Characterization of the Fourth α Isoform of the Na,K-ATPase

The Na,K-ATPase is a major ion transport protein found in higher eukaryotic cells. The enzyme is composed of two subunits, α and β, and tissue-specific isoforms exist for each of these, α1, α2 and α3 and β1, β2 and β3. We have proposed that an additional α isoform, α4, exists based on genomic and cDNA cloning. The mRNA for this gene is expressed in rats and humans, exclusively in the testis, however the expression of a corresponding protein has not been demonstrated. In the current study, the putative α4 isoform has been functionally characterized as a novel isoform of the Na,K-ATPase in both rat testis and in α4 isoform cDNA transfected 3T3 cells. Using an α4 isoform-specific polyclonal antibody, the protein for this novel isoform is detected for the first time in both rat testis and in transfected cell lines. Ouabain binding competition assays reveal the presence of high affinity ouabain receptors in both rat testis and in transfected cell lines that have identical K _D values. Further studies of this high affinity ouabain receptor show that it also has high affinities for both Na⁺ and K⁺. The results from these experiments definitively demonstrate the presence of a novel isoform of the Na,K-ATPase in testis. Received: 4 December 1998/Revised: 1 February 1999     

Do H+ ions obscure electrogenic Na+ and K+ binding in the E1 state of the Na,K-ATPase?

In contrast to other P-type ATPases, the Na,K-ATPase binding and release of ions on the cytoplasmic side, to the state called E1, is not electrogenic with the exception of the third Na+. Since the high-resolution structure of the closely related SR Ca-ATPase in state E1 revealed the ion-binding sites deep inside the transmembrane part of the protein, the missing electrogenicity in state E1 can be explained by an obscuring counter-movement of H+ ions. Evidence for such a mechanism is presented by analysis of pH effects on Na+ and K+ binding and by electrogenic H+ movements in the E1 conformation of the Na,K-ATPase.     

Significance of the β-Subunit in the Biogenesis of Na+/K+-ATPase

This review summarizes our experiments on the significance of the -subunit in the functional expression of Na⁺/K⁺-ATPase. The -subunit acts like a receptor for the -subunit in the biogenesis of Na⁺/K⁺-ATPase and facilitates the correct folding of the -subunit in the membrane. The -subunit synthesized in the absence of the -subunit is subjected to rapid degradation in the endoplasmic reticulum. Several assembly sites are assigned in the sequence of the -subunit from the cytoplasmic NH₂-terminal domain to the extracellular COOH-terminus: the NH₂-terminal region of the extracellular domain, the conservative proline in the third disulfide loop, the hydrophobic amino acid residues near the COOH-terminus and the cysteine residues forming the second and the third disulfide bridges. Upon assembly, the -subunit confers a resistance to trypsin on the -subunit. The conformations induced in the -subunit of Na⁺/K⁺-ATPase by Na⁺/K⁺- and H⁺/K⁺-ATPase -subunits are somehow different from each other and are named the NK-type and KH-type, respectively. The extracellular domain of the -subunit is involved in the folding of the -subunit leading to trypsin-resistant conformations. The sequences from Cys150 to the COOH-terminus of the Na⁺/K⁺-ATPase -subunit and from Ile89 to the COOH–terminus of the H⁺/K⁺-ATPase -subunit are necessary to form trypsin-resistant conformations of the NK- and HK-type. respectively. The first disulfide loop of the extracellular domain of the -subunits is critical in the expression of functional Na⁺/K⁺-ATPase.     

Voltage dependence of the effects of (±)-kavain on the rate of inactivation of Na+ channels

The dependence of the efficacy of the influence of a kava-pyrone (±)-kavain (330 µM) on the frequency of activation of Na⁺ channels and voltage dependence of the effects of (±)-kavain on the rate of inactivation of these channels were studied in experiments on isolated neurons from the rat hippocampus. In all series of experiments, the holding potential equalled –100 mV. The efficacy of (±)-kavain-induced blockade of Na⁺ channels was independent of the frequency of stimulation within the range up to 10/sec. In the control experiments, the rate of inactivation increased with the rise of depolarization from –40 mV to +30 mV, and then the saturation effect was observed. At the membrane potential of –40 mV, the rate of (±)-kavain-evoked inactivation increased approximately by a factor of 2.5. At the more positive shifts of the membrane potential, the efficacy of the effects of (±)-kavain on the rate of inactivation became noticeably reduced, and at +30 mV (±)-kavain exerted no distinct influence on this parameter.Neirofiziologiya/Neurophysiology, Vol. 28, No. 6, pp. 312–315, November–December, 1996.     

Export of Na+ from cells of the halotolerant microalga Dunaliella maritima: Na+/H+ antiporter or primary Na+-pump?

Transport of Na+ and K+ ions through the plasma membrane of intact cells of the halotolerant microalga Dunaliella maritima Massjuk was studied. Ion fluxes through the plasma membrane were induced by hyperosmotic shock (uptake of Na+ by the cells is transformed into extrusion of Na+) or by addition of K+ to a suspension of K+-deficient cells (uptake of K+ by the cells is associated with extrusion of Na+). The pathway of Na+ extrusion from the D. maritima cells does not depend on the direction or value of the proton gradient on the plasma membrane. In particular, the efficiency of Na+ extrusion was not changed at extracellular pH values varying from 6.0 to 8.0. The protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) (20 microM) and the H+-ATPase inhibitor N,N-dicyclohexyl carbodiimide (DCCD) (25 and 100 microM) inhibited accumulation of K+ by the cells but did not influence Na+ extrusion. Significant acidification of the medium did not induce a net current of Na+ from the cells through a Na+/H+ antiporter. The data indicate that the Na+/H+ antiporter of the plasma membrane of D. maritima is not responsible for Na+ extrusion from the cells. These results can be explained by the involvement of a primary electrogenic Na+ pump (a Na+-transporting ATPase) in Na+ transfer through the plasma membrane of this alga.     

Enhancement of Na,K-ATPase Activity as a Result of Removal of Redox Modifications from Cysteine Residues of the α1 Subunit: the Effect of Reducing Agents

Na,K-ATPase is a transmembrane enzyme that creates a gradient of sodium and potassium, which is necessary for the viability of animal cells. The activity of Na,K-ATPase depends on the redox status of the cell, decreasing with oxidative stress and hypoxia. Previously, we have shown that the key role in the redox sensitivity of Na,K-ATPase is played by the regulatory glutathionylation of cysteine residues of the catalytic alpha subunit, which leads to the inhibition of the enzyme. In this study, the effect of reducing agents (DTT, ME, TCEP) on the level of glutathionylation of the alpha subunit of Na,K-ATPase from rabbit kidneys and the enzyme activity has been evaluated. We have found that the reducing agents partially deglutathionylate the protein, which leads to its activation. It was impossible to completely remove glutathionylation from the native rabbit kidney protein. The treatment of a partially denatured protein on the PVDF membrane with reducing agents (TCEP, NaBH₄) also does not lead to the complete deglutathionylation of the protein. The obtained data indicate that Na,K-ATPase isolated from rabbit kidneys has both regulatory and basal glutathionylation, which appears to play an important role in the redox regulation of the function of Na, K-ATPase in mammalian tissues.     

Variability of the K+−Na+ discrimination of beauvericin in mitochondrial membranes

In intact mitochondria supplemented with succinate or -hydroxybutyrate, the rates of oxygen consumption induced by beauvericin followed the ionic selectivity pattern: Na⁺>Rb⁺, Cs⁺, K⁺, Li⁺.When the respiratory substrate is glutamate plus malate in the absence of phosphate, the selectivity pattern is: K⁺>Rb⁺>Cs⁺>Li⁺>Na⁺.When the media are supplemented with phosphate, the Na⁺/K⁺ discrimination of beauvericin is considerably modified with all the respiratory substrates, being K⁺>Na⁺ with succinate and Na⁺>K⁺ with glutamate plus malate, whereas no significant ionic selectivity differences were obtained with -hydroxybutyrate.The respiratory control induced by oligomycin in submitochondrial particles is released by beauvericin only in the presence of a nigericin-like carboxylic antibiotic and an alkali metal cation, being far more effective in K⁺ than in Na⁺.This selectivity is maintained regardless of whether NADH or succinate is used as a respiratory substrate.Release of respiratory control can also be obtained with a combination of beauvericin and NH₄Cl.This information indicates that the ionic selectivity pattern obtained with beauvericin in mitochondrial membranes is an intrinsic property of the antibiotic which, however, can be significantly modified by factors such as the nature of the translocatable substrate anion or other anionic species, as well as the possible operation of a Na⁺/H⁺ antiporter existent in the membrane.     

S-Glutathionylation of the Na,K-ATPase Catalytic α Subunit Is a Determinant of the Enzyme Redox Sensitivity

Na,K-ATPase is highly sensitive to changes in the redox state, and yet the mechanisms of its redox sensitivity remain unclear. We have explored the possible involvement of S-glutathionylation of the catalytic α subunit in redox-induced responses. For the first time, the presence of S-glutathionylated cysteine residues was shown in the α subunit in duck salt glands, rabbit kidneys, and rat myocardium. Exposure of the Na,K-ATPase to oxidized glutathione (GSSG) resulted in an increase in the number of S-glutathionylated cysteine residues. Increase in S-glutathionylation was associated with dose- and time-dependent suppression of the enzyme function up to its complete inhibition. The enzyme inhibition concurred with S-glutathionylation of the Cys-454, -458, -459, and -244. Upon binding of glutathione to these cysteines, the enzyme was unable to interact with adenine nucleotides. Inhibition of the Na,K-ATPase by GSSG did not occur in the presence of ATP at concentrations above 0.5 mm. Deglutathionylation of the α subunit catalyzed by glutaredoxin or dithiothreitol resulted in restoration of the Na,K-ATPase activity. Oxidation of regulatory cysteines made them inaccessible for glutathionylation but had no profound effect on the enzyme activity. Regulatory S-glutathionylation of the α subunit was induced in rat myocardium in response to hypoxia and was associated with oxidative stress and ATP depletion. S-Glutathionylation was followed by suppression of the Na,K-ATPase activity. The rat α2 isoform was more sensitive to GSSG than the α1 isoform. Our findings imply that regulatory S-glutathionylation of the catalytic subunit plays a key role in the redox-induced regulation of Na,K-ATPase activity.     

The α1 Na+−K+ pump of the Dahl salt-sensitive rat exhibits altered Na+ modulation of K+ transport in red blood cells

The properties of the α1 Na⁺-K⁺ pump were compared in Dahl salt-sensitive (DS) and salt-resistant (DR) strains by measuring ouabain-sensitive luxes (mmol/liter cell x hr = FU, Mean ± se) in red blood cells (RBCs) and varying internal ( _i ) and external ( _o ) Na⁺ and K⁺ concentrations. Kinetic parameters of several modes of operation, i.e., Na⁺/ K⁺, K⁺/K⁺, Na⁺/Na⁺ exchanges, were characterized and analyzed for curve-fitting using the Enzfitter computer program. In unidirectional flux studies (n=12 rats of each strain) into fresh cells incubated in 140 mm Na⁺ + 5 mm K⁺, ouabain-sensitive K⁺ influx was substantially lower in the DS than in DR RBCs, while ouabain-sensitive Na⁺ efflux and Na _i were similar in both strains. Thus, the coupling ratio between unidirectional Na⁺∶K⁺ fluxes was significantly higher in DS than in DR cells at similar RBC Na⁺ content. In the presence of 140 mm Na _o , activation of ouabain-sensitive K⁺ influx by K _o had a lower K _m and V _max in DS as estimated by the Garay equation (N=2.70 ± 0.33, K _m 0.74 ± 0.09 mm; V _max 2.87 ± 0.09 FU) than in DR rats (N=1.23 ± 0.36, K _m 2.31 ± 0.16 mm; v _max 5.70 ± 0.52 FU). However, the two kinetic parameters were similar following Na _o removal. The activation of ouabain-sensitive K⁺ influx by Na _i had significantly lower V _max in DS (9.3 ± 0.4 FU) than in DR (14.5 ± 0.6 FU) RBCs but similar K _m. These data suggest that the low K⁺ influx in DS cells is caused by a defect in modulation by Na _o and Na _i . Na⁺ efflux showed no differences in Na _i activation or trans effects by Na _o and K _o , thus accounting for the different Na⁺∶K⁺ coupling ratio in the Dahl strains. Further evidence for the differences in the coupling of ouabain-sensitive fluxes was found in studies of net Na⁺ and K⁺ fluxes, where the net ouabain-sensitive Na⁺ losses showed similar magnitudes in the two Dahl strains while the net ouabainsensitive K⁺ gains were significantly greater in the DR than the DS RBCs. Ouabain-sensitive Na⁺ influx and K⁺ efflux were also measured in these rat RBCs. The inhibition of ouabain-sensitive Na⁺ influx by K _o was fully competitive for the DS but not for the DR pumps. Thus, for DR pumps, K _o could activate higher K⁺ influx in DR pumps without a complete inhibition of ouabain-sensitive Na⁺ influx. This behavior is consistent with K _o interaction with distinct Na⁺ and K⁺ transport sites. In addition, the inhibition of K⁺ efflux by Na, was different between Dahl strains. Ouabain-sensitive K⁺ efflux at Na _i level of 4.6 mmol/liter cell, was significantly higher in DS (3.86 ± 0.67 FU) than in DR (0.86 ± 0.14 FU) due to a threefold higher K₅₀ for Na _i -inhibition 9.66 ± 0.41 vs. 3.09 ± 0.11 mmol/liter cell. This finding indicates that Na⁺ modulation of K⁺ transport is altered at both sides of the membrane. The dissociation of Na⁺ modulatory sites of K⁺ transport from Na⁺ transport sites observed in RBCs of Dahl strains suggests that K⁺ transport by the Na⁺-K⁺ pump is controlled by Na⁺ allosteric sites different from the Na⁺ transport sites. The alterations in K⁺ transport may be related to the amino acid substitution (Leu/Gln₂₇₆) reported for the cDNA of the α1 subunit of the Na⁺-K⁺ pump in the DS strain or to post-translational modifications during RBC maturation. These studies were supported by the following grants: NIH (HL-35664, HL-42120, HL-18318, HL-39267, HL-01967). J.R.R. is a Ford Foundation Predoctoral Fellow. A preliminary report of this work was presented at the International Conference on the Na⁺-K⁺ pump and 44th Annual Meeting of the Society of General Physiologists held at Woods Hole, MA, September 5–9, 1990, and published as an abstract in the J. Gen. Physiol. 96:70a, 1990.     

Extracellular Allosteric Regulatory Subdomain within the γ Subunit of the Epithelial Na+ Channel

The activity of the epithelial Na⁺ channel (ENaC) is modulated by Na⁺ self-inhibition, a down-regulation of the open probability of ENaC by extracellular Na⁺. A His residue within the extracellular domain of γENaC (γHis²³⁹) was found to have a critical role in Na⁺ self-inhibition. We investigated the functional roles of residues in the vicinity of this His by mutagenesis and analyses of Na⁺ self-inhibition responses in Xenopus oocytes. Significant changes in the speed and magnitude of Na⁺ self-inhibition were observed in 16 of the 47 mutants analyzed. These 16 mutants were distributed within a 22-residue tract. We further characterized this scanned region by examining the accessibility of introduced Cys residues to the sulfhydryl reagent MTSET. External MTSET irreversibly increased or decreased currents in 13 of 47 mutants. The distribution patterns of the residues where substitutions significantly altered Na⁺ self-inhibition or/and conferred sensitivity to MTSET were consistent with the existence of two helices within this region. In addition, single channel recordings of the γH239F mutant showed that, in the absence of Na⁺ self-inhibition and with an increased open probability, ENaCs still undergo transitions between open and closed states. We conclude that γHis²³⁹ functions within an extracellular allosteric regulatory subdomain of the γ subunit that has an important role in conferring the response of the channel to external Na⁺.     

Association with β-COP Regulates the Trafficking of the Newly Synthesized Na,K-ATPase

Plasma membrane expression of the Na,K-ATPase requires assembly of its α- and β-subunits. Using a novel labeling technique to identify Na,K-ATPase partner proteins, we detected an interaction between the Na,K-ATPase α-subunit and the coat protein, β-COP, a component of the COP-I complex. When expressed in the absence of the Na,K-ATPase β-subunit, the Na,K-ATPase α-subunit interacts with β-COP, is retained in the endoplasmic reticulum, and is targeted for degradation. In the presence of the Na,K-ATPase β-subunit, the α-subunit does not interact with β-COP and traffics to the plasma membrane. Pulse-chase experiments demonstrate that in cells expressing both the Na,K-ATPase α- and β-subunits, newly synthesized α-subunit associates with β-COP immediately after its synthesis but that this interaction does not constitute an obligate intermediate in the assembly of the α- and β-subunits to form the pump holoenzyme. The interaction with β-COP was reduced by mutating a dibasic motif at Lys⁵⁴ in the Na,K-ATPase α-subunit. This mutant α-subunit is not retained in the endoplasmic reticulum and reaches the plasma membrane, even in the absence of Na,K-ATPase β-subunit expression. Although the Lys⁵⁴ α-subunit reaches the cell surface without need for β-subunit assembly, it is only functional as an ion-transporting ATPase in the presence of the β-subunit.     

Regulation of the human Na⁺-dependent glucose cotransporter hSGLT2

The human Na(+)-glucose cotransporter SGLT2 is expressed mainly in the kidney proximal convoluted tubule where it is considered to be responsible for the bulk of glucose reabsorption. Phosphorylation profiling has revealed that SGLT2 exists in a phosphorylated state in the rat renal proximal tubule cortex, so we decided to investigate the regulation of human SGLT2 (hSGLT2) by protein kinases. hSGLT2 was expressed in human embryonic kidney (HEK) 293T cells, and the activity of the protein was measured using radiotracer and whole cell patch-clamp electrophysiology assays before and after activation of protein kinases. 8-Bromo-adenosine cAMP (8-Br-cAMP) was used to activate protein kinase A, and sn-1,2-dioctanoylglycerol (DOG) was used to activate protein kinase C (PKC). 8-Br-cAMP stimulated D-[α-methyl-(14)C]glucopyranoside ([(14)C]α-MDG) uptake and Na(+)-glucose currents by 200% and DOG increased [(14)C]α-MDG uptake and Na(+)-glucose currents by 50%. In both cases the increase in SGLT2 activity was marked by an increase in the maximum rate of transport with no change in glucose affinity. These effects were completely negated by mutation of serine 624 to alanine. Insulin induced a 250% increase in Na(+)-glucose transport by wild-type but not S624A SGLT2. Parallel studies confirmed that the activity of hSGLT1 was regulated by PKA and PKC due to changes in the number of transporters in the cell membrane. hSGLT1 was relatively insensitive to insulin. We conclude that hSGLT1 and hSGLT2 are regulated by different mechanisms and suggest that insulin is an SGLT2 agonist in vivo.     

Sodium-dependent modulation of the renal Na−K-ATPase: Influence of mineralocorticoids on the cortical collecting duct

Summary Mineralocorticoids play a major role in the regulation of sodium transport in a variety of tissues, including the cortical collecting duct (CCD) of the mammalian nephron. To assess, in part, the underlying mechanism(s) of this control, the present studies were designed to evaluate, first, the influence of mineralocorticoids on the Na–K-ATPase activity in the rabbit CCD and, secondly, a possible role of sodium entry into the cell at the luminal border on the regulation of the Na–K-ATPase. In the first series of studies, rabbits were maintained on a low sodium diet which raised serum aldosterone levels from 16 to 70 ng/dl after 3–4 days, with further elevations being expressed with treatment for two weeks or more. In CCDs isolated from these animals, the Na–K-ATPase increased from 13 to 40 pmol ADP min^–1 mm^–1 after 3–4 days on the low sodium regimen, but then declined, returning to control values after approximately 2 weeks. This decline in activity was preceded by a decrease in the Na⁺ concentration of the urine to low levels and hence, likely coincided with a decreased delivery of sodium to, and sodium entry into the cells of, the CCD. If dietary manipulations were used to maintain a high delivery of sodium to the CCD in the animal, elevation of plasma mineralocorticoid levels by treatment with deoxycorticosterone acetate (DOCA) caused a similar elevation in the Na–K-ATPase activity after 3–4 days, which did not decline with continued treatment for up to 2 weeks. Furthermore, it was observed that mineralocorticoids only exerted their effect on the Na–K-ATPase after a latent period of 1 day, well after sodium excretion had fallen, indicating that sodium entry into the CCD cells was already stimulated. If animals were simultaneously treated with DOCA and the sodium channel blocker amiloride for 3–4 days, the effects on the Na–K-ATPase were markedly reduced, whereas amiloride treatment alone had no effect on the enzyme activity. Since others have shown that mineralocorticoids induce synthesis of the Na–K-ATPase subunits in toad bladder cells in an amiloride-insensitive manner, sodium must be exerting its effect on a process after translation. It is concluded that the initial effect of mineralocorticoids in the CCD is on sodium entry with a delayed induction of the Na–K-ATPase, which is regulated by Na-dependent modulation of a posttranslational process.     

Mineralocorticoids modulate the expression of the β-3 subunit of the Na+, K+-ATPase in the renal collecting duct

Renal sodium reabsorption depends on the activity of the Na⁺,K⁺-ATPase α/β heterodimer. Four α (α_1–4) and 3 β (β_1–3) subunit isoforms have been described. It is accepted that renal tubule cells express α₁/β₁ dimers. Aldosterone stimulates Na⁺,K⁺-ATPase activity and may modulate α₁/β₁ expression. However, some studies suggest the presence of β₃ in the kidney. We hypothesized that the β₃ isoform of the Na⁺,K⁺-ATPase is expressed in tubular cells of the distal nephron, and modulated by mineralocorticoids. We found that β₃ is highly expressed in collecting duct of rodents, and that mineralocorticoids decreased the expression of β₃. Thus, we describe a novel molecular mechanism of sodium pump modulation that may contribute to the effects of mineralocorticoids on sodium reabsorption.     

Na,K-ATPase and the role of α isoforms in behavior

The Na,K-ATPase is composed of multiple isoforms and the isoform distribution varies with the tissue and during development. The α1 isoform for example, is the major isoform in the kidney and many other tissues, while the α2 isoform is the predominate one in skeletal muscle. All three isoforms are found in the brain although in adult rodent brain, the α3 isoform is located essentially in neurons while the α2 isoform is found in astrocytes and some limited neuronal populations. Interestingly the α4 isoform is found exclusively in the mid region of the sperm tail. The distribution of the isoforms of the Na,K-ATPase has been extensively studied in many tissues and during development. The examples cited above provide some indication to the diversity of Na,K-ATPase isoform expression. In order to understand the significance of this distribution, we have developed animals which lack the α1, α2, and α3 isoforms. It is anticipated that these studies will provide insight into the role that these isoforms play in driving various biological processes in specific tissues. Here we describe some of our studies which deal with the behavioral aspects of the α1, α2, and α3 deficient mice, particularly those that are haploinsufficient in one isoform i.e. lacking one functional gene for the α1, α2, or α3 isoforms. Such studies are important as two human diseases are associated with deficiency in the α2 and α3 isoforms. These are Familial Hemiplegic Migraine type 2 and Rapid-Onset Dystonia Parkinsonism, these diseases result from α2 and α3 isoform haploinsufficiency, respectively. We find that the haploinsufficiency of both α2 and α3 isoforms result in behavioral defects.     

Characterization of the Na⁺/H⁺ antiporter from Yersinia pestis

Yersinia pestis, the bacterium that historically accounts for the Black Death epidemics, has nowadays gained new attention as a possible biological warfare agent. In this study, its Na/H antiporter is investigated for the first time, by a combination of experimental and computational methodologies. We determined the protein''s substrate specificity and pH dependence by fluorescence measurements in everted membrane vesicles. Subsequently, we constructed a model of the protein''s structure and validated the model using molecular dynamics simulations. Taken together, better understanding of the Yersinia pestis Na/H antiporter''s structure-function relationship may assist in studies on ion transport, mechanism of action and designing specific blockers of Na/H antiporter to help in fighting Yersinia pestis -associated infections. We hope that our model will prove useful both from mechanistic and pharmaceutical perspectives.     

Na+-coupled Cl− transport in the gastric mucosa of the guinea pig

The Cl^–/HCO ₃ ^– exchange mechanism usually postulated to occur in gastric mucosa cannot account for the Na⁺-dependent electrogenic serosal to mucosal Cl^– transport often observed. It was recently suggested that an additional Cl^– transport mechanism driven by the Na⁺ electrochemical potential gradient may be present on the serosal side of the tissue. To verify this, we have studied Cl^– transport in guinea pig gastric mucosa. Inhibiting the (Na⁺, K⁺) ATPase either by serosal addition of ouabain or by establishing K⁺-free mucosal and serosal conditions abolished net Cl^– transport. Depolarizing the cell membrane potential with triphenylmethylphosphonium (a lipid-soluble cation), and hence reducing both the Na⁺ and Cl^– electrochemical potential gradients, resulted in inhibition of net Cl^– flux. Reduction of short-circuit current on replacing Na⁺ by choline in the serosal bathing solution was shown to be due to inhibition of Cl^– transport. Serosal addition of diisothiocyanodisulfonic acid stilbene (an inhibitor of anion transport systems) abolished net Cl^– flux but not net Na⁺ flux. These results are compatible with the proposed model of a Cl^–/Na⁺ cotransport mechanism governing serosal Cl^– entry into the secreting cells. We suggest that the same mechanism may well facilitate both coupled Cl^–/Na⁺ entry and coupled HCO ₃ ^– /Na⁺ exit on the serosal side of the tissue.     

Diverse pathways for maturation of the Na,K-ATPase β1 and β2 subunits in the endoplasmic reticulum of Madin-Darby canine kidney cells

Proper folding of the Na,K-ATPase β subunits followed by assembly with the α subunits is necessary for their export from the endoplasmic reticulum (ER). Here we examine roles of the ER lectin chaperone, calnexin, and non-lectin chaperone, BiP, in folding and quality control of the β(1) and β(2) subunits in Madin-Darby canine kidney cells. Short term prevention of glycan-calnexin interactions by castanospermine slightly increases ER retention of β(1), suggesting minor involvement of calnexin in subunit folding. However, both prolonged incubation with castanospermine and removal of N-glycosylation sites do not affect the α(1)-assembly or trafficking of β(1) but increase the amount of the β(1)-bound BiP, showing that BiP can compensate for calnexin in assisting β(1) folding. In contrast to β(1), prevention of either N-glycosylation or glycan-calnexin interactions abolishes the α(1)-assembly and export of β(2) from the ER despite increased β(2)-BiP binding. Mutations in the α(1)-interacting regions of β(1) and β(2) subunits impair α(1) assembly but do not affect folding of the β subunits tested by their sensitivity to trypsin. At the same time, these mutations increase the amount of β-bound BiP but not of β-bound calnexin and increase ER retention of both β-isoforms. BiP, therefore, prevents the ER export of folded but α(1)-unassembled β subunits. These α(1)-unassembled β subunits are degraded faster than α(1)-bound β subunits, preventing ER overload. In conclusion, folding of the β(1) and β(2) subunits is assisted predominantly by BiP and calnexin, respectively. Folded β(1) and β(2) either assemble with α(1) or bind BiP. The α(1)-bound β subunits traffic to the Golgi, whereas BiP-bound β subunits are retained and degraded in the ER.