Critical carboxyl group(s) in Na-dependent cotransporters of the intestinal brush-border membrane

We have previously provided functional evidence for a role of carboxyl group(s) in the mechanism of coupling of Na⁺ and d-glucose fluxes by the small-intestinal cotransporter(s) (Kessler, M. and Semenza, G. (1983) J. Membrane Biol. 76, 27–56). We present here a study on the inactivation of the Na⁺-dependent transport systems, but not of the Na⁺-independent ones, in the small-intestinal brush-border membrane, by hydrophobic carbodiimides. Although marginal or insignificant protection by the substrates or by Na⁺ was observed, the parallelism between Na⁺-dependence and inactivation by these carbodiimides strongly indicates the role of carboxyl group(s) previously indicated. Contrary to the carboxyl group identified by Turner ((1986) J. Biol. Chem. 261, 1041–1047) in the sugar binding site of the renal Na⁺/d-glucose cotransporter, the carboxyl group(s) studied here probably occur elsewhere in the cotransporter molecule.     

Reconstitution into liposomes of glucose active transport from the rabbit renal proximal tubule. Characteristics of the system

This paper describes the characteristics of Na⁺-dependent d-glucose transport into liposomes made from soybean phospholipids into which have been reconstituted detergent-solubilized components from the rabbit renal proximal tubular brush border membrane. Conditions for optimal and quantitative reconstitution of glucose carriers are defined. Na⁺-dependent d-glucose uptake occurs via a saturable system with a $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ of 0.125–0.135 mM, is responsive to the volume of the internal liposomal space, and shows ‘overshoot’ as seen in natural membranes. The rate of Na⁺-dependent d-glucose uptake and the magnitude of the ‘overshoot’ are proportional to the concentration of protein used in reconstitution.     

Transport of d-glucose by brush border membranes isolated from the renal cortex

The transport of d-glucose by brush border membranes isolated from the rabbit renal cortex was studied. At concentrations less than 2 mM, the rate of d-glucose uptake increased linearly with the concentration of the sugar. No evidence was found for a “high-affinity” (μM) saturable site. Saturation was indicated at concentrations of d-glucose greater than 5 mM. The uptake of d-glucose was stereospecific and selectively inhibited by d-galactose and other sugars. Phlorizin inhibited the uptake of d-glucose in the presence and absence of Na⁺. The glycoside was a potent inhibitor of the efflux of d-glucose. Preloading the brush border membrane vesicles with d-glucose, but not with l-glucose, accelerated exchange diffusion of d-glucose. These results demonstrate that the uptake of d-glucose by renal brush borders represents transport into an intravesicular space rather than solely binding. The rate of d-glucose uptake was increased when the Na⁺ in the extravesicular medium was high and the membranes were preloaded with a Na⁺-free medium. The rate of d-glucose uptake was inhibited by preloading the brush border membranes with Na⁺. These results are consistent with the Na⁺ gradient hypothesis for d-glucose transport in the kidney. Thus, the presence of a Na⁺-dependent facilitated transport of d-glucose in isolated renal brush border membranes is indicated. This finding is consistent with what is known of the transport of the sugar in more physiologically intact preparations and suggests that the membranes serve as an effective model system in examining the mechanism of d-glucose transport in the kidney.     

Reversed transport of amino acids in Ehrlich cells

Gramicidin induces a marked Na⁺-dependent efflux of amino acids from Ehrlich cells. In absence of Na⁺, gramicidin does not alter the efflux. In presence of gramicidin, glycine efflux is inhibited by methionine and less so by leucine. Glycine efflux caused by HgCl₂ is neither Na⁺ dependent nor inhibitable by amino acids. Neither efflux of inositol which is transported by an Na⁺-dependent route, nor efflux of several other solutes which are transported by Na⁺-independent routes, is affected by gramicidin. The antibiotic appears to permit a reversal in the direction of the operation of the Na⁺-dependent amino acid transport system. The increased efflux is partly, but not entirely, due to an increase in the cellular Na⁺ concentration and a reduction of the electrochemical potential difference for Na⁺.     

Interactions between Na+-dependent uptake of d-glucose,phosphate and l-alanine in rat renal brush border membrane vesicles

d-Glucose decreases phosphate reabsorption in rat proximal tubule. It is also postulated that some amino acids interact with phosphate reabsorption. To investigate the mechanism of these interactions, phosphate, d-glucose and l-alanine transport kinetics were measured in brush border membrane vesicles isolated from superficial rat kidney cortex by the calcium precipitation technique. At pH 7.4, Na⁺-dependent phosphate transport was inhibited in the presence of either d-glucose (39 mM) or l-alanine (2.4 mM). In this model, with d-glucose or with l-alanine the $\text{V}$ value of the phosphate uptake was decreased, whereas the apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ for the phosphate uptake was not affected. However, some inhibition of phosphate transport was observed in the presence of l-glucose, d-alanine or d-glucose after phlorizin preincubation. A 30% Na⁺-dependent l-alanine (0.1 mM) transport inhibition was observed in the presence of 5 mM phosphate. d-Glucose (1 mM) was also inhibited by 20% when 5 mM phosphate was added to incubation medium. According to several authors, in our model, d-glucose decreased the l-alanine transport and vice versa. Moreover, when the membrane potential was abolished, a clear inhibition of d-glucose by l-alanine persisted. These multiple interactions could be explained by the accelerated dissipation of the Na⁺ gradient insofar as the rate of the Na⁺ uptake was increased with d-glucose, l-alanine or phosphate and since the absence of variations in membrane potential did not suppress these inhibitions.     

Role of proton dissociation in the transport of acidic amino acids by the Ehrlich ascites tumor cells

The pH profile for the uptake of l-glutamic acid by the Ehrlich ascites tumor cell arises largely as a sum of the decline with falling pH of a slow, Na⁺-dependent uptake by System A, and an increasing uptake by Na⁺-independent System L. The latter maximizes at about pH 4.5, following approximately the titration curve of the distal carboxyl group. This shift in route of uptake was verified by (a) a declining Na⁺-dependent component. (b) an almost corresponding decline in the 2-(methylamino)-isobutyric acid-inhibitable component, (c) a rising component inhibited by 2-aminonorbornane-2-carboxylic acid. Other amino acids recognized as principally reactive with Systems A or L yielded corresponding inhibitory effects with some conspicuous exceptions: 2-Aminoisobutyric acid and even glycine become better substrates of System L as the pH is lowered; hence their inhibitory action on glutamic acid uptake is not lost. The above results were characterized by generally consistent relations among the half-saturation concentrations of the interacting amino acids with respect to: their own uptake, their inhibition of the uptake, one by another, and their trans stimulation of exodus, one by another.A small Na⁺-dependent component of uptake retained by l-glutamic acid but not by d-glutamic acid at pH 4.5 is inhibitable by methionine but by neither 2-(methylamino)-isobutyric acid nor the norbornane amino acid. We provisionally identified this component with System ASC, which transports l-glutamine throughout the pH range studied. No transport activity specific to the anionic amino acids was detected, and the unequivocally anionic cysteic acid showed neither significant mediated uptake nor inhibition of the uptake of glutamic acid or of the norbornane amino acid.     

Specificity of d-glucose transport by the apical membrane of Nereis diversicolor epidermis

(1) The specificity of d-[6-³H]glucose influx by a Na⁺-dependent and phlorizin-sensitive transport system in the apical epidermal membrane of the polychaete worm, Nereis diversicolor, was investigated in vivo. (2) The inhibitory effect of eleven d-glucose analogues on d-[6-³H]glucose influx from a 5 μM external concentration was recorded. The inhibitors (each tested at 5, 50, 500 and 5000 μM) were selected to illuminate the configurational requirements for interaction with the d-glucose transport system. (3) The following compounds were found to be significant inhibitors: methyl α-d-glucoside, methyl β-d-glucoside, d-galactose, $\text{3-O-}\text{methyl-}\text{d}\text{-glucose}$, 2-deoxy-d-glucose, d-xylose, myo-inositol, β-d-fructose; the effect was graded according to inhibitor concentration. l-Glucose also inhibited d-glucose influx but to the same extent at all four concentrations tested, suggesting transport site heterogeneity. d-Mannose and l-arabinose did not inhibit influx. (4) The most potent inhibitor, methyl-α-d-glucoside, was itself a substrate, and its transport was inhibited by phlorizin and d-glucose, as well as by substitution of Na⁺ in the incubation medium with Li⁺ or choline⁺. (5) We conclude that the specificity of the Na⁺-dependent d-glucose transporter in the apical epidermal membrane of Nereis is similar to that in the apical membrane of vertebrate small intestinal and proximal tubular epithelium, and in the tapeworm integument.     

Small-intestinal Na+/d-glucose cotransport. Inactivation of sugar transport and phlorizin binding by thiol-group and amino-group reagents

It has previously been shown that mercurials acting from the cytoplasmic side or from within the hydrophobic part of the membrane inactivate the small intestinal Na⁺/d-glucose cotransporter by blocking essential SH-groups (Klip, A., Grinstein, S. and Semenza, G. (1979) Biochim. Biophys. Acta 558, 233–245). Another (set of) sulfhydryl(s) which are critical for phlorizin binding and sugar transport function and which may lie on the luminal side of the brush border membrane, can be blocked by DTNB and 4,4′-dithiopyridine but not by $\text{N-}\text{ethylmaleimide}$. In addition, modification of amino groups by fluorescamine, reductive methylation and (under certain conditions) DIDS also lead to inactivation of the carrier's binding and transport functions. No evidence was obtained that any of the above groups is directly involved in the binding of either Na⁺/d-glucose or phlorizin, since none of these compounds prevented inactivation of the cotransporter.     

Characterisation and cloning of a Na-dependent broad-specificity neutral amino acid transporter from NBL-1 cells: a novel member of the ASC/B transporter family

Na⁺-dependent neutral amino acid transport into the bovine renal epithelial cell line NBL-1 is catalysed by a broad-specificity transporter originally termed System B⁰. This transporter is shown to differ in specificity from the B⁰ transporter cloned from JAR cells [J. Biol. Chem. 271 (1996) 18657] in that it interacts much more strongly with phenylalanine. Using probes designed to conserved transmembrane regions of the ASC/B⁰ transporter family we have isolated a cDNA encoding the NBL-1 cell System B⁰ transporter. When expressed in Xenopus oocytes the clone catalysed Na⁺-dependent alanine uptake which was inhibited by glutamine, leucine and phenylalanine. However, the clone did not catalyse Na⁺-dependent phenylalanine transport, again as in NBL-1 cells. The clone encoded a protein of 539 amino acids; the predicted transmembrane domains were almost identical in sequence to those of the other members of the B⁰/ASC transporter family. Comparison of the sequences of NBL-1 and JAR cell transporters showed some differences near the N-terminus, C-terminus and in the loop between helices 3 and 4. The NBL-1 B⁰ transporter is not the same as the renal brush border membrane transporter since it does not transport phenylalanine. Differences in specificity in this protein family arise from relatively small differences in amino acid sequence.     

Effects of ethanol in vitro on rat intestinal brush-border membranes

Ethanol, at concentrations found in the intestinal lumen after moderate drinking, has been shown to inhibit carrier-mediated intestinal transport processes. This inhibition could occur by direct interaction with membrane transporters, dissipation of the energy producing Na⁺ electrochemical gradient and/or nonspecific alteration of membrane integrity. The latter alteration may be reflected by changes in membrane fluidity, chemical composition or vesicular size. These possibilities were examined with studies in purified brush border membrane vesicles of rat intestine. Ethanol inhibited concentrative Na⁺-dependent d-glucose uptake in a dose-dependent manner. In contrast, ethanol did not inhibit concentrative d-glucose uptake under conditions of d-glucose trans-stimulation in the absence of a Na⁺ electrochemical gradient. Ethanol also inhibited initial, concentrative Na⁺-dependent taurocholic acid uptake, as well as equilibrium uptake. That ethanol exerted a dual effect on transport by increasing membrane conductance for Na⁺ while decreasing intravesicular space was supported by direct studies of Na⁺ uptake. Morphometric analysis confirmed that ethanol-treated membranes had a decreased intravesicular size when compared to untreated membranes. Finally, membrane fluidity measured by EPR showed that ethanol had a significant fluidizing effect without producing qualitative changes in membrane proteins, as determined by SDS gel electrophoresis. These results suggest that ethanol inhibits carrier-mediated transport by dissipation of the Na⁺ electrochemical gradient and alteration of membrane integrity rather than by direct interaction with membrane transporters.     

Neutral amino acid transport by marine fish intestine: role of the side chain

This work was devoted to the study of the structure-affinity relationships in neutral amino acid transport by intestinal brush border of marine fish (Dicentrarchus labrax). The effects of the length of the side chain on kinetics of glycine, alanine, methionine and amino isobutyric acid were investigated. In the presence of K⁺ two components were characterized: one is saturable by increased substrate concentrations, whereas the other can be described by simple diffusion mechanism. Simple diffusion, a passive, non-saturable, Na⁺-independent route, contributes largely to the transport of methionine and to a much lesser extend to alanine, glycine or alphaaminoisobutyric acid uptakes. If a branched chain is present, as in the case of amino isobutyric acid, diffusion is low. A Na⁺-independent, saturable system has been fully characterized for methionine, but not for branched amino acids such as amino isobutyric acid. In the presence of Na⁺ saturable components were shown. Two distinct Na⁺-dependent pathways have been characterized for glycine uptake, with low and high affinities. For alanine and methionine only one Na⁺-dependent high affinity system exists with the same half-saturation concentration and the same maximum uptake at saturable concentrations. Glycine high affinity system has the same half-saturation concentration as methionine or alanine uptake, whereas maximum uptake is lower. The substitution of the hydrogen by a methyl group results in a severe decrease of uptake (aminoisobutyric acid). Mutual inhibition experiments indicate that the same carriers could be responsible for methionine and alanine uptakes and probably glycine Na⁺-dependent uptake. The influence of Na⁺ concentrations (100^-1 mol·l^-1) on amino acid uptake was examined. Glycine, alanine, methionine and amino isobutyric acid transport can be described by a hyperbolic function, with a saturation uptake which is highly increased for methionine. However, the half-saturation concentration does not seem to be strongly affected by the amino acid structure. The effect of Na⁺ concentration (25 and 100 mmol·l^-1) on the kinetics of methionine uptake have been also examined. The maximum uptake of the saturable system clearly shows a typical relationship with concentration.Abbreviations [AA] amino acid concentration - AIB aminoisobutyric acid - [I] Inhibitor amino acid concentration - J _i uptake in the presence of inhibitor - J _o uptake without inhibitor - K _d passive diffusion constant - K _i inhibitor constant - K _t concentration of test amino acid for half-maximal flux - MES 2[N-morpholino]ethanesulphonic acid - V _max maximum uptake at saturable amino acid concentrations - V _tot total amino acid uptake     

Carrier-mediated transfer of d-glucose in brush border vesicles derived rom rabbit renal tubules. Na+-dependent versus Na+-independent transfer

A brush border preparation from rabbit renal tubules containing a high yield of vesicles has been used to study the transfer of d-glucose through the brush border membrane. In the presence of an Na⁺ gradient across the vesicular membrane, the vesicles could concentrate d-glucose to a factor of 1.5, whereas in the absence of an Na⁺ gradient, only equilibrium with the medium was achieved. Two types of transfer could be distinguished by their requirement of Na⁺, their sensitivity to phlorizin and their pH optimum. The Na⁺-independent transfer was about 100 times less sensitive to phlorizin than the Na⁺-dependent path and exhibited a pH optimum between 7 and 8, whereas the Na⁺-dependent transfer was highest at a pH between 8 and 9.The brush border preparation could be freed of most of the contaminating material derived from the basal and lateral tubular cell membrane by a discontinuous density gradient centrifugation. It still showed both forms of transfer to a similar extent, indicating that both are located in the brush border membrane.A study of the sensitivity of d-glucose transfer to phlorizin, in the presence and absence of Na⁺ at different temperature, suggests a single carrier species functioning in two interchangeable conformational states with different affinities for phlorizin rather than two transfer systems working independently.     

Stimulation of Na+-dependent amino acid uptake by activation of the Ca2+-dependent K+ channel in the Ehrlich ascites tumor cell

The activation of Ca²⁺-dependent K⁺ channel by propranolol or by ascorbate-phenazine methosulphate stimulates Na⁺-dependent transport of α-aminoisobutyric acid. This stimulation arises from a membrane hyperpolarization due to the specific increase of membrane K⁺ conductance. The same treatment does not modify the Na⁺-independent uptake of the norbornane amino acid.     

Phlorizin as a probe of the small-intestinal Na+,d-glucose cotransporter. A model

(1)‘Uptake’ of phlorizin by intestinal brush border membrane vesicles is stimulated, much as that of d-glucose, by the simultaneous presence of Na_out⁺ and $\text{Δψ?0}$. However, phlorizin contrary to d-glucose, fulfills all criteria of a non-translocated ligand (i.e., of a fully competitive inhibitor) of the Na⁺,d-glucose cotransporter. (2) The stoicheiometry of Na⁺/phlorizin binding is 1, as shown by a Hill coefficient of approx. 1 in the Na_out⁺-dependence of phlorizin binding. (3) The preferred order of binding at $\text{Δψ?0}$ is Na⁺ first, phlorizin second (4) The velocity of association of phlorizin to the cotransporter, but not the velocity of its dissociation therefrom, responds to Δψ. These observations while agreeing with the effect of $\text{Δψ?0}$ on the $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of phlorizin binding in the steady-state time range, also confirm that the mobile part of the cotransporter bears a negative charge of 1. (5) A model is proposed describing the Na⁺,Δψ-dependent interaction of phlorizin with the cotransporter and agreeing with a more general model of Na⁺,d-glucose cotransport. (6) The $\text{k}{}_{\mathrm{<mtext>on</mtext>}}$, $\text{k}{}_{\mathrm{<mtext>off</mtext>}}$ and $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ constants of phlorizin interaction with the Na⁺,d-glucose cotransporter are smaller in the kidney than in the small-intestinal brush border membrane, which results in a number of quantitative differences in the overall behaviour of the two systems.     

Studies of the kinetics of Na+ gradient-coupled glucose transport as found in brush-border membrane vesicles from rabbit jejunum

The Na⁺-dependent d-glucose transport reaction in rabbit jejunal brush-border vesicles was studied. Initial rate data were obtained by fitting a polynomial equation to progress curves at different d-glucose concentrations and extracting the slope of the tangent at zero-time. Kinetic replots of the initial rate values produced biphasic Hofstee patterns indicative of two pathways for transport distinguished by their $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ values for glucose. Neither was dependent on the presence of a membrane potential. Both were dependent on Na⁺ and both were inhibited by phlorizin. Increasing external sodium was found to elevate the apparent $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ for both pathways. Internal sodium was inhibitory. Pulsed progress curve analysis indicated that the effect of internal sodium was best characterized as carrier sequestration by a sodium-carrier binary complex. Inhibition by internal sodium was completely reversed by the presence, internally, of d-glucose. The presence of two pathways and the kinetic constants for these pathways do not agree with the conclusions of Hopfer and Groseclose (1980) J. Biol. Chem. 255, 4453–4462). Experiments are presented which bear on the reason for the disagreement.     

Biphasic action of growth hormone on intestinal amino acid absorption in striped bass hybrids

• 1.1. Weekly injections of bovine growth hormone (bGH) increased the maximal transport rate of both Na⁺-dependent and Na⁺ -independent l-leucine transport with little effect on the affinity constants in the intestine of striped bass hybrids.
• 2.2. The Na⁺-dependent and the Na⁺-independent transport of the non-metabolizable analog cycloleucine was also stimulated by bGH.
• 3.3. The Na⁺ -dependent active transport was stimulated 2 days after the hormone treatment, while the stimulation of the Na⁺-independent diffusional transport was not observed until after 2 weeks of treatment.
• 4.4. Studies of intestinal morphometry and l-leucine transport using brush border membrane vesicles suggested that bGH affects intestinal amino acid absorption initially by increasing the number of transporters per cell.
• 5.5. This phase is followed by a general increase of the intestinal mass after long-term treatment with the hormone.

     

Effect of H+ on the kinetics of Na+-dependent amino acid transport in ehrlich ascites tumor cells: Evidence for H+ as an alternative substrate

The effects of H⁺ on the kinetics of α-aminoisobutyric acid (AIB) influx in Ehrlich ascites tumor cells have been investigated at different external Na⁺ concentrations. Elevation of [H⁺] in the presence of both high (154 mEq/l) and low (10 mEq/l) external Na⁺ leads to decreases in the maximum influx (J) and increases in the apparent Michaleis-Menten constant (K) for influx of AIB. In the virtual absence of external Na⁺ (0.96 ± 0.04 mEq/l), alterations in [H⁺] are without measurable effect on AIB flux. Furthermore, addition of AIB (10 mM) to cell suspensions (pH 5.90) stimulates H⁺ uptake by the cells in either the presence or absence of Na⁺. The data are consistent with two kinetic models for Na⁺-dependent amino acid transport: an order bireactant (Na⁺-binding necessary before AIB binding) system or a random bireactant system. Both models require that H⁺ serve as an alternative substrate for Na⁺. The consistency of the models was tested by fit to data from the present study (not used to evaluate the kinetic parameters) and by prediction of the pH dependence of Na⁺-dependent amino acid transport compared to earlier studies.     

Isolation of the sodium-dependent d-glucose transport protein from brush-border membranes

Rabbit kidney brush-border membrane vesicles were exposed to bacterial protease which cleaves off a large number of externally oriented proteins. Na⁺-dependent d-glucose transport is left intact in the protease-treated vesicles. The protease-treated membrane was solubilized with deoxycholate and the deoxycholate-extracted proteins were further resolved by passage through Con A-Sepharose columns. Sodium-dependent d-glucose activity was found to reside in a fraction containing a single protein band of M_r ? 165000 which is apparently a dimer of M_r ? 85 000. When reconstituted and tested for transport, this protein showed Na⁺-dependent, stereo-specific and phlorizin-inhibitable glucose transport. Transport activity is completely recovered and is 20-fold increased in specific activity. A similar isolate was obtained from rabbit small intestinal brush-border membranes and kidneys from several other species of animals.     

Regulation of the Cardiac Na+-Ca2+ Exchanger by the Endogenous XIP Region

The cardiac sarcolemmal Na⁺-Ca²⁺ exchanger is modulated by intrinsic regulatory mechanisms. A large intracellular loop of the exchanger participates in the regulatory responses. We have proposed (Li, Z., D.A. Nicoll, A. Collins, D.W. Hilgemann, A.G. Filoteo, J.T. Penniston, J.N. Weiss, J.M. Tomich, and K.D. Philipson. 1991. J. Biol. Chem. 266:1014–1020) that a segment of the large intracellular loop, the endogenous XIP region, has an autoregulatory role in exchanger function. We now test this hypothesis by mutational analysis of the XIP region. Nine XIP-region mutants were expressed in Xenopus oocytes and all displayed altered regulatory properties. The major alteration was in a regulatory mechanism known as Na⁺-dependent inactivation. This inactivation is manifested as a partial decay in outward Na⁺-Ca²⁺ exchange current after application of Na⁺ to the intracellular surface of a giant excised patch. Two mutant phenotypes were observed. In group 1 mutants, inactivation was markedly accelerated; in group 2 mutants, inactivation was completely eliminated. All mutants had normal Na⁺ affinities. Regulation of the exchanger by nontransported, intracellular Ca²⁺ was also modified by the XIP-region mutations. Binding of Ca²⁺ to the intracellular loop activates exchange activity and also decreases Na⁺-dependent inactivation. XIP-region mutants were all still regulated by Ca²⁺. However, the apparent affinity of the group 1 mutants for regulatory Ca²⁺ was decreased. The responses of all mutant exchangers to Ca²⁺ application or removal were markedly accelerated. Na⁺-dependent inactivation and regulation by Ca²⁺ are interrelated and are not completely independent processes. We conclude that the endogenous XIP region is primarily involved in movement of the exchanger into and out of the Na⁺-induced inactivated state, but that the XIP region is also involved in regulation by Ca²⁺.     

A single mechanism for the stimulation of insulin release and 86Rb+ efflux from rat islets by cationic amino acids

The mechanisms by which cationic amino acids influence pancreatic B-cell function have been studied by monitoring simultaneously ⁸⁶Rb⁺ efflux and insulin release from perifused rat islets. The effects of two reference amino acids arginine and lysine were compared with those of closely related substances to define the structural requirements for recognition of these molecules as secretagogues. Arginine accelerated ⁸⁶Rb⁺ efflux and increased insulin release in the absence or in the presence of 7mm-glucose. Its effects on efflux did not require the presence of extracellular Ca²⁺ or Na⁺, but its insulinotropic effects were suppressed in a Ca²⁺-free medium and inhibited in an Na⁺-free medium. Among arginine derivatives, only 2-amino-3-guanidinopropionic acid mimicked its effects on ⁸⁶Rb⁺ efflux and insulin release; citrulline, guanidinoacetic acid, 3-guanidinopropionic acid and guanidine were inactive. Norvaline and valine also increased ⁸⁶Rb⁺ efflux, but their effect required the presence of extracellular Na⁺; they did not stimulate insulin release. Lysine as well as the shorter-chain cationic amino acids ornithine and 2,4-diaminobutyric acid accelerated ⁸⁶Rb⁺ efflux in a Ca²⁺- and Na⁺-independent manner. Their stimulation of insulin release was suppressed by Ca²⁺ omission, but only partially inhibited in an Na⁺-free medium. The uncharged glutamine and norleucine increased the rate of ⁸⁶Rb⁺ efflux in the presence of glucose, only if extracellular Na⁺ was present. Norleucine slightly increased release in a Ca²⁺- and Na⁺-dependent manner. The effects of lysine on efflux and release were not mimicked by other related substances such as 1,5-diaminopentane and 6-aminohexanoic acid. The results suggest that the depolarizing effect of cationic amino acids is due to accumulation of these positively charged molecules in B-cells. This causes acceleration of the efflux of K⁺ (⁸⁶Rb⁺) and activation of the influx of Ca²⁺ (which triggers insulin release). The prerequisite for the stimulation of B-cells by this mechanism appears to be the presence of a positive charge on the side chain of the amino acid, rather than a specific group.