Methylation increases the open probability of the epithelial sodium channel in A6 epithelia.

We used single channel methods on A6 renal cells to study the regulation by methylation reactions of epithelial sodium channels. 3-Deazaadenosine (3-DZA), a methyltransferase blocker, produced a 5-fold decrease in sodium transport and a 6-fold decrease in apical sodium channel activity by decreasing channel open probability (P(o)). 3-Deazaadenosine also blocked the increase in channel open probability associated with addition of aldosterone. Sodium channel activity in excised "inside-out" patches usually decreased within 1-2 min; in the presence of S-adenosyl-l-methionine (AdoMet), activity persisted for 5-8 min. Sodium channel mean time open (t(open)) before and after patch excision was higher in the presence of AdoMet than in untreated excised patches but less than t(open) in cell-attached patches. Sodium channel activity in excised patches exposed to both AdoMet and GTP usually remained stable for more than 10 min, and P(o) and the number of active channels per patch were close to values in cell-attached patches from untreated cells. These findings suggest that a methylation reaction contributes to the activity of epithelial sodium channels in A6 cells and is directed to some regulatory element closely connected with the channel, whose activity also depends on the presence of intracellular GTP.

Transfected connexin45 alters gap junction permeability in cells expressing endogenous connexin43.

Many cells express multiple connexins, the gap junction proteins that interconnect the cytosol of adjacent cells. Connexin43 (Cx43) channels allow intercellular transfer of Lucifer Yellow (LY, MW = 443 D), while connexin45 (Cx45) channels do not. We transfected full-length or truncated chicken Cx45 into a rat osteosarcoma cell line ROS-17/2.8, which expresses endogenous Cx43. Both forms of Cx45 were expressed at high levels and colocalized with Cx43 at plasma membrane junctions. Cells transfected with full-length Cx45 (ROS/Cx45) and cells transfected with Cx45 missing the 37 carboxyl-terminal amino acids (ROS/Cx45tr) showed 30-60% of the gap junctional conductance exhibited by ROS cells. Intercellular transfer of three negatively charged fluorescent reporter molecules was examined. In ROS cells, microinjected LY was transferred to an average of 11.2 cells/injected cell, while dye transfer between ROS/Cx45 cells was reduced to 3.9 transfer between ROS/Cx45 cells was reduced to 3.9 cells. In contrast, ROS/Cx45tr cells transferred LY to > 20 cells. Transfer of calcein (MW = 623 D) was also reduced by approximately 50% in ROS/Cx45 cells, but passage of hydroxycoumarin carboxylic acid (HCCA; MW = 206 D) was only reduced by 35% as compared to ROS cells. Thus, introduction of Cx45 altered intercellular coupling between cells expressing Cx43, most likely the result of direct interaction between Cx43 and Cx45. Transfection of Cx45tr and Cx45 had different effects in ROS cells, consistent with a role of the carboxyl-terminal domain of Cx45 in determining gap junction permeability or interactions between connexins. These data suggest that coexpression of multiple connexins may enable cells to achieve forms of intercellular communication that cannot be attained by expression of a single connexin.

Aldosterone alters the open probability of amiloride-blockable sodium channels in A6 epithelia.

We used patch-clamp methods to examine the effects of depletion and readdition of aldosterone on single, highly selective, amiloride-blockable sodium channels in the A6 cell line. Single-channel characteristics changed little before 24 h of continuous aldosterone depletion, although there was some reduction in short-circuit current. Thereafter, apical sodium permeability, measured as product of channel number per patch and individual channel open probability (NPo), was reduced between five- and sevenfold, primarily due to a large decrease in channel mean open time. With about the same time course, short-circuit current also decreased approximately fivefold. Readdition of aldosterone to depleted cells produced an increase in NPo within 2 h, primarily through an increase in mean open time. After readdition, channel number per patch increased twofold compared with cells not hormone deprived, with a return to control levels between 24 and 48 h after continuous exposure. The increase in short-circuit current followed a similar time course. The primary effect of aldosterone appears to be modulation of the open time of channels continuously present in the apical membrane, rather than promotion of the appearance or disappearance of channels from the membrane. In particular, it cannot be demonstrated statistically that aldosterone removal reduces the number of channels per patch, and there may actually be up to a twofold increase after a long period of aldosterone depletion.

Regulation of renal epithelial sodium channels.

The high selectivity, low conductance, amiloride-blockable, sodium channel of the mammalian distal nephron (i.e. cortical collecting tubule) is the site of discretionary regulation which allows maintainance of total body sodium balance. In order to understand the physiological events that participate in this regulation, we have used the patch-clamp technique which allows us to measure individual Na+ channel currents and permits access to the cytosolic side of the channel-protein as well as its associated regulatory components. Most of our experiments have utilized the A6 amphibian renal cell line, which when grown on permeable supports is an excellent model for the mammalian distal nephron. Different mechanisms have been examined: (1) regulation by hormonal factors such as Anti-Diuretic Hormone (ADH) and aldosterone, (2) regulation by G-proteins, (3) modulation by protein kinase C (PK-C), and (4) modulation by products of arachidonic acid metabolism. Consistent with noise analysis of tight epithelial tissues, ADH treatment increased the number of active channels in apical membrane patches of A6 cells, without any apparent change in the open probability (Po) of the individual channels. Agents that increased intracellular cAMP mimicked the effects of ADH. In contrast, aldosterone was found to act through a dramatic increase in Po rather than through changes in channel density. Inhibition of methylation by deazaadenosine antagonizes the stimulatory effect of aldosterone. In excised inside-out patches GTP gamma S inhibits channel activity, whereas GDP beta S or pertussis toxin stimulates activity suggesting regulatory control by G-proteins. PK-C has been shown to contribute to 'feed-back inhibition' of apical Na+ conductance in tight epithelia.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of the amiloride-blockable sodium channel from epithelial tissue.

The first step in net active transepithelial transport of sodium in tight epithelia is mediated by the amiloride-blockable sodium channel in the apical membrane. This sodium channel is the primary site for discretionary control of total body sodium and, therefore, investigating its regulatory mechanisms is important to our understanding of the physiology of fluid and electrolyte balance. Because essentially all of the regulatory sites on the channel are on the intracellular surface, patch clamp methods have proven extremely useful in the electrophysiological characterization of the sodium channel by isolating it from other channel proteins in the epithelial membrane and by allowing access to the intracellular surface of the protein. We have examined three different regulatory mechanisms. (1) Inhibition of channel activity by activation of protein kinase C; (2) activation of the channel by agents which activate G-proteins; and (3) modulation of channel kinetics and channel number by mineralocorticoids. Activation of protein kinase C by phorbol esters or synthetic diacylglycerols reduces the open probability of sodium channels. Protein kinase C can be activated in a physiological context by enhancing apical sodium entry. Actions which reduce sodium entry (low luminal sodium concentrations or the apical application of amiloride) increase channel open probability. The link between sodium entry and activation of protein kinase C appears to be mediated by intracellular calcium activity linked to sodium via a sodium/calcium exchange system. Thus, the intracellular sodium concentration is coupled to sodium entry in a negative feedback loop which promotes constant total entry of sodium. Activation of G-proteins by pertussis toxin greatly increases the open probability of sodium channels. Since channels can also be activated by pertussis toxin or GTP gamma S in excised patches, the G-protein appears to be closely linked in the apical membrane to the sodium channel protein itself. The mechanism for activation of this apical G-protein, when most hormonal and transmitter receptors are physically located on the basolateral membrane, is unclear. Mineralocorticoids such as aldosterone have at least two distinct effects. First, as expected, increasing levels of aldosterone increase the density of functional channels detectable in the apical membrane. Second, contrary to expectations, application of aldosterone increases the open probability of sodium channels. Thus aldosterone promotes the functional appearance of new sodium channels and promotes increased sodium entry through both new and pre-existant channels.