The glial and the neuronal glycine transporters differ in their reactivity to sulfhydryl reagents.

The neuronal (GlyT2) and glial (GlyT1) glycine transporters, two members of the Na(+)/Cl(-)-dependent neurotransmitter transporter superfamily, differ by many aspects, such as substrate specificity and Na(+) coupling. We have characterized under voltage clamp their reactivity toward the membrane impermeant sulfhydryl reagent [2-(trimethylammonium)-ethyl]-methanethiosulfonate (MTSET). In Xenopus oocytes expressing GlyT1b, application of MTSET reduced to the same extent the Na(+)-dependent charge movement, the glycine-evoked current, and the glycine uptake, indicating a complete inactivation of the transporters following cysteine modification. In contrast, this compound had no detectable effect on the glycine uptake and the glycine-evoked current of GlyT2a. The sensitivities to MTSET of the two transporters can be permutated by suppressing a cysteine (C62A) in the first extracellular loop (EL1) of GlyT1b and introducing one at the equivalent position in GlyT2a, either by point mutation (A223C) or by swapping the EL1 sequence (GlyT1b-EL1 and GlyT2a-EL1) resulting in AFQ <--> CYR modification. Inactivation by MTSET was five times faster in GlyT2a-A223C than in GlyT2a-EL1 or GlyT1b, suggesting that the arginine in position +2 reduced the cysteine reactivity. Protection assays indicate that EL1 cysteines are less accessible in the presence of all co-transported substrates: Na(+), Cl(-), and glycine. Application of dithioerythritol reverses the inactivation by MTSET of the sensitive transporters. Together, these results indicate that EL1 conformation differs between GlyT1b and GlyT2a and is modified by substrate binding and translocation.

Glycine receptor beta subunits play a critical role in potentiation of glycine responses by ICS-205,930.

The sensitivity of various types of recombinant glycine receptors (GlyRs) to ICS-205,930 was studied by fast perfusion in Xenopus laevis oocytes. This compound has previously been shown to potentiate glycine responses in rat spinal neurons between 10 nM and 1 microM, independently of its 5-HT(3) antagonist properties. In contrast, submicromolar concentrations of ICS-205,930 failed to affect responses of homomeric GlyRs formed from human alpha1 or alpha2 subunits, and micromolar concentrations (1-20 microM) acted differentially on the two types of homomeric receptors, potentiating the responses to glycine (10-20 microM) of alpha1 homomeric GlyRs and inhibiting the responses of alpha2 homomeric GlyRs. GlyRs beta subunits markedly influenced the modulations induced by ICS-205,930. In oocytes expressing alpha1/beta or alpha2/beta heteromeric GlyRs, low concentrations of ICS-205,930 (20 nM-1 microM) induced a potentiation of glycine responses that was counteracted by an inhibitory effect at higher concentrations. Thus, GlyRs beta subunits reduce by 2 orders of magnitude the concentration range potentiating alpha1-containing GlyRs and are required for potentiation of alpha2-containing GlyRs. These results reveal a new high-affinity potentiating site on GlyRs, to which beta subunits participate. The difference in ICS sensitivity between alpha1 and alpha2 GlyRs cannot be explained by their difference in TM2 segment and extracellular domains partly conserved between glycine and 5-HT(3) receptors are probably involved in the interaction of some 5-HT(3) antagonists with GlyRs.

Neuronal and glial glycine transporters have different stoichiometries.

A neurotransmitter transporter can potentially mediate uptake or release of substrate, and its stoichiometry is a key factor that controls the driving force and thus the neurotransmitter flux direction. We have used a combination of electrophysiology and radio-tracing techniques to evaluate the stoichiometries of two glycine transporters involved in glycinergic or glutamatergic transmission. We show that GlyT2a, a transporter present in glycinergic boutons, has a stoichiometry of 3 Na+/Cl-/glycine, which predicts effective glycine accumulation in all physiological conditions. GlyT1b, a glial transporter, has a stoichiometry of 2 Na+/Cl-/ glycine, which predicts that glycine can be exported or imported, depending on physiological conditions. GlyT1b may thus modulate glutamatergic synapses by increasing or decreasing the glycine concentration around N-methyl-D-aspartate receptors (NMDARs).

Differential properties of two stably expressed brain-specific glycine transporters.

Clonal cell lines stably expressing the glial glycine transporter 1b (GLYT1b) and the neuronal glycine transporter 2 (GLYT2) from rat brain have been generated and used comparatively to examine their kinetics, ion dependence, and electrical properties. Differential sensitivity of the transporters to sarcosine is clearly exhibited by the clonal cell lines. GLYT2 transports glycine with higher apparent affinity than GLYT1b and is not inhibited by any assayed compound, as deduced by glycine transport assays and electrophysiological recordings. A sigmoidal Na+ dependence of the glycine uptake by the stable cell lines is observed, indicating the involvement of more than one Na+ in the transport process. A more cooperative behavior for Na+ of GLYT2 than GLYT1b is suggested. One Cl- is required for GLYT1b and GLYT2 transport cycles, although GLYT1b shows three times higher affinity for this ion than GLYT2. The number of expressed transporters was sufficient to allow electrophysiological recordings of the uptake current in the two stable cell lines. GLYT2 exhibits more voltage dependence in both its glycine-evoked current and its capacitive currents recorded in the absence of substrate.

Control of NMDA receptor activation by a glycine transporter co-expressed in Xenopus oocytes.

We present evidence that membrane transporters can control the membrane receptor's agonist concentration in restricted extracellular spaces of a biological model. The model is constructed by co-expressing glycine/Na/Cl cotransporters (GLYT1b) and NMDA receptors (NMDARs) (composed of the subunits NR1 and NR2A or NR2B) in Xenopus oocytes. We use the high-affinity glycine site of the NMDARs as a sensor of the actual juxtamembrane glycine concentration. We show that glycine uptake by GLYT1b dramatically reduces NMDAR currents by reducing the glycine concentration in extracellular spaces in which diffusion is restricted. This effect appears only in oocytes in which GLYT1b and NMDAR are co-expressed. It is Na+- and voltage-dependent, and is abolished when Na+ is replaced by Li+ and when glycine is replaced by D-serine (a coagonist of the NMDAR that is not transported by GLYT1b). These results demonstrate the ability of the GLYT transporter to reduce glycine concentration at the level of NMDARs in restricted diffusion spaces. This observation could account for a prevalent role of membrane transporters in the modulation of synapse transmission in the CNS. From a more general point of view, our results draw attention to possible significant discrepancies between local concentrations at the level of substrate targets in biological membranes and their concentration in the bulk solution when membrane transporters are present.

Relaxation kinetics of the Na+/glucose cotransporter.

An important class of integral membrane proteins, cotransporters, couple solute transport to electrochemical potential gradients; e.g., the Na+/glucose cotransporter uses the Na+ electrochemical potential gradient to accumulate sugar in cells. So far, kinetic analysis of cotransporters has mostly been limited to steady-state parameters. In this study, we have examined pre-steady-state kinetics of Na+/glucose cotransport. The cloned human transporter (hSGLT1) was expressed in Xenopus oocytes, and voltage-clamp techniques were used to monitor current transients after step changes in membrane potential. Transients exhibited a voltage-dependent time constant (tau) ranging between 2 and 10 ms. The charge movement Q was fitted to a Boltzmann relation with maximal charge Qmax of approximately 20 nC, apparent valence z of 1, and potential V0.5 of -39 mV for 50% Qmax. Lowering external Na+ from 100 to 10 mM reduced Qmax 40%, shifted V0.5 from -39 to -70 mV, had no effect on z, and reduced the voltage dependence of tau. Qmax was independent of, but tau was dependent on, temperature (a 10 degrees C increase increased tau by a factor of approximately 2.5 at -50 mV). Addition of sugar or phlorizin reduced Qmax. Analyses of hSGLT1 pre-steady-state kinetics indicate that transfer upon a step of membrane potential in the absence of sugar is due to two steps in the reaction cycle: Na+ binding/dissociation (30%) and reorientation of the protein in the membrane field (70%). The rate-limiting step appears to be Na+ binding/dissociation. Qmax provides a measure of transporter density (approximately 10(4)/microns 2). Charge transfer measurements give insight into the partial reactions of the Na+/glucose cotransporter, and, combined with genetic engineering of the protein, provide a powerful tool for studying transport mechanisms.

Chloride channels in myocytes from rabbit colon are regulated by a pertussis toxin-sensitive G protein.

Because of the high intracellular Cl- concentration ([Cl-]i) in gastrointestinal smooth muscle, receptor-mediated opening of Cl- channels at the cell resting potential could represent a plausible mechanism for initial receptor-mediated cell depolarization. To test this hypothesis, we characterized activation of large-conductance Cl- channels by the neurokinin-1 (NK-1) receptor agonist [Sar9,Met(O2)11]-substance P, by specific second messengers, and by direct G protein activation in myocytes isolated from the rabbit colon longitudinal muscle layer. In excised inside-out patches, large-conductance ion channels selective for Cl- over Na+ could be induced by holding the patch at pipette potentials values > 60 mV. The channel showed multiple smaller conductance states (< or = 20) but could open and close via a main gate. When the channel was fully open, its slope conductance was 300 pS, with substates as small as 15 pS, comparable to the predominant conductance observed in cell-attached patches. The voltage-activation profile for full conductance was bell-shaped with maximal open probability (Po) for channel opening of approximately 0 mV. In cell-attached patches, addition of the NK-1 agonist to pipette solution activated a channel that corresponded to a subconductance state of the maxi Cl- channel. The voltage-activation profile for this subconductance state showed a maximal Po value for membrane potentials of approximately 0 mV, with rapid inactivation at more positive and partial inactivation at more negative membrane potentials. In excised inside-out patches, both the full and smaller conductance states of the Cl- channel were activated by the nonhydrolyzable guanosine triphosphate analogue guanosine 5'-O-(3-thiotriphosphate) and inhibited by pertussis toxin (PTX), whereas [Ca2+]i increased channel activity only in concentrations > 1 mM. In cell-attached patches, addition of different Ca2+ ionophores resulted in channel activation in 10% of cells, and activators of protein kinase A or protein kinase C had no effect. These findings are consistent with the hypothesis of a possible role of G protein-coupled Cl- channels in receptor-mediated initial cell depolarization in longitudinal colonic smooth muscle.

Whole-cell currents in isolated resting Necturus gastric oxynticopeptic cells.

1. Necturus gastric mucosa secretes Cl- actively across the gastric glands which are composed almost entirely of acid- and enzyme-secreting oxynticopeptic cells. Single channel studies on Necturus oxynticopeptic cells have shown that the basolateral membrane possesses multiple K(+)-selective channels but no observable Cl- channels while the apical membrane has Cl- channels but no observable K+ channels. To relate these channel properties to the conductance of the whole cell we have investigated the macroscopic membrane currents with conventional whole-cell patch-clamp techniques. 2. When bathed in amphibian Ringer solution, gastric oxynticopeptic cells had a membrane resistance of 47.8 +/- 2.8 M omega and a membrane capacitance of 75.5 +/- 2.7 pF (n = 82). This gave a specific membrane resistance of 3260 +/- 160 omega cm2 (n = 82). Reversal potentials of the oxynticopeptic cells were -13.8 +/- 1.2 mV (n = 45) for an intracellular Cl- concentration ([Cl-]i) of 42 mM and were significantly more negative -24.4 +/- 3.1 mV (n = 31, P < 0.001) for [Cl-]i = 22 mM. 3. In the absence of ATP in the pipette solution, there was an 80% reduction of the whole-cell current with a typical half-time (t1/2) of 5 min. The run-down was not observed when the pipette solution contained 4 mM ATP. 4. A slow and voltage-independent inhibition of 80% of the whole-cell currents occurred after addition of NPPB (35 microM). Ba2+ (10 mM) produced a reversible inhibition of 20% of the total current. Together, 35 microM NPPB and 10 mM Ba2+ eliminated 95% of the whole-cell currents. These data suggest that in the resting oxynticopeptic cells Cl- carried the major fraction of the current while K+ ions carried only a small fraction. 5. Total replacement of Cl- in the pipette and bath solution by gluconate- increased the membrane resistance to 751 +/- 104 M omega (n = 53) and shifted the reversal potential to -38.1 +/- 2.8 mV (n = 53). 6. Increasing the bath K+ concentration from 6 to 91 mM activated a current which had a high selectivity for K+ over choline+, Li+, Na+, Rb+ and Cs+ and was independent of Cl-. The activation of this K+ current (IK*) by high external K+ was not seen with ATP-free pipette solution. 7. Ba2+ or Cs+ had a voltage-dependent blocking effect of this inward K+ current. Ouabain (1 mM) or SCH 28080 (200 microM), specific inhibitors of the Na+,K(+)-ATPase and H+,K(+)-ATPase, had no effect.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of large-conductance chloride channels in rabbit colonic smooth muscle.

1. A large-conductance Cl- channel was characterized in cell-free membrane patches from the rabbit longitudinal colonic smooth muscle using the patch clamp technique. In addition, the regulation of these channels by neurokinin-1 (NK-1) receptor agonists and G proteins was studied. 2. No spontaneous channel activity was observed in cell-attached patches at the cell resting potential, or in excised patches at pipette potentials (Vp) between -20 and 20 mV. In excised patches, channel activity could be induced in thirty-six out of ninety-six patches by holding the patch at Vp values more negative than -60 mV or more positive than 60 mV. Once induced, the channel showed a bell-shaped voltage activation curve in high symmetric [Cl-], with maximal open probability between 20 and -5 mV. Varying cytosolic calcium concentration ([Ca2+]) between 5 x 10(-8) M and 1.0 mM had no effect on the voltage activation of the channel. 3. In inside-out and outside-out patches, when pipette and bath solutions contained equal [Cl-] (130 mM), the anion channel showed a linear current-voltage (I-V) relationship between -60 and 60 mV with a slope conductance of 309 +/- 20 pS (n = 13). Reversal potential measurements indicated that the channel was selective for Cl- over Na+ and K+ (PCl/PNa = 6:1). 4. Channel openings from the closed state to the full open state as well as transitions through smaller conductance states were observed. The smallest detectable substate had a conductance of 15.6 pS. Based on the similarities in selectivity and linearity of the I-V curve of the smaller conductances with the full open state, and kinetic analysis of channel activity, it is concluded that the large conductance channel is composed of multiple substates which can either open and close independently, or simultaneously via a main gate. 5. The stilbene derivative diiso-thiocyanato-stilbene-disulphonic acid (DIDS) and the diphenylamine-2-carboxylate analogue 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB) caused a dose-dependent, reversible flicker block of the small conductance and significantly reduced the macroscopic current flow through the channel. 6. In quiescent outside-out patches, when the pipette contained a 140 mM-CsCl solution with 10(-6) M-CaCl2, 1.2 mM-MgCl2 and 1 mM-GTP, and the bath contained Ringer solution, addition of the NK-1 receptor antagonists substance P methylester resulted in activation of the full conductance state and of smaller substates.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrogenic properties of the cloned Na+/glucose cotransporter: II. A transport model under nonrapid equilibrium conditions.

The results of the accompanying electrophysiological study of the cloned Na+/glucose cotransporter from small intestine (Parent, L., Supplisson, S., Loo, D.D.F., Wright, E.M. (1992) J. Mémbrane Biol. 125:49-62) were evaluated in terms of a kinetic model. The steady-state and presteady-state cotransporter properties are described by a 6-state ordered kinetic model ("mirror" symmetry) with a Na+:alpha MDG stoichiometry of 2. Carrier translocation in the membrane as well as Na+ and sugar binding and dissociation are treated as a function of their individual rate constants. Empty carrier translocation and Na+ binding/dissociation are the only steps considered to be voltage dependent. Currents were associated with the translocation of the negatively charged carrier in the membrane. Negative membrane potential facilitates sugar transport. One numerical solution was found for the 14 rate constants that account quantitatively for our experiment observations: i.e., (i) sigmoidal shape of the sugar-specific current-voltage curves (absence of outward currents and inward current saturation at high negative potentials), (ii) Na+ and voltage dependence of Ksugar0.5 and isugarmax, (iii) sugar and voltage dependence of KNa0.5 and iNamax, (iv) presteady-state currents and their dependence on external Na+, alpha MDG and membrane potential, and (v) and carrier Na+ leak current. We conclude that the main voltage effect is on carrier translocation. Na+ ions that migrate from the extracellular medium to their binding sites sense 25 to 35% of the transmembrane voltage, whereas charges associated with the carrier translocation experiences 60 to 75% of the membrane electrical field. Internal Na+ ion binding is not voltage dependent. In our nonrapid equilibrium model, the rate-limiting step for sugar transport is a function of the membrane potential, [Na]o and [alpha MDG]o. At 0 mV and at saturating [Na]o and [alpha MDG]o, the rate-limiting step for sugar transport is the empty carrier translocation (5 sec-1). As the membrane potential is made more negative, the empty carrier translocation gets faster and the internal Na+ dissociation becomes increasingly rate limiting. However, as [Na]o is decreased to less than 10 mM, the rate-limiting step is the external Na+ ions binding in the 0 to -150 mV potential range. At 0 mV, the external Na+ dissociation constant KNa' is 80 mM and decreases to 24 mM at -150 mV. The external sugar dissociation constant KNaS' is estimated to be 200 microM and voltage independent. Finally, the internal leak pathway (CNa2 translocation) is insignificant.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrogenic properties of the cloned Na+/glucose cotransporter: I. Voltage-clamp studies.

The cloned rabbit intestinal Na+/glucose cotransporter was expressed in Xenopus laevis oocytes. Presteady-state and steady-state currents associated with cotransporter activity were measured with the two-electrode voltage-clamp technique. Steady-state sugar-dependent currents were measured between -150 and +90 mV as a function of external Na+ ([Na]o) and alpha-methyl-D-glucopyranoside concentrations ([alpha MDG]o). K alpha MDG0.5 was found to be dependent upon [Na]o and the membrane potential. At Vm = -50 mV, increasing [Na]o from 10 to 100 mM decreased K alpha MDG0.5 from 1.5 mM to 180 microM. Increasing membrane potential toward negative values decreased K alpha MDG0.5 at nonsaturating [Na]o. For instance, at 10 mM [Na]o, K alpha MDG0.5 decreased from 1.5 mM to 360 microM on increasing the membrane potential from -50 to -150 mV. The i alpha MDGmax was relatively insensitive to [Na]o between 10 and 100 mM and weakly voltage dependent (e-fold increase per 140 mV). KNa0.5 and iNamax were found to be dependent upon membrane potential and [sugar]o. In the presence of 1 mM [alpha MDG]o, KNa0.5 decreased from 50 to 5 mM between 0 and -150 mV and iNamax increased twofold between -30 and -200 mV. The voltage dependence of KNa0.5 is consistent with an effect of potential on Na+ binding (Na(+)-well effect), whereas the voltage dependence of iNamax is compatible with the translocation step being voltage dependent. It is concluded that voltage influences both Na+ binding and translocation. Presteady-state currents were observed for depolarization pulses in the presence of 100 mM [Na]o. The transient current relaxed with a half time of approximately 10 msec, and both the half time and magnitude of the transient varied with the holding potential and the size of depolarization pulse. Presteady-state currents were not observed after the addition of phlorizin or alpha MDG to the external Na+ solution and were not observed for water-injected control oocytes. We conclude that presteady-state currents are due to the activity of the carrier and that they may give a novel insight to the transport mechanism of the Na+/glucose cotransporter.

The Na+/glucose cotransporter (SGLT1).

An important class of Na+ transport proteins is the cotransporters. They exist in bacteria and animal cells and are responsible for the "active" accumulation of sugars, amino acids, carboxylic acids and some ions, e.g., I-, Cl-, and PO-4, in cells. In the small intestine and renal proximal tubule the cotransporters play an important role in the transport of salt and water across the epithelia. The most well known and best characterized Na+ cotransporter is the intestinal brush border Na+/glucose cotransporter. We have cloned, sequenced, and expressed both the rabbit and human Na+/glucose cotransporters. The cDNAs code for 73kDa proteins with 662-664 residues (86% identity). Secondary structure analysis suggests a 12 membrane-spanning helical model with the N- and C-termini in the cytoplasm. A single N-linked glycosylation site is utilized at Asn248. These sugars are not required for function. Two essential residues for functional expression in oocytes have been identified, Asp28 and Arg300. In two sisters with glucose-galactose malabsorption the transport defect is caused by a missense mutation changing Asp28 to Asn28, and we have found that changing Arg300 to Cys300 eliminated transport. Current research is directed to finding residues and domains essential for ligand binding and transport, and we are using electrophysiological techniques to correlate structure and function.

Diversity of K+ channels in the basolateral membrane of resting Necturus oxyntic cells.

Patch-clamp techniques have been applied to characterize the channels in the basolateral membrane of resting (cimetidine-treated, nonacid secreting) oxyntic cells isolated from the gastric mucosa of Necturus maculosa. In cell-attached patches with pipette solution containing 100 mM KCl, four major classes of K+ channels can be distinguished on the basis of their kinetic behavior and conductance: (1) 40% of the patches contained either voltage-independent (a) or hyperpolarization-activated (b), inward-rectifying channels with short mean open times (16 msec for a, and 8 msec for b). Some channels showed subconductance levels. The maximal inward conductance gmax was 31 +/- 5 pS (n = 13) and the reversal potential Erev was at Vp = -34 +/- 6 mV (n = 9). (2) 10% of the patches contained depolarization-activated and inward-rectifying channels with gmax = 40 +/- 18 pS (n = 3) and Erev was at Vp = -31 +/- 5 mV (n = 3). With hyperpolarization, the channels open in bursts with rapid flickerings within bursts. Addition of carbachol (1 mM) to the bath solution in cell-attached patches increased the open probability Po of these channels. (3) 10% of the patches contained voltage-independent inward-rectifying channels with gmax = 21 +/- 3 pS (n = 4) and Erev was at Vp = -24 +/- 9 mV (n = 4). These channels exhibited very high open probability (Po = 0.9) and long mean open time (1.6 sec) at the resting potential. (4) 20% of the patches contained voltage-independent channels with limiting inward conductance of 26 +/- 2 pS (n = 3) and Erev at Vp = -33 +/- 3 mV (n = 3). The channels opened in bursts consisting of sequential activation of multiple channels with very brief mean open times (10 msec). In addition, channels with conductances less than 6 pS were observed in 20% of the patches. In all nine experiments with K+ in the pipette solution replaced by Na+, unitary currents were outward, and inward currents were observed only for large hyperpolarizing potentials. This indicates that the channels are more selective for K+ over Na+ and Cl-. A variety of K+ channels contributes to the basolateral K+ conductance of resting oxyntic cells.

A possible Na/Ca exchange in the follicle cells of Xenopus oocyte.

In manually dissected Xenopus oocytes, we found that the replacement of external sodium by Tris, choline, or lithium induced a large membrane depolarization and, in voltage clamp, a large inward current. This current appears to be due to activation of a calcium-dependent chloride conductance since it is reversed near ECl, increased by the removal of external chloride, and can be abolished by an injection of BAPTA or by the removal of external Ca2+. Using the Ca-dependent Cl current as a monitor of Ca concentration at the inner surface of the oocyte membrane, we are led to propose that the removal of external Na+ induces an increase in internal Ca2+ via the activation of a Na/Ca exchanger operating in the reverse mode. This interpretation is supported by the finding that the chloride current is diminished in either 3',4'-dichlorobenzamyl (DCB) or high external [Mg2+]o, both of which are known to block the Na/Ca exchanger, whereas it is increased when Li+, rather than Tris or choline, is used as the substitute for Na. The effect of zero [Na+]o was not obtained in oocytes from which follicular cells were removed by enzymatic treatment. This observation led us to test the possibility that the Na/Ca exchanger was present in the follicle cells and not in the oocyte membrane, assuming that entering Ca2+ could pass into the oocyte through gap junctions. Octanol, which blocks gap junctions, or a high [Ca2+]o both considerably reduced the inward current. While octanol probably blocked the gap junctions directly, we propose that the block by high [Ca2+] was due to an excessive rise of [Ca2+]i in the follicular cells. These results, taken together, indirectly suggest the presence of a Na/Ca exchanger in the follicular cells. These results, taken together, indirectly suggest the presence of a Na/Ca exchanger in the follicle cells of Xenopus oocyte which could contribute to the regulation of the internal Ca concentration of the oocyte before fertilization.

Neurokinin receptor-mediated regulation of [Ca]i and Ca-sensitive ion channels in mammalian colonic muscle.

In conclusion, these findings suggest the following: (1) NK receptor activation results in [Ca2+]i oscillations; (2) the receptor-mediated [Ca2+]i increase is partially due to influx of Ca2+ through L-type Ca2+ channels and partially to release from intracellular stores; (3) the receptor-mediated depolarization results from activation of a Cl- channel at the cell resting potential; (4) NK receptor-mediated release of [Ca2+]i may play a role in Cl- channel activation; (5) there is no evidence for multiple NK receptor types involved in cell activation.

Characterization of the D-glucose/Na+ cotransport system in the intestinal brush-border membrane by using the specific substrate, methyl alpha-D-glucopyranoside.

By using isolated membrane vesicles, we have investigated the tenet that D-glucose transport across the intestinal brush-border membrane involves at least two distinct, Na+-activated agencies (D-glucose transport systems S-1 and S-2), only one of which (S-1) can use methyl alpha-D-glucopyranoside (methyl alpha-glucoside) as a substrate. Our results with this glucose analogue show that: (a) As a function of time, methyl alpha-glucoside uptake exhibits a typical overshoot, similar to but smaller than that given by D-glucose with the same vesicle batch. (b) Nonlinear regression analysis of substrate-saturation curves reveals that, contrary to D-glucose, methyl alpha-glucoside transport involves a single transport system which we have identified as S-1. (c) Methyl alpha-glucoside exhibits an apparent affinity (defined as the reciprocal of Km) 4-times smaller than that of D-glucose for S-1 (Km(Dglucose) = 0.5 mM; Km(methyl alpha-glucoside) = 2 mM). However, methyl alpha-glucoside has a Vmax (230 pmol/mg protein per s) identical to that characterizing D-glucose transport by this system. (d) In the absence of Na+, methyl alpha-glucoside uptake is indistinguishable from simple diffusion, confirming that Na+ is an obligatory activator of S-1. (e) Phlorizin behaves as a fully competitive inhibitor of methyl alpha-glucoside transport (Ki = 18 microM), again indicating that S-1 is involved. (f) Neither phloretin nor cytochalasin B affects methyl alpha-glucoside uptake. We conclude that methyl alpha-glucoside is a substrate specific for S-1, which permits study of the properties of this system without interference by substrate fluxes taking place through any other channel.