Effect of Fe3+ on Na,K-ATPase: Unexpected activation of ATP hydrolysis

Iron is a key element in cell function; however, its excess in iron overload conditions can be harmful through the generation of reactive oxygen species (ROS) and cell oxidative stress. Activity of Na,K-ATPase has been shown to be implicated in cellular iron uptake and iron modulates the Na,K-ATPase function from different tissues. In this study, we determined the effect of iron overload on Na,K-ATPase activity and established the role that isoforms and conformational states of this enzyme has on this effect. Total blood and membrane preparations from erythrocytes (ghost cells), as well as pig kidney and rat brain cortex, and enterocytes cells (Caco-2) were used. In E1-related subconformations, an enzyme activation effect by iron was observed, and in the E2-related subconformations enzyme inhibition was observed. The enzyme's kinetic parameters were significantly changed only in the Na⁺ curve in ghost cells. In contrast to Na,K-ATPase α2 and α3 isoforms, activation was not observed for the α1 isoform. In Caco-2 cells, which only contain Na,K-ATPase α1 isoform, the FeCl₃ increased the intracellular storage of iron, catalase activity, the production of H₂O₂ and the expression levels of the α1 isoform. In contrast, iron did not affect lipid peroxidation, GSH content, superoxide dismutase and Na,K-ATPase activities. These results suggest that iron itself modulates Na,K-ATPase and that one or more E1-related subconformations seems to be determinant for the sensitivity of iron modulation through a mechanism in which the involvement of the Na, K-ATPase α3 isoform needs to be further investigated.     

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.     

Involvement of Na/K-ATPase in hydrogen peroxide-induced activation of the Src/ERK pathway in LLC-PK1 cells

We have shown that Na/K-ATPase interacts with Src. Here, we test the role of this interaction in H₂O₂-induced activation of Src and ERK. We found that exposure of LLC-PK1 cells to H₂O₂ generated by the addition of glucose oxidase into the culture medium activated Src and ERK1/2. It also caused a modest reduction in the number of surface Na/K-ATPases and in ouabain-sensitive Rb⁺ uptake. These effects of H₂O₂ seem similar to those induced by ouabain, a specific ligand of Na/K-ATPase, in LLC-PK1 cells. In accordance, we found that the effects of H₂O₂ on Src and ERK1/2 were inhibited in α1 Na/K-ATPase-knockdown PY-17 cells. Whereas expression of wild-type α1 or the A420P mutant α1 defective in Src regulation rescued the pumping activity in PY-17 cells, only α1, and not the A420P mutant, was able to restore the H₂O₂-induced activation of protein kinases. Consistent with this, disrupting the formation of the Na/K-ATPase/Src complex with pNaKtide attenuated the effects of H₂O₂ on the kinases. Moreover, a direct effect of H₂O₂ on Na/K-ATPase-mediated regulation of Src was demonstrated. Finally, H₂O₂ reduced the expression of E-cadherin through the Na/K-ATPase/Src-mediated signaling pathway. Taken together, the data suggest that the Na/K-ATPase/Src complex may serve as one of the receptor mechanisms for H₂O₂ to regulate Src/ERK protein kinases and consequently the phenotype of renal epithelial cells.     

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.     

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     

Probable involvement of sulfhydryl groups and a metal as essential components of the cellulase of Clostridium thermocellum

The crude extracellular cellulase from Clostridium thermocellum was oxidatively inactivated by air and inhibited by sulfhydryl reagents. Activity-loss was prevented and reversed by the addition of a high concentration (10 mM) dithiothreitol (DDT) at zero time and up to 24 h respectively. In the presence of a low concentration (0.4 mM) of DTT, the enzyme was more rapidly inactivated than in air alone. This was probably due to autoxidation of the low DTT concentration to H₂O₂ as shown by its prevention by a high DTT concentration, exclusion of air, or catalase; and by the oxidative inactivation of the enzyme by H₂O₂. The inactivation by H₂O₂ could be prevented by a high concentration of DTT but not by air exclusion. EDTA protected the enzyme from inactivation in air by a low concentration of DTT or by H₂O₂. This is presumably due to the role of metals in oxidation of SH groups. Furthermore, copper (5 M) also caused inactivation and this was prevented by the presence of a high DTT concentration. Even in the protective atmosphere of a high DTT concentration, cellulase was inactivated by certain apolar chelating agents such as o-phenanthroline and -¹-dipyridyl, such inactivation being preventable by the prior incubation of the chelator with a mixture of Fe²⁺ and Fe³⁺. These data suggest that the clostridial cellulase, unlike the enzyme from aerobic fungi, contains essential sulfhydryl groups and is stimulated by iron. The endo--glucanase component of the cellulase complex was not susceptible to oxidative inactivation.Abbreviations DTT dithiothreitol - CMC carboxymethylcellulose - DTNB 5,5-dithiobis-(2-nitrobenzoic acid) - NEM N-ethylmaleimide - p-CMB p-chloromercuribenzoic acid     

Isoforms of Na,K-ATPase inArtemia salina: II. Tissue distribution and kinetic characterization

Summary To characterize the molecular properties conveyed by the isoforms of the subunit of Na,K-ATPase, the two major transepithelial transporting organs in the brine shrimp (Artemia salina), the salt glands and intestines, were isolated in pure form. The isoforms were quantified by ATP-sensitive fluorescein isothiocyanate (FITC) labeling. The salt gland enzyme exhibits only the 1 isoform, whereas the intestinal enzyme exhibits both the 1 and the 2 isoforms. After 32 hours of development, Na,K-ATPase activity [in mol P_i/mg protein/hr (1u)] in whole homogenates was 32±6 in the salt glands and 12±3 in the intestinal preparations (mean±sem). The apparent half-maximal activation constants (K _1/2) of the salt gland enzyme as compared to the intestinal enzyme were 3.7±0.6mm vs. 23.5±4mm (P<0.01) for Na⁺, 16.6±2.2mm vs. 8.29±1.5mm for K⁺ (P<0.01), and 0.87±0.8mm vs. 0.79±1.1mm for ATP (NS). The apparentK _i's for ouabain inhibition were 1.1×10^–4 m vs. 2×10^–5 m, respectively. Treatment of whole homogenates with deoxycholic acid (DOC) produced a maximal Na,K-ATPase activation of 46% in the salt gland as compared to 23% in the intestinal enzyme. Similar differences were found with sodium dodecyl sulfate (SDS). The two distinct forms of Na,K-ATPase isolated from the brine shrimp differed markedly in three kinetic parameters as well as in detergent sensitivity. The differences inK _1/2 for Na⁺ and K⁺ are more marked than those reported for the mammalian Na,K-ATPase isoforms. These differences may be attributed to the relative abundances of the subunit isoforms; other potential determinants (e.g. differences in membrane lipids), however, have not been investigated.During the tenure of an Educational Commission For Foreign Medical Graduates Visiting Associate Professorship.     

Assessment of the antimicrobial,antioxidant and cytotoxic activities of the wild edible mushroom <Emphasis Type="Italic">Agaricus lanipes</Emphasis> (F.H. Møller &amp; Jul. Schäff.) Hlaváček

The present investigation was undertaken to evaluate the antimicrobial and antioxidant activities of the wild edible mushroom Agaricus lanipes, and also to investigate its cytotoxicity and potential and possible apoptotic effect against the A549 lung cancer cell line in in vitro conditions. Total antioxidant capacity, total phenolic content, total oxidant status, total antioxidant status, lipid hydroperoxides, and total free –SH levels of A. lanipes were found to be 4.55 mg T/g, 14.6 mg GA equivalent/g, 3.10 mg H₂O₂ equivalent/g, 2.25 mg H₂O₂ equivalent/g, and 1.90 µmol/g, respectively. The methanolic extract of A. lanipes had relatively strong antimicrobial activity against seven tested microorganism strains. It also had high anti-proliferative potency and strong pro-apoptotic effects, and this mushroom used as a daily nutrient could be a source for new drug developments and treatment in cancer therapies, and could be a guide for studies in this area.     

Effect of clotrimazole on the pump cycle of the Na,K-ATPase

The effect of the antimycotic drug clotrimazole (CLT) on the Na,K-ATPase was investigated using fluorescence and electrical measurements. The results obtained by steady-state fluorescence experiments with the electrochromic styryl dye RH421 were combined with those achieved by a pre-steady-state method based on fast solution exchange on a solid supported membrane that adsorbs the protein. Both techniques are suitable for monitoring the electrogenic steps of the pump cycle and are in general complementary, yielding distinct kinetic information. The experiments show clearly that CLT affects specific partial reactions of the pump cycle of the Na,K-ATPase with an affinity in the low micromolar range and in a reversible manner. All results can be consistently explained by proposing the CLT-promoted formation of an ion-occluded-CLT-bound conformational E₂ state, that acts as a “dead-end” side track of the pump cycle, where X stands for H⁺ or K⁺. Na⁺ binding, enzyme phosphorylation, and Na⁺ transport were not affected by CLT, and at high CLT concentrations of the enzyme remained active in the physiological transport mode. The presence of Na⁺ and K⁺ destabilized the inactivated form of the Na,K-ATPase.     

Na,K-ATPase in several tissues of the rat: Tissue-specific expression of subunit mRNAs and enzyme activity

Summary The relative contents of Na,K-ATPase subunit mRNAs in rat renal cortex; ventricular myocardium, skeletal muscle (hind limb), liver and brain (cerebrum) were measured. Expressed per unit DNA, mRNA₁ content was 2-fold greater in the kidney and brain as compared to either heart, skeletal muscle or liver. The hierarchy of mRNA₂ expression was brain > skeletal muscle > heart, whereas mRNA₃ was restricted to brain. Betal subunit mRNA content in both kidney and brain exceeded the abundance of liver mRNA ₁ by 7-fold. In all tissues examined, the combined abundances of the alpha subunit mRNAs exceeded the content of mRNA ₁ The hierarchy of Na,K-ATPase activity expressed per unit. DNA was brain > kidney > skeletal muscle = heart > liver. The sum of mRNA as well as mRNA ₁ content, expressed per g of tissue, was highest in brain and kidney. A statistically significant correlation between mRNA ₁ content and Na,K-ATPase activity was evident.     

Role of Nitric Oxide and Hydrogen Peroxide During the Salt Resistance Response

Ion homeostasis is essential for plant cell resistance to salt stress. Under salt stress, to avoid cellular damage and nutrient deficiency, plant cells need to maintain adequate K nutrition and a favorable K to Na ratio in the cytosol. Recent observations revealed that both nitric oxide (NO) and hydrogen peroxide (H₂O₂) act as signaling molecules to regulate K to Na ratio in calluses from Populus euphratica under salt stress. Evidence indicated that NO mediating H₂O₂ causes salt resistance via the action of plasma membrane H⁺-ATPase but that activity of plasma membrane NADPH oxidase is dependent on NO. Our study demonstrated the signaling transduction pathway. In this addendum, we proposed a testable hypothesis for NO function in regulation of H₂O₂ mediating salt resistance.Key Words: hydrogen peroxide, nitric oxide, signaling molecule, salt resistanceUnder salinity conditions, tolerant plant cells achieve ion homeostasis by extruding Na to the external medium and/or compartmentalizing into vacuoles, maintaining K uptake and high K and low Na in the cytosol.^1,2 Control of Na movement across the plasma membrane (PM) and tonoplast in order to maintain a low Na concentration in the cytoplasm is a key factor of cellular adaptation to salt stress.^3,4 Na transport across the PM is dependent on the electrochemical gradient created by the PM H⁺-ATPase.^5,6 It has been proven that the activity of the PM H⁺-ATPase is a key index of plant adaptation to salt stress.⁷ Therefore, the regulation of expression of the PM H⁺-ATPase may represent an important cellular mechanism for salt resistance. In contrast to our understanding of the regulation of PM H⁺-ATPase by other factors, the roles of NO and H₂O₂ act as signals under salt stress have been less known.Previous studies have shown that both NO and H₂O₂ function as stress signals in plants, mediating a range of resistance mechanisms in plants under stress conditions.^8–10 We have previously shown that NO serves as a signal in inducing salt resistance by increasing the K to Na ratio, which is dependent on the increased PM H⁺-ATPase activity in calluses from reed.¹¹ Although NO acts as a signal molecule under salt stress and induces salt resistance by increasing PM H⁺-ATPase activity, our research results also indicated NO can not activate purified PM H⁺-ATPase activity, at least in vitro. Subsequently, we set out to find the other signal molecules and factors between NO and PM H⁺-ATPase activity. Since our studies have indicated that NO can not induce salt resistance directly, what roles dose it play in salt resistance in tolerant cells under salt stress? We initially hypothesized ABA or H₂O₂ might be downstream signal molecules to regulate the activity of PM H⁺-ATPase. Further results indicated H₂O₂ content increased greatly under salt stress. Since H₂O₂ might be the candidate downstream signal molecule, we tested PM H⁺-ATPase activity and K to Na ratio in calluses by adding H₂O₂. The results suggested that H₂O₂ inducing an increased PM H⁺-ATPase activity resulted in an increased K to Na ratio. Summing up this new assay that allows us to speculate NO maybe regulate the H₂O₂ generation.Since H₂O₂ is involved in downstream signal molecule of NO, PM NADPH oxidase, the main source of H₂O₂ production, might be the regulated target of NO. We took a pharmacological approach to examine the speculation. The results indicated that PM NADPH oxidase is required for H₂O₂ accumulation and PM NADPH oxidase activity could attribute to NO in calluses under salt stress. These results also raised another question regarding what concentrations of NO can induce such effects. In our experiments, NO content was induced 1.6 times higher than the control values under salt treatment. We speculated there exists an effective balance point in NO signal system similar to previous reports by Delledonne et al.¹² in disease resistance.Further research work is required to decipher the mechanism through which NO and H₂O₂ acts and how K and Na elements uptake might be connected with salt resistance. We would like to propose a simple testable model that accounts for the results reported in this paper (Fig. 1). According to our model, H₂O₂ rather than NO is the major signaling molecular that mediated directly PM H⁺-ATPase under salt stress. Normally, NO generated from nitric oxide synthase (NOS) acts as a signal molecule to regulate other mechanisms. Under salt stress, accumulated NO activates PM NADPH oxidase activity. Then, a number of H₂O₂ is produced from PM NADPH oxidase. The PM H⁺-ATPase is activated greatly by the accumulated H₂O₂. Eventually, the transmembrane electrochemical gradient is created and K to Na ratio increases. The model we have proposed here is testable and should provide further insights into salt resistance mechanism regulated by NO and H₂O₂ signal molecules.Open in a separate windowFigure 1Hypothetical model for the potential function of NO and H₂O₂ as signaling molecules in inducing salt resistance. Salt stress activates a signal transduction cascade that leads to the increased activity of PM H⁺-ATPase, whose expression produces salt resistance. NO is generated by NOS, and H₂O₂ is produced by NADPH oxidase attributed to NO. The activity of PM H⁺-ATPase is regulated by H₂O₂ directly under salt stress. The model is based on the recent results in calluses from P. euphratica¹² and those previously reported on the NO function in reed.¹¹Research on roles of NO and H₂O₂ under stress conditions in plant is advancing rapidly. Further analysis of salt resistance mechanism with novel technology will certainly increase our knowledge in this field.     

Nitration of the Striatal Na,K-ATPase α3 Isoform Occurs in Normal Brain Development but Is Not Increased During Hypoxia-Ischemia in Newborn Piglets

Neonatal hypoxia-ischemia (HI) can result in significant sensorimotor abnormalities, including movement and posture disorders. These neurological impairments are believed to result from basal ganglia (striatum) damage, but the exact cause of this injury is not known. One mechanism involved in brain injury after HI is the generation of reactive oxygen species, which damage cellular macromolecules. We tested the hypothesis that inactivation of plasma membrane enzyme Na,K-ATPase during striatal neurodegeneration after HI emerges with peroxynitrite attack on the enzyme. In vitro, reaction of peroxynitrite (100–500 M) with purified Na,K-ATPase produced nitration of the (catalytic) and (transport) subunits, as quantified by immunoblots of the reaction products for nitrotyrosine. To evaluate for peroxynitrite damage to Na,K-ATPase in vivo, striatal plasma membrane fractions from 1-week-old piglets subjected to asphyxic cardiac arrest and recovery were also studied by immunoprecipitation. During the progression of striatal neurodegeneration and loss of enzyme function 3–24 h after arrest, nitration of the ₃ (neuronal) isoform of Na,K-ATPase was not increased relative to sham control. Suprisingly, however, nitration of this isoform occurs during normal brain development and peaks at 2 weeks of age. We conclude that Na,K-ATPase is a target of peroxynitrite, but that this mechanism is not responsible for enzyme inactivation after HI. Protein nitration may serve as marker of other normal, noninjurious cell processes in the developing brain.     

Hydrogen peroxide and nitric oxide trigger redox-related cyst formation in cultures of the dinoflagellate Lingulodinium polyedrum

The dinoflagellate Lingulodinium polyedrum is a toxin producer that shows the ability of turning to resting cysts as a survival strategy when exposed to environmental unfavorable conditions, such as nitrogen and phosphorus depletion, abrupt changes in temperature or light, and chemical or mechanical stress. Algal adaptation to all these conditions involves hydrogen peroxide (H₂O₂) and nitric oxide (NO) as key redox signals for housekeeping cellular processes. Thus, we aim here to shed light on the role of H₂O₂ and NO (from aqueous decomposition of sodium nitroprusside, SNP) as prooxidant agents and putative redox signals for encystment of the dinoflagellate L. polyedrum. Harsh oxidative stress imposed by 500 μM H₂O₂ treatment forced L. polyedrum cells to rapidly encyst, in less than 30 min, whereas slower cyst formation was observed upon lower H₂O₂ doses. L. polyedrum encystment was marked by a significant increase in the antioxidant carotenoid peridinin, although other photosynthetic pigments (chlorophyll a and β-carotene) and light-harvesting complexes (peridinin complex protein, PCP) were all diminished in cyst forms. Although SOD activity (a frontline antioxidant enzyme) was severely inhibited by increasing doses of H₂O₂, a theoretical compensatory effect was provided by the dose-dependent increase of ascorbate peroxidase activity (APX), which resulted in significant lower levels of lipid peroxidation during cyst formation. Although SNP data cannot be fully compared to those found with H₂O₂ treatments, changes in APX activity and in biomarkers of lipid and protein oxidation matched the dose–responses found in H₂O₂ experiments, revealing similar biochemical and morphological responses against increasing oxidative conditions during cyst formation. Our data significantly contribute to a better understanding of the relationship between encystment, photosynthesis, and antioxidant responses triggered by H₂O₂ and NO in L. polyedrum, a harmful diarrhetic shellfish poisoning toxin (DSPs) producer.     

Inhibition of peroxidase-catalyzed protein tyrosine nitration by antithyroid drugs and their analogues

In this paper, we describe the effect of some commonly used thiourea-based antithyroid drugs and their analogues on the peroxidase-catalyzed nitration reactions. The nitration of bovine serum albumin (BSA) and cytochrome c was studied using the antibody against 3-nitro-l-tyrosine. This study reveals that the thione-based antithyroid drugs effectively inhibit lactoperoxidase (LPO)-catalyzed nitration of BSA. These compounds show very weak inhibition towards the nitration of cytochrome c. Some of these compounds also inhibit myeloperoxidase (MPO)-catalyzed nitration of l-tyrosine. A structure-activity correlation study on the peroxidase-catalyzed nitration of l-tyrosine reveals that the presence of thione/selone moiety is important for the inhibition. Although the presence of a free N-H group adjacent to CS moiety is necessary for most of the thiones to inhibit the LPO-catalyzed nitration, the corresponding selones do not require the presence of any free N-H group for their activity. Furthermore, experiments with different concentrations of H₂O₂ suggest that the antithyroid drugs and related thiones inhibit the nitration reaction mainly by coordinating to the Fe(III)-center of the enzyme active site as previously proposed for the inhibition of peroxidase-catalyzed iodination. On the other hand, the selenium compounds inhibit the nitration by scavenging H₂O₂ without interacting with the enzyme active site. This assumption is based on the observations that catalase effectively inhibits tyrosine nitration by scavenging H₂O₂, which is one of the substrates for the nitration. In contrast, superoxide dismutase (SOD) does not alter the nitration reactions, indicating the absence of superoxide radical anion (O₂^-) during the peroxidase-catalyzed nitration reactions.     

Phosphorylation of the Na,K-ATPase by Ca,phospholipid-dependent andcAMP-dependent protein kinases. Mapping of the region phosphorylated by Ca,phospholipid-dependent protein kinase

Ca,phospholipid-dependent (PKC) andcAMP-dependent (PKA) protein kinases phosphorylate the -subunit of the Na,K-ATPase from duck salt gland with the incorporation of 0.3 and 0.5 mol³²P/mol of -subunit, respectively. PKA (in contrast to PKC) phosphorylates the -subunit only in the presence of detergents. Limited tryptic digestion of the Na,K-ATPase phosphorylated by PKC demonstrates that³²P is incorporated into the N-terminal 41-kDa fragment of the -subunit. Selective chymotrypsin cleavage of phosphorylated enzyme yields a 35-kDa radioactive fragment derived from the central region of the -subunit molecule. These findings suggest that PKC phosphorylates the -subunit of the Na,K-ATPase within the region restricted by C₃ and T₁ cleavage sites.     

Exploring the molecular basis of human manganese superoxide dismutase inactivation mediated by tyrosine 34 nitration

Manganese Superoxide Dismutase (MnSOD) is an essential mitochondrial antioxidant enzyme that protects organisms against oxidative damage, dismutating superoxide radical () into H₂O₂ and O₂. The active site of the protein presents a Mn ion in a distorted trigonal–bipyramidal environment, coordinated by H26, H74, H163, D159 and one ⁻OH ion or H₂O molecule. The catalytic cycle of the enzyme is a “ping-pong” mechanism involving Mn³⁺/Mn²⁺. It is known that nitration of Y34 is responsible for enzyme inactivation, and that this protein oxidative modification is found in tissues undergoing inflammatory and degenerative processes. However, the molecular basis about MnSOD tyrosine nitration affects the protein catalytic function is mostly unknown.In this work we strongly suggest, using computer simulation tools, that Y34 nitration affects protein function by restricting ligand access to the active site. In particular, deprotonation of 3-nitrotyrosine increases drastically the energetic barrier for ligand entry due to the absence of the proton.Our results for the WT and selected mutant proteins confirm that the phenolic moiety of Y34 plays a key role in assisting superoxide migration.     

Regulation of the activity of glyceraldehyde 3-phosphate dehydrogenase by glutathione and H2O2

The activity lost during storage of a solution of muscle glyceraldehyde 3-phosphate dehydrogenase was rapidly restored on adding a thiol compound, but not arsenite or azide. On treatment with H₂O₂, the enzyme was partially inactivated and complete loss of activity occurred in the presence of glutathione. Samples of the enzyme pretreated with glutathione followed by removal of the thiol compound by filtration on a Sephadex column showed both full activity and its complete loss on adding H₂O₂, in the absence of added glutathione. Most of the activity was restored when the H₂O₂-inactivated enzyme was incubated with glutathione (25mM) or dithiothreitol (5mM) whereas arsenite or azide were partly effective and ascorbate was ineffective. The need for incubation for a long time with a strong reducing agent for restoration of activity suggests that the oxidized group (disulfide or sulfenate) must be in a masked state in the H₂O₂-inactivated enzyme. Analysis by SDS-PAGE gave evidence for the formation of a small quantity of glutathione-reversible disulfide-form of the enzyme. Circular dichroic spectra indicated a decrease in -helical content in the inactivated form of the enzyme. The evidence suggest that glutathione and H₂O₂ can regulate the active state of this enzyme.     

Cytochemical and immunocytochemical localization of Na,K-ATPase α subunit isoenzymes in the rat heart

In order to understand the functional significance of Na,K-ATPase subunits as well as their isoenzymes, a precise subcellular localization of these in the myocyte is a crucial prerequisite. Cytochemical, immunofluorescence, preembedding immunogold and horse radish peroxidasediaminobenzidine methods, demonstrated ₁ isoenzyme immunoreactivity on the sarcolemma, T-tubules and the subsarcolemmal cisterns of the adult cardiac myocytes. Cytochemically, ouabain resistant Na,K-ATPase precipitate was localized only in the subsarcolemmal cisterns and junctional sarcoplasmic reticulum. For ₂ isoenzyme, immunoreactivity was demonstrated on the sarcolemma as well as in all areas of the myocytes in particularly a close proximation to the sarcoplasmic reticulum and microsomes. For ₃ isoenzyme, only a weak insignificant signal was noted on the sarcolemma, intercalated disc and sarcoplasm. It is suggested that cytochemical ouabain resistant precipitate present in subsarcolemmal cisterns and junctional sarcoplasmic reticulum represent ₁ isoenzyme of Na,K-ATPase. A differential as well as unique localization of subunit isoenzymes of Na,K-ATPase in specific structures of cardiac myocytes may suggest importance in physiological function at these sites.