Role of free radicals on mechanism of radiation nephropathy

Purpose: In our study, after applying a single dose of 612 cGy irradiation, we aimed to observe the role of free radicals on tissue damage in the kidney caused by radiation by measuring NO level, Na/K-ATPase activity and TBARS amount which is an indicator of free radical damage. On the other hand we investigated whether the tissue damage can be prevented by vitamin A or not. Materials and methods: This study was performed on three groups: 1. Control group 2. The group to which irradiation was administrated 3. The group which was given radiation + vitamin A. The irradiation group of animals were given a single dose of gamma irradiation at a sublethal dose. In the group which was administrated both irradiation + vitamin A, vitamin A was given for two days prior to irradiation. The amount of NO was measured by ESR spectroscopy, Na/K-ATPase and TBARS were measured by spectrophotometry. Results and conclusions: As a result of radiation mediated tissue damage in the kidney, we observed a NO loss, a decrease in Na/K-ATPase activitiy and an increase in TBARS amount. Although the administration of vitamin A before radiation, did not have any effect on NO loss and decrease in Na/K-ATPase.     

Stimulation-associated redistribution of Na,K-ATPase in rat lacrimal gland

Summary To test the possibility that stimulation of secretion leads Na,K-ATPase to be recruited from cytoplasmic pools and inserted into basal-lateral plasma membranes, we surveyed the subcellular distributions of Na, K-ATPase in resting and stimulated fragments of rat exorbital lacrimal gland. After a two-dimensional separation procedure based on differential sedimentation and density gradient centrifugation, we defined sixdensity windows, which differ from one another in their contents of biochemical markers. The membranes equilibrating inwindow I could be identified as a sample of basal-lateral membranes; in resting preparations these membranes contained Na,K-ATPase enriched 16.6-fold with respect to the initial homogenates.Windows II throughVI contained various cytoplasmic membrane populations; these accounted for roughly 80% of the total recovered Na,K-ATPase activity. Thirty-minute stimulation with 10 m carbachol caused a 1.4-fold increase (P<0.05) in the total Na,K-ATPase content ofwindow I; this increase could be largely accounted for by a 1.7-fold decrease in the total Na,K-ATPase content ofdensity window V. Acid phosphatase activity also redistributed following stimulation, but it was recruited from a different source, and it was inserted into membranes equilibrating inwindows II andIII as well as into the membranes ofwindow I.     

Palytoxin Acts on Na+,K+-ATPase but not Nongastric H+,K+-ATPase

Palytoxin (PTX) opens a pathway for ions to pass through Na,K-ATPase. We investigate here whether PTX also acts on nongastric H,K-ATPases. The following combinations of cRNA were expressed in Xenopus laevis oocytes: Bufo marinus bladder H,K-ATPase α₂- and Na,K-ATPase β₂-subunits; Bufo Na,K-ATPase α₁- and Na,K-ATPase β₂-subunits; and Bufo Na,K-ATPase β₂-subunit alone. The response to PTX was measured after blocking endogenous Xenopus Na,K-ATPase with 10 μm ouabain. Functional expression was confirmed by measuring ⁸⁶Rb uptake. PTX (5 nm) produced a large increase of membrane conductance in oocytes expressing Bufo Na,K-ATPase, but no significant increase occurred in oocytes expressing Bufo H,K-ATPase or in those injected with Bufo β₂-subunit alone. Expression of the following combinations of cDNA was investigated in HeLa cells: rat colonic H,K-ATPase α₁-subunit and Na,K-ATPase β₁-subunit; rat Na,K-ATPase α₂-subunit and Na,K-ATPase β₂-subunit; and rat Na,K-ATPase β₁- or Na,K-ATPase β₂-subunit alone. Measurement of increases in ⁸⁶Rb uptake confirmed that both rat Na,K and H,K pumps were functional in HeLa cells expressing rat colonic HKα₁/NKβ₁ and NKα₂/NKβ₂. Whole-cell patch-clamp measurements in HeLa cells expressing rat colonic HKα₁/NKβ₁ exposed to 100 nm PTX showed no significant increase of membrane current, and there was no membrane conductance increase in HeLa cells transfected with rat NKβ₁- or rat NKβ₂-subunit alone. However, in HeLa cells expressing rat NKα₂/NKβ₂, outward current was observed after pump activation by 20 mm K⁺ and a large membrane conductance increase occurred after 100 nm PTX. We conclude that nongastric H,K-ATPases are not sensitive to PTX when expressed in these cells, whereas PTX does act on Na,K-ATPase.     

Phosphorylation of the alpha-subunit of Na,K-ATPase from duck salt glands by cAMP-dependent protein kinase inhibits the enzyme activity

Although it was shown earlier that phosphorylation of Na,K-ATPase by cAMP-dependent protein kinase (PKA) occurs in intact cells, the purified enzyme in vitro is phosphorylated by PKA only after treatment by detergent. This is accompanied by an unfortunate side effect of the detergent that results in complete loss of Na,K-ATPase activity. To reveal the effect of Na,K-ATPase phosphorylation by PKA on the enzyme activity in vitro, the effects of different detergents and ligands on the stoichiometry of the phosphorylation and activity of Na,K-ATPase from duck salt glands (11-isoenzyme) were comparatively studied. Chaps was shown to cause the least inhibition of the enzyme. In the presence of 0.4% Chaps at 1 : 10 protein/detergent ratio in medium containing 100 mM KCl and 0.3 mM ATP, PKA phosphorylates serine residue(s) of the Na,K-ATPase with stoichiometry 0.6 mol P_i/mol of -subunit. Phosphorylation of Na,K-ATPase by PKA in the presence of the detergent inhibits the Na,K-ATPase. A correlation was found between the inclusion of P_i into the -subunit and the loss of activity of the Na,K-ATPase.     

Human myocardial Na,K-ATPase concentration in heart failure

The Na,K-ATPase is of major importance for active ion transport across the sarcolemma and thus for electrical as well as contractile function of the myocardium. Furthermore, it is receptor for digitalis glycosides. In human studies of the regulatory aspects of myocardial Na,K-ATPase concentration a major problem has been to obtain tissue samples. Methodological accomplishments in quantification of myocardial Na,K-ATPase using vanadate facilitated ³H-ouabain binding to intact samples have, however, made it possible to obtain reliable measurements on human myocardial necropsies obtained at autopsy as well as on biopsies of a wet weight of only 1–2 mg obtained during heart catheterisation. However, access to the ultimately, normal, vital myocardial tissue has come from the heart transplantation programs, through which myocardial samples from cardiovascular healthy organ donors have become available. In the present paper we evaluate the various values reported for normal human myocardial Na,K-ATPase concentration, its regulation in heart disease and the association with digitalization. Normal myocardial Na,K-ATPase concentration level is found to be 700 pmol/g wet weight. No major variations were found between or within the walls of the heart ventricles. During the first few years of life a marked decrease in myocardial Na,K-ATPase concentration is followed by a stable level obtained in early adulthood and normally maintained throughout life. In patients with enlarged cardiac x-ray silhouette a significant positive, linear correlation between left ventricular ejection fraction (EF) and Na,K-ATPase concentration was established. A maximum reduction in Na,K-ATPase concentration of 89% was obtained when EF was reduced to 20%. Generally, heart failure associated with heart dilatation, myocardial hypertrophy as well as ischaemic heart disease is associated with reductions in myocardial Na,K-ATPase concentration of around 25%. During digoxin treatment of heart failure patients a further reduction in functional myocardial Na,K-ATPase concentration of 15% has been found. Thus, the total reduction in functional myocardial Na,K-ATPase concentration in digitalised heart failure patients may well be of the magnitude 40%. In conclusion, it has become possible to quantify human myocardial Na,K-ATPase in health and disease. Revealed reductions are in heart failure of importance for contractile function, generation of arrhythmia and for digoxin treatment.     

Subcellular distribution of tissue kallikrein and Na,K-ATPase α-subunit in rat parotid striated duct cells

Intracellular protein distribution and sorting were examined in rat parotid striated duct cells, in which tissue kallikrein is apical, and Na,K-ATPase is basolateral. Electron-microscopic immunogold cytochemistry, with both polyclonal and monoclonal antibodies, demonstrated these enzymes at opposite poles of the cells and in distinct intracellular sites. Kallikrein was found within apical secretory granules, whereas Na,K-ATPase was present on basolateral cell membranes. In addition, kallikrein was localized throughout cisternae of all Golgi profiles, whereas Na,K-ATPase (-subunit) was found only in small peripheral vesicles and/or lateral cisternal extensions of a basal subset of Golgi profiles. These differences in the subcellular distribution of the two marker antigens were most clearly seen with double immunogold labelling. Our results suggest that kallikrein, an apical, regulated secretory protein, and Na,K-ATPase, a basolateral, constitutively transported membrane protein, are segregated at (or prior to) the level of the Golgi apparatus rather than in the trans-Golgi network (TGN), as was expected.Abbreviations ATP adenosine tri-phosphate - HBSS Hanks' balanced salt solution - GaM goat anti-mouse - GaR goat anti-rabbit - PBS phosphate-buffered saline - RaM rabbit anti-mouse - RER rough endoplasmic reticulum - TGN trans-Golgi network     

Regulation of Na,K-ATPase during acute lung injury

A hallmark of acute lung injury is the accumulation of a protein rich edema which impairs gas exchange and leads to hypoxemia. The resolution of lung edema is effected by active sodium transport, mostly contributed by apical Na⁺ channels and the basolateral located Na,K-ATPase. It has been reported that the decrease of Na,K-ATPase function seen during lung injury is due to its endocytosis from the cell plasma membrane into intracellular pools. In alveolar epithelial cells exposed to severe hypoxia, we have reported that increased production of mitochondrial reactive oxygen species leads to Na,K-ATPase endocytosis and degradation. We found that this regulated process follows what is referred as the Phosphorylation–Ubiquitination–Recognition–Endocytosis–Degradation (PURED) pathway. Cells exposed to hypoxia generate reactive oxygen species which activate PKCζ which in turn phosphorylates the Na,K-ATPase at the Ser18 residue in the N-terminus of the α1-subunit leading the ubiquitination of any of the four lysines (K16, K17, K19, K20) adjacent to the Ser18 residue. This process promotes the α1-subunit recognition by the μ2 subunit of the adaptor protein-2 and its endocytosis trough a clathrin dependent mechanism. Finally, the ubiquitinated Na,K-ATPase undergoes degradation via a lysosome/proteasome dependent mechanism.     

Expression of the Avian Na,K-ATPase Subunits in Dictyostelium discoideum

This study explored whether Dictyostelium discoideum can be used to express the avian Na,K-ATPase, a heterodimeric membrane protein. Dictyostelium was able to express mRNAs encoding the avian Na,K-ATPase subunits. However, Dictyostelium expressed avian Na,K-ATPase protein when only when a Dictyostelium consensus ribosomal binding sequence, AAAATAAA, was inserted in front of the open reading frames of the α₁- and β₁-subunit cDNAs and the first eight codons following the start-translation codons were changed to Dictyostelium preferred codons. These modified mRNAs appeared to be much less stable than the forms that were not readily translated. Dictyostelium could express the avian β-subunit alone but only expressed the α₁-subunit when the β₁-subunit was co-expressed. Subunit assembly occurred in cells expressing both α₁- and β₁-subunits. The bulk of the exogenously expressed sodium pump subunits remained in an intracellular compartment, presumed to be the endoplasmic reticulum. Dictyostelium exported little or no Na,K-ATPase or free β-subunit to the plasma membrane. Received: 7 July 1998/Revised: 8 October 1998     

Na/K-ATPase under Oxidative Stress: Molecular Mechanisms of Injury

1. The authors compare oxidative injury to brain and kidney Na/K-ATPase using in vitro and in vivo approaches. The substrate dependence of dog kidney Na/K-ATPase was examined both before and after partial hydrogen peroxide modification. A computer simulation model was used for calculating kinetic parameters.2. The substrate dependence curve for the unmodified endogenous enzyme displayed a typical curve with an intermediate plateau, adequately described by the sum of hyperbolic and sigmoidal components.3. The modified enzyme demonstrated a dependent curve that closely approximates normal hyperbola. The estimated ATP K _m value for the endogenous enzyme was about 85 M; the K _h was equal to 800 M. The maximal number of protomers interacting was 8. Following oxidative modification, the enzyme substrate dependence curve did not show a significant change in the maximal protomer rate V _m, while the K _m was increased slightly and interprotomer interaction was abolished.4. Na/K-ATPase from an ischemic gerbil brain showed a 22% decrease in specific activity. The maximal rate of ATP hydrolysis by an enzyme protomer changed slightly, but the sigmoidal component, characterizing the enzyme's ability to form oligomers was abolished completely. The K _m value was almost unchanged, but the Hill coefficient fell to 1. These data show that Na/K-ATPase molecules isolated from the ischemic brain have lost the ability to interact with one another.5. We suggest that the most important consequence of oxidative modification is Na/K-ATPase oligomeric structure formation and subsequent hydrolysis rate suppression.     

Vanadate-induced inhibition of renin secretion is unrelated to inhibition Na,K-ATPase activity

There is evidence that three inhibitors of Na,K-ATPase activity--ouabain, K-free extracellular fluid, and vanadate--inhibit renin secretion by increasing Ca2+ concentration in juxtaglomerular cells, but in the case of vanadate, it is uncertain whether the increase in Ca2+ is due to a decrease in Ca2+ efflux (inhibition of Ca-ATPase activity, or inhibition of Na,K-ATPase activity, followed by an increase in intracellular Na+ and a decrease in Na-Ca exchange) or to an increase in Ca2+ influx through potential operated Ca channels (inhibition of electrogenic Na,K transport, followed by membrane depolarization and activation of Ca channels). In the present experiments, the rat renal cortical slice preparation was used to compare and contrast the effects of ouabain, of K-free fluid, and of vanadate on renin secretion, in the absence and presence of methoxyverapamil, a Ca channel blocker. Basal renin secretory rate averaged 7.7 +/- 0.3 GU/g/60 min, and secretory rate was reduced to nearly zero by 1 mM ouabain, by K-free fluid, by 0.5 mM vanadate, and by K-depolarization (increasing extracellular K+ to 60 mM). Although 0.5 microM methoxyverapamil completely blocked the inhibitory effect of K-depolarization, it failed to antagonize the inhibitory effects of ouabain, of K-free fluid, and of vanadate. A concentration of methoxyverapamil two hundred times higher (100 microM) completely blocked the inhibitory effects of vanadate, but still failed to antagonize the effects of ouabain and of K-free fluid. Collectively, these observations demonstrate that vanadate-induced inhibition of renin secretion cannot be attributed entirely to Na,K-ATPase inhibition, since in the presence of methoxyverapamil, the effect of vanadate differed from the effects of either ouabain (a specific Na,K-ATPase inhibitor) or K-free fluid. Moreover, it cannot be attributed entirely to a depolarization-induced influx of Ca2+ through potential-operated Ca channels, since methoxyverapamil antagonized K-depolarization-induced inhibition of renin secretion much more effectively than it antagonized vanadate-induced inhibition.     

Interaction of hypothalamic Na,K-ATPase inhibitor with isolated human peripheral blood mononuclear cells

A ligand for the digitalis receptor located on the membrane-embedded Na,K-ATPase (NKA; EC 3.6.1.37) has been isolated from bovine hypothalamus (hypothalamic inhibitory factor; HIF) and identified as isomeric ouabain (Tymiaket al, 1993,Proc. Natl. Acad. Sci. 90: 8189–8193). In analogy to cardioactive steroids (CS) derived from plants or from toad, HIF inhibits the Na/K-exchange process and the ATPase activity of isolated Na,K-ATPase although by a different molecular action mechanism. In the present work we show that, as plant-derived ouabain, HIF inhibits⁸⁶Rb-uptake by isolated human lymphocytes with an IC₅₀ of about 20 nM; above this concentration HIF reduces cell viability in contrast to ouabain. The decrease in cell viability by excess HIF is accompanied by discrete morphological alterations (mitochondrial swelling) visible by transmission electron microscopy of ultra-thin sectioned peripheral blood mononuclear cells. Taken together the results show that the hypothalamic NKA inhibitor blocks NKA of isolated human lymphocytes with high potency at nanomolar concentrations without toxicity; concentrations exceeding the ones required to block⁸⁶Rb-uptake reduce cell viability, probably due to leak formation across the NKA molecule. Thus, lymphocytes constitute a potential target for HIF action and by their altered NKA status a possible messenger between the nervous and the immune system.Abbreviations D-PBS Dulbecco's phosphate buffered saline - HBSS Hank's balanced salt Solution - NKA Na,K-ATPase     

Polarized membrane distribution of potassium-dependent ion pumps in epithelial cells: Different roles of the <Emphasis Type="Italic">N</Emphasis>-glycans of their <Emphasis Type="Italic">β</Emphasis> subunits

The Na,K-ATPases and the H,K-ATPases are two potassium-dependent homologous heterodimeric P₂-type pumps that catalyze active transport of Na⁺ in exchange for K⁺ (Na,K-ATPase) or H⁺ in exchange for K⁺ (H,K-ATPase). The ubiquitous Na,K-ATPase maintains intracellular ion balance and membrane potential. The gastric H,K-ATPase is responsible for acid secretion by the parietal cell of the stomach. Both pumps consist of a catalytic α-subunit and a glycosylated β-subunit that is obligatory for normal pump maturation and trafficking. Individual N-glycans linked to the β-subunits of the Na,K-ATPase and H,K-ATPase are important for stable membrane integration of their respective α subunits, folding, stability, subunit assembly, and enzymatic activity of the pumps. They are also essential for the quality control of unassembled β-subunits that results in either the exit of the subunits from the ER or their ER retention and subsequent degradation. Overall, the importance of N-glycans for the␣maturation and quality control of the H,K-ATPase is greater than that of the Na,K-ATPase. The roles of individual N-glycans of the β-subunits in the post-ER trafficking, membrane targeting and plasma membrane retention of the Na,K-ATPase and H,K-ATPase are different. The Na,K-ATPase β ₁-subunit is the major β-subunit isoform in cells with lateral location of the pump. All three N-glycans of the Na,K-ATPase β ₁-subunit are important for the lateral membrane retention of the pump due to glycan-mediated interaction between the β ₁-subunits of the two neighboring cells in the cell monolayer and cytosolic linkage of the α-subunit to the cytoskeleton. This intercellular β ₁–β ₁ interaction is also important for formation of cell–cell contacts. In contrast, the N-glycans unique to the Na,K-ATPase β ₂-subunit,which has up to eight N-glycosylation sites, contain apical sorting information. This is consistent with the apical location of the Na,K-ATPase in normal and malignant epithelial cells with high abundance of the β ₂-subunit. Similarly, all seven N-glycans of the gastric H,K-ATPase β-subunit determine apical sorting of this subunit. Supported in part by NIH grants DK46917, DK58333, D53642, and USVA     

The influence of Lyn kinase on Na,K-ATPase in porcine lens epithelium

Na,K-ATPase is essential for the regulation of cytoplasmic Na⁺ and K⁺ levels in lens cells. Studies on the intact lens suggest activation of tyrosine kinases may inhibit Na,K-ATPase function. Here, we tested the influence of Lyn kinase, a Src-family member, on tyrosine phosphorylation and Na,K-ATPase activity in membrane material isolated from porcine lens epithelium. Western blot studies indicated the expression of Lyn in lens cells. When membrane material was incubated in ATP-containing solution containing partially purified Lyn kinase, Na,K-ATPase activity was reduced by 38%. Lyn caused tyrosine phosphorylation of multiple protein bands. Immunoprecipitation and Western blot analysis showed Lyn treatment causes an increase in density of a 100-kDa phosphotyrosine band immunopositive for Na,K-ATPase ₁ polypeptide. Incubation with protein tyrosine phosphatase 1B (PTP-1B) reversed the Lyn-dependent tyrosine phosphorylation increase and the change of Na,K-ATPase activity. The results suggest that Lyn kinase treatment of a lens epithelium membrane preparation is able to bring about partial inhibition of Na,K-ATPase activity associated with tyrosine phosphorylation of multiple membrane proteins, including the Na,K-ATPase ₁ catalytic subunit. lens; Na,K-ATPase; tyrosine phosphorylation; Lyn     

Fatty Acid-Induced Modulation of Ouabain Responsiveness of Rat Na,K-ATPase Isoforms

Membrane phospholipids represent a potential influence on the enzymatic properties of the Na,K-ATPase. Little is known concerning the effects of the fatty acid environment surrounding the enzyme on the kinetic properties of the Na,K-ATPase. We used the most obvious difference among the α isoforms of rat, their affinities for digitalis glycosides, to examine the relationship between the lipid environment and the Na,K-ATPase. Specific membrane environments that differ in their fatty acid composition were produced by drug-induced diabetes, as well as variations in diet. The α1 isoforms in various tissues were then characterized by their resistance to ouabain in Na,K-ATPase-enriched membrane microsomal fractions. The Na,K-ATPase activity in nerves and hearts were altered by diabetes and partially restored in nerves after a fish oil diet. Evaluation of enzyme kinetics (dose-response curves for ouabain) in membrane preparations allowed us to correlate the ouabain affinity of α1 isoform with fatty acid composition. The affinity of the α1 isoform for ouabain was significantly increased with accretions in the total amount of fatty acids of the n-6 series (P < 0.0001). Our observations provide a partial explanation for the observed difference in isoform properties among tissues. Moreover, these results underline the interaction between membrane fatty acids and the glycoside binding site of the Na,K-ATPase α1 subunit. Received: 15 June 1998/Revised: 18 November 1998     

Fluctuation driven transport and models of molecular motors and pumps

Non-equilibrium fluctuations can drive vectorial transport along an anisotropic structure in an isothermal medium by biasing the effect of thermal noise (k _B T). Mechanisms based on this principle are often called Brownian ratchets and have been invoked as a possible explanation for the operation of biomolecular motors and pumps. We discuss the thermodynamics and kinetics for the operation of microscopic ratchet motors under conditions relevant to biology, showing how energy provided by external fluctuations or a non-equilibrium chemical reaction can cause unidirectional motion or uphill pumping of a substance. Our analysis suggests that molecular pumps such as Na,K-ATPase and molecular motors such as kinesin and myosin may share a common underlying mechanism. Received: 18 February 1998 / Revised version: 5 May 1998 / Accepted: 14 May 1998     

Major organ-specific glycoproteins in isolated brain and kidney membranes identified as Na,K-ATPase subunits by combined glycan-, lectin-, and immunoblotting

In the present work combined glycan-, lectin-, and immunoblotting of isolated brain and kidney membranes shows that the and subunits of Na,K-ATPase are the most abundant glycoproteins. Further,Datura stramonium andGalanthus nivalis agglutinins recognize the Na,K-ATPase subunits in a mutually exclusive manner in membranes from human, rabbit and rat brain or human, rabbit, rat, pig and dog kidney indicating the presence of species-independent organ-typical glycoforms. The glycosylation status is not related to the ouabain-sensitivity. Taken together, the data reveals organ-specific glycoforms of Na,K-ATPase which might have roles for organ identification and recognition.Abbreviations NKA Na,K-ATPase (EC 3.6.1.37) - PAGE polyacrylamide gel electrophoresis in dodecylsulfate - Con-A Concanavalin A - DSA Datura stramonium agglutinin - GNA Galanthus nivalis agglutinin - MAA Maackia amurensis agglutinin - PNA Peanut agglutinin - SNA Sambucus nigra agglutinin - WGA Wheat germ agglutinin Abbreviations used in figures K kidney - B brain - Cr Crude - De Detergent-treated - Fe fetuin - Ct creatinase - I-blot immuno-blot - L-blot lectin-blot