The DCCD-binding polypeptide is close to the F1 ATPase-binding site on the cytoplasmic surface of the cell membrane of Escherichia coli

Removal of the F₁ ATPase from membrane vesicles of $\text{Escherichia}\text{coli}$ resulted in leakage of protons across the membrane through the F_O portion of the ATPase complex. The leakage of protons was prevented by antiserum to the N,N′-dicyclohexylcarbodiimide (DCCD)-binding polypeptide in everted but not in “right-side out” membrane vesicles. The antiserum prevented the rebinding of F₁ ATPase to F₁-stripped everted membrane vesicles. It is concluded that in F₁-depleted vesicles the DCCD-binding polypeptide is exposed on the cytoplasmic surface of the cell membrane at or close to the binding site of the F₁ ATPase.     

The DCCD-binding polypeptide alone is insufficient for proton translocation through F0 in membranes of Escherichia, coli

In contrast to membrane vesicles of wild-type strains which become leaky to protons on removal of the F₁ ATPase, those of the mutant $\text{Escherichia}\text{,}\text{coli}\text{,}\text{N}{}_{\mathrm{I44}}$, which lacks the F₁ ATPase, can maintain a proton gradient. A normal N,N′-dicyclohexylcarbodiimide (DCCD)-binding polypeptide is present in the F₀ portion of the ATPase complex of the mutant. However, the 19000 molecular weight component of F₀ is absent. We conclude that the latter polypeptide, in addition to the DCCD-binding polypeptide, is required for a functional proton channel in F₀.     

Interaction of phloretin with the anion transport protein of the red blood cell membrane

Phloretin is an inhibitor of anion exchange and glucose and urea transport in human red cells. Equilibrium binding and kinetic studies indicate that phloretin binds to band 3, a major integral protein of the red cell membrane. Equilibrium phloretin binding has been found to be competitive with the binding of the anion transport inhibitor, 4,4′-dibenzamido-2,2′-disulfonic stilbene (DBDS), which binds specifically to band 3. The apparent binding (dissociation) constant of phloretin to red cell ghost band 3 in 28.5 mM citrate buffer, pH 7.4, 25°C, determined from equilibrium binding competition, is $\text{1.8 ± 0.1}\text{μM}$. Stopped-flow kinetic studies show that phloretin decreases the rate of DBDS binding to band 3 in a purely competitive manner, with an apparent phloretin inhibition constant of $\text{1.6 ± 0.4}\text{μM}$. The pH dependence of equilibrium binding studies show that it is the charged, anionic form of phloretin that competes with DBDS binding, with an apparent phloretin inhibition constant of 1.4 μM. The phloretin binding and inhibition constants determined by equilibrium binding, kinetic and pH studies are all similar to the inhibition constant of phloretin for anion exchange. These studies suggest that phloretin inhibits anion exchange in red cells by a specific interaction between phloretin and band 3.     

Identification of an anion channel protein from electric organ of Narke japonica

The anion permeability of membrane vesicles prepared from the electric organ of $\text{Narke japonica}$ was inhibited by the addition of 4,4′-diisothiocyano-stilbene-2,2′-disulfonic acid (DIDS). The permeability was measured by measuring changes in the scattered-light intensity caused by the osmotic volume change of vesicles; and also by the efflux measurement of ions from the vesicles using radioisotopes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of membrane vesicles treated with dihydro analog of DIDS ([³H]H₂DIDS) showed that the H₂DIDS binding protein has a molecular weight of 180,000, and exists in membrane vesicles as a dimer formed by a disulfide bond between monomers of molecular weight 90,000.     

Activation by a calcium-binding protein of guanylate cyclase in Tetrahymena pyriformis.

A Ca²⁺-binding protein (TCBP), which was isolated from $\text{Tetrahymena pyriformis}$, enhanced about 20-fold particulate-bound guanylate cyclase activity in $\text{Tetrahymena}$ cells in the presence of a low concentration of Ca²⁺, while the adenylate cyclase activity was not increased. The enhancement was eliminated by ethylene glycol-bis (β-aminoethyl ether)-N,N′-tetraacetic acid. The enzyme activity was not stimulated by rabbit skeletal muscle troponin-C, the Ca²⁺-binding component of troponin, or other some proteins. In the presence of TCBP, stimulating effect of calcium ion on the enzyme activity was observed within the range of pCa 6.0 to 4.6, and was immediate and reversible.     

Calcium transport and Ca2+-ATPase activity in ram spermatozoa plasma membrane vesicles

Plasma membrane vesicles, isolated from ejaculated ram sperm, were found to contain Ca²⁺-activated Mg²⁺-ATPase and Ca²⁺ transport activities. Membrane vesicles that were exposed to oxalate as a Ca²⁺-trapping agent accumulated Ca²⁺ in the presence of Mg²⁺ and ATP. The $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ for Ca²⁺ uptake was 33 nmol/mg protein per h, and the $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ values for Ca²⁺ and ATP were 2.5 μM and 45 μM, respectively. 1 μM of the Ca²⁺ ionophore A23187, added initially, completely inhibited net Ca²⁺ uptake and, if added later, caused the release of Ca²⁺ previously accumulated. A Ca²⁺-activated ATPase was present in the same membrane vesicles which had a $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ of 1.5 μmol/mg protein per h at free Ca²⁺ concentration of 10 μM. This Ca²⁺-ATPase had $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ values of 4.5 μM and 110 μM for Ca²⁺ and ATP, respectively. This kinetic parameter was similar to that observed for uptake of Ca²⁺ by the vesicles. The Ca²⁺-ATPase activity was insensitive to ouabain. Both Ca²⁺ transport and Ca²⁺-ATPase activity were inhibited by the flavonoid quercetin. Thus, ram spermatozoa plasma membranes have both a Ca²⁺ transport activity and a Ca²⁺-stimulated ATPase activity with similar substrate affinities and specificities and similar sensitivity to quercetin.     

Lack of involvement of lipoic acid in membrane-associated energy transduction in Escherichia coli.

Oxidative phosphorylation, active transport of proline, aerobic- and ATP-driven proton translocation and transhydrogenation of NADP⁺ by NADH, occurred in lipoic acid-deficient cells or vesicles of a lipoic acid auxotroph of $\text{E. coli}$, W1485 lip 2. Addition of lipoic acid had little effect on these processes. Tributyltin chloride, which has been proposed to inhibit oxidative phosphorylation by reaction with lipoic acid (Cain $\text{et al.}$, Biochem. J. (1977) $\text{166}$, 593), was an effective inhibitor of aerobic and ATP-dependent proton translocation and transhydrogenation in lipoic acid-deficient vesicles from this organism. Our results do not support the proposal of Partis $\text{et al.}$ (FEBS Lett. (1977) $\text{75}$, 47) that lipoic acid is involved in the energy transducing processes associated with the membrane of $\text{E. coli}$.     

Membrane reconstitution in chl-r mutants of Escherichia coli K 12.: VII. Purification of the soluble ATPase of supernatant extracts and kinetics of incorporation into reconstituted particles

Membrane-bound ATPase (EC 3.6.1.3) of Escherichia coli K 12 is released in a soluble form by the mechanical treatments applied to the cells in order to break them. The purification of the soluble enzyme is described. The purified protein gives a single band in 7.5 % polyacrylamide gel electrophoresis. The molecular weight is estimated to be 350 000. The enzyme is cold-labile, Mg²⁺ dependent, insensitive to inhibition by $\text{N,N′-}\text{dicyclohexylcarbodiimide}$ and specific for ATP and ADP. Membranes depleted of their ATPase activity by dilution in a buffer of low ionic strength and without Mg²⁺ are able to incorporate the purified ATPase only in the presence of 2–6 mM Mg²⁺. ATPase binds to particles formed by complementation between supernatant extracts of chl A and chl B mutants. There are three kinds of particles of different buoyant densities (1.10, 1.18 and 1.23); ATPase binds only to the 1.10 and 1.18 particles. The kinetics of incorporation have been studied. ATPase begins to be incorporated into the 1.10 particles after 10 min of incubation up to a maximum at 20 min: from 30 min, ATPase is incorporated only into 1.18 particles and the amount of incorporated ATPase increases in proportion with the peak of 1.18 particles. These kinetics have a hyperbolic pattern. In order to explain the mechanism of assembly involved in complementation, two hypotheses are proposed.     

Inhibition of anion transport in human red blood cells by 5,5′-dithiobis(2-nitrobenzoic acid)

The uptake of [³²P]phosphate into human red blood cells was inhibited ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 0.6}\text{mM}$) by the sulfhydryl reagent 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB). 2-Nitro-5-thiobenzoic acid (NTB), the reduced form of DTNB, was a less potent inhibitor ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 7}\text{mM}$). The inhibition of anion transport by DTNB could be reversed by washing DTNB-treated cells with isotonic buffer, or by incubating DTNB-treated cells with 2-mercaptoethanol, which converted DTNB to NTB. DTNB competitively inhibited the binding of 4-[¹⁴C]-benzamido-4′-aminostilbene-2,2′-disulfonate, a potent inhibitor of anion transport ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 1?2 μ}\text{M}$), to band 3 protein in cells and ghost membranes. These results suggest that the stilbene-disulfonate binding site in band 3 protein can readily accommodate the organic anion DTNB, and that inhibition by DTNB was not due to reaction with an essential sulfhydryl group.     

Effects of calcium ions and quinolinic acid on rat kidney mitochondrial kynurenine aminotransferase

At pH 6.4, rat kidney mitochondrial kynurenine aminotransferase activity is enhanced several-fold by the addition of CaCl₂, apparently because Ca⁺⁺ facilitates the translocation of α-ketoglutarate, one of the substrates, across the mitochondrial inner membrane. Chloride salts or Mg⁺⁺, Mn⁺⁺, Na⁺, K⁺, and NH₄⁺ did not have this effect. At pH 6.8, the enzyme activity was near maximal even without added Ca⁺⁺ but was strongly depressed by either of two calcium chelating agents, quinolinic acid (Q.A.) and ethyleneglycol-bis(β-aminoethyl ether)N,N′-tetraacetic acid (EGTA). These observations support the view that Ca⁺⁺ is involved in regulating kidney mitochondrial translocation of α-ketoglutarate and that the reported interference of polycarboxylate anion translocation by Q.A. $\text{in vivo}$ depends on the ability of that agent to chelate Ca⁺⁺.     

Oxidative phosphorylation by membrane vesicles from Bacillus alcalophilus

ADP and P_i-loaded membrane vesicles from l-malate-grown Bacillus alcalophilus synthesized ATP upon energization with $\text{ascorbate}\text{N,N,N′,N′-}\text{tetramethyl}\text{-p-}\text{phenylenediamine}$. ATP synthesis occurred over a range of external pH from 6.0 to 11.0, under conditions in which the total protonmotive force was as low as ?30 mV. The phosphate potentials (ΔG_p) were calculated to be 11 and 12 kcal/mol at pH 10.5 and 9.0, respectively, whereas the values in vesicles at these two pH values were quite different (?40 ± 20 mV at pH 10.5 and ?125 ± 20 mV at pH 9.0). ATP synthesis was inhibited by KCN, gramicidin, and by N,N′-dicyclohexylcarbodiimide. Inward translocation of protons, concomitant with ATP synthesis, was demonstrated using direct pH monitoring and fluorescence methods. No dependence upon the presence of Na⁺ or K⁺ was found. Thus, ATP synthesis in B. alcalophilus appears to involve a proton-translocating ATPase which functions at low .     

Stringent control of glycolysis in Escherichia coli.

When $\text{Escherichia}\text{coli}\text{CP78}\text{(}\text{rel}{}^{\mathrm{+}}$) growing on glucose was starved for isoleucine by the addition of valine, the intracellular levels of fructose 6-phosphate, fructose 1,6-bisphosphate and dihydroxyacetone phosphate were abruptly decreased to one-half, but those of glucose 6-phosphate and ATP remained constant. In contrast, this was not the case with CP79($\text{rel}{}^{\mathrm{?}}$). Chloramphenicol released the response observed in CP78. These results suggest that the glycolytic activity is also under the stringent control. Since only glucosephosphate isomerase[EC 5.3.1.9] was significantly inhibited by guanosine 5′-diphosphate 3′-diphosphate among several glycolytic enzymes tested, the enzyme might be responsible for the decrease observed in CP78.     

A second mechanism for sodium extrusion in Halobacterium halobium: a light-driven sodium pump.

Membrane vesicles from a red mutant of $\text{Halobacterium}\text{halobium}$ R₁ accumulate protons when illuminated causing the pH of the suspension to rise. Sodium is extruded from the vesicles and a membrane potential is formed. This potential and the proton uptake are abolished by valinomycin if K⁺ is present. In contrast, Na⁺-efflux is uninhibited by valinomycin even though no membrane potential is detectable and H⁺ influx does not occur. $\text{Bis}$ (hexafluoracetonyl)acetone (1799) stimulates proton uptake but does not abolish membrane potential. We propose that a light-dependent sodium pump is present. Passive proton uptake occurs in response to the electrical gradient created by this light-driven Na⁺ pump in contrast to the $\text{active}$ proton, and passive Na⁺ flux that occurs in response to the light-driven proton pump described in vesicles of the parent strain of $\text{H.}\text{halobium}$ R₁.     

Characterization of cytochalasin B binding to adult rat liver parenchymal cells in primary culture

The characterization of cytochalasin B binding and the resulting effect on hexose transport in rat liver parenchymal cells in primary culture were studied. The cells were isolated from adult rats by perfusing the liver in situ with collagenase and separating the hepatocytes from the other cell types by differential centrifugation. The cells were established in primary culture on collagen-coated dishes. The binding of [4-³H]cytochalasin B and transport of $\text{3-O-}\text{methyl}\text{-}\text{D}\text{-[}{}^{14}\text{C]glucose}$ into cells were investigated in monolayer culture followed by digestion of cells and scintillation counting of radioactivity. The binding of cytochalasin B to cells was rapid and reversible with association and dissociation being essentially complete within 2 min. Analysis of the kinetics of cytochalasin B binding by Scatchard plots revealed that binding was biphasic, with the parenchymal cell being extremely rich in high-affinity binding sites. The high-affinity site, thought to be the glucose-transport carrier, exhibited a K_D of 2.86 · 10^?7 M, while the low-affinity site had a K_D of 1.13 · 10^?5M. Sugar transport was monitored by $\text{3-O-}\text{methyl}\text{-}\text{D}\text{-}\text{glucose}$ uptake and it was found that cytochalasin B (10^?5M) drastically inhibited transport. However, D-glucose (10^?5M) did not displace cytochalasin B, and cytochalasin E, which does not inhibit transport, was competitive for cytochalasin B at only the low-affinity site, demonstrating that the cytochalasin B inhibition of sugar transport occurs at the high-affinity site but that the inhibition is non-competitive in nature. Therefore, the liver parenchymal cells may represent an unusually rich source of glucose-transport system which may be useful in the isolation of this important membrane carrier.     

Effect of fatty acids on plasma membrane lipid dynamics and cation permeability in neuroblastoma cells

In this study the effects of experimental modifications of plasma membrane lipid lateral mobility on the electrical membrane properties and cation transport of mouse neuroblastoma cells, clone Neuro-2A, have been studied. Short-term supplementation of a chemically defined growth medium with oleic acid or linoleic acid resulted in an increase in the lateral mobility of lipids as inferred from fluorescence recovery after photobleaching of the lipid probe 3,3′-dioctadecylindocarbocyanide iodide. These changes were accompanied by a marked depolarization of the membrane potential from ?51 mV to ?36 mV, 1.5 h after addition, followed by a slow repolarization. Tracer flux studies, using ⁸⁶Rb⁺ as a radioactive tracer for K⁺, demonstrated that the depolarization was not caused by changes in (Na⁺ + K⁺)-ATPase-mediated K⁺ influx or in the transmembrane K⁺ gradient. The permeability ratio ($\text{P}{}_{\mathrm{<mtext>Na</mtext>}}\text{P}{}_{\mathrm{<mtext>K</mtext>}}$), determined from electrophysiological measurements, however, increased from 0.10 to 0.27 upon supplementation with oleic acid or linoleic acid. This transient rise of $\text{P}{}_{\mathrm{<mtext>Na</mtext>}}\text{P}{}_{\mathrm{<mtext>K</mtext>}}$ was shown by ²⁴Na⁺ and ⁸⁶Rb⁺ flux measurements to be due to both an increase of the Na⁺ permeability and a decrease of the K⁺ permeability. None of these effects occurred upon supplementation of the growth medium with stearic acid.     

Pyridine nucleotide distributions and enzyme mass action ratios in hepatocytes from fed and starved rats.

Hepatocytes isolated from fed or starved rats were rapidly lysed using the recently described technique of turbulent flow (M. E. Tischler, P. Hecht, and J. R. Williamson, 1977, Arch. Biochem. Biophys., 181, 278–292). Pyridine nucleotide and metabolite contents were measured in the particulate fraction of both whole and disrupted cells after centrifugation through silicone oil. Lactate/pyruvate, β-hydroxybutyrate/acetoacetate, isocitrate/α-ketoglutarate, and malate/pyruvate ratios were determined for calculation of the free $\text{NADH}\text{NAD}{}^{\mathrm{+}}$ and $\text{NADPH}\text{NADP}{}^{\mathrm{+}}$ ratios in the cytosol and mitochondria. Lactate/pyruvate ratios measured in the extracellular and cytosolic compartments were in good agreement. Ratios of β-hydroxybutyrate/acetoacetate measured in the extracellular, cytosolic, and mitochondrial compartments also agreed well. Addition of ammonia to fed or starved rat liver cells incubated with lactate, pyruvate, β-hydroxybutyrate, and acetoacetate caused an oxidation of both the NAD and NADP redox states in the mitochondria and cytosol, although the NADP system was oxidized to a greater extent. Calculation of the free NADH and NAD concentrations in the cytosol provided values of about 1 and 400 to 500 μm, respectively, under control conditions. The concentrations of free NADH and NAD in the mitochondria were considerably higher, being 300 to 400 μm and 4 to 6 mm, respectively. The free andm bound NAD systems in both the cytosol and mitochondria were more oxidized in the presence of ammonia. NAD and NADP redox potential differences across the mitochondrial membrane (ΔE_h) were not significantly affected by ammonia addition and were generally similar in cells from both fed and starved rats: ?52 and ?56 mV for the NAD system and ?19 to ?29 mV for the NADP system. For the NAD system the cytosolic potential was ?260 mV in the absence of ammonia and ?250 mV in its presence, the mitochondrial values being ?315 and ?303 mV, respectively. The average cytosolic NADP potential, on the other hand, was ?400 mV in the absence and ?384 mV in the presence of ammonia. The mitochondrial fractions yielded NADP potentials of ?420 mV in the absence of ammonia with both fed and starved rats. Ammonia decreased the mitochondrial NADP potential to ?404 mV in fed rats and to ?415 mV in starved rats. The calculated free $\text{NADH}\text{NAD}{}^{\mathrm{+}}$ and $\text{NADPH}\text{NADP}{}^{\mathrm{+}}$ ratios as well as metabolite concentrations were used to evaluate the mass action ratios of both cytosolic and mitochondrial enzymes. Cytosolic alanine aminotransferase remained near equilibrium in the absence and presence of ammonia, while cytosolic and mitochondrial aspartate aminotransferase reactions deviated up to fivefold. The glutamate dehydrogenase reaction was in near equilibrium with the NAD system, but deviated by three to four orders of magnitude from equilibrium with the NADP system in the direction favoring glutamate synthesis rather than deaminatión. Cytosolic malate dehydrogenase deviated from equilibrium by about one order of magnitude, while mitochondrial malate dehydrogenase and citrate synthase deviated by two to six orders of magnitude. These data emphasize the importance of regulation of the citric acid cycle at the citrate synthase step.     

The location of a disulfonic stilbene binding site in band 3, the anion transport protein of the red blood cell membrane

The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, a specific, potent, irreversible inhibitor of anion transport in red blood cells is located in a 15 000 dalton transmembrane segment of band 3, produced by chymotrypsin treatment of ghosts stripped of extrinsic proteins. The segment was cleaved into three fragments of 7000, 4000 and 4000 daltons by CNBr. The C-terminus of the segment is located in the 7000 dalton fragment; the N-terminus in one of the 4000 dalton fragments; and the binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid in the middle 4000 dalton fragment. The latter was cleaved by $\text{N-}\text{bromosuccinimide}$ into two fragments of 2000 daltons. The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid was located on the fragment containing the newly formed N-terminus. It is concluded that the binding site is located about 9000 daltons from the C-terminus (at the outside face of the membrane) and 6000 daltons from the N-terminus (at the cytoplasmic face). In view of the existing evidence that the binding site may be located near the outside face of the membrane, it is suggested that the 15 000 dalton segment is folded, so that it crosses the bilayer three times.