Chimeric domain analysis of the compatibility between H(+), K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits for the functional expression of gastric H(+),K(+)-ATPase

Gastric H(+),K(+)-ATPase consists of alpha-subunit with 10 transmembrane domains and beta-subunit with a single transmembrane domain. We constructed cDNAs encoding chimeric beta-subunits between the gastric H(+),K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits and co-transfected them with the H(+),K(+)-ATPase alpha-subunit cDNA in HEK-293 cells. A chimeric beta-subunit that consists of the cytoplasmic plus transmembrane domains of Na(+),K(+)-ATPase beta-subunit and the ectodomain of H(+),K(+)-ATPase beta-subunit assembled with the H(+),K(+)-ATPase alpha-subunit and expressed the K(+)-ATPase activity. Therefore, the whole cytoplasmic and transmembrane domains of H(+),K(+)-ATPase beta-subunit were replaced by those of Na(+),K(+)-ATPase beta-subunit without losing the enzyme activity. However, most parts of the ectodomain of H(+),K(+)-ATPase beta-subunit were not replaced by the corresponding domains of Na(+), K(+)-ATPase beta-subunit. Interestingly, the extracellular segment between Cys(152) and Cys(178), which contains the second disulfide bond, was exchangeable between H(+),K(+)-ATPase and Na(+), K(+)-ATPase, preserving the K(+)-ATPase activity intact. Furthermore, the K(+)-ATPase activity was preserved when the N-terminal first 4 amino acids ((67)DPYT(70)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the corresponding amino acids ((63)SDFE(66)) of Na(+),K(+)-ATPase beta-subunit. The ATPase activity was abolished, however, when 4 amino acids ((76)QLKS(79)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the counterpart ((72)RVAP(75)) of Na(+),K(+)-ATPase beta-subunit, indicating that this region is the most N-terminal one that discriminates the H(+),K(+)-ATPase beta-subunit from that of Na(+), K(+)-ATPase.

Identification of a novel gene of the X,K-ATPase beta-subunit family that is predominantly expressed in skeletal and heart muscles

We have identified the fifth member of the mammalian X,K-ATPase beta-subunit gene family. The human and rat genes are largely expressed in skeletal muscle and at a lower level in heart. The deduced human and rat proteins designated as beta(muscle) (beta(m)) consist of 357 and 356 amino acid residues, respectively, and exhibit 89% identity. The sequence homology of beta(m) proteins with known Na,K- and H,K-ATPase beta-subunits are 30.5-39.4%. Unlike other beta-subunits, putative beta(m) proteins have large N-terminal cytoplasmic domains containing long Glu-rich sequences. The data obtained indicate the existence of hitherto unknown X,K-ATPase (most probably Na,K-ATPase) isozymes in muscle cells.

Cation selectivity of gastric H,K-ATPase and Na,K-ATPase chimeras

Chimeras of the catalytic subunits of the gastric H,K-ATPase and Na, K-ATPase were constructed and expressed in LLC-PK1 cells. The chimeras included the following: (i) a control, H85N (the first 85 residues comprising the cytoplasmic N terminus of Na,K-ATPase replaced by the analogous region of H,K-ATPase); (ii) H85N/H356-519N (the N-terminal half of the cytoplasmic M4-M5 loop also replaced); and (iii) H519N (the entire front half replaced). The latter two replacements confer a decrease in apparent affinity for extracellular K+. The 356-519 domain and, to a greater extent, the H519N replacement confer increased apparent selectivity for protons relative to Na+ at cytoplasmic sites as shown by the persistence of K+ influx when the proton concentration is increased and the Na+ concentration decreased. The pH and K+ dependence of ouabain-inhibitable ATPase of membranes derived from the transfected cells indicate that the H519N and, to a lesser extent, the H356-519N substitution decrease the effectiveness of K+ to compete for protons at putative cytoplasmic H+ activation sites. Notable pH-independent behavior of H85N/H356-519N at low Na+ suggests that as pH is decreased, Na+/K+ exchange is replaced largely by (Na+ + H+)/K+ exchange. With H519N, the pH and Na+ dependence of pump and ATPase activities suggest relatively active H+/K+ exchange even at neutral pH. Overall, this study provides evidence for important roles in cation selectivity for both the N-terminal half of the M4-M5 loop and the adjacent transmembrane helice(s).

H,K-ATPase alpha subunit C-terminal membrane topology: epitope tags in the insect cell expression system

The H,K-ATPase responsible for gastric acidification is a heterodimeric (alpha and beta subunit) P-type ATPase, an integral protein of parietal cell apical membranes, which promotes the electroneutral exchange of K+ for protons, is stimulated by K+ and is inhibited by 2-methyl-8-(phenylmethoxy)imidazo[1, 2-alpha]pyridine-3-acetonitrile (SCH 28080). Hydropathy analysis of the catalytic alpha subunit has been interpreted in terms of four N-terminal transmembrane domains, a cytoplasmically oriented segment containing ATP binding and phosphorylation sites, and a C-terminal region with four or six putative transmembrane domains. Several lines of evidence implicate the C-terminal region of P-type ATPases in cation-binding and occlusion, conformational changes, and interactions with the beta subunit (HKbeta), making the definition of topology a prerequisite for understanding the structural basis of these functions. Influenza haemagglutinin epitopes (YPYDVPDYA; flu tag) were inserted in predicted hydrophilic segments of the alpha subunit (HKalpha) to establish the membrane orientation of two amino acids with different predicted topologies in the C-terminal four- and six-transmembrane models. Wild-type and mutated HKalpha and HKbeta cDNA species were expressed in insect cells (Sf9) via recombinant baculovirus infection, and expression of H,K-ATPase was verified by immunoblotting with HKalpha- and HKbeta-specific and flu-tag-specific antibodies. Functional assays showed K+-stimulated, SCH 28080-sensitive ATPase activity, confirming neo-native topology in H,K-ATPase heterodimers expressed in Sf9 cells. The topology of flu tags was determined by microsomal protease protection assays in Sf9 cells and immunolabelling of HKalpha and HKbeta in intact and permeabilized Sf9 cells. In addition, MS of native H,K-ATPase tryptic peptides identified cytoplasmically oriented HKalpha residues. The results indicated cytoplasmic exposure of Leu844 and Phe996, and luminal exposure of Pro898, leading to a revised secondary structure model of the C-terminal third of HKalpha.

The nongastric H+-K+-ATPases: molecular and functional properties

The Na-K/H-K-ATPase gene family is divided in three subgroups including the Na-K-ATPases, mainly involved in whole body and cellular ion homeostasis, the gastric H-K-ATPase involved in gastric fluid acidification, and the newly described nongastric H-K-ATPases for which the identification of physiological roles is still in its infancy. The first member of this last subfamily was first identified in 1992, rapidly followed by the molecular cloning of several other members. The relationship between each member remains unclear. The functional properties of these H-K-ATPases have been studied after their ex vivo expression in various functional expression systems, including the Xenopus laevis oocyte, the insect Sf9 cell line, and the human HEK 293 cells. All these H-K-ATPase alpha-subunits appear to encode H-K-ATPases when exogenously expressed in such expression systems. Recent data suggest that these H-K-ATPases could also transport Na+ in exchange for K+, revealing a complex cation transport selectivity. Moreover, they display a unique pharmacological profile compared with the canonical Na-K-ATPases or the gastric H-K-ATPase. In addition to their molecular and functional characterizations, a major goal is to correlate the molecular expression of these cloned H-K-ATPases with the native K-ATPases activities described in vivo. This appears to be more complex than anticipated. The discrepancies between the functional data obtained by exogenous expression of the nongastric H-K-ATPases and the physiological data obtained in native organs could have several explanations as discussed in the present review. Extensive studies will be required in the future to better understand the physiological role of these H-K-ATPases, especially in disease processes including ionic or acid-base disorders.

Environmental distal renal tubular acidosis in Thailand: an enigma

Distal renal tubular acidosis is a common health problem in northeastern Thailand, with the population background of the low potassium intake, low urine citrate, and decreased red blood cell Na-K adenosine triphosphatase (ATPase) activity and the environment of the high soil vanadium. The disease is usually seen in the people with low socioeconomic status in summer. The patients have decreased gastric acidity and low urine potassium. There are varying degrees of renal function from normal to impairment. Gastric hypoacidity is an important clue. Defects in H-K ATPase and anion exchange (AE2) mechanism are considered. The urine vanadium is higher in the patients than that of normal rural northeastern villagers. Inhibition of H-K ATPase by vanadium seems possible and requires more supporting evidence. AE1 gene mutation is noted in few patients. The cause of dRTA is not apparent. The AE2 gene and H-K ATPase gene remain to be studied. Both environmental and genetic factors could contribute to the pathogenesis of the disease.

[Potassium transport in yeast]

K+ transport is vital for all cells. The first model to explain K+ transport in yeast was a redox potential driven H+/K+ antiporter. Later, a H+-ATPase was described which generates a H+ gradient, acid outside. This proton gradient is used by a secondary transporter, which transports K+ to the inside. These transporters are separate proteins, that have been isolated and their genes have been cloned. Furthermore, in Saccharomyces cerevisiae two different K+ transporters have been described. K+ exit occurs through K+ channels and through H+/K+ antiporters that seem to anticipate in the regulation of internal pH. In addition, yeast produces a large amount of CO2 during the fermentation process. CO2 accumulation in turn results in the establishment of a Donnan potential due to the accumulation of bicarbonate, which retains large quantities of K+. In S. cerevisiae, bicarbonate is responsible for a large accumulation of K+. Also, the H+-ATPase, by pumping protons to the outside, favors the formation of bicarbonate which cannot diffuse to the extracellular environment leading to cytoplasmic pH values near 7.0. Bicarbonate accumulation allows yeast to maintain large pH gradients across the plasma membrane.

A chimeric gastric H+,K+-ATPase inhibitable with both ouabain and SCH 28080

2-Methyl-8-(phenylmethoxy)imidazo(1,2-a)pyridine-3acetonitrile+ ++ (SCH 28080) is a K+ site inhibitor specific for gastric H+,K+-ATPase and seems to be a counterpart of ouabain for Na+,K+-ATPase from the viewpoint of reaction pattern (i.e. reversible binding, K+ antagonism, and binding on the extracellular side). In this study, we constructed several chimeric molecules between H+,K+-ATPase and Na+,K+-ATPase alpha-subunits by using rabbit H+,K+-ATPase as a parental molecule. We found that the entire extracellular loop 1 segment between the first and second transmembrane segments (M1 and M2) and the luminal half of the M1 transmembrane segment of H+, K+-ATPase alpha-subunit were exchangeable with those of Na+, K+-ATPase, respectively, preserving H+,K+-ATPase activity, and that these segments are not essential for SCH 28080 binding. We found that several amino acid residues, including Glu-822, Thr-825, and Pro-829 in the M6 segment of H+,K+-ATPase alpha-subunit are involved in determining the affinity for this inhibitor. Furthermore, we found that a chimeric H+,K+-ATPase acquired ouabain sensitivity and maintained SCH 28080 sensitivity when the loop 1 segment and Cys-815 in the loop 3 segment of the H+,K+-ATPase alpha-subunit were simultaneously replaced by the corresponding segment and amino acid residue (Thr) of Na+,K+-ATPase, respectively, indicating that the binding sites of ouabain and SCH 28080 are separate. In this H+, K+-ATPase chimera, 12 amino acid residues in M1, M4, and loop 1-4 that have been suggested to be involved in ouabain binding of Na+, K+-ATPase alpha-subunit are present; however, the low ouabain sensitivity indicates the possibility that the sensitivity may be increased by additional amino acid substitutions, which shift the overall structural integrity of this chimeric H+,K+-ATPase toward that of Na+,K+-ATPase.

Conformation-dependent inhibition of gastric H+,K+-ATPase by SCH 28080 demonstrated by mutagenesis of glutamic acid 820

Gastric H+,K+-ATPase can be inhibited by imidazo pyridines like 2-methyl-8-[phenylmethoxy] imidazo-(1,2a) pyridine 3-acetonitrile (SCH 28080). The drug shows a high affinity for inhibition of K+-activated ATPase and for prevention of ATP phosphorylation. The inhibition by SCH 28080 can be explained by assuming that SCH 28080 binds to both the E2 and the phosphorylated intermediate (E2-P) forms of the enzyme. We observed recently that some mutants, in which glutamic acid 820 present in transmembrane domain six of the catalytic subunit had been replaced (E820Q, E820N, E820A), lost their K+-sensitivity and showed constitutive ATPase activity. This ATPase activity could be inhibited by similar SCH 28080 concentrations as the K+-activated ATPase of the wild-type enzyme. SCH 28080 also inhibited ATP phosphorylation at 21 degrees C of the mutants E820D, E820N, and E820A, although with varying efficacy and affinity. ATP-phosphorylation of mutant E820Q was not inhibited by SCH 28080; in contrast, the phosphorylation level at 21 degrees C was nearly doubled. These findings can be explained by assuming that mutation of Glu820 favors the E1 conformation in the order E820Q >E820A >E820N >wild-type = E820D. The increase in the phosphorylation level of the E820Q mutant can be explained by assuming that during the catalytic cycle the E2-P intermediate forms a complex with SCH 28080. This intermediate hydrolyzes considerably slower than E2-P and thus accumulates. The high tendency of the E820Q mutant for the E1 form is further supported by experiments showing that ATP phosphorylation of this mutant is rather insensitive towards vanadate, inorganic phosphate, and K+.

H-K-ATPase in the RCCT-28A rabbit cortical collecting duct cell line

In the present study, we demonstrate that the rabbit cortical collecting duct cell line RCCT-28A possesses three distinct H-K-ATPase catalytic subunits (HKalpha). Intracellular measurements of RCCT-28A cells using the pH-sensitive dye 2', 7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) indicated that the mechanism accounting for recovery from an acid load exhibited both K+ dependence and sensitivity to Sch-28080 characteristic of H-K-ATPases. Recovery rates were 0.022 +/- 0.005 pH units/min in the presence of K+, 0.004 +/- 0.002 in the absence of K+, and 0.002 +/- 0.002 in the presence of Sch-28080. The mRNAs encoding the HKalpha1 subunit and the H-K-ATPase beta-subunit (HKbeta) were detected by RT-PCR. In addition, two HKalpha2 species were found by RT-PCR and 5' rapid amplification of cDNA ends (5'-RACE) in the rabbit renal cortex. One was homologous to HKalpha2 cDNAs generated from other species, and the second was novel. The latter, referred to as HKalpha2c, encoded an apparent 61-residue amino-terminal extension that bore no homology to reported sequences. Antipeptide antibodies were designed on the basis of this extension, and these antibodies recognized a protein of the appropriate mass in both rabbit renal tissue samples and RCCT-28A cells. Such findings constitute very strong evidence for expression of the HKalpha2c subunit in vivo. The results suggest that the rabbit kidney and RCCT-28A cells express at least three distinct H-K-ATPases.

Colonic H-K-ATPase beta-subunit: identification in apical membranes and regulation by dietary K depletion

P-type ATPases require both alpha- and beta-subunits for functional activity. Although an alpha-subunit for colonic apical membrane H-K-ATPase (HKcalpha) has been identified and studied, its beta-subunit has not been identified. We cloned putative beta-subunit rat colonic H-K-ATPase (HKcbeta) cDNA that encodes a 279-amino-acid protein with a single transmembrane domain and sequence homology to other rat beta-subunits. Northern blot analysis demonstrates that this HKcbeta is expressed in several rat tissues, including distal and proximal colon, and is highly expressed in testis and lung. HKcbeta mRNA abundance is upregulated threefold compared with normal in distal colon but not proximal colon, testis, or lung of K-depleted rats. In contrast, Na-K-ATPase beta1 mRNA abundance is unaltered in distal colon of K-depleted rats. Na depletion, which also stimulates active K absorption in distal colon, does not increase HKcbeta mRNA abundance. Western blot analyses using a polyclonal antibody raised to a glutathione S-transferase-HKcbeta fusion protein established expression of a 45-kDa HKcbeta protein in both apical and basolateral membranes of rat distal colon, but K depletion increased HKcbeta protein expression only in apical membranes. Physical association between HKcbeta and HKcalpha proteins was demonstrated by Western blot analysis performed with HKcbeta antibody on immunoprecipitate of apical membranes of rat distal colon and HKcalpha antibody. Tissue-specific upregulation of this beta-subunit mRNA in response to K depletion, localization of its protein, its upregulation by K depletion in apical membranes of distal colon, and its physical association with HKcalpha protein provide compelling evidence that HKcbeta is the putative beta-subunit of colonic H-K-ATPase.

Mutagenesis of glutamate 820 of the gastric H+,K+-ATPase alpha-subunit to aspartate decreases the apparent ATP affinity

Mutagenesis of Glu820, present in the catalytic subunit of gastric H+,K+-ATPase, into an Asp hardly affects K+-stimulated ATPase and K+-stimulated dephosphorylation of the enzyme. The ATP phosphorylation rate of the E820D mutant, however, is rather low and the apparent affinity for ATP in the phosphorylation process of this mutant is 2-3 times lower than that of the wild type enzyme. The reduction in the ATP phosphorylation rate of the E820D mutant has only an effect on the ATPase activity at low temperature. These findings suggest that Glu820 might play a role in H+ stimulation of the phosphorylation process.

Identification of a gastritogenic epitope of the H/K ATPase beta-subunit

We have previously shown that autoimmune gastritis can be elicited in mice by immunization with the gastric parietal cell H/K ATPase alpha beta heterodimer and that tolerance specifically induced to the H/K ATPase beta-subunit protects mice from the development of gastritis. Here we have identified the immunodominant gastritogenic epitope of the H/K ATPase beta-subunit (H/Kbeta). Epitope mapping was carried out with a panel of 21 overlapping peptides that spanned the entire sequence of the gastric H/K ATPase beta-subunit. T cells from gastric H/K ATPase-immunized mice responded to only one of the overlapping peptides, namely H/Kbeta253-277. Furthermore, a single subcutaneous immunization of 6-week-old BALB/c mice with the ATPase beta-subunit peptides resulted in a T-cell response to only H/Kbeta253-277. Multiple immunization with the overlapping H/K ATPase peptides demonstrated that H/Kbeta253-277 was capable of inducing a mononuclear infiltrate specifically within the gastric mucosa. We conclude that H/Kbeta253-277 is the dominant gastritogenic epitope of the gastric H/K ATPase.

Ouabain-sensitive H,K-ATPase: tissue-specific expression of the mammalian genes encoding the catalytic alpha subunit

Human ATP1AL1 and corresponding genes of other mammals encode the catalytic alpha subunit of a non-gastric ouabain-sensitive H,K-ATPases, the ion pump presumably involved in maintenance of potassium homeostasis. The tissue specificity of the expression of these genes in different species has not been analyzed in detail. Here we report comparative RT-PCR screening of mouse, rat, rabbit, human, and dog tissues. Significant expression levels were observed in the skin, kidney and distal colon of all species (with the exception of the human colon). Analysis of rat urogenital organs also revealed strong expression in coagulating and preputial glands. Relatively lower expression levels were detected in many other tissues including brain, placenta and lung. In rabbit brain the expression was found to be specific to choroid plexus and cortex. Prominent similarity of tissue-specific expression patterns indicates that animal and human non-gastric H,K-ATPases are indeed products of homologous genes. This is also consistent with the high sequence similarity of non-gastric H,K-ATPases (including partial sequences of hitherto unknown cDNAs for mouse and dog proteins).

Different sources of acidity in glucose-elicited extracellular acidification in the yeast Saccharomyces cerevisiae

Three wild-type strains of Saccharomyces cerevisiae, viz. K, Y55 and sigma 1278b, two mutants lacking one or both of the putative K+ transporters, trk1 delta and trk1 delta trk2 delta, and a mutant in the plasma membrane H(+)-ATPase, viz. pma1-105, were compared in their extracellular acidification following addition of glucose and subsequent addition of KCl; in ATPase activity in purified plasma membranes; and in respiration on glucose. The glucose-induced acidification was the greater the higher the respiratory quotient, i.e. the higher the anaerobic metabolism. A markedly lower acidification was found in the ATPase-deficient pma1-105 strain but also in the TRK-deficient double mutant. The acidification pattern after addition of KCl corresponds to expectations in the TRK mutants; however, a similarly decreased acid production was found in the ATPase-deficient mutant pma1-105. The highest rate of ATP hydrolysis in vitro was found with the trk1 delta trk2 delta mutant where glucose-, as well as KCl-induced acidification were lowest. Likewise, the pma1-105 mutant with extremely low acidification showed only a minutely lower ATP hydrolysis than did its parent Y55 strain. Apparently, several different sources of acidity are involved in the glucose-induced acidification (including extrusion of organic acids); in fact, contrary to the general belief, the H(+)-ATPase may play a minor role in this process in some strains.

A tyrosine-based signal regulates H-K-ATPase-mediated potassium reabsorption in the kidney

Isoforms of the H-K-ATPase participate in active K resorption in the renal collecting tubule. The cytoplasmic tail of the beta-subunit of the gastric H-K-ATPase includes a 4 amino acid motif which is highly homologous to tyrosine-based endocytosis signals. We have generated transgenic mice expressing an H-K-ATPase beta-subunit in which the tyrosine residue in this sequence has been mutated to alanine. Mice expressing the mutated protein manifest constitutive hypersecretion of gastric acid, demonstrating that the beta-subunit tyrosine-based motif is required for the regulated endocytosis of the H-K pump and hence the cessation of gastric acid output. To test the possibility that the tyrosine-based sequence in the tail of the H-K-ATPase beta-subunit plays a role in regulating the function of renal H-K-ATPases, we examined renal K clearance in normal and in transgenic mice. Blood pressure, urine volume, glomerular filtration rate (GFR), plasma Na, and Na excretion are similar in control and transgenic mice. However, plasma K concentrations are significantly higher in transgenic mice (4.76 +/- 0.13 meq/l in transgenic and 4. 12 +/- 0.04 meq/l in control; n = 9, P < 0.05) and K excretion is lower in the transgenic animals (fractional excretion of K was 26.2 +/- 3.62% in transgenic and 50.1 +/- 4.78% in control; n = 9, P < 0. 01). These data suggest that the tyrosine-based signal in the cytoplasmic tail of the H-K-ATPase beta-subunit functions in the kidney as it does in the stomach to internalize H-K pump and thus inactivate pump function. Its elimination may result in the constitutive presence of the pump at the cell surface and lead to excessive urinary K reabsorption.

ATP1AL1, a member of the non-gastric H,K-ATPase family, functions as a sodium pump

The human ATP1AL1-encoded protein (an alpha subunit of the human non-gastric H,K-ATPase) has previously been shown to assemble with the gastric H,K-ATPase beta subunit (gH,Kbeta) to form a functionally active ionic pump in HEK 293 cells. This pump has been found to be sensitive to both SCH 28080 and ouabain. However, the 86Rb+-influx mediated by the ATP1AL1-gH,Kbeta heterodimer in HEK 293 cells is at least 1 order of magnitude larger than the maximum ouabain-sensitive proton efflux detected in the same cells. In this study we find that the intracellular Na+ content in cells expressing ATP1AL1 and gH,Kbeta is two times lower than that in control HEK 293 cells in response to incubation for 3 h in the presence of 1 microM ouabain. Moreover, analysis of net Na+ efflux in HEK 293 expressing the ATP1AL1-gH,Kbeta heterodimer reveals the presence of Na+ extrusion activity that is not sensitive to 1 microM ouabain but can be inhibited by 1 mM of this drug. In contrast, ouabain-inhibitable Na+ efflux in control HEK 293 cells is similarly sensitive to either 1 microM or 1 mM ouabain. Finally, 86Rb+ influx through the ATP1AL1-gH,Kbeta complex is comparable to the 1 mM ouabain-sensitive Na+ efflux in the same cells. The data presented here suggest that the enzyme formed by ATP1AL1 and the gastric H,K-ATPase beta subunit in HEK 293 cells mediates primarily Na+,K+ rather than H+,K+ exchange.

Colonic H+-K+-ATPase is induced and mediates increased HCO3- reabsorption in inner medullary collecting duct in potassium depletion

BACKGROUND

Potassium depletion increases HCO3- reabsorption in outer medullary collecting duct (OMCD) by activation of colonic (c) H-K-ATPase (HKA). The purpose of the current experiments was to examine the role of the isoforms of HKA in HCO3- reabsorption by terminal inner medullary collecting duct (IMCD) cells in potassium depletion.

METHODS

Sprague-Dawley rats were fed a potassium-free diet and studied after 8 to 10 days. mRNA expression of HKA isoforms in terminal portion of inner medulla was examined and correlated with HCO3- reabsorption in the terminal IMCD.

RESULTS

Gastric (g) HKA mRNA decreased whereas colonic (c) HKA mRNA expression was heavily induced in terminal portion of inner medulla in potassium depleted rats. Net HCO3- flux (JtCO2) in terminal IMCD increased in potassium depletion (4.56 to 7.06 pmol/min/mm tubule length, P < 0.001). In normal rats, 1 mM ouabain in perfusate had no effect on JtCO2, whereas 10 microM Schering 28080 (SCH) decreased JtCO2 to 2.4 (P < 0.002). In KD rats, 1 mM ouabain decreased JtCO2 to 4.9 (P < 0.005) and 10 microM SCH decreased JtCO2 to 3.3 (P < 0.001). However, the inhibitory effects of SCH and ouabain on JtCO2 in potassium depleted animals were not additive.

CONCLUSIONS

The data indicate that gHKA is suppressed whereas cHKA is induced in potassium depletion and mediates increased HCO3- reabsorption in terminal IMCD. The results further indicate that cHKA in vivo is sensitive to both SCH and ouabain.

Tubule function in transgenic mice

Many transporters involved in renal electrolyte transport have recently been identified and cloned. The availability of genetically manipulated mice, especially transgenic knockout and overexpression models, has made it possible to examine ion transport in kidney tubules in the absence of specific transporters whose function in defined tubule segments is well known. Such selective alterations in transport functions are also useful to investigate adaptive mechanisms by which the kidney compensates for specific transport lesions. Examples of mouse models displaying altered renal transport function include targeted disruption of genes encoding the Na-H exchanger isoforms NHE2 and NHE3, the thiazide-sensitive Na-Cl cotransporter TSC, CFTR, and the colonic isoform of the H,K-ATPase. Moreover, mice with null mutation in the Na-H exchanger isoform NHE1 have been also identified. In addition, a strain of mice with enhanced H,K-ATPase expression due to a defective endocytosis signal has been developed. Other transporter knockout models will soon become available. In this review we focus on the physiological characterization of renal tubule transport in animals with well-defined genetic transport lesions.

Functional expression of putative H+-K+-ATPase from guinea pig distal colon

A guinea pig cDNA encoding the putative colonic H+-K+-ATPase alpha-subunit (T. Watanabe, M. Sato, K. Kaneko, T. Suzuki, T. Yoshida, and Y. Suzuki; GenBank accession no. D21854) was functionally expressed in HEK-293, a human kidney cell line. The cDNA for the putative colonic H+-K+-ATPase was cotransfected with cDNA for either rabbit gastric H+-K+-ATPase or Torpedo Na+-K+-ATPase beta-subunit. In both expressions, Na+-independent, K+-dependent ATPase (K+-ATPase) activity was detected in the membrane fraction of the cells, with a Michaelis-Menten constant for K+ of 0.68 mM. The expressed K+-ATPase activity was inhibited by ouabain, with its IC50 value being 52 microM. However, the activity was resistant to Sch-28080, an inhibitor specific for gastric H+-K+-ATPase. The ATPase was not functionally expressed in the absence of the beta-subunits. Therefore, it is concluded that the cDNA encodes the catalytic subunit (alpha-subunit) of the colonic H+-K+-ATPase. Although the beta-subunit of the colonic H+-K+-ATPase has not been identified yet, both gastric H+-K+-ATPase and Na+-K+-ATPase beta-subunits were found to act as a surrogate for the colonic beta-subunit for the functional expression of the ATPase. The present colonic H+-K+-ATPase first expressed in mammalian cells showed the highest ouabain sensitivity in expressed colonic H+-K+-ATPases so far reported (rat colonic in Xenopus oocytes had an IC50 = 0.4-1 mM; rat colonic in Sf9 cells had no ouabain sensitivity).

Expression of HKalpha2 protein is increased selectively in renal medulla by chronic hypokalemia

Our laboratory has demonstrated by Northern analysis that chronic hypokalemia increases HKalpha2 (i.e., alpha-subunit of the colonic H+-K+-ATPase) mRNA abundance in the rat. To determine whether the increase in mRNA correlated with an increase in HKalpha2 protein, an antibody was raised against a synthetic peptide derived from amino acids 686-698 of the HKalpha2 sequence. The anti-HKalpha2 antibody hybridized to rat distal colon membranes which migrated at approximately 100 kDa (expected mobility of HKalpha2). HKalpha2 protein was not detected in plasma membranes from rat whole kidney or stomach (100 microg) derived from control animals. The antibody was then used to investigate changes in expression of HKalpha2 in renal cortex, renal medulla, and distal colon in two pathophysiological conditions: 1) chronic hypokalemia (LK) and 2) chronic metabolic acidosis (CMA). In LK rats there was a marked, but selective, increase in the abundance of HKalpha2 protein in membranes prepared from renal medulla. Nevertheless, a corresponding increase in HKalpha2 protein abundance was not observed in membranes prepared from the distal colon of LK rats. HKalpha2 protein abundance in CMA was indistinguishable from controls. Moreover, chronic hypokalemia had no effect on expression of alpha1-Na+-K+-ATPase or HKalpha1 in kidney or distal colon under any experimental condition. Therefore, HKalpha2 protein is tissue- and site-specifically upregulated in response to chronic hypokalemia but not by CMA. Furthermore, this regulatory response is localized to the renal medulla.

Structural aspects of the gastric H,K ATPase: the M5/M6 domain and alpha beta association

This review summarizes some of the structural information that has been obtained on the gastric H,K ATPase. Methods such as tryptic digestion, site specific labeling and in vitro translation combine to provide a ten membrane segment model with however reservations as to the full transmembrane nature of M5 or M6. Labeling this region with the thiophilic luminal face reagent omeprazole provided cogent evidence that cys 813 but not cys 822 was labeled. On the other hand, cysteine mutagenesis provided evidence that removal of cys 813 did not affect inhibition of Rb transport by omeprazole whereas removal of cys 822 although not affecting ATPase activity abolished omeprazole inhibition of transport. A model to reconcile these data is presented where M5 and M6 although intramembranal are not transmembrane hairpin structures. Analysis of the region of alpha beta interaction by tryptic digestion and WGA chromatography to define those fragments of alpha that remain beta associated shows that leu 853 to arg 922 in the TM7-loop are a major region of association with the beta subunit. Yeast two hybrid analysis, when combined with these data and those from a chimeric construct, indicates that the sequence Q 907 to R 922 is the important element of interaction in the alpha subunit and no other extracytoplasmic domain was found to interact. Two regions of the beta subunit interact with this region of the alpha subunit between Q64 and N130 as well as A156 and R188. Apparently the beta subunit is folded around a small region of the large extracytoplasmic loop between TM7 and TM8, closer to TM8.

Constitutive activation of gastric H+,K+-ATPase by a single mutation

In the reaction cycle of P-type ATPases, an acid-stable phosphorylated intermediate is formed which is present in an intracellularly located domain of the membrane-bound enzymes. In some of these ATPases, such as Na+,K+-ATPase and gastric H+, K+-ATPase, extracellular K+ ions stimulate the rate of dephosphorylation of this phosphorylated intermediate and so stimulate the ATPase activity. The mechanism by which extracellular K+ ions stimulate the dephosphorylation process is unresolved. Here we show that three mutants of gastric H+,K+-ATPase lacking a negative charge on residue 820, located in transmembrane segment six of the alpha-subunit, have a high SCH 28080-sensitive, but K+-insensitive ATPase activity. This high activity is caused by an increased 'spontaneous' rate of dephosphorylation of the phosphorylated intermediate. A mutant with an aspartic acid instead of a glutamic acid residue in position 820 showed hardly any ATPase activity in the absence of K+, but K+ ions stimulated ATPase activity and the dephosphorylation process. These findings indicate that the negative charge normally present on residue 820 inhibits the dephosphorylation process. K+ ions do not stimulate dephosphorylation of the phosphorylated intermediate directly, but act by neutralizing the inhibitory effect of a negative charge in the membrane.

The prokaryote-to-eukaryote transition reflected in the evolution of the V/F/A-ATPase catalytic and proteolipid subunits

Changes in the primary and quarternary structure of vacuolar and archaeal type ATPases that accompany the prokaryote-to-eukaryote transition are analyzed. The gene encoding the vacuolar-type proteolipid of the V-ATPase from Giardia lamblia is reported. Giardia has a typical vacuolar ATPase as observed from the common motifs shared between its proteolipid subunit and other eukaryotic vacuolar ATPases, suggesting that the former enzyme works as a hydrolase in this primitive eukaryote. The phylogenetic analyses of the V-ATPase catalytic subunit and the front and back halves of the proteolipid subunit placed Giardia as the deepest branch within the eukaryotes. Our phylogenetic analysis indicated that at least two independent duplication and fusion events gave rise to the larger proteolipid type found in eukaryotes and in Methanococcus. The spatial distribution of the conserved residues among the vacuolar-type proteolipids suggest a zipper-type interaction among the transmembrane helices and surrounding subunits of the V-ATPase complex. Important residues involved in the function of the F-ATP synthase proteolipid have been replaced during evolution in the V-proteolipid, but in some cases retained in the archaeal A-ATPase. Their possible implication in the evolution of V/F/A-ATPases is discussed.

Identification of the site of inhibition by omeprazole of a alpha-beta fusion protein of the H,K-ATPase using site-directed mutagenesis

The alpha subunit of eukaryotic P-type ATPases has ten experimentally defined transmembrane or membrane inserted segments. The fifth and sixth of these are short, not predicted by hydropathy analysis, do not insert independently into microsomal membranes, and are readily removed after tryptic digestion and therefore may be membrane inserted sequences. Acid transport by the gastric H, K-ATPase is covalently inhibited by several substituted pyridyl methylsulfinyl benzimidazoles, such as omeprazole. These act as probes of accessible extracytoplasmic thiols because they are accumulated in the acid transporting gastric vesicles and then convert to thiol reactive, cationic tetracyclic sulfenamides. Inhibition is due mainly to disulfide formation with Cys813 or Cys822 in M5/6 and perhaps with a contribution from Cys892 in the loop between transmembrane segment (TM) 7 and TM8. Identification of the specific cysteine responsible for inhibition should be able to define the turn between M5 and M6. The gastric H,K-ATPase alpha-beta heterodimer was expressed as a fusion protein in HEK 293 cells. Transient transfection resulted in most of the protein being retained in the endoplasmic reticulum with only core glycosylation and minor activity of the ATPase evident. Stable transfection resulted in plasma membrane localization of the protein and complex glycosylation. The transfected but not the control cells displayed cation-stimulated, SCH 28080-inhibited ATPase activity and SCH 28080- and omeprazole-inhibited 86Rb uptake. The two cysteines in M5/6 and Cys892 in the TM7/8 loop were mutated to the amino acids found in the Na,K-ATPase in order to determine which of the three cysteine residues were important for benzimidazole inhibition. Mutation of one, two, or all three cysteines did not alter enzyme activity, 86Rb transport, or SCH 28080 inhibition. Only removal of Cys822 blocked omeprazole inhibition of 86Rb transport. These data suggest that Cys822 is present in a region of the enzyme most easily accessed by the cationic sulfenamide formed by omeprazole, presumably the turn between M5 and M6.