed as pmol/mg protein per 10min.

Electrophysiology. Stably transfected cells have advantages for electrophysiology over transiently transfected cells. Theyexpress more uniformly, have more negative resting potentials( $-$ 30 to $-$ 50 mV), and form tighter seals (>20 G $Omega$ ) for whole-cellvoltage clamp than, for example, transiently transfected HeLacells (Risso et al., 1996). Before electrical recording, parentalor stably transfected cells were plated at a density of 10⁵ per 35 mm culture dish, and attached cells were washed threetimes with bath solution at room temperature. The normal bathcontained (in mM): 130 NaCl, 1.3 KCl, 1.3 KH₂PO₄, 0.5 MgSO₂, 1.5CaCl₂, 10 HEPES, and 34 dextrose. The solution was adjusted topH 7.35 and 300 mOsm with 1 M NaOH and dextrose. Pipette solutionsfor the whole-cell recording contained (in mM): 130 KCl, 0.1 CaCl₂,2 MgCl₂, 1.1 EGTA, 10 HEPES, and 30 dextrose adjusted to pH 7.35and 270 mOsm. Free Ca in the pipette was calculated as 0.1 µM.To confirm specificity, we recorded substrate-induced currentsin the absence and presence of GGFL. Electrodes were pulled witha Programmable puller (Sachs-Flaming, PC-84). An Axopatch 200Aor EPC7 amplifier band limited at 5000 Hz was used to measurecurrent. Series conductance was 0.1 µS or greater, and cell capacitancewas 25-80 pF, implying 2500-8000 µm² surface area. HP-21 are clonal cell lines, and expression levelsare constant to within a factor of two; however, with increasingpassages there is decreasing expression. This prevented normalizationof the current to surface area. Voltage steps ranged from $-$ 140to $-$ 20 mV and lasted 500 msec. Test pulses were separated by $-$ 20mV holding potentials for 4 sec. Values for steady-state currentswere taken between 400 and 500 msec after the step. Data werestored digitally on a VCR and analyzed on a Nicolet 4094 oscilloscopeand an IBM-AT or Compaq Pentium computer, using instrumentationand programs written by W. N. Goolsby (Emory University, Atlanta,GA) or using pClamp 6.0.

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Multiple colonies of rat PROT cDNA-transfected HEK-293 cells were isolated after Geneticin (G418) selection and assayed forGGFL-sensitive [³H]-PRO uptake. One of these lines (HP-21) was expanded and analyzedfor expression of PROT by immunolabeling, radiolabeled flux studies,and electrophysiological measurements. As documented in Renicket al. (1999), affinity-purified antipeptide antibodies directedagainst the N or C terminus of the rat PROT protein routinelyrecognize two specific immunoreactive bands on immunoblots ofHP-21 membranes: an intense, broad immunoreactive band centeredat ~69 kDa and a weaker immunoreactive band centered at ~53 kDa.No specific labeling is observed in parental HEK membranes orwhen immunoblots are exposed to preimmune serum. Preabsorptionof either antibody with the peptide used for its purificationabolishes all immunolabeling (for a sample blot, see Renick etal., 1999). We previously observed that the anti-PROT antibodiesrecognize a single broad immunoreactive band centered at ~68 kDaon immunoblots of rat and human brain tissue (Shafqat et al.,1995; Velaz-Faircloth et al., 1995; Renick et al., 1999). Deglycosylationof rat brain membranes with PNGase F reduced the apparent molecularmass of the mammalian brain PROT protein from ~68 to ~53 kDa,a size that corresponds to that of the primary PROT translationproduct determined by in vitro-coupled transcription and translationof the rat PROT cDNA in the absence of microsomes (Velaz-Fairclothet al., 1995; Renick et al., 1999). On the basis of these findingswe conclude that the ~69 kDA band observed in HP-21 membranesrepresents the mature N-glycosylated PROT protein, whereas the~53 kDa band represents the unglycosylated primary translationproduct. Interestingly, although the apparent molecular mass ofthe major PROT immunoreactive band varies between experiments,depending on the percentage of acrylamide in the SDS-PAGE geland the particular batch of molecular weight standards, a cleardifference in electrophoretic mobilities is observed between PROTsexpressed in HEK-293 stable transfectants (HP-21) and the immunoreactiverat brain PROT run side by side on the same 8% SDS-PAGE gel (Renicket al., 1999). These results suggest that the primary PROT translationproduct is subject to differential N-glycosylation in HEK-293cells versus ratbrain.

HP-21 cells transport proline

HP-21 cells accumulated PRO in a time- and dose-dependent manner (Fig. 1). PRO uptake is approximately linear up to 20 min(Fig. 1A). To explore the functional properties of PROT, we performedkinetic analysis of [³H]-PRO uptake. Nonlinear least-squares curve fitting of saturationdata was accomplished by using the generalized Hill equation (seeMaterials and Methods). Proline uptake follows saturable kinetics,with K_m = 20.12 ± 3.14 µM and V_max = 892.26 ± 39.03 pmol/10⁵ cells per 10 min (Fig. 1B). The Eadie-Hofstee transformationyields a linear curve consistent with a single high-affinity interactionwith an apparent K_m of 21 µM (Fig. 1C). In contrast to the endogenouslow-affinity PRO uptake observed in nontransfected HEK cells,which have a K_m of ~350 µM (Shafqat et al., 1995), HP-21 cellswere capable of saturable uptake at low micromolar proline concentrations.

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Figure 1. Characterization of proline transport. A, Time course of transport. HEK-293 cells stably transfected with rat PROT cDNA reveal time-dependent PRO uptake. Proline transport was assayed, as described in Materials and Methods, for increasing time periods, and the picomoles of accumulated PRO were plotted against the incubation time. The data points represent the means ± SEM (2 or 3 batches of cells; 6 experimental values for each point). B, Concentration dependence of transport. Proline uptake was measured, over a concentration range from 1 to 100 µM, during a 20 min incubation time in KRHT buffer at 37°C. We kept the concentration of radiolabeled PRO (50 nM) constant and adjusted the total concentration to desired values by adding appropriate concentrations of unlabeled PRO. The high-affinity component of PRO uptake was calculated by subtracting the uptake values obtained in the presence of 100 µM GGFL from total uptake measured in the absence of GGFL. We have plotted the PRO uptake rate versus PRO concentration. The data points represent the means ± SEM as in A. The data were analyzed first by nonlinear curve fitting, with the Hill coefficient as a free parameter. After determining that the coefficient was close to one, we set it exactly to one and determined V_max and K_m. Proline uptake follows saturable kinetics, with K_m = 20.12 ± 3.14 µM and V_max = 892.26 ± 39.03 pmol/10⁵ cells per 10 min. C, Eadie-Hofstee plot. The data used in B are plotted as PRO uptake rate, V, versus V/[S]. These data were fit by linear regression to a line with V_max (y-intercept) of 816.3 pmol/10⁵ cells per 10 min and K_m ( $-$ slope) of 20.7 µM.

Inhibition of L-proline uptake by leu-enkephalin and its des-tyrosyl derivative

To characterize uptake, we tested the ability of unlabeled PRO and several structurally related compounds to compete for [³H]-PRO uptake. Unlabeled PRO and its six-member ring congener,PIP, another possible substrate of PROT (Fremeau et al., 1992;Shafqat et al., 1995), produced a concentration-dependent reductionof [³H]-PRO uptake in HP-21 cells. The apparent K_i values for thesecompounds were, respectively, 16.10 ± 1.92 and 17.44 ± 1.58 µM(Fig. 2). PROT exhibits significant amino acid sequence homologywith other members of the GAT1 gene family but is unique in demonstratinga particular affinity for enkephalins. Fremeau et al. (1996) reportedthat leucine-enkephalin (YGGFL) and its des-tyrosyl derivative(GGFL) specifically inhibited high-affinity PRO uptake withoutaffecting the plasma membrane transporter activity of severalother members of the gene family. Here, we demonstrate that YGGFLand its des-tyrosyl derivative GGFL produced a concentration-dependentreduction of [³H]-PRO uptake in HP-21 cells (Fig. 2). GGFL was more potent (K_i= 3.51 ± 0.67 µM) than YGGFL (K_i = 9.44 ± 1.88 µM) at inhibitingPRO uptake in the HP-21 cells.

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Figure 2. Inhibitor sensitivity of proline uptake in HP-21 cells. Inhibitor potencies were estimated in 50 nM [³H]-PRO in standard transport assays that were conducted with various concentrations (in moles per liter) of transport inhibitors and/or substrate. The data are expressed as a percentage of PRO accumulated in the absence of antagonist. The data were fit to a two-parameter expression: the percentage of PRO transport remaining is equal to 100/(1 + (IC₅₀/[I])ⁿ), where IC₅₀ is the concentration of competitor giving 50% of inhibition, [I] is the inhibitor concentration, and n is the Hill coefficient. IC₅₀ values were converted to K_i values by using the Cheng and Prusoff (1973) correction for substrate concentration. Using this analysis, we calculated the following K_i values (in µM): GGFL, 3.51; YGGFL, 9.44; proline, 16.1; pipecolic acid, 17.44. These data are the average ± SEM of two experiments performed in triplicate.

Ion dependence of [³H]-L-proline uptake

Isotonic substitution of extracellular Na ions with Li or extracellular Cl ions with isethionate abolished PRO uptake. Thisinhibition was reversible. In contrast, endogenous low-affinitytransport of PRO is dependent on extracellular Na, but not onextracellular Cl (Shafqat et al., 1995). Saturation curves forthe dependence of [³H]-PRO uptake on Na and Cl concentration are presented in Figure3, A and B. Specific uptake by HP-21 cells increased with Na concentrationin a sigmoidal manner, with an apparent K_m = 40.7 ± 1.7 mM. Incontrast, the relationship between specific uptake and Cl concentrationwas hyperbolic, with an apparent K_m = 7 ± 1 mM. The Hill coefficientsfor Na and Cl were set to the values n = 2 and n = 1, respectively,after initial nonlinear trials that resulted in values close tothese. These data are consistent with a substrate stoichiometryfor rPROT of 1 PRO: 2 Na: 1 Cl and a net transfer of one elementarycharge per transport cycle at physiological pH.

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Figure 3. Na and Cl concentration dependence of proline uptake in HP-21 cells. Transport rates were measured by using a 10 min incubation as described in Materials and Methods. The standard assay buffer was modified by replacing NaCl with LiCl or Na-isethionate to reach the desired Na or Cl concentration. For each Na or Cl concentration the uptake measured into nontransfected HEK cells was taken as background. A, External [Na] was varied, and the data were fit to: V = V_max [Na]ⁿ/(K_mⁿ + [Na]ⁿ). The data were analyzed first by nonlinear curve fitting, with the Hill coefficient as a free parameter. After determining that the coefficient was close to two, we set it exactly to two and determined V_max and K_m. Holding at n = 2, V_max = 67.41 ± 4.49 pmol/mg protein and K_m = 40.7 ± 1.7 mM. B, External [Cl] was varied, and the data were fit as in A. The data were analyzed first by nonlinear curve fitting, with the Hill coefficient as a free parameter. After determining that the coefficient was close to one, we set it exactly to one and determined V_max and K_m. Holding at n = 1, V_max = 28.46 ± 1.12 pmol/mg protein and K_m = 7.0 ± 1.3 mM. The difference in maximal velocities represents a difference in expression level between batches of cells used in the two assays (n = 6). Expression levels decrease with increasing passage numbers.

Proline induces a GGFL-sensitive current in HP-21 cells

Figure 4 shows data from a HP-21 cell in the whole-cell voltage-clamp mode. The holding potential was $-$ 40 mV and the testpotential was $-$ 140 mV for 500 msec. The raw data were obtainedat room temperature and are neither leak-subtracted nor capacity-compensated.PRO (40 µM) had no effect on parental cells. These data demonstratethat PRO increases the steady-state component of the current andthat GGFL blocks this induced current to control levels. PRO-inducedcurrent is defined as the current in the presence of PRO minusthe current without PRO (control: Cont). The inset shows the effectof 40 µM PIP at $-$ 120 mV. GGFL blocks PIP-induced current withequal effectiveness (n = 4). GGFL has no effect on the pre-steady-statecontrol current, and, similarly, control-proline curves show nopre-steady-state effects. Instead, the apparent difference betweenthe on and the off transients represents similar activation/relaxationkinetics of the steady-state currents. Interestingly, two moleculesthat previously were shown to inhibit PRO uptake in PROT-transfectedHeLa cells, L-norleucine and sarcosine (Fremeau et al., 1992;Shafqat et al., 1995), also were able to generate GGFL-sensitiveinward current at negative voltages (100 µM bath substrate concentration;data not shown). These data support the conclusion that PROT-mediatedPRO uptake is electrogenic. Because PRO, PIP, L-norleucine, andsarcosine are able to induce similar currents through the prolinetransporter, we suggest that these substrates have a similar mechanismof action and a common permeation pathway. On the other hand,the competitive peptide inhibitors GGFL and YGGFL (data not shownfor the latter) themselves are unable to induce currents but inhibitsubstrate-induced currents. These data support the suggestionfrom previous data that GGFL and YGGFL are nontransported inhibitorsof PROT, i.e., antagonists (Fremeau et al., 1996).

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Figure 4. Substrate-induced current in HP-21 cells. Shown is substrate-induced current after bath application of PRO to a voltage-clamped HP-21 cell. The holding potential was $-$ 40 mV, and the test potential was $-$ 140 mV for 500 msec. After 40 µM PRO was added to the bath, the inward current increased at $-$ 40 and $-$ 140 mV. Substrate-induced current is defined as the difference between the background current (Cont) and PRO-induced inward current. The traces represent raw data without leak subtraction or capacity compensation. The inset shows the inward current induced by bath application of PIP (40 µM) at $-$ 120 mV. External GGFL was 100 µM and was added in the presence of PRO or PIP.

I-V curves and mean-variance analysis for proline and L-pipecolate

Figure 5, A and B, compares current-voltage I-V curves for PRO- and PIP-induced currents obtained from parallel dishes oftransfected cells. The I-V relationships were defined by plottingthe (background-subtracted) substrate-induced currents againstthe test voltage. We used concentrations of ~2× the K_m for uptake,measuring the average substrate-induced current between 400 and500 msec during the test pulse. The I-V for PRO and PIP are similarin shape and absolute value, providing circumstantial evidencefor a mutual mechanism of uptake; however, we have not exploredwhether PRO and PIP compete for similar binding sites or occludeeach other's currents. To investigate whether charge transportedthrough PROTs is uncoupled (Galli et al., 1996, 1997; Larssonet al., 1996; Lester et al., 1996; Sonders and Amara, 1996), weinvestigated the elementary events that underlie the PRO-inducedcurrents. Figure 5, C and D, shows results obtained from currentfluctuations induced by PRO and PIP, respectively. Between $-$ 140and $-$ 60 mV, the value of i(1 $-$ p) for PRO is 31.4 ± 17.7 fA andfor PIP is 56.4 ± 48.7 fA (mean ± SD), with a slope not significantlydifferent from zero for either substrate (p < 0.05). Therefore,the >2× increase of substrate-induced current observed in thesame voltage range does not result from an increase in the elementarycurrent, and there is no statistical correlation between the macroscopicand microscopic current-voltage relations (r < 0.01). The subtractionprocedure that we used compares the variance with and withoutPRO or PIP. For this analysis we selected cells that displayedno leak current, i.e., GGFL returned the traces to the controlvalue. Unlike norepinephrine transporters (Galli et al., 1996,1998), there is no significant difference in control varianceor in transient currents in the presence or absence of inhibitor.

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Figure 5. Steady-state I-V curves for PRO- and PIP-induced currents in HP-21 cells. A, Steady-state I-V curve for PRO-induced currents was obtained from 500 msec test pulses that ranged from $-$ 120 to $-$ 20 mV in 20 mV increments. Substrate concentration was 40 µM. GGFL blocked substrate-induced currents at concentrations between 100 and 600 µM. The plot shows that GGFL-sensitive, PRO-induced currents apparently reverse for potentials between $-$ 10 and $-$ 30 mV. However, there is no significant positive current at any potential. B, The steady-state I-V curve for PIP-induced current was obtained by stepping the voltage for 500 msec from $-$ 140 to $-$ 20 mV, in 20 mV increments, from a $-$ 40 mV holding potential. The substrate concentration was 40 µM. GGFL blocked the substrate-induced current at concentrations of 100 µM. The plot shows a GGFL-blocked PIP-induced current, which also apparently reverses between $-$ 10 and $-$ 30 mV. C, The plot shows the difference variance of the PRO-induced current fluctuations, viz., $sigma$ ² = $sigma$ ²_PRO $-$ $sigma$ ²_CO, at different voltages. The ratio of the difference variance to the mean steady-state current: I = I_PRO $-$ I_CO, was plotted against the voltage. The value of the ratio $sigma$ ²/I is not voltage-dependent. Using this procedure in 40 µM PRO, we were able to estimate the magnitude of the underlying events at different voltages. D, L-Pipecolate-induced current fluctuations followed the proline pattern. We estimated the increased variance as: $sigma$ ² = $sigma$ ²_PIP $-$ $sigma$ ²_CO. An Axopatch 200A band limited with a four-pole Butterworth filter at 2000 Hz was used to measure currents. The ratio of the variance to the mean current (I = I_PIP $-$ I_CO) ratio did not show voltage dependence. All data points represent means ± SD (n = 4).

The action of GGFL is membrane side-specific

Although it is evident that GGFL blocks PRO uptake and PRO-induced current when added to the outside, it is unclear whetherits action, or the action of any transporter antagonist, is sided.To evaluate whether GGFL inhibits PROT at an internal site, weperformed experiments in which high concentrations of GGFL wereperfused into the cell. When the electrodes were filled with 1mM GGFL in intracellular buffer, application of 40 µM PRO to thebath induced an inward current, as shown in Figure 6A. Applicationof external GGFL (100 µM) blocked this current. In parallel experimentswith dissolved green fluorescent protein (GFP) in the pipette,there was rapid and direct access of the pipette solution to theinterior of the cell as observed by fluorescence (data not shown).Nevertheless, to insure that the GGFL entered the cell, we waited15 min after forming the whole-cell configuration. Externallyapplied substrate-induced currents were recorded up to 45 minafter the seal was broken. These data support the hypothesis thatGGFL binds to an external site that is unavailable from the intracellularcompartment. The magnitude and voltage dependence of the (external)GGFL-sensitive PRO-induced current is similar to I-V values obtainedin the presence of GGFL in the intracellular compartment (Fig.6B). Thus GGFL in the cytoplasmic compartment does not affectthe ability of the substrate to induce PROT-mediated, voltage-dependentinward current.

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Figure 6. Transporter side-specific block of PRO-induced current by GGFL. A, PRO induces an inward current with 1 mM GGFL in the whole-cell pipette. The application of GGFL (100 µM) to the bath (extracellular side of the transporter) blocks PRO-induced current. The cell was held at $-$ 40 mV. Note the presence of a leak current in these cells, which is observed inconsistently in other cells. B, Plotted is the current-voltage relationship of the substrate-induced current, obtained by using 1 mM GGFL in the whole-cell pipette. Data are the means ± SD of six to eight experiments (PRO application and washout under perfusion) from two different cells normalized to the PRO-induced current at $-$ 120 mV. The shape of the curve suggests saturation at hyperpolarized holding potentials similar to I-V values for PRO and PIP in the absence of internal GGFL (A, B).

  DISCUSSION

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ABSTRACT
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MATERIALS AND METHODS
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DISCUSSION
REFERENCES

In vitro flux assays demonstrate that the transport of PRO into the presynaptic terminals is Na-dependent (Fremeau et al.,1992, 1996). Our uptake data are consistent with a model in whichrPROT has a stoichiometry of 1 PRO: 2 Na: 1 Cl. The coupling mostlikely occurs when PRO and the cotransported ions bind the transporteron the external side with an unknown sequence of events. Consideringthe stoichiometry of the individual transporter events, rPROTwould move one elementary charge per transport cycle at physiologicalpH. Uptake therefore would generate an inward current proportionalto the number of transporters present on the cell surface andthe rate of transport. Proline transport has been studied previouslyonly with radiolabeled flux assays in which the membrane voltageis not controlled, and we present similar data in the presentpaper. Electrogenic transport generating inward current mandatesdepolarization, which with substrate accumulation possibly couldinhibit uptake. Thus the shapes of the uptake curves may not reflectentirely the fundamental properties of the transport protein.Moreover, flux assays depend on radiolabeled compounds that arenot always available, as in the case of L-pipecolate. We addressedthese issues by studying the substrate-induced current with thepatch-clamp technique, under the assumption that uptake and currentare related. Using the transport-associated current as an indicatorof PROT activity, we were able to assay function under definedionic composition and transmembranevoltage.

We engineered a cell line, HP-21, by stably transfecting HEK-293 cells with rPROT cDNA. These cells demonstrate Na- and Cl-dependentPRO uptake that saturates at micromolar concentrations and hasa Hill coefficient near 1 for L-proline. GGFL and YGGFL addedexternally block this transport process. Parallel incubation withunlabeled PRO and PIP demonstrate that both substrates inhibitthe transport of radiolabeled L-proline with similar potency.If we assume a stoichiometry of 1 PRO: 2 Na: 1 Cl (Q = 1) andconvert a nominal 500 pmol/10⁶ cells per minute (see Fig. 1) to charges per second, one cellwould generate <1 pA net inward current. In Figure 5, A and B,we show that both PRO and PIP induce an inward current of approximately $-$ 5 pA at $-$ 40 mV and $-$ 20 pA at $-$ 140 mV. Note, however, that cellsare selected individually for high currents and that voltage isclamped at negative potentials, which is likely to promote uptake.In contrast, uptake velocities represent the average from thousandsof unclamped cells. These differences between current and uptakemeasurements may explain the disparity between recorded and calculatedcurrent. In any case, it is clear that PROTs contrast markedlywith NETs and SERTs, which may generate 100× the predicted coupledcurrent (Galli et al., 1996, 1997).

At concentrations of ~2× the K_m for uptake and at $-$ 120 mV, PRO or PIP could induce $-$ 20 pA of current. This may be indicativeof the previously suggested voltage dependence of the PRO uptakeprocess (Miller et al., 1997a). To test whether the elementarycharge transfer changes with voltage, we analyzed the PRO-inducedcurrent fluctuations at different potentials. The ratio of varianceto mean, $sigma$ ²/I = i(1 $-$ p), measures the size of the elementary transport event(Galli et al., 1996). For PROTs this ratio is small (tens of fAs)compared with norepinephrine transporters (hundreds of fAs), andin PROTs the ratio is approximately independent of voltage between $-$ 140 and $-$ 60 mV. PROT currents apparently reverse at membranepotentials between $-$ 10 to $-$ 30 mV; however, there is considerableerror in measurements near the reversal potential and thereforelarge variability in the data. Some cells had a leak current (PROT-associatedcurrent as revealed by GGFL in the absence of PRO), whereas othercells did not. Except for these differences, which we attributeto cell-to-cell variation, substrate-induced currents and currentfluctuations are similar in PRO or PIP. The variance-mean ratiosuggests elementary events of quantal size i ~0.01 pA, approximatelyone-tenth the amplitude of the analogous event in hNET or dSERT(Galli et al., 1996, 1997). The voltage-dependent current likelyis related to a voltage-dependent turnover of a coupled transporterrather than voltage-dependent stoichiometry. Moreover, PRO andPIP currents show similar voltage sensitivity at the macroscopic(whole-cell I-V curve) and microscopic (single transporter, $sigma$ ²/I-V curve) levels, consistent with a common mechanism for theaction of these two substrates. GGFL and YGGFL block both thetransport process and the substrate-induced inward current, butthey do not themselves induce a transporter-associated current.These data support the hypothesis that GGFL and YGGFL are nontransportedPROTantagonists.

We also obtained data in support of the hypothesis that enkephalin-mediated block of the transporter process is sided. Figure6 demonstrates that GGFL does not inhibit PRO-induced currentswhen applied from the inside of the cell, suggesting that theGGFL-binding site faces only the extracellular compartment. Thistopologically specific inhibition may represent an important physiologicalinteraction between enkephalins and mammalian PROTs (for review,see Fremeau et al., 1996). Enkephalins are stored and releasedfrom large dense-cored vesicles in the CNS (Sesack and Pickel,1992). The concentration of enkephalins in these vesicles is ~1mM, and, given the geometry of excitatory synapses, the concentrationof enkephalin bathing PROTs could be >10 µM (Chen et al., 1995),i.e., near the range that inhibits the proline transporter. Ourdata show that the peptide fragment GGFL retains the ability toinhibit proline uptake and proline-induced current. Because enkephalinsare degraded by enzymatic hydrolysis generating the des-tyrosylderivative, we infer that inhibition of proline uptake may persistwell after the opioid actions of theenkephalins.

In summary, we have characterized a stable rat PROT-expressing mammalian cell line that is suitable for radiometric and biophysicaltechniques. Our experiments are consistent with a coupling modelof 1 PRO: 2 Na: 1 Cl. The magnitude of the substrate-induced currentat resting membrane potentials is close to the predicted sizeof the hypothetical current calculated from V_max values for PROuptake. Thus, unlike other transporters in this gene family, theproline transporter does not appear to mediate large, uncoupledcurrents. The putative endogenous substrate, L-proline, and itsstructurally related congener, L-pipecolate, show similar affinityand efficacy for PROT. Moreover, the level of the substrate-inducedcurrent is similar for PRO and PIP, further supporting the hypothesisthat these substrates activate PROT by similar mechanisms. Thisconclusion is sustained by fluctuation analysis of the elementaryevents associated with the substrate-induced current. We concludethat PROT is electrogenic and that PRO, PIP, L-norleucine, andsarcosine are substrates of PROT. Specifically, we have shownthat PIP is either a substrate for the transporter or a rare antagonistof neurotransmitter uptake capable of inducing an inward current.Using the patch-clamp technique in whole-cell configuration, wedemonstrated that YGGFL and GGFL are transport blockers and identifiedthe side of action of GGFL. Finally, unlike other members of thisgene family subject to similar biophysical analysis, rPROT expressedin HEK-293 cells apparently lacks excess uncoupled current. Instead,our results indicate that rPROT behaves as a classical transporterwith fixedstoichiometry.

  FOOTNOTES

Received Sept. 15, 1998; revised May 13, 1999; accepted May 14, 1999.

This work was supported by a National Alliance for Research on Schizophrenia and Depression Young Investigator Award (A.G.)and National Institutes of Health Grants NS-33373 (L.J.D.) andNS-32501 (R.T.F.). We thank Dr. Barbara Domin for her assistancein generating the HP-21 cell line and Dawn Borromeo for her invaluablehelp in maintaining cell lines, preparing solutions, and othertechnicalassistance.
Correspondence should be addressed to Dr. Louis J. DeFelice, Department of Pharmacology, Vanderbilt University Medical Center,Nashville, TN 37232-6600.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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