Synthesis and characterization of methylbromoamiloride, a potential biochemical probe of epithelial Na+ channels

Oxidative stress induced by L-buthionine-(S,R)-sulfoximine, a selective inhibitor of glutathione metabolism, abrogates mouse kidney mineralocorticoid receptor function

In vitro studies have demonstrated that cysteine groups present in most of the steroid receptors play an essential role in the steroid binding process as well as in the ability of this superfamily of signaling proteins to function as transcription factors. However, there is poor experimental evidence, if any, which demonstrates that under conditions of oxidative stress the steroid receptors in general, and the mineralocorticoid receptor in particular, are affected in vivo in a similar fashion as has been described for cell-free systems or cells in culture. In the present work we report that when mice are exposed to oxidative stress by treatment with L-buthionine-(S,R)-sulfoximine (L-(S,R)-BSO), a glutathione depleting agent, the aldosterone-dependent mineralocorticoid biological response (measured as sodium retention and potassium elimination) was diminished in a directly proportional manner with respect to the depletion of renal glutathione. Accordingly, the steroid binding capacity of the mineralocorticoid receptor was also abrogated, whereas the receptor protein level remained unchanged. The harmful effects observed in mice after glutathione depletion were efficiently prevented by co-treatment with glutathione monoethyl ester. Similar inhibition in the steroid binding capacity was also generated in vitro by receptor alkylation and receptor oxidation, an effect which was prevented in the presence of reducing agents. Since the glutathione deficit generated in vivo by treatment with L-(S,R)-BSO did not significantly affect other renal proteins which are known to be required for the mineralocorticoid mechanism of action, we suggest that in renal cells a low redox potential exerts drastic and uncompensated inhibition of the receptor-mediated mineralocorticoid biological response. This effect was ascribed to the loss of steroid binding capacity of oxidized receptor, most likely by modification of essential cysteines as supported by experiments where a decreased number of reactive thiols and reduced covalent binding of thiol-reactive ligand were evidenced on immunopurified receptor after in vivo treatment with L-(S,R)-BSO.

Structure and function of amiloride-sensitive Na+ channels

A new molecular biological epoch in amiloride-sensitive Na+ channel physiology has begun. With the application of these new techniques, undoubtedly a plethora of new information and new questions will be forthcoming. First and foremost, however, is the question of how many discrete amiloride-sensitive Na+ channels exist. This question is important not only for elucidating structure-function relationships, but also for developing strategies for pharmacological or, ultimately, genetic intervention in such diseases as obstructive nephropathy, Liddle's syndrome, or salt-sensitive hypertension where amiloride-sensitive Na+ channel dysfunction has been implicated [17, 62]. Epithelia Na+ channels purified from kidney are multimeric. However, it is not yet clear which subunits are regulatory and which participate directly as a part of the Na+ conducting core and what is the nature of the gate. The combination of electrophysiologic techniques such as patch clamp and the ability to study reconstituted channels in planar lipid bilayers along with molecular biology techniques to potentially manipulate the individual subunits should provide the answers to questions that have puzzled physiologists for decades. It seems clear that the robust versatility of the channel in responding to a wide range of differing and potentially synergistic regulatory inputs must be a function of its multimeric structure and relation to the cytoskeleton. Multiple mechanisms of regulation imply multiple regulatory sites. This hypothesis has been validated by the demonstration that enzymatic carboxyl methylation and phosphorylation have both individual and synergistic effects on the purified channel in planar lipid bilayers. Of the multiple mechanisms proposed for channel regulation, evidence is now available to support the ideas that channels may be activated (or inactivated) by direct modifications including phosphorylation and carboxyl methylation, by activation or association of regulatory proteins such as G proteins, and by recruitment from subapical membrane domains. The observation that channel gating is achieved primarily through regulation of open probability without alterations in conductance may simplify future understanding of the molecular events involved in gating once the regulatory sites have been identified. As more Na+ channels or Na+ channel subunits are cloned from different epithelia, it will become possible to piece together the puzzle of epithelial Na+ channels. It is interesting to observe that renal Na+ channel proteins contain a subunit which falls into the 70 kD range. This size protein is in the range reported for the aldosterone-induced proteins [12, 46, 153].(ABSTRACT TRUNCATED AT 400 WORDS)

Single-channel behavior of a purified epithelial Na+ channel subunit that binds amiloride

The apical membrane of high electrical resistance epithelia, which is selectively permeable to Na+, plays an essential role in the maintenance of salt balance. Na+ entry from the apical fluid into the cells is mediated by amiloride-blockable Na(+)-specific channels. The channel protein, purified from both amphibian and mammalian sources, is composed of several subunits, only one of which the 150-kDa polypeptide, specifically binds the Na+ transport inhibitor amiloride. The goal of the present study was to investigate whether the isolated amiloride-binding subunit of the channel could conduct Na+. The patch-clamp technique was used to study the 150-kDa polypeptide incorporated into a lipid bilayer formed on the tip of a glass pipette. Unitary conductance jumps averaged 4.8 pS at 100 mM Na2HPO4. Open times ranged from 24 ms to several seconds. The channel spent most of the time in the closed state. Channel conductance and gating were independent of voltage between -60 and +100 mV. Amiloride (0.1 microM) decreased the mean open time of the channel by 98%. We conclude that the 150-kDa subunit of the amiloride-blockable Na+ channel conducts current and may be sufficient for the Na+ transport function of the whole channel.

Cation transport probes: the amiloride series

The use of amiloride and its analogs in the study of ion transport requires a knowledge of the pharmacology of inhibition of transport proteins, and of effects on enzymes, receptors, and other cellular processes, such as DNA, RNA, and protein synthesis, and cellular metabolism. We have reviewed the pharmacology of inhibition of these processes by amiloride an its analogs, as well as the use of amiloride analogs as potential probes for the characterization of ion transport systems.

Amiloride and its analogs as tools in the study of ion transport

Amiloride inhibits most plasma membrane Na+ transport systems. We have reviewed the pharmacology of inhibition of these transporters by amiloride and its analogs. Thorough studies of the Na+ channel, the Na+/H+ exchanger, and the Na+/Ca2+ exchanger, clearly show that appropriate modification of the structure of amiloride will generate analogs with increased affinity and specificity for a particular transport system. Introduction of hydrophobic substituents on the terminal nitrogen of the guanidino moiety enhances activity against the Na+ channel; whereas addition of hydrophobic (or hydrophilic) groups on the 5-amino moiety enhances activity against the Na+/H+ exchanger. Activity against the Na+/Ca2+ exchanger and Ca2+ channel is increased with hydrophobic substituents at either of these sites. Appropriate modification of amiloride has produced analogs that are several hundred-fold more active than amiloride against specific transporters. The availability of radioactive and photoactive amiloride analogs, anti-amiloride antibodies, and analogs coupled to support matrices should prove useful in future studies of amiloride-sensitive transport systems. The use of amiloride and its analogs in the study of ion transport requires a knowledge of the pharmacology of inhibition of transport proteins, as well as effects on enzymes, receptors, and other cellular processes, such as DNA, RNA, and protein synthesis, and cellular metabolism. One must consider whether the effects seen on various cellular processes are direct or due to a cascade of events triggered by an effect on an ion transport system.

Preparation of 6-125I-labeled amiloride derivatives

Amiloride and certain of its derivatives are effective inhibitors of Na/H antiporters and of epithelial Na channels. We describe a simple method for the preparation of a variety of pharmacologically active 6-iodoamiloride derivatives that are labeled with 125I at high specific radioactivity. 6-Dechloroamiloride derivatives (bearing a hydrogen atom instead of the chlorine at the 6 position of the amiloride molecule) are reacted with 125ICl, prepared by the oxidation of the iodide in Na125I preparations. The 125I-labeled derivatives are separated from free 125I by anion exchange chromatography, or purified by thin layer chromatography. Both 6-dechloroamiloride and 5-(N-alkyl)-6-dechloroamiloride derivatives can be labeled by this method, with yields varying between 10 and 70%, depending on the ICl concentration and the structure of the 5-N-alkyl group. Efficient radiolabeling at high specific radioactivity also depends on the use of freshly prepared batches of 125I. Using carrier-free 125I, [125I]6-iodoamiloride and [125I]6-iodo-5-(N-tert-butyl)amiloride were prepared with yields of 27 and 22%, respectively. Potential applications of the 125I-labeled amiloride derivatives include ligand binding and affinity labeling experiments.

Purification and characterization of the amiloride-sensitive sodium channel from A6 cultured cells and bovine renal papilla

The amiloride-binding Na+ channel protein of high electrical resistance epithelia was solubilized and purified from cultured A6 toad kidney cells and bovine renal papilla. Purification was assessed by enrichment in [3H]methylbromoamiloride specific binding. Chromatography of 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS)-solubilized plasma membrane vesicles on agarose-immobilized wheat-germ agglutinin provided a 130-fold enrichment of the amiloride-binding component compared to the cell homogenate. Further purification was achieved by either amiloride-affinity chromatography or size-exclusion HPLC. When the HPLC and amiloride affinity-purified material was injected into a second higher molecular weight exclusion HPLC column, only a single peak with Mr 800,000 was found. Further HPLC separation of the Mr 800,000 material at low ionic strength resolved two peaks with apparent Mrs 800,000 and 700,000. Only the 700-kDa component displayed specific [3H]methylbromoamiloride binding activity. The final binding specific activity achieved was 1300 pmol/mg of protein, corresponding to 91% homogeneity of the protein.

Identification of the renal Na+/H+ exchanger with N,N'-dicyclohexylcarbodiimide (DCCD) and amiloride analogues

Dicyclohexylcarbodiimide (DCCD) and the 5-ethyl-isopropyl-6-bromo-derivative of amiloride (Br-EIPA) have been used as affinity and photoaffinity labels of the Na+/H+ exchanger in rat renal brush-border membranes. Intravesicular acidification by the Na+/H+ exchanger was irreversibly inhibited after incubation of vesicles for 30 min with DCCD. The substrate of the antiporter, Na+, and the competitive inhibitor, amiloride, protected from irreversible inhibition. The Na+-dependent transport systems for sulfate, dicarboxylates, and neutral, acidic, and basic amino acids were inhibited by DCCD, but not protected by amiloride. An irreversible inhibition of Na+/H+ exchange was also observed when brush-border membrane vesicles were irradiated in the presence of Br-EIPA. Na+ and Li+ protected. [14C]-DCCD was mostly incorporated into three brush-border membrane polypeptides with apparent molecular weights of 88,000, 65,000 and 51,000. Na+ did not protect but rather enhanced labeling. In contrast, amiloride effectively decreased the labeling of the 65,000 molecular weight polypeptide. In basolateral membrane vesicles one band was highly labeled by [14C]DCCD that was identified as the alpha-subunit of the Na+,K+-ATPase. [14C]-Br-EIPA was mainly incorporated into a brush-border membrane polypeptide with apparent molecular weight of 65,000. Na+ decreased the labeling of this protein. Similar to the Na+/H+ exchanger this Na+-protectable band was absent in basolateral membrane vesicles. We conclude that a membrane protein with an apparent molecular weight of 65,000 is involved in rat renal Na+/H+ exchange.

Detergent solubilization, functional reconstitution, and partial purification of epithelial amiloride-binding protein

The amiloride-binding protein from cultured toad kidney cells (A6) was solubilized in 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), functionally reconstituted into liposomes, and partially purified. The specific binding of [3H]methylbromoamiloride ([3H]CH3BrA) was measured in intact A6 epithelia, A6 cell homogenate (H), apical plasma membrane vesicle (V1), and CHAPS-solubilized V1 and on material obtained after affinity chromatography of CHAPS-solubilized plasma membrane vesicles on agarose-immobilized wheat germ agglutinin (WGA). Specific [3H]CH3BrA binding to H, V1, and WGA material reached equilibrium after 10 min. Scatchard analysis of [3H]CH3BrA binding to V1 and WGA material revealed a homogeneous class of binding sites with KD's of 130 and 128 nM, respectively. These KD values were similar to the apparent inhibitory dissociation constant determined from amiloride inhibition of 22Na+ influx in both intact A6 epithelia and V1. The total number of specific binding sites was 4 pmol/mg of V1 protein, which represented a 10-fold enrichment compared to H, and 66.6 pmol/mg of WGA material (a 148-fold enrichment). From association/displacement kinetic studies of specific [3H]CH3BrA binding to V1, the rate constants of association (ka) and dissociation (kd) were calculated to be 3.6 X 10(5) M-1 s-1 and 49.5 X 10(-3) s-1, respectively. These values yield an equilibrium dissociation constant of 138 nM. In solubilized V1 protein, binding activity was enriched approximately 20-fold over H and was markedly dependent upon the relative concentrations of detergent and phospholipid. CHAPS solubilization of V1 resulted in an average 44% recovery of protein with 90% retention of the total number of specific [3H]CH3BrA binding sites. After WGA chromatography 2.7% of the applied protein and 46% of the specific binding sites were recovered.(ABSTRACT TRUNCATED AT 250 WORDS)

Porous-bottom dishes for culture of polarized cells

Porous-bottom dishes offer several advantages for growing and studying epithelia in culture. Many epithelia differentiate more on porous surfaces than on plastic tissue culture dishes. In addition, separate solutions can be maintained on each side of the epithelium and can be sampled easily for studies of transport and other polarized functions. We describe the fabrication of dishes with a cellulose ester filter, a collagen-coated polycarbonate filter, or a collagen membrane forming the surface for cell attachment at the bottom of the dish.

The amiloride-sensitive sodium channel

Net Na+ movement across the apical membrane of high-electrical resistance epithelia is driven by the electrochemical potential energy gradient. This entry pathway is rate limiting for transepithelial transport, occurs via a channel-type mechanism, and is specifically inhibited by the diuretic drug amiloride. This channel is selective for Na+, Li+, and H+, saturates with increasing extracellular Na+ concentration, and is not affected, at least in frog skin epithelium, by changes in apical membrane surface potential. There also appears to be multiple inhibitory regions associated with each Na+ channel. We discuss the possible implications of a voltage-dependent block by amiloride in terms of macroscopic inhibitory phenomena. We describe the use of cultured epithelial systems, in particular, the toad kidney-derived A6 cell line, and the preparation of apical plasma membrane vesicles to study the Na+ entry process. We discuss experiments in which single, amiloride-sensitive channel activity has been detected and summarize current experimental approaches directed at the biochemical identification of this ubiquitous Na+ transport system.