Effect of ethylisopropyl amiloride,a Na+-H+ exchange inhibitor,on cardioprotective effect of ischaemic and angiotensin preconditioning

The present study is designed to investigate the role of Na⁺-H⁺ exchanger in the cardioprotective effect of ischaemic and angiotensin (Ang II) preconditioning. Isolated perfused rat heart was subjected to global ischaemia for 30 min followed by reperfusion for 120 min. Coronary effluent was analysed for LDH and CK release to assess the degree of cardiac injury. Myocardial infarct size was estimated macroscopically using TTC staining. Left ventricular developed pressure (LVDP) and dp/dt were recorded to evaluate myocardial contractility. Four episodes of ischaemic or Ang II preconditioning markedly reduced LDH and CK release in coronary effluent and decreased myocardial infarct size. 5-(N-ethyl-N-isopropyl)amiloride (EIPA), a Na⁺-H⁺ exchange inhibitor, produced no marked effect on ischaemic preconditioning and Ang II preconditioning induced cardioprotection. On the other hand, EIPA administration prior to global ischaemia produced a similar reduction in myocardial injury as was noted with ischaemic preconditioning or Ang II preconditioning. On the basis of these results, it may be concluded that inhibition of Na⁺-H⁺ exchanger protects against ischaemia-reperfusion induced myocardial injury whereas activation of Na⁺-H⁺ exchanger may not mediate the cardioprotective effect of ischaemic and Ang II preconditioning.     

Na+-H+ exchange in cardiac sarcolemmal vesicles

The transport of Na+ by a purified sarcolemmal vesicular preparation from canine ventricular tissue was studied as a function of both internal and external pH. The uptake of Na+ into sarcolemmal vesicles increased upon raising the extravesicular pH of the reaction medium. Half-maximal uptake of Na+ was observed at a pHo of about 8.1 and maximal uptake occurred at pH 8.6. The uptake of Na+ by sarcolemma was also dependent upon the intravesicular pH. Na+ uptake into sarcolemmal vesicles was greatly attenuated in the absence of a H+ gradient across the membrane. Transport of Na+ was potently inhibited by amiloride, a known blocker of Na+-H+ exchange. LiCl was also an effective inhibitor of Na+ transport. In the presence of optimal H+ gradients, Na+ uptake was linear for the first 5 seconds of the reaction and exhibited a Vmax of 290 nmol Na+/mg per min and a KNa of 3.5 mM. These experiments strongly indicate the presence of a Na+-H+ exchange system in cardiac sarcolemma. This activity appeared to be relatively specific for this membrane fraction. The identification of Na+-H+ exchange activity in a sarcolemmal vesicular fraction from the heart will permit extensive characterization of the regulation and kinetics of this antiporter in future investigations.     

Inhibition of Na+/Ca2+ exchange in pituitary plasma membrane vesicles by analogues of amiloride

Amiloride is a weak inhibitor of Na+/Ca2+ exchange in isolated plasma membrane vesicles prepared from GH3 rat anterior pituitary cells. However, substitution on either a terminal guanidino nitrogen atom or the 5-amino nitrogen atom can increase inhibitory potency ca. 100-fold (I50 approximately 10 microM). A structure-activity study indicates that defined structural modifications of guanidino substituents are associated with increases in inhibitory activity. In contrast, analogues bearing 5-amino substituents generally increase in potency with increasing hydrophobicity of the substitution. Specificity in action of either class is indicated by several criteria. These inhibitors do not disrupt the osmotic integrity of the membrane, nor do they significantly interfere with plasmalemmal Ca2+-ATPase-driven Ca2+ uptake, Na+,K+-ATPase enzymatic activity, or the function of Ca2+ or K+ channels. Inhibition is freely reversible, further indicating a lack of nonspecific membrane effects. The mechanism by which each inhibitor class blocks exchange was found to be identical. Protonation of the guanidino moiety (i.e., cationic charge) is essential for activity. Analysis of transport inhibition as a function of Ca2+ concentration indicates noncompetitive kinetics. However, inhibition was reversed by elevating intravesicular Na+, indicating a competitive interaction with this ion. These results suggest that the inhibitors function as Na+ analogues, interact at a Na+ binding site on the carrier (presumably the site at which the third Na+ binds), and reversibly tie up the transporter in an inactive complex. In addition to blocking pituitary exchange, these analogues are effective inhibitors of the bovine brain and porcine cardiac transport systems.     

Lysophospholipids do not directly modulate Na+-H+ exchange

Lysophosphatidylcholine (LPC) has been reported to stimulate Na⁺-H⁺ exchange in rat cardiomyocytes. This action may be important in pathological conditions like ischemic injury where LPC is generated and Na⁺-H⁺ exchange activation is an important determinant of cardiac damage and dysfunction. It is unclear, however, if this stimulation of Na⁺-H⁺ exchange by LPC occurs through a direct action on the exchanger or through stimulation of a second messenger pathway. The purpose of the present investigation was to determine if lysolipids could directly affect Na⁺-H⁺ exchange. Purified cardiac sarcolemmal membranes were isolated and Na⁺-H⁺ exchange was measured by radioisotopic methods following addition of LPC. There were no effects of LPC on Na⁺-H⁺ exchange at LPC concentrations of 100 M at all reaction times examined. Lysophosphatidylethanolamine (LPE), lysophosphatidylserine (LPS), lysophosphatidylinositol (LPI) and lysoplasmenylcholine (LP_EC) also did not alter Na⁺-H⁺ exchange at all concentrations and reaction times examined. We conclude that any stimulatory effects of lysolipids on Na⁺-H⁺ exchange do not occur through a direct action on the exchanger or its membrane lipid environment and must occur through a second messenger pathway.     

Na+-H+ exchange and Na+ entry across the apical membrane of Necturus gallbladder

The role of Na+-H+ exchange in Na+ transport across the apical membrane was evaluated in Necturus gallbladder epithelium by means of intracellular Na+ activity (aNai) and 22Na+ uptake measurements. Under control conditions, complete replacement of Na+ in the mucosal solution with tetramethylammonium reduced aNai from 14.0 to 6.9 mM in 2 min (P less than 0.001). Mucosal addition of the Na+-H+ exchange inhibitor amiloride (10(-3) M) reduced aNai from 15.0 to 13.3 mM (P less than 0.001), whereas bumetanide (10(-5) and 10(-4) M) had no effect. Na+ influx across the apical membrane was studied by treating the tissues with ouabain, bathing them in Na-free solutions, and suddenly replacing the mucosal solution with an Na-containing solution. When the mucosal solution was replaced with Na-Ringer's, aNai increased at approximately 11 mM/min. This increase was inhibited by 54% by amiloride (10(-3) M, P less than 0.001) and was unaffected by bumetanide (10(-5) M). Amiloride-inhibitable Na+ fluxes across the apical membrane were also induced by the imposition of pH gradients. Na+ influx was also examined in tissues that had not been treated with ouabain. Under control conditions, 22Na+ influx from the mucosal solution into the epithelium was linear over the first 60 s and was inhibited by 40% by amiloride (10(-3) M, P less than 0.001) and by 19% by bumetanide (10(-5) M, P less than 0.025). We conclude that Na+-H+ exchange is a major pathway for Na+ entry in Necturus gallbladder, which accounts for at least half of apical Na+ influx both under transporting conditions and during exposure to ouabain. Bumetanide-inhibitable Na+ entry mechanisms may account for only a smaller fraction of Na+ influx under transporting conditions, and cannot explain influx in ouabain-treated tissues. These results support the hypothesis that NaCl entry results primarily from the operation of parallel Na+-H+ and Cl--HCO-3 exchangers, and not from a bumetanide-inhibitable NaCl cotransporter.     

Amiloride-inhibited Na+ uptake into toad bladder microsomes is Na+-H+ exchange

Amiloride-inhibited Na+ transport into toad urinary bladder microsomes is sensitive to a pH gradient across the vesicular membrane. The magnitude of the gradient was measured directly with acridine orange. Also Na+ could stimulate amiloride-sensitive proton efflux from the microsomes. These results indicated that the transport process was Na+-H+ exchange.     

Characterization of potent Na+/H+ exchange inhibitors from the amiloride series in A431 cells

Na+/H+ exchange is stimulated in a variety of cell types by addition of mitogenic polypeptides such as epidermal growth factor or platelet-derived growth factor. In order to assess the importance of Na+/H+ exchange in the mitogenic response, it is desirable to have available inhibitors of this process which exhibit high affinity and good specificity. We characterize in this report a number of 5-alkylamino-substituted derivatives of amiloride [3,5-diamino-6-chloro-N-(diaminomethylene)pyrazinecarboxamide++ +] which show much higher affinity than the parent compound for the Na+/H+ antiporter in A431 cells. High affinity is conferred by substitution with two alkyl groups and is increased by introducing a branched alkyl chain. An analogue bearing a 5-anilino group is also very potent. These analogues effectively inhibit the elevation of intracellular pH upon stimulation of Na+/H+ exchange by growth factors. We have assessed other potential inhibitory effects of these compounds on cellular metabolism. In agreement with previous reports, we find that amiloride inhibits protein synthesis both in cells and in cell-free translation systems. While amiloride and its analogues show similar inhibition of protein synthesis in a cell-free system, most analogues inhibit cellular protein synthesis at much lower concentrations than does amiloride. These analogues are also potent inhibitors of purified Na,K-ATPase and cause a profound decrease in intracellular K+ as well as ATP content. These latter effects, however, require analogue concentrations which are 5-7 times higher than those inhibiting cellular protein synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of alteration of extracellular Na+ or Ca2+ and inhibition of Ca2+ entry, Na(+)-H+ exchange, and Na(+)-Ca2+ exchange by diltiazem, amiloride, and dichlorobenzamil on the response of cardiac cell aggregates to epidermal growth factor

The purpose of this study was to examine the effect of epidermal growth factor (EGF) on cardiac function and to explore ionic mechanisms as potential explanations for EGF-induced changes in cardiac contractile frequency. Cardiac cell aggregates were prepared from 7-day-old chick embryo hearts and were maintained in culture. EGF over a concentration range of 5 to 20 ng/ml produced a dose-dependent increase in cardiac contractile frequency. Inhibition of Na(+)-H+ exchange by amiloride antagonized the action of EGF. Inhibition of Na(+)-Ca2+ exchange by dichlorobenzamil prevented the effects of EGF. Inhibition of voltage-dependent calcium influx by diltiazem also antagonized the effect of EGF. The positive chronotropic action of EGF was significantly enhanced when the concentration of Na+ or Ca2+ was increased in the medium. These data indicate that EGF has a definite dose-dependent effect on the cardiac contractile frequency that is operative through ionic transport mechanisms that include increased calcium entry through voltage-dependent calcium channels and stimulation of Na(+)-H+ and Na(+)-Ca2+ exchange. The similarity in the effects of inhibition of these three ionic mechanisms suggests they are interrelated so that interference at any step in the process inhibits the action of EGF on cardiac myocytes.     

The interaction of amiloride analogues with the Na+/H+ exchanger in kidney medulla microsomes

The effects of ten amiloride analogues on Na+-H+ exchange in rabbit kidney medulla microsomes have been examined. Most of the analogues appeared to inhibit Na+ uptake into the microsomes more effectively than did amiloride either in the presence or absence of a pH gradient. However, the analogues were also capable of stimulating Na+ efflux from the microsomes at concentrations somewhat higher than the concentrations at which they inhibited Na+ influx. The concentrations at which the analogues stimulated Na+ efflux were about 2-4-times higher than the concentrations at which they blocked influx. This suggested that the two processes were related. The analogues that stimulated efflux most effectively (the 5-N-benzyl-amino analogue of amiloride and the 5-N-butyl-N-methylamino analogue) were shown to induce completely reversible effects. These analogues did not stimulate L-[3H]glucose efflux from medulla microsomes which ruled out nonspecific vesicle destruction or reversible detergent effects. These analogues also induced Na+ efflux from microsomes in the presence of high concentrations of added buffer, which ruled out weak-base uncoupling effects. The possibility exists that these analogues are carried into the microsomes via the Na+-H+ exchange protein and that this permits them to both block Na+ influx into the microsomes and stimulate Na+ efflux as well.     

Thrombin stimulates Na+-H+ exchange across the human platelet plasma membrane

We have investigated the release of protons from thrombin-stimulated platelets. Addition of thrombin to suspensions of washed platelets resulted in fast liberation of H+. In the presence of 0.1 mM amiloride, a potent inhibitor of the Na+/H+ transport system, the amount of protons liberated was decreased by about 50%, and was further reduced to about 15% by 1 mM amiloride. Similar inhibition of H+ release was observed after Na+ in the incubating medium had been replaced by choline. We conclude that one of the earliest events in thrombin-stimulated platelets consists of the activation of an Na+/H+ countertransport, which leads to an increase in intracellular pH.     

Inhibition of Na+-dependent Ca2+ efflux from heart mitochondria by amiloride analogues

The Na+-induced release of accumulated Ca2+ from heart mitochondria is inhibited by amiloride, benzamil and several other amiloride analogues. These drugs do not affect uptake or release of Ca2+ mediated by the ruthenium red-sensitive uniporter and their effects, like those of diltiazem and other Ca2+-antagonists, appear to be localized principally at the Na+/Ca2+ antiporter of the mitochondrion. Benzamil inhibits Na+/Ca2+ antiport non-competitively with respect to [Na+] with a Ki of 167 microM. In the presence of 1.5 mM Pi the Ki for benzamil inhibition of this reaction is decreased to 87 microM.     

Interrelationships among quinidine, amiloride, and lithium as inhibitors of the renal Na+-H+ exchanger

We examined the effects of quinidine, amiloride and Li+ on the kinetics of Na+-H+ exchange in microvillus membrane vesicles isolated from the rabbit renal cortex. Quinidine reversibly inhibited the initial rate of Na+-H+ exchange (I50 200 microM). The plot of 1/V versus [quinidine] was curvilinear, with Hill coefficient greater than 1.0, indicating that the drug interacts at two or more inhibitory sites or at a single site on at least two different conformations of the transporter. Quinidine decreased the Vmax for Na+-H+ exchange and increased the Km for Na+, indicating a mixed-type mechanism of inhibition. In contrast, plots of 1/V versus [amiloride] and 1/V versus [Li+] were linear, indicating single inhibitory sites; amiloride and Li+ each increased the Km for Na+ with no effect on Vmax, indicating a competitive mechanism of inhibition. Addition of Li+ increased the intercept with no change in slope of the 1/V versus [amiloride] plot, indicating that Li+ and amiloride are mutually exclusive inhibitors of Na+-H+ exchange. Addition of quinidine increased the slopes of the plots of 1/V versus [amiloride] and 1/V versus [Li+], indicating that the binding of quinidine is not mutually exclusive with the binding of amiloride and Li+. Results from this and previous studies are consistent with the concept that the inhibitor amiloride and the transportable substrates Na+, H+, Li+, and NH+4 all mutually compete for binding to a single site, the external transport site of the renal Na+-H+ exchanger. However, our findings indicate that quinidine interacts with the Na+-H+ exchanger on at least one additional site that is not shared by Na+, Li+, or amiloride.     

Amiloride inhibits phorbol ester-stimulated Na+/H+ exchange and protein kinase C. An amiloride analog selectively inhibits Na+/H+ exchange

The human leukemic cell line, HL-60, differentiates in response to tumor-promoting phorbol esters. Recently, we have reported that one of the first events evoked by phorbol esters in HL-60 cells is the stimulation of Na+-dependent H+ efflux. In efforts to determine whether stimulation of Na+/H+ exchange by phorbol esters is coupled to induction of cellular differentiation, we found that 1) amiloride, a frequently used inhibitor of Na+/H+ exchange, rapidly inhibits phorbol ester-stimulated protein phosphorylation in vivo and protein kinase C-mediated phosphorylation in vitro, both with potency similar to that with which amiloride inhibits Na+/H+ exchange; 2) an amiloride analog, dimethylamiloride, is a far more potent inhibitor of Na+/H+ exchange than is amiloride, while being no more potent than amiloride in inhibiting phorbol ester/protein kinase C-mediated phosphorylation; and 3) at concentrations sufficient to completely inhibit Na+/H+ exchange, amiloride blocked phorbol ester-induced adhesion of HL-60 cells (adhesion being a property indicative of the differentiated state), but dimethylamiloride (as well as ethylisopropylamiloride, another very potent amiloride analog) did not. Thus, dimethylamiloride represents a potential tool for distinguishing protein kinase C-coupled from Na+/H+ exchange-coupled events in phorbol ester-stimulated cells.     

Cationic interactions with Na+-H+ exchange and passive Na+ flux in cardiac sarcolemmal vesicles

Na⁺-H⁺ exchange and passive Na⁺ flux were investigated in cardiac sarcolemmal vesicles as a function of changing the ionic composition of the reaction media. The inclusion of EGTA in the reaction medium resulted in a potent stumulation of Na⁺ uptake by Na⁺-H⁺ exchange. It was found that millimolar concentrations of Mg²⁺ and Li⁺ were capable of inhibiting Na⁺-H⁺ exchange by 80%. One mechanism by which these ions may inhibit intravesicular Na⁺ accumulation by Na⁺-H⁺ exchange is via an increase in Na⁺ efflux. An examination of Na⁺ efflux kinetics from vesicles pre-loaded with Na⁺ revealed that Na⁺, Ca²⁺, Mg²⁺ and Li⁺ could stimulate Na⁺ efflux. Na⁺-H⁺ exchange was potently inhibited by an organic divalent cation, dimenthonium, which screens membrane surface charge. This would suggest that Na⁺-H⁺ exchange occurs in the diffuse double layer region of cardiac sarcolemma and this phenomenon is distinctly different from other Na⁺ transport processes. The results in this study indicate that in addition to a stimulation of Na⁺ efflux, the inhibitory effects of Mg²⁺, Ca²⁺ and Li⁺ on Na⁺-H⁺ exchange may also involve a charge dependent screening of Na⁺ interactions with the membrane.     

Mechanisms of cardiodepression by an Na+-H+ exchange inhibitor methyl-N-isobutyl amiloride (MIA) on the heart: lack of beneficial effects in ischemia-reperfusion injury

Although Na+-H+ exchange (NHE) inhibitors such as methyl-N-isobutyl amiloride (MIA) are known to depress the cardiac function, the mechanisms of their negative inotropic effect are not completely understood. In this study, isolated rat hearts were perfused with MIA to study its action on cardiac performance, whereas isolated subcellular organelles such as sarcolemma, myofibrils, sarcoplasmic reticulum, and mitochondria were treated with MIA to determine its effect on their function. The effect of MIA on intracellular Ca2+ mobilization was examined in fura-2-AM-loaded cardiomyocytes. MIA was observed to depress cardiac function in a concentration-dependent manner in HCO3- -free buffer. On the other hand, MIA had an initial positive inotropic effect followed by a negative inotropic effect in HCO3-containing buffer. MIA increased the basal concentration of intracellular Ca2+ ([Ca2+]i) and augmented the KCl-mediated increase in [Ca2+]i. MIA did not show any direct effect on myofibrils, sarcolemma, and sarcoplasmic reticulum ATPase activities; however, this agent was found to decrease the intracellular pH, which reduced the myofibrils Ca2+-stimulated ATPase activity. MIA also increased Ca2+ uptake by mitochondria without having any direct effect on sarcoplasmic reticulum Ca2+ uptake. In addition, MIA did not protect the hearts subjected to mild Ca2+ paradox as well as ischemia-reperfusion-mediated injury. These results suggest that the increase in [Ca2+]i in cardiomyocytes may be responsible for the initial positive inotropic effect of MIA, but its negative inotropic action may be due to mitochondrial Ca2+ overloading as well as indirect depression of myofibrillar Ca2+ ATPase activity. Thus the accumulation of [H+]i as well as occurrence of intracellular and mitochondrial Ca2+ overload may explain the lack of beneficial effects of MIA in preventing the ischemia-reperfusion-induced myocardial injury.     

Na+-H+ exchange at the apical membrane of Necturus gallbladder. Extracellular and intracellular pH studies

The mechanism of luminal solution acidification was studied in Necturus gallbladder by measurement of mucosal solution and intracellular pH with glass electrodes. When the gallbladder was bathed by a Na-Ringer's solution it acidified the luminal side by a Na+-dependent, amiloride- inhibitable process. In the presence of ouabain, acidification was reduced but could be stimulated to a rate greater than that under control conditions by the imposition of an inwardly directed Na+ gradient. These results suggest that luminal acidification results from Na+-H+ exchange at the apical membrane and not by diffusion of metabolic CO2. Li+ can substitute for Na+ but K+, Rb+, Cs+, and tetramethylammonium (TMA+) cannot. The maximal rate of exchange was about five times greater for Na+ than for Li+. Intracellular pH (pHi) was measured with recessed-tip glass microelectrodes; with the tissue bathed in Na-Ringer's solution (pH 7.75), pHi was 7.51 +/- 0.04. After inhibition of Na+-H+ exchange by mucosal perfusion with amiloride (1 mM) or by complete Na+ replacement with TMA+, phi fell reversibly by 0.15 and 0.22 pH units, respectively. These results support the conclusion that Na+-H+ exchange at the apical membrane is the mechanism of luminal acidification and is involved in the maintenance of steady state pHi.     

Kappa-opioid receptor stimulation increases the expression of Na+-H+ exchange gene in the heart

Kappa-opioid receptor (OR) stimulation increases intracellular pH (pHi) via activating the Na+-H+ exchange (NHE). In the present study, we determined the expression of the gene of NHE1, the predominant NHE isoform in the heart, and intracellular pH (pHi) upon kappa-OR stimulation in the rat heart. We found that 1 microM U50,488H (trans-3,4-dichloro-N-methyl-N-(2-(1 pyrrolidinyl)cyclohexyl)benzeneacetamide), a selective kappa-OR agonist, increased the expression of the NHE1 gene. We also found that U50,488H dose-dependently increased pHi in the heart. The effects were abolished by 1 microM nor-binaltorphimine (nor-BNI), a selective kappa-OR antagonist, indicating that the events were kappa-OR mediated. The effects on both NHE1 gene expression and pHi were also abolished by 5 microM chelerythrine and 5 microM BSM (bisyndolylmaleimide), protein kinase C (PKC) inhibitors, indicating that PKC mediated the actions. In addition, the effect of U50,488H on pHi was blocked by 10 microM EIPA (ethylisopropyl amiloride), a NHE1 inhibitor, indicating that NHE1 also mediated the action of U50,488H. The present study provides evidence for the first time that kappa-OR stimulation increased the NHE1 gene expression in the heart via a PKC dependent pathway. Kappa-OR stimulation also increases pHi via PKC and NHE in the heart.     

Glutamate 346 of human Na+-H+ exchanger NHE1 is crucial for modulating both the affinity for Na+ and the interaction with amiloride derivatives

A NHE1 variant that exhibits very high resistance to (3-methyl sulfonyl-4-piperidinobenzoyl) guanidine methane sulfonate (HOE694), a potent inhibitor of Na(+)-H(+) exchangers, was selected and characterized. Sequencing of the coding region corresponding to the N-terminal domain of this variant revealed the presence of only one mutation located within membrane-spanning segment 9 (M9). This base pair change replaces a glutamate (Glu) with an aspartate (Asp). We reproduced this amino acid change in wild-type NHE1 and found that this mutation alone is responsible for the huge decrease in sensitivity to the HOE694 compound and to ethylisopropylamiloride (EIPA). We found that the NHE1-Glu(346)Asp mutant was more than 2000-fold more resistant to HOE694 and up to 300-fold more resistant to EIPA than wild-type NHE1, with the size, rather than the charge, of the amino acid in position 346 having the greatest effect. Interestingly, its affinity for Na(+) was at least 4-fold lower than that of wild-type NHE1. Mutation of amino acids in the vicinity of Glu(346) did not change the sensitivity of mutated NHE1 proteins to inhibitors. We suggest there is a direct interaction of Glu(346) or involvement of Glu(346) in a coordination site with NHE inhibitors and with Na(+).     

Determination of the coupling ratio for Na+-H+ exchange in renal microvillus membrane vesicles

We evaluated the H⁺:Na⁺ coupling ratio of the Na⁺-H⁺ exchanger present in microvillus membrane vesicles isolated from the rabbit renal cortex. Our approach was to impose transmembrane Na⁺ and H⁺ gradients of varying magnitude and then to measure the net flux of Na⁺ over the subsequent 5-s period. The Na⁺-H⁺ exchanger was observed to be at equilibrium (i.e. no significant net Na⁺ flux) whenever [Na⁺]_i/[Na⁺]_o was equal to [H⁺]_i/[H⁺]_o. Moreover, under all conditions the magnitude and direction of net Na⁺ flux was independent of changes in the transmembrane electrical potential difference. These results are consistent with a value of 1.0 for the coupling ratio of Na⁺-H⁺ exchange in renal microvillus membrane vesicles.     

Regulation of Na+-H+ exchange by transmethylation reactions in rat colonic brush-border membranes

Incubation of rat colonic brush-border membrane vesicles with 200 microM S-adenosyl-L-[Me-3H]methionine resulted in the labeling of both membrane phospholipids and proteins. This labeling was decreased approximately 50% by the methylation inhibitor S-adenosyl-L-homocysteine (2 mM). Utilizing the pH-sensitive fluorescent dye, acridine orange, as a means of determining Na+-H+ exchange, S-adenosyl-L-methionine (200 microM) significantly increased sodium-stimulated proton efflux in these vesicles at all concentrations of sodium (2.5-50 mM) tested. Examination of the kinetic parameters for sodium-stimulated proton efflux in the presence and absence of 200 microM S-adenosyl-L-methionine revealed that the methyl donor increased the Vmax for this exchange mechanism (expressed in arbitrary fluorescence units) by approx. 36% but did not influence its Km for sodium. S-Adenosyl-L-homocysteine (2 mM) inhibited S-adenosyl-L-methionine-mediated stimulation of this exchange process. The results demonstrate that methylation of membrane phospholipids and/or proteins can modulate Na+-H+ exchange in rat colonic brush-border membrane vesicles.