Effect of phagocytosis on membrane transport of nonelectrolytes.

The activities of specific transport systems were determined before and after large portions of the surface membrane had been interiorized by phagocytosis of inert particles. In five separate transport systems in rabbit polymorphonuclear leukocytes (adenosine and two adenine transport systems) and alveolar macrophages (adenosine and lysine transport systems), the rate of transport was unaffected even after an estimated 35-50% of the membrane had been internalized. Studies of the kinetics of lysine and adenosine transport, exchange diffusion of lysine transport in alveolar macrophages, and the specificities of adenine transport in polymorphonuclear leukocytes indicate that the nature of the membrane transport systems is not altered by phagocytosis. Therefore the constancy of transport indicates that the number of carriers remains the same before and after phagocytosis. It was also shown that this constancy of transport did not depend on the introduction into the surface of new transport sites during phagocytosis. Therefore transport sites are preserved on the surface during the internalization of membrane which accompanies phagocytosis. The results are best explained by the concept that the membrane is mosaic in character with geographically separate transport and phagocytic sites.

Accessibility of the N-ethylmaleimide-unreactive sulfhydryl of human erythrocyte Band 3.

The human erythrocyte anion exchange protein, Band 3, was reacted with N-ethylmaleimide (NEM) in cells to a stoichiometry of 5.3 mol NEM per mol Band 3, indicating that all NEM-reactive cysteines in Band 3 were labeled. Quantitatively NEM-blocked Band 3 was still able to bind to and be eluted by reducing agents from a mercurial affinity resin, [p-(chloromercuribenzamido)ethylene]amino-Sepharose. Reaction of NEM-blocked Band 3 with p-chloromercuribenzoate (pCMB) did not prevent binding to the resin due to exchange of pCMB for the immobilized mercurial. pCMB has been reported to inhibit water and urea permeation across the red cell membrane, and this has been attributed to reaction with a NEM-reactive sulfhydryl in Band 3. The interaction of Band 3 with the immobilized ligand directly demonstrates the reaction of NEM-blocked Band 3 with a mercurial and indicates that the NEM-unreactive, pCMB-reactive sulfhydryl residue is accessible to within approximately equal to 12 A (the distance from the solid support to the Hg) of the surface of the solubilized Band 3 protein.

A possible mechanism of the generation of singlet molecular oxygen in nadph-dependent microsomal lipid peroxidation.

A simplified system, consisting of NADPH, Fe3+-ADP, EDTA, liposomes, NADPH-cytochrome c reductase and Tris - HCl buffer (pH 6.8), has been employed in studies of the generation of singlet oxygen in NADPH-dependent microsomal lipid peroxidation. The light emitted by the system involves 1deltag type molecular oxygen identifiable by its characteristic emission spectrum and its behavior with beta-carotene. The generation of another excited species (a compound in the triplet state) could be demonstrated in this system by changes of light intensity and emission spectra which arise from photosensitizer (9,10-dibromoanthracene sulfonate, eosin, Rose-Bengal)-mediated energy transfers. Chemiluminescence in the visible region was markedly quenched by various radical trappers and by an inhibitor of NADPH-cytochrome c reductase, but not by superoxide dismutase. During the early stage of lipid peroxidation, the intensity of chemiluminescence was proportional to the square of the concentration of lipid peroxide. These characteristics suggest that singlet oxygen and a compound in the triplet state (probably a carbonyl compound) are generated by a self-reaction of lipid peroxy radicals.

Studies on the ferredoxin-ferredoxin-NADP reductase complex: kinetic and solvent perturbation studies on the location of sulfhydryl and aromatic amino acid residues.

The molecular weight of spinach ferredoxin-NADP reductase [EC 1.6.99.4] was estimated to be 33,100 by the sedimentation equilibrium method. On the basis of this molecular weight, the amino acid composition of the reductase was determined. The reactivity of ferredoxin toward p-chloromercuribenzoate was investigated. By measuring the time course of the reaction, 1 mol of ferredoxin was found to react with about 8 mol of p-chloromercuribenzoate in 10 min. Under low ionic strength conditions (1 mM NaCl), the second-order rate constants of this reaction determined spectrophotometrically at 420 and 250 nm were 3,640 and 3,690 M-1.S-1, respectively; under high ionic strength conditions (100 mM NaCl), these rate constants were 1,360 and 1,270 M-1.S-1, respectively. In the presence of the reductase, the rate constants under low and high ionic strength conditions were 54 and 1,040 M-1.S-1, respectively. By investigation of the solvent perturbation effects on the aromatic amino acid residues with 20% ethylene glycol, it was found that ferredoxin, ferredoxin-NADP reductase, and the complex between these proteins had 2.8, 6.3, and 3.8 mol of exposed tyrosyl residues per mol of protein, respectively. It therefore seems likely that about 5 tyrosyl residues may exist in the neighborhood of the binding site of the complex of these proteins.

Purification and properties of an enzyme catalyzing the splitting of carbon-mercury linkages from mercury-resistant Pseudomonas K-62 strain. I. Splitting enzyme 1.

An enzyme (S-1) which catalyzes the splitting of carbon-mercury linkages of organomercury compounds was purified about 24-fold from the cell-free extract of mercury-resistant Pseudomonas K-62 strain by treatment with streptomycin, precipitation with ammonium sulfate, and successive chromatography on Sephadex G-150, DEAE-Sephadex, and DEAE-cellulose. A purified preparation of the enzyme showed a single band on polyacrylamide gel electrophoresis, and was colorless. The molecular weight of the enzyme was estimated to be 19,000, and Km was 5.3 X 10(-5) M for p-chloromercuribenzoic acid (PCMB). The temperature and pH optimum for the reaction were 50degrees and 7.0, respectively. The enzyme was capable of catalyzing the decomposition of methylmercuric chloride (MMC), ethylmercuric chloride (EMC), phenylmercuric acetate (PMA), and PCMB in the presence of a sulfhydryl compound to form a mercuric ion plus methane, ethane, benzene, or benzoic acid, respectively. The mercuric ion thus formed was reduced to metallic mercury by metallic mercury-releasing enzyme (MMR-enzyme).

Desensitization of substrate inhibition of acto-H-meromyosin ATPase by treatment of H-meromyosin with rho-chloromercuribenzoate. Relation between the extent of desensitization and the amount of bound rho-chloromercuribenzoate1.

H-Meromyosin (CMB leads to betaME-H-meromyosin) was prepared by tryptic digestion of myosin, which had been treated with CMB bound to H-meromyosin and the extent of desensitization of the substrate inhibition of acto-H-meromyosin ATPase [EC 3.6.1.3.] was investigated. Both the dissociation of acto-H-meromyosin induced by ATP and substrate inhibition decreased with increase in the amount of bound CMB to a minimum value at about 1 mole of CMB bound per mole of H-meromyosin. The substrate inhibition of acto-H-meromyosin ATPase was restored to the original level by complete removal of the bound CMB by further treatment of CMB leads to beta ME-H-meromyosin with a large excess of beta-mercaptoethanol. The dissociation constant of acto-H-meromyosin in the presence of ATP decreased markedly on modification with CMB, while the maximum ATPase activity ar a sufficiently high concentration of F-actin remained essentially unchanged. Acto-H-meromyosin was reconstituted from F-actin and CMB LEADS TO beta ME-H-meromyosin, containing less than the stoichiometric amount of bound CMB. Its ATPase activity and the extent of dissociation of acto-H-meromyosin induced by ATP were explained as those of a mixture of unmodified H-meromyosin and CMB leads to beta ME-H-meromyosin containing 1 mole of CMB per mole of H-meromyosin. Half of the light chains (g2), with a molecular weight of 18,000, were removed from myosin by treatment with CMB and beta-mercaptoethanol. After this treatment, on further incubation of the myosin with a large excess of beta-mercaptoethanol, the myosin contained only half of the g2, but the substrate inhibition of acto-H-meromyosin ATPase was restored completely. The initial burst of P1 liberation and the EDTA-ATPase activity decreased to almost zero on specific modification of the SH1-groups with NEM, while the initial burst decreased to some extent and the EDTA-ATPase activity to 50% of the original value on binding of 1 mole CMB per mole of H-meromyosin. The actomyosin-type of ATPase activity was strongly inhibited by modification with CMB. The extent of the dissociation of acto-H-meromyosin induced by ATP was unaffected by modification with NEM, while it decreased on further treatment of NEM-myosin with CMB FOLLOWED BY BETA-MERCAPTOETHANOL.

Effect of p-chloromercuribenzoate on Clostridium perfringens beta toxin.

p-Chloromercuribenzoate (PCMB) was shown to bind to Clostridium perfringens beta toxin. Treatment of the toxin with N-ethylmaleimide (NEM), 5,5'-dithio-bis(2-nitro-benzoic acid) (DTNB), o-iodosobenzoate (OIBA) and metal ions such as Cu2+ and Ag+ decreased the lethal activity, but PCMB did not affect the lethal activity. On the other hand, the binding of PCMB to the toxin was inhibited by DTNB and NEM in a dose-dependent manner. Furthermore, the lethal activity of beta toxin pretreated with PCMB was not blocked by treatment with NEM, DTNB, OIBA, Cu2+ and Ag+. However, the PCMB-treated toxin treated with reduced glutathione, dithiothreitol, 2-mercaptoethanol, liver homogenate or serum from mice was inactivated by NEM.

[Participation of its reaction center in the electrochemical reduction of ferredoxin]. / Ob uchastii v élektrokhimicheskom vosstanovlenii ferredoksina ego reaktsionnogo tsentra.

In the experiments with reaction center modification of ferredoxin its participation in reduction has been shown. Polarographic characteristics of ferredoxin and apoferredoxin have been compared. While removing iron and labile sulphur from ferredoxin reaction center the reduction wave of Fe-S bonds with E 1/2 = -0.33 V (N. H. E.) transforms into the reduction wave of S-S bonds with E 1/2 = -0,39 V at pH = 7.

[Migration of parachloromercuribenzoic acid along the binding sites of hunan oxyhemoglobin]. / Migratsiia parakhlormerkurbenzoinoi kisloty po tsentram sviazyvaniia oksigemoglobina cheloveka.

Oxidation kinetics-characterized state of human oxyhemoglobin bound with p-chloromercuribenzoic acid (PCMB) (above 2 mole per tetramer) is changed during incubation at 20 degrees C. This suggests transfer of PCMB molecules from primary occupied centres to the secondary ones having higher affinity to PCMB. The same effect is observed at increased temperature without incubation. By means of gel-chromatography the hypothesis that the change of oxyhemoglobin state is accompanied by its increased equilibrium dissociation into dimers is acknowledge.

Denaturation studies of active-site labeled papain using electron paramagnetic resonance and fluorescence spectroscopy.

A spin-labeled p-chloromercuribenzoate (SL-PMB) and a fluorescence probe, 6-acryloyl-2-dimethylaminonaphthalene (Acrylodan), both of which bind to the single SH group located in the active site of papain, were used to investigate the interaction of papain (EC 3.4.22.2) with two protein denaturants. It was found that the active site of papain was highly stable in urea solution, but underwent a large conformational change in guanidine hydrochloride solution. Electron paramagnetic resonance and fluorescence results were in agreement and both paralleled enzymatic activity of papain with respect to both the variation in pH and denaturation. These results strongly suggest that SL-PMB and Acrylodan labels can be used to characterize the physical state of the active site of the enzyme.

Structure of the interhelical loops and carboxyl terminus of bacteriorhodopsin by X-ray diffraction using site-directed heavy-atom labeling.

The positions of single amino acids in the interhelical loop regions and the C-terminal tail of bacteriorhodopsin (bR) were investigated by X-ray diffraction using site-directed heavy-atom labeling. Since wild-type bR does not contain any cysteines, appropriate cysteine mutants were produced with a unique sulfhydryl group at specific positions. These sites were then labeled with mercury using the sulfhydryl specific reagent p-chloromercuribenzoate (p-CMB). The cysteine mutants D96A/V101C, V130C, A160C, and G231C were derivatized with labeling stoichiometries of 0.93 +/- 5%, 0.85 +/- 5%, 0.79 +/- 7%, and 0.77 +/- 8%, respectively (Hg per bR). No incorporation was observed with wild-type bR under the same conditions. All mutants and heavy-atom derivatives were fully active as judged by the kinetics of the photocycle and of the proton release and uptake. Moreover, the unit cell dimensions of the two-dimensional P3 lattice were unchanged by the mutations and the derivatization. This allowed the position of the mercury atoms, projected onto the plane of the membrane, to be calculated from the intensity differences in the X-ray diffraction pattern between labeled and unlabeled samples using Fourier difference methods. The X-ray diffraction data were collected at room temperature from oriented purple membrane films at 100% relative humidity without the use of dehydrating solvents. These native conditions of temperature, humidity, and solvent are expected to preserve the structure of the surface-exposed loops. Sharp maxima corresponding to a single mercury atom were found in the difference density maps for D96A/V101C and V130C. Residues 101 and 130 are in the short loops connecting helices C/D and D/E, respectively. No localized difference density was found for A160C and G231C. Residue 160 is in the longer loop connecting helices E and F, whereas residue 231 is in the C-terminal tail. Residues 160 and 231 are apparently in a more disordered and mobile part of the structure.