Transport of protons and potassium ions across the membranes of bacteria <Emphasis Type="Italic">Enterococcus hirae</Emphasis> dependent on ATP and nicotinamide adenine dinucleotides

The transport of protons and potassium ions across the membranes of the bacteria Enterococcus hirae growing in an alkaline medium (pH 8.0) or under experimental conditions (pH 7.5) during glucose fermentation accomplished by a KtrI system of absorption of potassium ions, which can interact with F₀F₁-ATPase to form at H⁺-K⁺-pump, has been studied. It was found on cells with a high membrane permeability that the administration of nicotinamide adenine dinucleotides results in the potassium absorption which is insensitive to the inhibitor of F₀F₁-ATPase N,N′-dicyclohexylcarbodiimide. It is assumed that, along with the KtrI system which interacts with F₀F₁-ATPase, a separate KtrI or another K⁺ absorption system operates in these bacteria under particular conditions, which is dependent on NAD⁺ +NADH. Presumably, these interact with this system, changing its conformational state required for the transition to the “active” form.     

Relationship of K+-Uptaking System with H+-Translocating ATPase in Enterococcus hirae, Grown at a High or Low Alkaline pH

Potassium ion pool was studied in glycolyzing Enterococcus hirae, grown at high or low alkaline pH (pH 9.5 and 8.0, respectively). Energy-dependent increase of K⁺ pool was lower for the wild-type cells, grown at pH 9.5, than that for the cells grown at pH 8.0. It was inhibited by N,N′-dicyclohexylcarbodiimide (DCCD). The stoichiometry of DCCD-inhibited K⁺ influx to DCCD-inhibited H⁺ efflux for the wild-type cells, grown at pH 9.5 or 8.0, was fixed for different K⁺ external activity. DCCD-inhibited ATPase activity of membrane vesicles was significantly stimulated by K⁺ for the wild-type cells grown at pH 9.5, and required K⁺ for the wild-type cells grown at pH 8.0, while the levels of α and β subunits of the F₁ and b subunit of the F₀ were lower for the cells grown at pH 9.5 than that for the cells grown at pH 8.0. Such an ATPase activity was residual in membrane vesicles from the atpD mutant with a nonfunctional F₀F₁. ATPase activity of membrane vesicles from the mutant with defect in Na⁺-ATPase was higher for the cells grown at pH 9.5 than that for the cells grown at pH 8.0, and was inhibited by DCCD. An energy-dependent increase of K⁺ pool in this bacterium, grown at a high or low alkaline pH, is assumed to occur through a K⁺ uptaking system, most probably the Trk. The latter functions in a closed relationship with the H⁺-translocating ATPase F₀F₁. Received: 30 June 1997 / Accepted: 4 August 1997     

Metabolic and ionoregulatory responses of the Amazonian cichlid, <Emphasis Type="Italic">Astronotus ocellatus</Emphasis>, to severe hypoxia

We examined the metabolic and ionoregulatory responses of the Amazonian cichlid, Astronotus ocellatus, to 20 h exposure to severe hypoxia (0.37 ± 0.19 mg O₂/l; 4.6% air saturation) or 8 h severe hypoxia followed by 12 h recovery in normoxic water. During 20 h exposure to hypoxia, white muscle [ATP] was maintained at normoxic levels primarily through a 20% decrease in [creatine phosphate] (CrP) and an activation of glycolysis yielding lactate accumulation. Muscle lactate accumulation maintained cytoplasmic redox state ([NAD⁺]/[NADH]) and was associated with an inactivation of the mitochondrial enzyme pyruvate dehydrogenase (PDH). The inactivation of PDH was not associated with significant changes in cytoplasmic allosteric modulators ([ADP_free], redox state, or [pyruvate]). Hypoxia exposure caused a ∼65% decrease in gill Na⁺/K⁺ ATPase activity, which was not matched by changes in Na⁺/K⁺ ATPase α-subunit protein abundance indicating post-translational modification of Na⁺/K⁺ ATPase was responsible for the decrease in activity. Despite decreases in gill Na⁺/K⁺ ATPase activity, plasma [Na⁺] increased, but this increase was possibly due to a significant hemoconcentration and fluid shift out of the extracellular space. Hypoxia caused an increase in Na⁺/K⁺ ATPase α-subunit mRNA abundance pointing to either reduced mRNA degradation during exposure to hypoxia or enhanced expression of Na⁺/K⁺ ATPase α-subunit relative to other genes.     

Formate Hydrogenlyase Is Needed for Proton-Potassium Exchange Through the F0F1-ATPase and the TrkA System in Anaerobically Grown and Glycolysing Escherichia coli

Anaerobically grown and glycolysing Escherichia coli produced H₂ and carried out H⁺-K⁺-exchange in two steps, the first of which had the fixed stoichiometry for DCCD-sensitive fluxes (2H⁺/K⁺), and the second one had a variable stoichiometry for DCCD-sensitive fluxes. H₂ production and the 2H⁺/K⁺-exchange were lost in the ΔfdhF or ΔhycA-H mutant. In the ΔfdhF mutant, H⁺-K⁺-exchange with K _m for K⁺-uptake of 2.3 mM and less K⁺-gradient between the cytoplasm and the medium were observed. H₂ production and H⁺-K⁺-exchange with a high K _m for K⁺-uptake were carried out in the uncD mutant; however, both H₂ production and H⁺-K⁺-exchange were lost in the Δunc or uncE mutant. H₂ production was observed in the trkA trkD kdpA mutant. It was displayed in protoplasts with increased membrane permeability when donor or acceptor of reducing equivalents—formate with DTT or NADH respectively—was added. The F₀F₁ and the TrkA(H) or the F₀ and the TrkA(G) had been assumed to form the united supercomplexes, functioning as a H⁺-K⁺-pump or antiporter respectively (for review see Bioelectrochem Bioenerg 33:1, 1994). Results allow the proposal that H₂ production by FHL has a relationship with the H⁺-K⁺-exchange through a H⁺-K⁺-pump and via an H⁺-K⁺-antiporter. Formate and NADH can serve as a donor and an acceptor of reducing equivalent respectively, for operation of such supercomplexes. Received: 12 December 1996 / Accepted: 19 March 1997     

Relationship of the Escherichia coli TrkA System of Potassium Ion Uptake with the F0F1-ATPase Under Growth Conditions Without Anaerobic or Aerobic Respiration

K⁺ uptake by the Escherichia coli TrkA system is unusual in that it requires both ATP and ; a relation withH⁺ circulation through the membrane is thereforesuggested. The relationship of this system with theF₀F₁-ATPase was studied in intact cells grownunder different conditions. A significant increase of theN,N-dicyclohexylcarbodiimide(DCCD)-inhibitedH⁺ efflux through the F₀F₁ by 5 mMK⁺, but not by Na⁺ added into thepotassium-free medium was revealed only in fermenting wild-type orparent cells, that were grown under anaerobic conditions withoutanaerobic or aerobic respiration and with the production ofH₂. Such an increase disappeared in the unc or the trkA mutants that have alteredF₀F₁ or defective TrkA, respectively.This finding indicates a closed relationship between TrkA andF₀F₁, with these transport systems beingassociated in a single mechanism that functions as an ATP-drivenH⁺–K⁺-exchanging pump. ADCCD-inhibited H⁺–K⁺-exchangethrough these systems with the fixed stoichiometry of H⁺and K⁺ fluxes(2H⁺/K⁺) and a higherK⁺ gradient between the cytoplasm and the externalmedium were also found in these bacteria. They were not observed incells cultured under anaerobic conditions in the presence of nitrate orunder aerobic conditions with respiration and without production ofH₂. The role of anaerobic or aerobic respiration as adeterminant of the relationship of the TrkA with theF₀F₁ is postulated. Moreover, an increase ofDCCD-inhibited H⁺ efflux by added K⁺, aswell as the characteristics of DCCD-sensitiveH⁺–K⁺-exchange found in a parentstrain, were lost in the arcA mutant with a defectiveArc system, suggesting a repression of enzymes in respiratorypathways. In addition, K⁺ influx in the latest mutantwas not markedly changed by valinomycin or with temperature. ThearcA gene product or the Arc system is proposed to beimplicated in the regulation of the relationship between TrkAand F₀F₁.     

Valinomycin pulse-induced phosphorylation of ADP in dark anaerobic cells of the cyanobacteriumAnacystis nidulans

Addition of valinomycin to dark anaerobic suspensions ofAnacystis nidulans resulted in a transient hyperpolarization of the electrical potential across the cell membrane ( _CM) and seen from anilinonaphthalenesulfonate (ANS) fluorescence quenching and from distribution ratios of³H-tetraphenylphosphonium (TPP⁺) and¹⁴C-thiocyanate (SCN^–). At the same time a similar transient increase of intracellular ATP levels was observed, which was paralleled by decreasing ADP levels and eliminated by the uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP) and the F₀F₁-ATPase inhibitors dicyclohexylcarbodiimide (DCCD) and 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (NBD), and in the presence of K⁺ in the medium. Since the steady-state concentration of K⁺ in dark anaerobic cells was around 150 mM, it is concluded that a valinomycin-induced K⁺ diffusion potential across the cell membrane can serve as an energy source for ATP synthesis by a reversible H⁺-ATPase present in the membrane.     

Two gears of pumping by the sodium pump

The kinetics of the phosphorylation and subsequent conformational change of Na⁺,K⁺-ATPase was investigated via the stopped-flow technique using the fluorescent label RH421 (pH 7.4, 24°C). The enzyme was preequilibrated in buffer containing 130 mM NaCl to stabilize the E1(Na⁺)₃ state. On mixing with ATP in the presence of Mg²⁺, a fluorescence increase occurred, due to enzyme conversion into the E2P state. The fluorescence change accelerated with increasing ATP concentration until a saturating limit in the hundreds of micromolar range. The amplitude of the fluorescence change (ΔF/F₀) increased to 0.98 at 50 μM ATP. ΔF/F₀ then decreased to 0.82 at 500 μM. The decrease was attributed to an ATP-induced allosteric acceleration of the dephosphorylation reaction. The ATP concentration dependence of the time course and the amplitude of the fluorescence change could not be explained by either a one-site monomeric enzyme model or by a two-pool model. All of the data could be explained by an (αβ)₂ dimeric model, in which the enzyme cycles at a low rate with ATP hydrolysis by one α-subunit or at a high rate with ATP hydrolysis by both α-subunits. Thus, we propose a two-gear bicyclic model to replace the classical monomeric Albers-Post model for kidney Na⁺,K⁺-ATPase.     

Sulfite inhibits the F1F0-ATP synthase and activates the F1F0-ATPase of Paracoccus denitrificans

The F₁F₀ complex of Paracoccus denitrificans (PdF₁F₀) is the fastest ATP synthase but the slowest ATPase. Sulfite exerts maximal activation of the PdF₁F₀-ATPase (Pacheco-Moisés, F., García, J. J., Rodríguez-Zavala, J. S., and Moreno-Sánchez, R. (2000). Eur. J. Biochem. 267, 993–1000) but its effect on the PdF₁F₀-ATP synthase activity remains unknown. Therefore, we studied the effect of sulfite on ATP synthesis and ³²Pi ATP exchange reactions of inside-out membrane vesicles of P. denitrificans. Sulfite inhibited both reactions under conditions of maximal pH and normal sensitivity to dicyclohexylcarbodiimide. Sulfite increased by 10- and 5-fold the K _0.5 for Mg²⁺-ADP and Pi during ATP synthesis, respectively, and by 4-fold the IC₅₀ of Mg²⁺-ADP for inhibition of the PdF₁F₀-ATPase activity. Thus, sulfite exerts opposite effects on the forward and reverse functioning of the PdF₁F₀ complex. These effects are not due to membrane or PdF₁F₀ uncoupling. Kinetic and structural modifications that could account for these results are discussed.     

Osmosensitivity of the 2H+−K+-exchange and the H+-ATPase complex F0F1 in anaerobically grownEscherichia coli

Escherichia coli grown anaerobically for osmotic studies upon increased osmolarity in alkaline medium carried out H⁺–K⁺-exchange in two steps, the first of which was DCCD¹ sensitive and osmo-dependent and had the 2H⁺/K⁺ stoichiometry. H⁺-efflux in the presence of protonophore (CCCP) upon increase of osmolarity was shown to be high and inhibited by DCCD, whereas H⁺-efflux induced by a decrease of osmolarity was small and not inhibited by DCCD. The 2H⁺/K⁺-exchange was absent intrkA anduncA mutants. InuncB mutant 2H⁺/K⁺-exchange was not DCCD-and osmosensitive. Competition between DCCD and osmoshock on inhibition of 2H⁺/K⁺-exchange was found. Osmosensitivity of this exchange disappeared in spheroplasts. Osmosensitivity of both 2H⁺/K⁺-exchange and the F₀F₁ and osmoregulation of the F₀F₁ via F₀ and a periplasmic space are postulated.Abbreviations F₀F₁ H⁺-ATPase complex - F₀ H⁺-channel, proteolipid - F₁ H⁺-ATPase - Trk constitutive system for K⁺ uptake - PV periplasmic protein valve - DCCD N,N-dicyclohexylcarbodiimide - CCCP carbonylcyanide-m-chlorophenylhydrazone - _H or _K transmembrane electrochemical gradient for H⁺ or K⁺ respectively - membrane potential - upshock or downshock increase or decrease of medium osmolarity, respectively - CGSC E. coli Genetic Stock Center, Yale University, USA     

l-proline dehydrogenase of Triticum vulgare germ: Purification,properties and cofactor interactions

The enzyme catalysing the l-proline-dependent reduction of NAD⁺has been purified over 600-fold from wheat germ acetone powder extracts. l-Proline, 3,4 dehydro-dl-proline, thiazolidine-4-carboxylate were the only substrates utilized readily. The K_m for l-proline was 1·0 mM and for NAD⁺ 0·8 mM. The enzyme was highly specific for NAD⁺ with NADP⁺ and NADPH acting as effective competitive inhibitors with a K_i of 1·8 and 0·4 μM, respectively. All ribonucleoside triphosphates tested were good non-competitive inhibitors, in particular UTP. The purified enzyme could reduce pyrroline-5-carboxylate, either chemically synthesized or generated in a linked assay system from ornithine by a highly-purified ornithine transaminase. In the latter case both NADH and NADPH were utilized equally well as the reductant. With chemically synthesized dl-pyrroline-5-carboxy-late as the substrate. NADPH was used at only 25% the rate of NADH, and NADPH strongly inhibited the oxidation of NADH.     

Gel electrophoretic and density gradient analysis of the (K + Ca)-ATPase and the (Na + K)-ATPase activities of cardiac membrane vesicles

The two major ATPase activities of intact and leaky cardiac membrane vesicles (microsomes) were characterized with respect to ionic activation requirements. The predominant ATPase activity of intact vesicles was (K⁺ + Ca²⁺)-ATPase, an enzymic activity localized to sarcoplasmic reticulum, whereas the predominant ATPase activity of leaky, sodium dodecyl sulfate-pretreated vesicles was (Na⁺ + K⁺)-ATPase, an enzymic activity localized to sarcolemma. The (K⁺ + Ca²⁺)-ATPase activity was stimulated 4- to 5-fold by 100 mM K⁺ in the presence of 50 μM Ca²⁺. Phosphorylation of the (K⁺ + Ca²⁺)-ATPase of intact vesicles with [γ-³²P]ATP was Ca²⁺ dependent, and monovalent cations including K⁺ increased the level of [³²P]phosphoprotein by up to 50% when phosphorylation was measured at 5°C. After the intact vesicles were treated with SDS (0.30 mg/ml), (K⁺ + Ca²⁺)-ATPase was inactivated, as was Ca²⁺-dependent ³²P incorporation. The monovalent cation-stimulated ATPase activity of the particulate residue (SDS-extracted membrane vesicles) displayed the usual characteristics of ouabain-sensitive (Na⁺ + K⁺)-ATPase and the activity was increased 9- to 14-fold over the small amount of patent (Na⁺ + K⁺)-ATPase activity of intact membrane vesicles. ³²P incorporation by the (Na⁺ + K⁺)-ATPase of SDS-extracted vesicles was Na⁺ dependent, and Na⁺-stimulated incorporation was increased 7- to 9-fold over that of intact vesicles.Slab gel polyacrylamide electrophoresis of both intact and SDS-extracted crude vesicle preparations revealed at least 40 distinct Coomassie Blue-positive protein bands and provided evidence for a possible heterogeneous membrane origin of the vesicles. Periodic acid-Schiff staining of the gels revealed at least two major glycoproteins. Simultaneous electrophoresis of the ³²P-intermediates of the (K⁺ + Ca²⁺)-ATPase and the (Na⁺ + K⁺)-ATPase in the same gels did not resolve the two enzymes clearly. With sucrose gradient centrifugation of intact membrane vesicles, it was possible to physically resolve the two ATPase activities. Latent (Na⁺ + K⁺)-ATPase activity (unmasked by exposing the various fractions to SDS) was found in the higher regions of the gradient, whereas (K⁺ + Ca²⁺)-ATPase activity was primarily in the denser regions. A reasonable interpretation of the data is that cardiac microsomes consist of membrane vesicles derived both from sarcolemma and sarcoplasmic reticulum. (Na⁺ + K⁺)-ATPase is localized to intact vesicles of sarcolemma but is mainly latent, whereas (K⁺ + Ca²⁺)-ATPase is mostly patent and is localized to vesicles of sarcoplasmic reticulum.     

Transport of Na<Superscript>+</Superscript> and K<Superscript>+</Superscript> by an antiporter-related subunit from the <Emphasis Type="Italic">Escherichia coli </Emphasis>NADH dehydrogenase I produced in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The NADH dehydrogenase I from Escherichia coli is a bacterial homolog of the mitochondrial complex I which translocates Na⁺ rather than H⁺. To elucidate the mechanism of Na⁺ transport, the C-terminally truncated NuoL subunit (NuoL_N) which is related to Na⁺/H⁺ antiporters was expressed as a protein A fusion protein (ProtA–NuoL_N) in the yeast Saccharomyces cerevisiae which lacks an endogenous complex I. The fusion protein inserted into membranes from the endoplasmatic reticulum (ER), as confirmed by differential centrifugation and Western analysis. Membrane vesicles containing ProtA–NuoL_N catalyzed the uptake of Na⁺ and K⁺ at rates which were significantly higher than uptake by the control vesicles under identical conditions, demonstrating that ProtA–NuoL_N translocated Na⁺ and K⁺ independently from other complex I subunits. Na⁺ transport by ProtA–NuoL_N was inhibited by EIPA (5-(N-ethyl-N-isopropyl)-amiloride) which specifically reacts with Na⁺/H⁺ antiporters. The cation selectivity and function of the NuoL subunit as a transporter module of the NADH dehydrogenase complex is discussed. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

The role of the invariant glutamate 95 in the catalytic site of Complex I from Escherichia coli

Replacement of glutamate 95 for glutamine in the NADH- and FMN-binding NuoF subunit of E. coli Complex I decreased NADH oxidation activity 2.5-4.8 times depending on the used electron acceptor. The apparent K_m for NADH was 5.2 and 10.4 μM for the mutant and wild type, respectively. Analysis of the inhibitory effect of NAD⁺ on activity showed that the E95Q mutation caused a 2.4-fold decrease of K_i^NAD+ in comparison to the wild type enzyme. ADP-ribose, which differs from NAD⁺ by the absence of the positively charged nicotinamide moiety, is also a competitive inhibitor of NADH binding. The mutation caused a 7.5-fold decrease of K_i^ADP-ribose relative to wild type enzyme. Based on these findings we propose that the negative charge of Glu95 accelerates turnover of Complex I by electrostatic interaction with the negatively charged phosphate groups of the substrate nucleotide during operation, which facilitates release of the product NAD⁺. The E95Q mutation was also found to cause a positive shift of the midpoint redox potential of the FMN, from − 350 mV to − 310 mV, which suggests that the negative charge of Glu95 is also involved in decreasing the midpoint potential of the primary electron acceptor of Complex I.     

Oxidative phosphorylation in Zymomonas mobilis

The obligately fermentative aerotolerant bacterium Zymomonas mobilis was shown to possess oxidative phosphorylation activity. Increased intracellular ATP levels were observed in aerated starved cell suspension in the presence of ethanol or acetaldehyde. Ethanolconsuming Z. mobilis generated a transmembrane pH gradient. ATP synthesis in starved Z. mobilis cells could be induced by external medium acidification of 3.5–4.0 pH units. Membrane vesicles of Z. mobilis coupled ATP synthesis to NADH oxidation. ATP synthesis was sensitive to the protonophoric uncoupler CCCP both in starved cells and in membrane vesicles. The H⁺-ATPase inhibitor DCCD was shown to inhibit the NADH-coupled ATP synthesis in membrane vesicles. The physiological role of oxidative phosphorylation in this obligately fermentative bacterium is discussed.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - CCCP carbonyl cyanide m-chlorophenylhydrazone     

Regulation of Glycolytic Oscillations by Mitochondrial and Plasma Membrane H-ATPases

We investigated the coupling between glycolytic and mitochondrial membrane potential oscillations in Saccharomyces cerevisiae under semianaerobic conditions. Glycolysis was measured as NADH autofluorescence, and mitochondrial membrane potential was measured using the fluorescent dye 3,3′-diethyloxacarbocyanine iodide. The responses of glycolytic and membrane potential oscillations to a number of inhibitors of glycolysis, mitochondrial electron flow, and mitochondrial and plasma membrane H⁺-ATPase were investigated. Furthermore, the glycolytic flux was determined as the rate of production of ethanol in a number of different situations (changing pH or the presence and absence of inhibitors). Finally, the intracellular pH was determined and shown to oscillate. The results support earlier work suggesting that the coupling between glycolysis and mitochondrial membrane potential is mediated by the ADP/ATP antiporter and the mitochondrial F₀F₁-ATPase. The results further suggest that ATP hydrolysis, through the action of the mitochondrial F₀F₁-ATPase and plasma membrane H⁺-ATPase, are important in regulating these oscillations. We conclude that it is glycolysis that drives the oscillations in mitochondrial membrane potential.     

F0 cysteine,bCys21, in the Escherichia coli ATP synthase is involved in regulation of potassium uptake and molecular hydrogen production in anaerobic conditions

The single cysteine in the b subunit of the membranous F₀ sector and the 19 cysteines in extramembranous F₁ sector of the Escherichia coli ATP synthase were replaced by alanine. When cells were grown under anaerobic conditions on glucose, the k _cat for ATP hydrolysis of membrane vesicles containing the bCys21Ala mutant enzyme, but not enzymes with other cysteine replacements, was lower, while ATP-driven H⁺ pumping was unchanged. However, the ATP-dependent increase in the number of accessible thiol groups in membrane vesicles was negated. Furthermore, K⁺ uptake and molecular hydrogen production by whole cells and protoplasts was greatly decreased. These results indicate a role for the F₀ subunit bCys21 in the functionality of F₀F₁ and coupling to other membranous activities under fermentative conditions.     

Na+,K+-ATPase Na+ Affinity in Rat Skeletal Muscle Fiber Types

Previous studies in expression systems have found different ion activation of the Na⁺/K⁺-ATPase isozymes, which suggest that different muscles have different ion affinities. The rate of ATP hydrolysis was used to quantify Na⁺,K⁺-ATPase activity, and the Na⁺ affinity of Na⁺,K⁺-ATPase was studied in total membranes from rat muscle and purified membranes from muscle with different fiber types. The Na⁺ affinity was higher (K _m lower) in oxidative muscle compared with glycolytic muscle and in purified membranes from oxidative muscle compared with glycolytic muscle. Na⁺,K⁺-ATPase isoform analysis implied that heterodimers containing the β₁ isoform have a higher Na⁺ affinity than heterodimers containing the β₂ isoform. Immunoprecipitation experiments demonstrated that dimers with α₁ are responsible for approximately 36% of the total Na,K-ATPase activity. Selective inhibition of the α₂ isoform with ouabain suggested that heterodimers containing the α₁ isoform have a higher Na⁺ affinity than heterodimers containing the α₂ isoform. The estimated K _m values for Na⁺ are 4.0, 5.5, 7.5 and 13 mM for α₁β₁, α₂β₁, α₁β₂ and α₂β₂, respectively. The affinity differences and isoform distributions imply that the degree of activation of Na⁺,K⁺-ATPase at physiological Na⁺ concentrations differs between muscles (oxidative and glycolytic) and between subcellular membrane domains with different isoform compositions. These differences may have consequences for ion balance across the muscle membrane.     

Immunocytochemical localization of H+?K+-ATPase in the rat colon

Summary The presence and distribution of gastric-type H⁺−K⁺-ATPase were investigated in the rat colon using a monoclonal antibody raised against hog gastric H⁺−K⁺-ATPase. Rat stomach was used as positive control. Rat kidney and ileum, in both of which H⁺−K⁺-ATPase has been reported in the past, were also studied. In stomach, very strong staining was found confined to the parietal cells, and a strong band atM _r∼94 kDa on the immunoblots. In colon a moderate staining was found in the supranuclear region of the epithelial cells, with similar intensity and distribution of staining of the surface and deep mucosa of the crypts, throughout the length of the colon. Another monoclonal antibody, specific to the 31 kDa subunit of H⁺-ATPase, used as a negative control, or omission of the primary antibody, resulted in lack of any staining in either colon or stomach. On immunoblots of homogenates of colonic mucosa, no specific band could be identified, either due to very low expression of the H⁺−K⁺-ATPase or loss of antigenicity of the epitope during the processing steps. No positive staining was observed in rat kidney and ileum, suggesting that they contain isoforms that are structurally different.     

Characteristics of antibody inhibition of rat kidney (Na+−K+)-ATPase

Summary Antibodies which were raised against highly purified membrane-bound (Na⁺–K⁺)-ATPase from the outer medulla of rat kidneys inhibit the (Na⁺–K⁺)-ATPase activity up to 95%. The antibody inhibition is reversible. The time course of enzyme inhibition and reactivation is biphasic in semilogarithmic plots.In the purified membrane-bound (Na⁺–K⁺)-ATPase negative cooperativity was observed (a) for the ATP dependence of the (Na⁺–K⁺)-ATPase activity (n=0.86), (b) for the ATP binding to the enzyme (n=0.58), and (c) for the ouabain inhibition of the (Na⁺–K⁺)-ATPase activity (n=0.77). By measuring the Na⁺ dependence of the (Na⁺–K⁺-ATPase reaction, a positive homotropic cooperativity (n=1.67) was found.As reactivation of the antibody-inhibited enzyme proceeds very slowly (t _0.5=5.2hr), it was possible to measure characteristics of the antibody-(Na⁺–K⁺)-ATPase complex: The antibodies exerted similar effects on the ATP dependence of the (Na⁺–K⁺)-ATPase reaction and on the ATP binding of the enzyme.V _max of the (Na⁺–K⁺)-ATPase reaction and the number of ATP binding sites were reduced whileK _{0.5 ATP} for the (Na⁺–K⁺)-ATPase activity and for the ATP binding were increased by the antibodies. The Hill coefficients for the ATP binding and for the ATP dependence of the enzyme activity were not significantly altered by the antibodies. The antibodies increased theK _0.5 value for the Na⁺ stimulation of the (Na⁺–K⁺)-ATPase activity, but they did not alter the homotropic interactions between the Na⁺-binding sites. The negative cooperativity which was observed for the ouabain inhibition of the (Na⁺–K⁺)-ATPase activity was abolished by the antibodies.The data are tentatively explained by the following model: The antibodies bind to the (Na⁺–K⁺)-ATPase from the inner membrane side, reduce the ATP binding symmetrically at the ATP binding sites and reduce thereby also the (Na⁺–K⁺)-ATPase activity of the enzyme. The antibodies may inhibit the ATP binding by a direct interaction or by means of a conformational change at the ATP binding sites. This may possibly also lead to the alteration of the Na⁺ dependence of the (Na⁺–K⁺)-ATPase activity and to the observed alteration of the dose response to the ouabain inhibition.     

Biochemical controls of citrate synthase in chickpea bacteroids

Bacteroids formed by Mesorhizobium ciceri CC 1192 in symbiosis with chickpea plants (Cicer arietinum L.) contained a single form of citrate synthase [citrate oxaloacetate-lyase (CoA-acetylating) enzyme; EC 4.1.3.7], which had the same electrophoretic mobility as the enzyme from the free-living cells. The citrate synthase from CC 1192 bacteroids had a native molecular mass of 228 ± 32 kDa and was activated by KCl, which also enhanced stability. Double reciprocal plots of initial velocity against acetyl-CoA concentration were linear, whereas the corresponding plots with oxaloacetate were nonlinear. The K _m value for acetyl-CoA was 174 μM in the absence of added KCl, and 88 μM when the concentration of KCl in reaction mixtures was 100 mM. The concentrations of oxaloacetate for 50% of maximal activity were 27 μM without added KCl and 14 μM in the presence of 100 mM KCl. Activity of citrate synthase was inhibited 50% by 80 μM NADH and more than 90% by 200 μM NADH. Inhibition by NADH was linear competitive with respect to acetyl-CoA (K _is = 23.1 ± 3 μM) and linear noncompetitive with respect to oxaloacetate (K _is = 56 ± 3.8 μM and K _ii = 115 ± 15.4 μM). NADH inhibition was relieved by NAD⁺ and by micromolar concentrations of 5′-AMP. In the presence of 50 or 100 mM KCl, inhibition by NADH was apparent only when the proportion of NADH in the nicotinamide adenine dinucleotide pool was greater than 0.6. In the microaerobic environment of bacteroids, NADH may be at concentrations that are inhibitory for citrate synthase. However, this inhibition is likely to be relieved by NAD⁺ and 5′-AMP, allowing carbon to enter the tricarboxylic acid cycle. Received: 14 July 1999 / Accepted: 20 September 1999