Purification and properties of the F1F0 ATPase of Ilyobacter tartaricus, a sodium ion pump

The ATPase of Ilyobacter tartaricus was solubilized from the bacterial membranes and purified. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified enzyme revealed the usual subunit pattern of a bacterial F1F0 ATPase. The polypeptides with apparent molecular masses of 56, 52, 35, 16.5, and 6.5 kDa were identified as the alpha, beta, gamma, epsilon, and c subunits, respectively, by N-terminal protein sequencing and comparison with the sequences of the corresponding subunits from the Na(+)-translocating ATPase of Propionigenium modestum. Two overlapping sequences were obtained for the polypeptides moving with an apparent molecular mass of 22 kDa (tentatively assigned as b and delta subunits). No sequence could be determined for the putative a subunit (apparent molecular mass, 25 kDa). The c subunits formed a strong aggregate with the apparent molecular mass of 50 kDa which required treatment with trichloroacetic acid for dissociation. The ATPase was inhibited by dicyclohexyl carbodiimide, and Na+ ions protected the enzyme from this inhibition. The ATPase was specifically activated by Na+ or Li+ ions, markedly at high pH. After reconstitution into proteoliposomes, the enzyme catalyzed the ATP-dependent transport of Na+, Li+, or Hi+. Proton transport was specifically inhibited by Na+ or Li+ ions, indicating a competition between these alkali ions and protons for binding and translocation across the membrane. These experiments characterize the I. tartaricus ATPase as a new member of the family of FS-ATPases, which use Na+ as the physiological coupling ion for ATP synthesis.     

A triple mutation in the a subunit of the Escherichia coli/Propionigenium modestum F1Fo ATPase hybrid causes a switch from Na+ stimulation to Na+ inhibition

Previously we have shown that the Na+-translocating Escherichia coli (F1-delta)/Propionigenium modestum (Fo+delta) hybrid ATPase acquires a Na+-independent phenotype by the c subunit double mutation F84L, L87V that is reflected by Na+-independent growth of the mutant strain MPC8487 on succinate [Kaim, G., and Dimroth, P. (1995) J. Mol. Biol. 253, 726-738]. Here we describe a new class of mutants that were obtained by random mutagenesis and screening for Na+-independent growth on succinate. All six mutants of the new class contained four mutations in the a subunit (S89P, K220R, V264E, I278N). Results from site-specific mutagenesis revealed that the substitutions K220R, V264E, and I278N were sufficient to create the new phenotype. The resulting E. coli mutant strain MPA762 could only grow in the absence but not in the presence of Na+ ions on succinate minimal medium. This effect of Na+ ions on growth correlated with a Na+-specific inhibition of the mutant ATPase. The Ki for NaCl was 1. 5 mM at pH 6.5, similar to the Km for NaCl in activating the parent hybrid ATPase at this pH. On the other hand, activation by Li+ ions was retained in the new mutant ATPase. In the absence of Na+ or Li+, the mutant enzyme had the same pH optimum at pH 6.5 and twice the specific activity as the parent hybrid ATPase. In accordance with the kinetic data, the reconstituted mutant ATPase catalyzed H+ or Li+ transport but no Na+ transport. These results show for the first time that the coupling ion selectivity of F1Fo ATPases is determined by structural elements not only of the c subunit but also of the a subunit.     

Molecular basis for the coupling ion selectivity of F1F0 ATP synthases: probing the liganding groups for Na+ and Li+ in the c subunit of the ATP synthase from Propionigenium modestum

The conserved glutamate residue at position 65 of the Propionigenium modestum c subunit is directly involved in binding and translocation of Na+ across the membrane. The site-specific introduction of the cQ32I and cS66A substitutions in the putative vicinity to cE65 inhibited growth of the single-site mutants on succinate minimal agar, indicating that both amino acid residues are important for proper function of the oxidative phosphorylation system. This growth inhibition was abolished, however, if the cF84L/cL87V double mutation was additionally present in the P. modestum c subunit. The newly constructed Escherichia coli strain MPC848732I, harboring the cQ32I/cF84L/cL87V triple mutation, revealed a change in the coupling ion specificity from Na+ to H+. ATP hydrolysis by this enzyme was therefore not activated by NaCl, and ATP-driven H+ transport was not affected by this alkali salt. Both activities were influenced, however, by LiCl. These data demonstrate the loss of the Na+ binding site and retention of Li+ and H+ binding sites within this mutant ATPase. In the E. coli strain MPC848766A (cS66A/cF84L/cL87V), the specificity of the ATPase was further restricted to H+ as the exclusive coupling ion. Therefore, neither Na+ nor Li+ stimulated the ATPase activity, and no ATP-driven Li+ transport was observed. The ATPase of the E. coli mutant MPC32N (cQ32N) was activated by NaCl and LiCl. The mutant ATPase exhibited a 5-fold higher Km for NaCl but no change in the Km for LiCl in comparison to that of the parent strain. These results demonstrate that the binding of Na+ to the c subunit of P. modestum requires liganding groups provided by Q32, E65, and S66. For the coordination of Li+, two liganding partners, E65 and S66, are sufficient, and H+ translocation was mediated by E65 alone.     

Inactivation of the Kluyveromyces lactis H+-ATPase by dicyclohexylcarbodiimide: binding stoichiometry and effect of nucleophiles

Dicyclohexylcarbodiimide (DCCD) inactivated the plasma membrane H+-ATPase (EC 3.6.1.35) from Kluyveromyces lactis, with a second-order rate constant of 420 M(-1) min(-1). The inhibition kinetics was apparently complex, due to degradation of DCCD with time. Neither Mg2+ nor Mg-ADP affected the inactivation of the ATPase by DCCD. In contrast, vanadate, a transition state analog of phosphate, partially protected the enzyme with a Kd of 14 microM, indicating a coupling between the DCCD-reactive site and the vanadate-binding site. The incubation of H+-ATPase with 14C-DCCD showed that the incorporation of 1.2 mol of DCCD/mol ATPase leads to complete inactivation. The hydrophobic carbodiimide reacted with the protonated form of the carboxylic group, which displayed a pKa of 7.4, strongly suggesting that the residue is in the hydrophobic environment of the membrane. Benzylamine increased the rate of inactivation by DCCD. In this case, full inactivation of the enzyme was associated with the incorporation of 2.4 mol of DCCD/mol of enzyme, indicating the opening of new reactive sites, resulting from a conformational change induced by benzylamine.     

A case of lung adenocarcinoma associated with remarkably high levels of CA 19-9 and lymphangitis carcinomatosa

A mutant of Methanobacterium thermoautotrophicum with a lesion in membrane Na+-translocating ATPase (synthase) was isolated. The total ATPase activity in permeabilized cells of this mutant was elevated three-fold as compared with the wild-type strain. In contrast to wild-type cells, mutant ATPase was neither inhibited by DCCD nor stimulated by Na+ ions. The methane formation orate of the mutant cells at pH 7.5 under non-growing conditions was nearly twice that of the wild-type strain and was stimulated by sodium ions. On the other hand, the ATP synthesis driven by methanogenesis under the same conditions was lower that of the wild-type under the same conditions, and contrary to the wild-type was not stimulated by Na+ ions. ATP synthesis driven by a potassium diffusion potential in the presence of sodium ions was markedly diminished in the mutant cells. The membrane potential values of the wild-type and the mutant cells in the presence of 10 mM NaCl at pH 7.0 were comparable at energized conditions (-223 mV and -230 mV respectively). The Mg2+-dependent ATPase activity of the 10(5) x g supernatant of broken cells from the mutant cells was 30% higher than in the wild-type. On the other hand, two bands with Mg2+-dependent ATPase activity were identified by native PAGE in this fraction in both wild-type as well as in mutant. These data suggest that the binding of Na+-translocating ATPase (synthase) to the membrane spanning part is changed in the mutant strain.     

How potassium affects the activity of the molecular chaperone Hsc70. I. Potassium is required for optimal ATPase activity

Several functions of the 70-kilodalton heat shock cognate protein (Hsc70), such as peptide binding/release and clathrin uncoating, have been shown to require potassium ions. We have examined the effect of monovalent ions on the ATPase activity of Hsc70. The steady-state ATPase activities of Hsc70 and its amino-terminal 44-kDa ATPase fragment are minimal in the absence of K+ and reach a maximum at approximately 0.1 M [K+]. Activation of the ATPase turnover correlates with the ionic radii of monovalent ions; those that are at least 0.3 A smaller (Na+ and Li+) or larger (Cs+) than K+ show negligible activation, whereas ions with radii differing only approximately 0.1 A from that of K+ (NH4+ and Rb+) activate to approximately half the turnover rate observed with K+. Single turnover experiments with Hsc70 demonstrate that ATP hydrolysis is 5-fold slower with Na+ than with K+. The equilibrium binding of ADP or ATP to Hsc70 is unperturbed when K+ is replaced with Na+. These results are consistent with a role for monovalent ions as specific cofactors in the enzymatic hydrolysis of ATP.     

Interaction of the delta and b subunits contributes to F1 and F0 interaction in the Escherichia coli F1F0-ATPase

Interactions of the F1F0-ATPase subunits between the cytoplasmic domain of the b subunit (residues 26-156, bcyt) and other membrane peripheral subunits including alpha, beta, gamma, delta, epsilon, and putative cytoplasmic domains of the a subunit were analyzed with the yeast two-hybrid system and in vitro reconstitution of ATPase from the purified subunits as well. Only the combination of bcyt fused to the activation domain of the yeast GAL-4, and delta subunit fused to the DNA binding domain resulted in the strong expression of the beta-galactosidase reporter gene, suggesting a specific interaction of these subunits. Expression of bcyt fused to glutathione S-transferase (GST) together with the delta subunit in Escherichia coli resulted in the overproduction of these subunits in soluble form, whereas expression of the GST-bcyt fusion alone had no such effect, indicating that GST-bcyt was protected by the co-expressed delta subunit from proteolytic attack in the cell. These results indicated that the membrane peripheral domain of b subunit stably interacted with the delta subunit in the cell. The affinity purified GST-bcyt did not contain significant amounts of delta, suggesting that the interaction of these subunits was relatively weak. Binding of these subunits observed in a direct binding assay significantly supported the capability of binding of the subunits. The ATPase activity was reconstituted from the purified bcyt together with alpha, beta, gamma, delta, and epsilon, or with the same combination except epsilon. Specific elution of the ATPase activity from glutathione affinity column with the addition of glutathione after reconstitution demonstrated that the reconstituted ATPase formed a complex. The result indicated that interaction of b and delta was stabilized by F1 subunits other than epsilon and also suggested that b-delta interaction was important for F1-F0 interaction.     

High prevalence of mutations in the microtubule-associated protein tau in a population study of frontotemporal dementia in the Netherlands

We report here the large-scale purification of vacuolar (V0V1)-type Na+-ATPase from Enterococcus hirae achieved using column anion-exchange and gel filtration chromatographies; 32 mg of purified enzyme comprising nine subunits, A, B, C, D, E, F, G, I, and K, was obtained from 20 liter culture. This amount is 500-fold larger than that reported in the previous paper [Murata, T., Takase, K., Yamato, I., Igarashi, K., and Kakinuma, Y. (1997) J. Biol. Chem. 272, 24885-24890]. The purified enzyme shows a high specific activity of ATP hydrolysis (35.7 micromol Pi released/min/mg protein). ATP-driven 22Na+ uptake by reconstituted V0V1-proteoliposomes exhibited an apparent Kt value for Na+ of 40 microM, which is near the Km value (20 microM) for Na+ of the ATP hydrolytic activity. Denatured gel electrophoresis revealed that six subunits, A, B, C, D, E, and F, are releasable as the V1 subunit from the V0V1 complex by incubation with ethylenediaminetetraacetic acid; subunit G was not identified. The remaining V0-liposomes containing I and K subunits catalyzed Na+ uptake in response to potassium diffusion potential (Deltapsi, inside negative); the Kt value for Na+ of this reaction was estimated to be about 2 mM. Inhibition by N,N'-dicyclohexylcarbodiimide (DCCD) of the Na+-ATPase activity and Deltapsi-driven Na+ uptake by the V0-liposomes was prevented by the presence of Na+, suggesting that the Na+ binding site overlaps with the DCCD-reactive site.     

Topological and functional relationship of subunits F1-gamma and F0I-PVP(b) in the mitochondrial H+-ATP synthase

Diamide treatment of the F0F1-ATP synthase in "inside out" submitochondrial particles (ESMP) in the absence of a respiratory Delta mu H+ as well as of isolated Fo reconstituted with F1 or F1-gamma subunit results in direct disulfide cross-linking between cysteine 197 in the carboxy-terminal region of the F0I-PVP(b) subunit and cysteine 91 at the carboxyl end of a small alpha-helix of subunit F1-gamma, both located in the stalk. The F0I-PVP(b) and F1-gamma cross-linking cause dramatic enhancement of oligomycin-sensitive decay of Delta mu H+. In ESMP and MgATP particles the cross-linking is accompanied by decoupling of respiratory ATP synthesis. These effects are consistent with the view that F0I-PVP(b) and F1-gamma are components of the stator and rotor of the proposed rotary motor, respectively. The fact that the carboxy-terminal region of F0I-PVP(b) and the short alpha-helix of F1-gamma can form a direct disulfide bridge shows that these two protein domains are, at least in the resting state of the enzyme, in direct contact. In isolated F0, diamide also induces cross-linking of OSCP with another subunit of F0, but this has no significant effect on proton conduction. When ESMP are treated with diamide in the presence of Delta mu H+ generated by respiration, neither cross-linking between F0I-PVP(b) and F1-gamma subunits nor the associated effects on proton conduction and ATP synthesis is observed. Cross-linking is restored in respiring ESMP by Delta mu H+ collapsing agents as well as by DCCD or oligomycin. These observations indicate that the torque generated by Delta mu H+ decay through Fo induces a relative motion and/or a separation of the F0I-PVP(b) subunit and F1-gamma which places the single cysteine residues, present in each of the two subunits, at a distance at which they cannot be engaged in disulfide bridging.     

Inactivation of rat brain Na+ K+ ATPase by sodium dodecylsulfate: effect of pH, magnesium ions and temperature

The relative stabilities to SDS inactivation of the rat brain Na(+)-ATPase catalytic subunit isoforms in the conditions of the surface charge modulation and temperature modification of the physical state of the membrane lipids were examined. The higher sensitivity of the Na+,K(+)-ATPase a1-isoform than a+ to SDS inactivation occurs under the conditions of the detergent treatment of microsomes at pH 7.5 and room temperature. The decrease in pH in ATP-free medium up to 6.2 or temperature elevation up to 37 degrees C eliminates the differences in SDS sensitivity of the Na+,K(+)-ATPase isoforms. The enhancement of the SDS binding with a subunit due to changes in membrane surface charge in the first case or increase of accessibility of the protein intramembrane regions for detergent due to the decrease of the packing density of the boundary lipids in the second case are supposed.     

Voltage-generated torque drives the motor of the ATP synthase

The mechanism by which ion-flux through the membrane-bound motor module (F0) induces rotational torque, driving the rotation of the gamma subunit, was probed with a Na+-translocating hybrid ATP synthase. The ATP-dependent occlusion of 1 (22)Na+ per ATP synthase persisted after modification of the c subunit ring with dicyclohexylcarbodiimide (DCCD), when 22Na+ was added first and ATP second, but not if the order of addition was reversed. These results support the model of ATP-driven rotation of the c subunit oligomer (rotor) versus subunit a (stator) that stops when either a 22Na+-loaded or a DCCD-modified rotor subunit reaches the Na+-impermeable stator. The ATP synthase with a Na+-permeable stator catalyzed 22Na+out/Na+in-exchange after reconstitution into proteoliposomes, which was not significantly affected by DCCD modification of the c subunit oligomer, but was abolished by the additional presence of ATP or by a membrane potential (DeltaPsi) of 90 mV. We propose that in the idling mode of the motor, Na+ ions are shuttled across the membrane by limited back and forth movements of the rotor against the stator. This motional flexibility is arrested if either ATP or DeltaPsi induces the switch from idling into a directed rotation. The Propionigenium modestum ATP synthase catalyzed ATP formation with DeltaPsi of 60-125 mV but not with DeltapNa+ of 195 mV. These results demonstrate that electric forces are essential for ATP synthesis and lead to a new concept of rotary-torque generation in the ATP synthase motor.     

Alpha 2 mRNA of Na+K+ ATPase is increased in astroctyes of rat hippocampus after treatment with kainic acid

The Na+K+ ATPase (Na+ pump) plays a central role in regulating cation homeostasis and is thought to have an important role in cell proliferation. The multitude of subunit isoforms comprising the functional Na+K+ ATPase has raised the possibility that specific subunit isoform combinations may be involved in different cellular processes. We have investigated the involvement of the specific isoforms in neurons and glia at the site of a CNS lesion. Intracerebroventricular injection of kainic acid was used to induce neuronal cell loss and reactive gliosis in rat hippocampus and levels of Na+K+ ATPase subunit isoform mRNA levels were determined in cells of rat hippocampus using in situ hybridization. alpha 2 mRNA levels increased 35-40% in CA1 and CA3 astrocytes between 1-3 weeks after KA injection with no significant change in other subunit isoform mRNA levels. In addition alpha 3 mRNA levels in CA1 pyramidal neurons were decreased by approx. 35%. Small neurons in the CA1 and CA3 region showed no changes in mRNA levels for any of the Na+K+ ATPase subunit isoforms. These results may indicate a possible role for alpha 2 subunit isoform in the conversion of glial cells from a normal phenotype to the reactive phenotype characteristic in this model of CNS injury.     

Identification of N,N'-dicyclohexylcarbodiimide-reactive glutamic and aspartic acid residues in Escherichia coli transhydrogenase and the exchange of these by site-specific mutagenesis

Pyridine nucleotide transhydrogenase (EC 1.6.1.1) from Escherichia coli was investigated with respect to the role of glutamic and aspartic acid residues reactive to N,N'-dicyclohexylcarbodiimide (DCCD) and potentially involved in the proton-pumping mechanism of the enzyme. The E. coli transhydrogenase consists of an alpha (510 residues) and a beta (462 residues) subunit. DCCD reacts with the enzyme to inhibit catalytic activity and proton pumping. This reagent modifies Asp alpha 232, Glu alpha 238, and Glu alpha 240 as well as amino acid residue(s) in the beta subunit. Using the cloned and overexpressed E. coli transhydrogenase genes (Clarke, D. M., and Bragg, P. D. (1985) J. Bacteriol. 162, 367-373), Asp alpha 232 and Glu alpha 238 were replaced independently by site-specific mutagenesis. In addition, Asp alpha 232, Glu alpha 238, and Glu alpha 240 were replaced to generate triple mutants. The specific catalytic activities of the mutant transhydrogenases alpha D232N, alpha D232E, alpha D232K, alpha D232H, alpha E238K, and alpha E238Q as well as of the triple mutants alpha D232N, alpha E238Q, alpha E240Q and alpha D232H, alpha E238Q, alpha E240Q were in the range of 40-90% of the wild-type activity. Proton-pumping activity was present in all mutants. Examination of the extent of subunit modification by [14C]DCCD revealed that the label was still incorporated into both alpha and beta subunits in the Asp alpha 232 mutants, but that the alpha subunit was not labeled in the triple mutants. Catalytic and proton-pumping activities were nearly insensitive to DCCD in the triple mutants. This suggests that loss of catalytic and proton-pumping activities is associated with modification of the aspartic and glutamic acid residues of the alpha subunit. In the presence of the substrate NADPH, the rate of modification of the beta subunit by [14C]DCCD was increased, and there was a greater extent of enzyme inactivation. By contrast, NADH and 3-acetylpyridine-NAD+ protected the catalytic activity of the transhydrogenase from inhibition by DCCD. The protection was particularly marked in the E238Q and E238K mutants. It is concluded that the Asp alpha 232, Glu alpha 238, and Glu alpha 240 residues are not essential for catalytic activity or proton pumping. The inactivation by DCCD is likely due to the introduction of a sterically hindering group that reacts with the identified acidic residues close to the NAD(H)-binding site.     

The stalk region of the Escherichia coli ATP synthase. Tyrosine 205 of the gamma subunit is in the interface between the F1 and F0 parts and can interact with both the epsilon and c oligomer

The soluble portion of the Escherichia coli F1F0 ATP synthase (ECF1) and E. coli F1F0 ATP synthase (ECF1F0) have been isolated from a novel mutant gammaY205C. ECF1 isolated from this mutant had an ATPase activity 3.5-fold higher than that of wild-type enzyme and could be activated further by maleimide modification of the introduced cysteine. This effect was not seen in ECF1F0. The mutation partly disrupts the F1 to F0 interaction, as indicated by a reduced efficiency of proton pumping. ECF1 containing the mutation gammaY205C was bound to the membrane-bound portion of the E. coli F1F0 ATP synthase (ECF0) isolated from mutants cA39C, cQ42C, cP43C, and cD44C to reconstitute hybrid enzymes. Cu2+ treatment or reaction with 5,5'-dithio-bis(2-nitro-benzoic acid) induced disulfide bond formation between the Cys at gamma position 205 and a Cys residue at positions 42, 43, or 44 in the c subunit but not at position 39. Using Cu2+ treatment, this covalent cross-linking was obtained in yields as high as 95% in the hybrid ECF1 gammaY205C/cQ42C and in ECF1F0 isolated from the double mutant of the same composition. The covalent linkage of the gamma to a c subunit had little effect on ATPase activity. However, ATP hydrolysis-linked proton translocation was lost, by modification of both gamma Cys-205 and c Cys-42 by bulky reagents such as 5,5'-dithio-bis (2-nitro-benzoic acid) or benzophenone-4-maleimide. In both ECF1 and ECF1F0 containing a Cys at gamma 205 and a Cys in the epsilon subunit (at position 38 or 43), cross-linking of the gamma to the epsilon subunit was induced in high yield by Cu2+. No cross-linking was observed in hybrid enzymes in which the Cys was at position 10, 65, or 108 of the epsilon subunit. Cross-linking of gamma to epsilon had only a minimal effect on ATP hydrolysis. The reactivity of the Cys at gamma 205 showed a nucleotide dependence of reactivity to maleimides in both ECF1 and ECF1F0, which was lost in ECF1 when the epsilon subunit was removed. Our results show that there is close interaction of the gamma and epsilon subunits for the full-length of the stalk region in ECF1F0. We argue that this interaction controls the coupling between nucleotide binding sites and the proton channel in ECF1F0.     

Molecular determinants of high affinity binding of alpha-scorpion toxin and sea anemone toxin in the S3-S4 extracellular loop in domain IV of the Na+ channel alpha subunit

alpha-Scorpion toxins and sea anemone toxins bind to a common extracellular site on the Na+ channel and inhibit fast inactivation. Basic amino acids of the toxins and domains I and IV of the Na+ channel alpha subunit have been previously implicated in toxin binding. To identify acidic residues required for toxin binding, extracellular acidic amino acids in domains I and IV of the type IIa Na+ channel alpha subunit were converted to neutral or basic amino acids using site-directed mutagenesis, and altered channels were transiently expressed in tsA-201 cells and tested for 125I-alpha-scorpion toxin binding. Conversion of Glu1613 at the extracellular end of transmembrane segment IVS3 to Arg or His blocked measurable alpha-scorpion toxin binding, but did not affect the level of expression or saxitoxin binding affinity. Conversion of individual residues in the IVS3-S4 extracellular loop to differently charged residues or to Ala identified seven additional residues whose mutation caused significant effects on binding of alpha-scorpion toxin or sea anemone toxin. Moreover, chimeric Na+ channels in which amino acid residues at the extracellular end of segment IVS3 of the alpha subunit of cardiac Na+ channels were substituted into the type IIa channel sequence had reduced affinity for alpha-scorpion toxin characteristic of cardiac Na+ channels. Electrophysiological analysis showed that E1613R has 62- and 82-fold lower affinities for alpha-scorpion and sea anemone toxins, respectively. Dissociation of alpha-scorpion toxin is substantially accelerated at all potentials compared to wild-type channels. alpha-Scorpion toxin binding to wild type and E1613R had similar voltage dependence, which was slightly more positive and steeper than the voltage dependence of steady-state inactivation. These results indicate that nonidentical amino acids of the IVS3-S4 loop participate in alpha-scorpion toxin and sea anemone toxin binding to overlapping sites and that neighboring amino acid residues in the IVS3 segment contribute to the difference in alpha-scorpion toxin binding affinity between cardiac and neuronal Na+ channels. The results also support the hypothesis that this region of the Na+ channel is important for coupling channel activation to fast inactivation.     

The responsiveness of generic quality of life instruments in rheumatic diseases. A systematic review of randomized controlled trials

Pseudomonas carboxyl proteinase (PCP), isolated from Pseudomonas sp. 101, is the first example from a prokaryote of unique carboxyl proteinases [EC 3.4.23.33] which are insensitive to aspartic proteinase inhibitors, such as pepstatin, diazoacetyl-DL-norleucine methylester, and 1,2-epoxy-3(p-nitrophenoxy)propane. To identify the catalytic residue(s) of PCP, chemical modification was carried out using carboxyl residue-specific reagents, carbodiimides. PCP was inactivated effectively by N,N'-dicyclohexylcarbodiimide (DCCD) with pseudo-first-order kinetics. For the inactivation, 0.7 mol DCCD was involved per 1 mol PCP. The effects of pH and methanol on the inactivation showed that two carboxyl residues (Asp and/or Glu) were involved in the reaction. The inactivation by DCCD was prevented by a competitive inhibitor, tyrostatin, or a synthetic substrate in a concentration-dependent manner. Based on these data, differential labeling of PCP with DCCD was carried out: Firstly, PCP was treated with cold DCCD in the presence of tyrostatin. After removal of the tyrostatin, which covered the substrate binding site, by dialysis, the PCP was treated with [14C]DCCD to label carboxyl residue(s) essential for its function. Two labeled peptides were isolated by HPLC from a trypsin digest of cold- and [14C]DCCD modified PCP. On analysis of their amino acid sequences, it was revealed that the [14C]DCCD was bound to Asp140 and Glu222 of PCP, respectively. Based on these data, it was strongly suggested that Asp140 and Glu222 of PCP were involved in its catalytic function or substrate binding.     

Subcellular distribution of ankyrin in developing rabbit heart--relationship to the Na+-Ca2+ exchanger

Ankyrins are a multigene family of proteins that function as adapters between the cytoskeleton and trans-membrane proteins, such as ion channels. Previous studies have shown the linkage between ankyrin and ionic transport proteins such as Na+-K+ ATPase, voltage-dependent Na+ channels and Ca2+ channels. In the present study, we have investigated the subcellular distribution of ankyrin and its relationship to the Na+-Ca2+ exchange protein in immature and adult rabbit ventricular myocytes. Isolated single cardiomyocytes from neonatal, juvenile and adult rabbit hearts were examined by immunofluorescence labeling techniques, using antibodies against ankyrin and the Na+-Ca2+ exchanger. We found that in neonatal rabbit cardiac myocytes, ankyrin labeling was mainly present at the Z disk, whereas the Na+-Ca2+ exchanger was only present on the peripheral sarcolemma. At 2 weeks of age, ankyrin labeling was still predominantly observed at the level of the Z disks as well as in the partially developed T-tubules. In the adult cells, however, ankyrin and the Na+-Ca2+ exchanger seem to be co-localized within T-tubules and at the costamere region of the peripheral sarcolemma. Immunogold labeling studies at the higher resolution electron microscopic level using cyrosection tissues of rabbit heart at different ages confirm these findings. These results indicate that the distribution pattern of ankyrin and the Na+-Ca2+ exchanger changes with development in rabbit ventricular myocytes.     

A critical role for the S4-S5 intracellular loop in domain IV of the sodium channel alpha-subunit in fast inactivation

Na+ channel fast inactivation is thought to involve the closure of an intracellular inactivation gate over the channel pore. Previous studies have implicated the intracellular loop connecting domains III and IV and a critical IFM motif within it as the inactivation gate, but amino acid residues at the intracellular mouth of the pore required for gate closure and binding have not been positively identified. The short intracellular loops connecting the S4 and S5 segments in each domain of the Na+ channel alpha-subunit are good candidates for this role in the Na+ channel inactivation process. In this study, we used scanning mutagenesis to examine the role of the IVS4-S5 region in fast inactivation. Mutations F1651A, near the middle of the loop, and L1660A and N1662A, near the COOH-terminal end, substantially disrupted Na+ channel fast inactivation. The mutant F1651A conducted Na+ currents that decayed very slowly, while L1660A and N1662A had large sustained Na+ currents at the end of 30-ms depolarizing pulses. Inactivation of macroscopic Na+ currents was nearly abolished by the N1662A mutation and the combination of the F1651A/L1660A mutations. Single channel analysis revealed frequent reopenings for all three mutants during 40-ms depolarizing pulses, indicating a substantial impairment of the stability of the inactivated state compared with wild type (WT). The F1651A and N1662A mutants also had increased mean open times relative to WT, indicating a slowed rate of entry into the inactivated state. In addition to these effects on inactivation of open Na+ channels, mutants F1651A, L1660A, and N1662A also impaired fast inactivation of closed Na+ channels, as assessed from measurements of the maximum open probability of single channels. The peptide KIFMK mimics the IFM motif of the inactivation gate and provides a test of the effect of mutations on the hydrophobic interaction of this motif with the inactivation gate receptor. KIFMK restores fast inactivation of open channels to the F1651A/L1660A mutant but does not restore fast inactivation of closed F1651A/L1660A channels, suggesting that these residues interact with the IFM motif during inactivation of closed channels. Our results implicate F1651, L1660, and N1662 of the IVS4-S5 loop in inactivation of both closed and open Na+ channels and suggest that the IFM motif of the inactivation gate interacts with F1651 and/or L1660 in the IVS4-S5 loop during inactivation of closed channels.     

F0 and F1 parts of ATP synthases from Clostridium thermoautotrophicum and Escherichia coli are not functionally compatible

F1-stripped membrane vesicles from Clostridium thermoautotrophicum and Escherichia coli were reconstituted with F1-ATPases from both bacteria. Reconstituted F1F0-ATPase complexes were catalytically active, i.e. capable of hydrolyzing ATP. Homologous-type ATPase complexes having F0 and F1 parts of ATP synthases from the same origin were DCCD sensitive and supported ATP-driven enhancement of anilinonaphthalene sulfonate (ANS) fluorescence. Hybrid-type ATPase complexes having F0 and F1 parts of ATP synthases from different origins were neither DCCD sensitive nor did they support ATP-driven enhancement of ANS fluorescence. Analyzing these results it has been demonstrated that the F0 and F1 parts of ATP synthases of these two bacteria are not functionally compatible.     

Energy transduction in the thermophilic anaerobic bacterium Clostridium fervidus is exclusively coupled to sodium ions

The thermophilic, peptidolytic, anaerobic bacterium Clostridium fervidus is unable to generate a pH gradient in the range of 5.5-8.0, which limits growth of the organism to a narrow pH range (6.3-7.7). A significant membrane potential (delta psi approximately -60 mV) and chemical gradient of Na+ (-Z delta pNa approximately -60 mV) are formed in the presence of metabolizable substrates. Energy-dependent Na+ efflux is inhibited by the Na+/H+ ionophore monensin but is stimulated by uncouplers, suggesting that the Na+ gradient is formed by a primary pumping mechanism rather than by secondary Na+/H+ antiport. This primary sodium pump was found to be an ATPase that has been characterized in inside-out membrane vesicles and in proteoliposomes in which solubilized ATPase was reconstituted. The enzyme is stimulated by Na+, resistant to vanadate, and sensitive to nitrate, which is indicative of an F/V-type Na(+)-ATPase. In the proteoliposomes Na+ accumulation depends on the presence of ATP, is inhibited by the ATPase inhibitor nitrate, and is completely prevented by the ionophore monensin but is stimulated by protonophores and valinomycin. These and previous observations, which indicated that secondary amino acid transport uses solely Na+ as coupling ion, demonstrate that energy transduction at the membrane in C. fervidus is exclusively dependent on a Na+ cycle.