Respiratory nitrate reductase: its localization in the cytoplasmic membrane of Klebsiella aerogenes and Bacillus licheniformis.

The sidedness of the respiratory nitrate reductase in the cytoplasmic membrane of Bacillus licheniformis and Klebsiella aerogenes was studied by indirect immunofluorescence and by lactoperoxidase-catalyzed iodination. It was shown that the two subunits (Mr 150000 and 57000, respectively) of nitrate reductase of B. licheniformis are localized on the cytoplasmic side of the membrane, whereas the K. aerogenes enzyme is a transmembrane protein. The different localization of nitrate reductase in the membranes of these organisms may be related to their different r?le in oxidative phosphorylation.     

Quaternary structure and composition of squash NADH:nitrate reductase

NADH:nitrate reductase (EC 1.6.6.1) was isolated from squash cotyledons (Cucurbita maxima L.) by a combination of Blue Sepharose and zinc-chelate affinity chromatographies followed by gel filtration on Bio-Gel A-1.5m. These preparations gave a single protein staining band (Mr = 115,000) on sodium dodecyl sulfate gel electrophoresis, indicating that the enzyme is homogeneous. The native Mr of nitrate reductase was found to be 230,000, with a minor form of Mr = 420,000 also occurring. These results indicate that the native nitrate reductase is a homodimer of Mr = 115,000 subunits. Acidic amino acids predominate over basic amino acids, as shown both by the amino acid composition of the enzyme and an isoelectric point for nitrate reductase of 5.7. The homogeneous nitrate reductase had a UV/visible spectrum typical of a b-type cytochrome. The enzyme was found to contain one each of flavin (as FAD), heme iron, molybdenum, and Mo-pterin/Mr = 115,000 subunit. A model is proposed for squash nitrate reductase in which two Mr = 115,000 subunits are joined to made the native enzyme. Each subunit contains 1 eq of FAD, cytochrome b, and molybdenum/Mo-pterin.     

Constitutive and nitrate-induced,membrane-bound nitrate reductase fromBradyrhizobium japonicum

Nitrate reductase (NR) activity was detected in membranes from cells ofBradyrhizobium japonicum cultured in defined medium either with glutamate or nitrate as the only nitrogen source. With gel filtration, the relative molecular mass (Mr) of the NR in cells growth with glutamate was estimated to be about 78 kDa. The enzyme from cells grown aerobically with nitrate had an Mr of 236 kDa, the same as that of the NR from microaerobically nitrate-grown cells. When cells that had been grown with glutamate were incubated microaerobically in both the absence and the presence of nitrate, the enzyme from each source resembled that of nitrate-grown cells in having an Mr of 236 kDa. In glutamate-grown cells that were further incubated, both microaerobiosis and nitrate were required for fully expression of the activity of the enzyme.     

Purification and properties of a dissimilatory nitrate reductase from Haloferax denitrificans.

A membrane-bound nitrate reductase (nitrite:(acceptor) oxidoreductase, EC 1.7.99.4) from the extremely halophilic bacterium Haloferax denitrificans was solubilized by incubating membranes in buffer lacking NaCl and purified by DEAE, hydroxylapatite, and Sepharose 6B gel filtration chromatography. The purified nitrate reductase reduced chlorate and was inhibited by azide and cyanide. Preincubating the enzyme with cyanide increased the extent of inhibition which in turn was intensified when dithionite was present. Although cyanide was a noncompetitive inhibitor with respect to nitrate, nitrate protected against inhibition. The enzyme, as isolated, was composed of two subunits (Mr 116,000 and 60,000) and behaved as a dimer during gel filtration (Mr 380,000). Unlike other halobacterial enzymes, this nitrate reductase was most active, as well as stable, in the absence of salt.     

Purification and characterization of the respiratory nitrate reductase of Bacillus licheniformis.

1. Respiratory nitrate reductase of Bacillus licheniformis was extracted from the bacterial membranes by treatment with deoxycholate and purified to a homogeneous state by means of gel chromatography and anion-exchange chromatography. 2. The enzyme (Mr = 193,000, s20, w = 8.6) consists of two subunits, having apparent molecular weight of 150,000 (alpha subunit) and 57,000 (beta subunit), which are present in an equimolar ratio. It does not contain carbohydrate. Ageing of the enzyme appears to result in splitting of the polypeptide chains at specific sites followed by dissociation and reassociation of the digestion products in various combinations. 3. In contrast to Klebsiella aerogenes repiratory nitrate reductase, which is isolated in a tetrameric form that can be reversibly dissociated into a monomeric form by detergents, B. licheniformis nitrate reductase, after isolation, is always present in a monomeric form. This property is related to the difference in membrane localization of the enzyme in the two organisms. 4. B licheniformis nitrate reductase contains 6.9 atoms of non-heme iron, 6.7 atoms of acid-labile sulfide and 0.93 atoms of molybdenum per molecule of enzyme. The molybdenum seems to be part of a low-molecular weight peptide Mo-cofactor) to which it may be bound by interaction with thiol-groups. 5. Antiserum against the native enzyme contains antibodies against both subunits as well as the Mo-cofactor. The Mo-cofactor does not have any antigenic determininants in common with either the alpha or the beta subunit. Also neither subunit cross-reacts with antiserum against the other subunit. Whereas the respiratory nitrate reductases from K. aerogenes and Escherichia coli are immunologically related, the native enzyme from B. licheniformis does not show any cross-reaction with antiserum prepared against either the K. aerogenes or the E. coli enzyme.     

Limited proteolysis of nitrate reductase purified from membranes of Escherichia coli.

The heterogeneous form of nitrate reductase released from the membrane fraction of Escherichia coli by heat treatment was converted to a new electrophoretic form by incubation with trypsin. As a result of the trypsin treatment, the heat-released enzyme was converted from an associating-dissociating system to a nonassociating monomer (Mr approximately 200,000) which retained full enzymatic activity. Several distinct subunits in the 47,000- to 59,000-dalton range were converted to a single 43,000-dalton subunit during the trypsin treatment, while the other major subunit (155,000 daltons) was unaffected. Nitrate reductase extracted from the membrane fraction with deoxycholate and ammonium sulfate was composed of two apparently homogeneous subunits (155,000 and 59,000 daltons). The detergent-extracted enzyme preparation was converted by trypsin to an electrophoretic form very similar to the product of trypsin treatment of the heat-released enzyme with an identical subunit composition (155,000 and 43,000 daltons). These results demonstrate that the heterogeneous subunits present in the heat-released enzyme are produced during heat treatment by proteolytic cleavage of a single 59,000-dalton subunit. The fragments removed by trypsin treatment are implicated in the self-associating properties of the heat-released enzyme.     

The orientation of transhydrogenase in the inner mitochondrial membrane of rat liver

The orientation of the transmembranous enzyme, pyridine dinucleotide transhydrogenase, in the inner mitochondrial membrane of rat liver has been determined by evaluating effects of proteases on the integrity of the enzyme in mitoplasts and submitochondrial particles. Following treatment of these membranes with the nonspecific protease, proteinase K, antigenic proteolytic products were detected by immunoblot analysis using polyclonal antibody prepared against purified bovine heart enzyme. Proteinase K treatment of mitoplasts converted the 110,000 transhydrogenase monomer into a single immunoreactive species having Mr 75,000. This proteolytic product is stable to further incubation with the protease. Treatment of submitochondrial particles with proteinase K resulted in the disappearance of the 110,000 monomer and the transient formation of an intermediate product with Mr 52,000. Information from these proteolysis studies was used to construct a model of the orientation of transhydrogenase in the inner mitochondrial membrane. This model indicates that transhydrogenase (Mr 110,000) contains a core of proteolytically inaccessible proteins within the membrane (Mr 23,000) bounded by extramembranous domains on the matrix (Mr 52,000) and cytoplasmic (Mr 35,000) face of the inner mitochondrial membrane.     

Purification, structure and properties of the respiratory nitrate reductase of Klebsiella aerogenes.

1. The respiratory nitrate reductase of Klebsiella aerogenes was solubilized from the bacterial membranes by deoxycholate and purified further by means of gel chromatography in the presence of deoxycholate, and anion-exchange chromatography. 2. Dependent on the isolation procedure two different homogeneous forms of the enzyme, having different subunit compositions, can be obtained. These forms are designated nitrate reductase I and nitrate reductase II. Both enzyme preparations are isolated as tetramers having sedimentation constants (s20,w) of 22.1 S and 21.7 S for nitrate reductase I and II, respectively. The nitrate reductase I tetramer has a molecular weight of about 106. 3. In the presence of deoxycholate both enzyme preparations dissociate reversibly into their respective monomeric forms. The monomeric form of nitrate reductase I has a molecular weight of about 260 000 and a sedimentation constant of 9.8 S. For nitrate reductase II these values are 180 000 and 8.5 S, respectively. 4. Nitrate reductase I consists of three different subunits, having molecular weights of 117 000; 57 000 and 52 000, which are present in a 1:1:2 molar ratio, respectively. Nitrate reductase II contains only the subunits with a molecular weight of 117 000 and 57 000 in a equimolar ratio. 5. Treatment at pH 9.5 in the presence of deoxycholate and 0.05 M NaCl or ageing removes the 52 000 Mr subunit from nitrate reductase I. This smallest subunit, in contrast to the other subunits, is a basic protein. 6. The 52 000 Mr subunit has no catalytic function in the intramolecular electron transfer from reduced benzylviologen to nitrate. However, it appears to have a structural function since nitrate reductase II, which lacks this subunit, is much more labile than nitrate reductase I. Inactivation of nitrate reductase II can be prevented by the presence of deoxycholate. 7. The spectrum of the enzyme resembles that of iron-sulfur proteins. No cytochromes or contaminating enzyme activities are present in the purified enzyme. Only reduced benzylviologen was found to be capable of acting as an electron donor. 8. p-Chlormercuribenzoate enhances the enzymatic activity at concentrations of 0.1 mM and lower. At higher p-chlormercuribenzoate concentrations the enzymatic activity is inhibited non-competitively with either nitrate or benzylviologen as a substrate. The inhibition is not counteracted by cysteine.     

Isolation and properties of bovine kidney brush border vacuolar H(+)-ATPase. A proton pump with enzymatic and structural differences from kidney microsomal H(+)-ATPase

Vacuolar H(+)-ATPase was isolated from highly purified bovine kidney brush border, using a previously described immunoaffinity method. The affinity purified enzyme had reconstitutively active ATP-induced acidification that was inhibited by N-ethylmaleimide. The brush border H(+)-ATPase had a single pH optimum of 7.3, and a single Km for ATP of 360 microM. The enzyme showed no lipid activation; it had a substrate preference of ATP greater than ITP greater than UTP greater than GTP much greater than CTP, with an ATP:GTP selectivity of 1.69. The brush border H(+)-ATPase required no monovalent anion or cation for activity and was inhibited by the oxyanions NO3(-1) much greater than SO4(-2); sulfite stimulated activity at low concentrations and inhibited at higher concentrations. The inhibition produced by nitrate could not be attributed to dissociation of subunits from the enzyme. The divalent or trivalent cation preference was Mn+2 much greater than Mg+2 much greater than Co+2 greater than Al+3 greater than Ca+2 much greater than Ba+2,Sr+2; 1 mM Zn+2 inhibited the enzyme completely, but Cu+2 inhibited only 49% of activity at concentrations up to 5 mM. Sodium dodecyl sulfate-polyacrylamide gels of the brush border H(+)-ATPase showed subunits at Mr 70,000, a doublet at 56,000, 45,000, 42,000, 38,000, 33,000, 31,000, 15,000, 14,000, and 12,000. On two-dimensional gels, the pl value for the Mr 70,000 subunit was 6.3, for the Mr 56,000 was 6.4, and for the Mr 31,000 was 7.5-8.5, and microheterogeneity was observed in the Mr 56,000 and 31,000 subunits. A comparison of kidney cortex brush border H(+)-ATPase with kidney cortex microsomal H(+)-ATPase revealed differences in pH optimum, Km for ATP, lipid dependence, substrate preference, divalent ion preference, copper sensitivity, and in microheterogeneity of the Mr 56,000 and 31,000 subunits, providing evidence that different functional and structural classes of vacuolar H(+)-ATPase are segregated to specific membrane compartments.     

Characterization of the respiratory nitrate reductase of Klebsiella aerogenes as a molybdenum-containing iron-sulfur enzyme.

1. In respiratory nitrate reductase I of Klebsiella aerogenes, 0.24 atom of molybdenum, eight iron-sulfur groups and four tightly bound, non-heme iron atoms per molecule of enzyme (Mr 260 000) are found. 2. EPR spectra at 83 degrees K of oxidized and reduced nitrate reductase I show complex lines at g = 2.02 and g = 1.98, which are more intense in the reduced than in the oxidized enzyme. The resonances, the shape and intensity of which are rather temperature insensitive, are attributed to two species of paramagnetic molybdenum. In dithionite-reduced enzyme all these lines are saturated at the same microwave power of 15 mW. This is not the case in oxidized enzyme, where the resonance at g = 2.02 is hard to saturate. Addition of nitrate to dithionite-reduced reductase I decreases the intensity of the EPR lines to about that of oxidized enzyme. The participation of molybdenum in the electron transfer process has been discussed. 3. At 18 degrees K the oxidized enzyme exhibits an axial-symmetrical signal with g parallel = 2.10 and g = 2.03, and a signal with unknown symmetry at g = 2.015. Upon reduction by dithionite, a ferredoxin type of signal is observed with g values at 2.05, 1.95 and 1.88, while the g = 2.015 signal disappears. Reoxidation by nitrate causes a concomitant disappearance of the ferredoxin type of signal and reappearance of the g = 2.015 signal; hence iron-sulfur centres participate in the transfer of electrons to nitrate. 4. Nitrate reductase II, containing only two (Mr 117 000 and 57 000) of the three subunits found in nitrate reductase I and lacking the tightly bound iron, does not exhibit the axial-symmetrical signal (g = 2.10 and 2.03). Thus, it suggested that this signal in nitrate reductase I stems from an iron centre in the low-molecular weight subunit (Mr 52 000). 5. Inhibition studies confirm the participation of metals in the transfer of electrons from reduced benzylviologen to nitrate and show that the binding sites for these substrates are different.     

Isolation and characterisation of a soluble active fragment of hydrogenase isoenzyme 2 from the membranes of anaerobically grown Escherichia coli

An active tryptic fragment of membrane-bound hydrogenase isoenzyme 2 from anaerobically grown Escherichia coli has been purified. The soluble enzyme derivative was released from the membrane fraction by trypsin cleavage. The purification procedure involved ion-exchange, hydroxyapatite and gel permeation chromatography. The enzyme derivative was purified 100-fold from the membrane fraction and the specific activity of the final preparation was 320 mumol benzyl viologen reduced min-1 mg protein-1 (H2:benzyl viologen oxidoreductase). The native enzyme derivative had an Mr of 180,000 and was composed of equimolar amounts of polypeptides of Mr 61,000 and 30,000. It possessed 12.5 mol Fe, 12.8 mol acid-labile S2- and 3.1 mol Ni/180,000 g enzyme. Antibodies were raised to the purified preparation which cross-reacted with hydrogenase isoenzyme 2 but not with isoenzyme 1 in detergent-dispersed preparations. Western immunoblot analysis revealed that isoenzyme 2 which had not been exposed to trypsin contained cross-reacting polypeptides of Mr 61,000 and 35,000. Trypsin treatment of the membrane-bound enzyme to form the soluble derivative of isoenzyme 2, therefore, cleaves a polypeptide of Mr 35,000 to produce the 30,000-Mr fragment. Trypsin treatment of the detergent-dispersed isoenzyme 2 produces the same fragmentation of the enzyme. Neither of the subunits of the enzyme revealed any immunological identity with those of hydrogenase isoenzyme 1.     

p-cresol methylhydroxylase from a denitrifying bacterium involved in anaerobic degradation of p-cresol

A bacterium, strain PC-07, previously isolated as part of a coculture capable of growing on p-cresol under anaerobic conditions with nitrate as the acceptor was identified as an Achromobacter sp. The first enzyme of the pathway, p-cresol methylhydroxylase, which converts its substrate into p-hydroxybenzyl alcohol, was purified. The enzyme had an Mr of 130,000 and the spectrum of a flavocytochrome. It was composed of flavoprotein subunits of Mr 54,000 and cytochrome subunits of Mr 12,500. The midpoint redox potential of the cytochrome was 232 mV. The Km and kcat for p-cresol were 21 microM and 112 s-1 respectively, and the Km for phenazine methosulfate, the artificial acceptor used in the assays, was determined to be 1.7 mM. These properties place the enzyme in the same class as the p-cresol methylhydroxylases from aerobically isolated Pseudomonas spp.     

Solubilization and some properties of a semicarbazide-sensitive amine oxidase in brown adipose tissue of the rat.

A semicarbazide-sensitive clorgyline-resistant amine oxidase (SSAO) was solubilized from membrane fractions of rat brown adipose tissue by the non-ionic detergent, Triton X-100. Alteration of ionic strength or addition of chelating agents alone failed to release the enzyme from its membrane. Lipid-depletion led to loss of enzyme activity and alteration of substrate affinity. Over 80% of the activity of the solubilized enzyme was found in gel filtration fractions corresponding to an Mr of between 160 000 and 180 000. The glycoprotein nature of SSAO was established from affinity chromatography with either immobilized concanavalin A or Lens culinaris lectin. Elution of over 50% SSAO activity from the lentil lectin was achieved with 0.25M-alpha-methyl D-mannoside to give 80-90-fold purification of the enzyme. Irradiation inactivation gave a value for Mr of around 183 000 for both soluble and membrane-bound SSAO. Substrate affinity and inhibitor sensitivity of the enzyme were unaltered by solubilization. The copper-chelating agent, diethyldithiocarbamate, did not affect the enzyme, shedding doubt on the suggestion that SSAO is a copper-requiring enzyme. The significance of these findings in relation to the nature of SSAO and to its disposition within the cell membrane is discussed.     

Receptor-mediated activation of spermatozoan guanylate cyclase

The sea urchin egg peptides speract (Gly-Phe-Asp-Leu-Asn-Gly-Gly-Gly-Val-Gly) and resact (Cys-Val-Thr-Gly-Ala-Pro-Gly-Cys-Val-Gly-Gly-Arg-Leu-NH2) bind to spermatozoa of the homologous species (Lytechinus pictus or Arbacia punctulata, respectively) and cause transient elevations of cyclic GMP concentrations (Hansbrough, J. R., and Garbers, D. L. (1981) J. Biol. Chem. 256, 1447-1452). The addition of these peptides to spermatozoan membrane preparations caused a rapid and dramatic (up to 25-fold) activation of guanylate cyclase. The peptide-induced activation of guanylate cyclase was transient, and the subsequent decline in enzyme activity coincided with conversion of a high Mr (phosphorylated) form of guanylate cyclase to a low Mr (dephosphorylated) form. When membranes were incubated at pH 8.0, the high Mr form was converted to the low Mr form without substantial changes in basal enzyme activity. However, the peptide-stimulated activity of the low Mr form of guanylate cyclase was much less than the peptide-stimulated activity of the high Mr form. Activation of the low Mr form by peptide was not transient and persisted for at least 10 min. In addition, the pH 8.0 treatment that caused the Mr conversion of guanylate cyclase also caused an increase in the peptide-binding capacity of the membranes. We propose a model in which activation of the membrane form of guanylate cyclase is receptor-mediated; the extent of enzyme activation is modulated by its phosphorylation state.     

Purification and properties of membrane-bound hydrogenase isoenzyme 1 from anaerobically grown Escherichia coli K12

Hydrogenase isoenzyme 1 from the membrane fraction of anaerobically grown Escherichia coli has been purified to near homogeneity. The preparation involved dispersion of the membrane fraction with deoxycholate followed by ammonium sulphate precipitation, ion-exchange, hydroxyapatite and gel filtration chromatography steps. The enzyme was assayed by quantification of the H2:benzyl viologen oxidoreductase activity immunoprecipitated by a non-inhibitory antiserum specific for the enzyme. The enzyme constituted about 8% of the hydrogenase activity found in the detergent-dispersed membranes, the remainder being attributable to hydrogenase isoenzyme 2. Isoenzyme 1 was purified 130-fold and the specific activity of the final preparation was 10.6 mumol benzyl viologen reduced min-1 (mg protein)-1 (H2:benzyl viologen oxidoreductase). The final preparation contained polypeptides of apparent Mr 64,000, 31,000 and 29,000. Antibodies were raised both to the final preparation and to immunoprecipitation arcs containing hydrogenase isoenzyme 1, excised from crossed immunoelectrophoresis plates. The former cross-reacted with all three polypeptides in the enzyme preparation but the latter recognised only the Mr-64,000 polypeptide. Immunological analysis revealed that the polypeptides of apparent Mr 31,000 and 29,000 are fragments of a single polypeptide of Mr 35,000 which is present in the detergent-dispersed membranes. The fragmentation of the Mr-35,000 polypeptide during the preparation correlates with a change in the electrophoretic mobility of the enzyme. A similar electrophoretic mobility change was observed, accompanied by cleavage of the Mr-35,000 polypeptide to one of 32,000 when the enzyme was analysed after exposure of detergent-dispersed membranes to trypsin. The enzyme in the detergent-dispersed membranes consists minimally of two subunits of Mr 64,000 and two subunits of Mr 35,000. It contained 12.2 mol Fe and 9.1 mol acid-labile S2-/200,000 g enzyme. The enzyme, purified from bacteria grown in the presence of 63Ni, was found to contain 0.64 (+/- 0.20) mol Ni/200,000 g enzyme. A constant ratio of 63Ni immunoprecipitated to hydrogenase isoenzyme 1 activity immunoprecipitated by antiserum specific for the enzyme was observed during the preparation, consistent with Ni being part of the enzyme. The enzyme has a low Km for H2 (2.0 microM) in the H2:benzyl viologen oxidoreductase assay. It catalyses H2 evolution employing reduced methyl viologen as electron donor. It is inhibited reversibly by CO and irreversibly by N-bromosuccinimide.     

Identification of the membrane form of phenylalanine hydroxylase from the human liver and characteristics of its subunit composition

Phenylalanine hydroxylase was detected among human liver bioptats and autoptats extracted with 0.4% Triton X-100 from the 105,000 g homogenate fraction. In contrast to the membrane form of the rat liver enzyme, human liver phenylalanine hydroxylase is detected both by its enzymatic activity and immunochemically under non-denaturating conditions. The enzymatic activity of phenylalanine hydroxylase makes 5-15% of that of the cytoplasmic fraction and 20-30% of the amount of antigen in the cytoplasmic fraction and 20-30% of the amount of antigen in the cytoplasmic fraction as can be evidenced from rocket immunoelectrophoresis data. Immunoblotting of proteins performed after denaturating electrophoresis of the membrane and cytoplasmic fractions revealed an antigen band with a similar electrophoretic mobility. The subunit composition of the enzyme in both fractions was characterized by two-dimensional electrophoresis with subsequent immunoblotting. It was found that the membrane fraction of the enzyme is represented only by the L-subunit with Mr of 55 kD, whereas the cytoplasmic fraction, besides the predominant L-subunit, also contains 2H-subunits of the enzyme with Mr = 57 kD. These 2H-subunits differ between themselves as well as from the L-subunit by the pI value.     

Purification of the Neurospora crassa plasma membrane H+-ATPase by high-pressure liquid chromatography in the presence of sodium dodecyl sulfate

Current methods for purifying the Mr 100,000 H+-ATPase from the plasma membrane of fungi and higher plants rely on detergent solubilization followed by density gradient centrifugation. The procedure yields catalytically active enzyme of high purity but takes several days, and the yields are low. For chemical studies on the primary structure of this enzyme, an alternative more rapid procedure was sought. In this paper a method which uses a high-performance gel filtration column in the presence of sodium dodecyl sulfate to purify nanomole quantities of the enzyme in only 30 min is described. With this procedure the enzyme was isolated free of other protein contaminants, as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Gel filtration was performed on a high-pressure liquid chromatograph equipped with a diode array spectrophotometric detector, allowing spectral analysis of the membrane proteins. An ultraviolet absorption spectrum of the plasma membrane Mr 104,000 H+-ATPase revealed an absorption peak at ca. 275 nm that is consistent with its content of aromatic amino acids.     

Identification and localization of enzymes of the fumarate reductase and nitrate respiration systems of escherichia coli by crossed immunoelectrophoresis

Crossed immunoelectrophoresis was used to analyze the components of membrane vesicles of anaerobically grown Escherichia coli. The number of precipitation lines in the crossed immunoelectrophoresis patterns of membrane vesicles isolated from E. coli grown anaerobically on glucose plus nitrate and on glycerol plus fumarate were 83 and 70, respectively. Zymogram staining techniques were used to identify immunoprecipitates corresponding to nitrate reductase, formate dehydrogenase, fumarate reductase, and glycerol-3-phosphate dehydrogenase in crossed immunoelectrophoresis reference patterns. The identification of fumarate reductase by its succinate oxidizing activity was confirmed with purified enzyme and with mutants lacking or overproducing this enzyme. In addition, precipitation lines were found for hydrogenase, cytochrome oxidase, the membrane-bound ATPase, and the dehydrogenases for succinate, malate, dihydroorotate, D-lactate, 6-phosphogluconate, and NADH. Adsorption experiments with intact and solubilized membrane vesicles showed that fumarate reductase, hydrogenase, glycerol-3-phosphate dehydrogenase, nitrate reductase, and ATPase are located at the inner surface of the cytoplasmic membrane; on the other hand, the results suggest that formate dehydrogenase is a transmembrane protein.     

Purification and properties of the phosphorylated form of guanylate cyclase

Guanylate cyclase is dephosphorylated in response to the interaction of egg peptides with a spermatozoan surface receptor (Suzuki, N., Shimomura, H., Radany, E. W., Ramarao, C. S., Ward, G. E., Bentley, J. K., and Garbers, D. L. (1984) J. Biol. Chem. 259, 14874-14879). Here, the phosphorylated form of guanylate cyclase was purified to apparent homogeneity from detergent-solubilized spermatozoan membranes by the use of GTP-agarose, DEAE-Sephacel, and concanavalin A-Sepharose chromatography. To prevent dephosphorylation of the enzyme during purification, glycerol (35%) was required in all buffers. Following purification, a single protein-staining band of Mr 160,000 was obtained on sodium dodecyl sulfate-polyacrylamide gels. The final specific activity of the purified enzyme was 83 mumol of cyclic GMP formed/min/mg of protein at 30 degrees C, an activity 5-fold higher than that observed with the purified, dephosphorylated form of guanylate cyclase. A preparation containing protein phosphatase from spermatozoa, or highly purified alkaline phosphatase (from Escherichia coli), catalyzed the dephosphorylation of the enzyme; this resulted in a subsequent decrease in guanylate cyclase activity and a shift in the Mr from 160,000 to 150,000. The phosphate content of the high Mr form of the enzyme was 14.6 mol/mol protein whereas the phosphate content of the low Mr form was 1.6 mol/mol protein. All phosphate was localized on serine residues. The Mr 160,000 form of guanylate cyclase demonstrated positive cooperative kinetics with respect to MnGTP while the Mr 150,000 form displayed linear, Michaelis-Menten type kinetics. The phosphorylation state of the membrane form of guanylate cyclase, therefore, appears to dictate not only the absolute activity of the enzyme but also the degree of cooperative interaction between catalytic or GTP-binding sites.     

The existence and properties of two dimers of rat liver ecto-5''-nucleotidase.

Immunoaffinity-purified rat liver 5'-nucleotidase contained two subunits of Mr 70 000 (alpha) and 38 000 (beta). Charge-shift electrophoresis and chemical cross-linking revealed that approx. 80% of the solubilized enzyme activity occurred as an alpha alpha-dimer of Mr 140 000. The remaining 20% was an alpha beta-dimer of Mr 108 000. The beta-subunit did not possess enzymic activity. Peptide mapping and immunoblotting with antibodies against the alpha- and beta-subunits showed that the beta-subunit was homologous with a part of the alpha-subunit. Three monoclonal antibodies against rat liver 5'-nucleotidase were characterized as binding to the extracellular domain of the enzyme. All three monoclonal antibodies and concanavalin A bound to the alpha-subunit, but no binding could be detected to the beta-subunit. It was therefore concluded that the beta-subunit was a fragment of an alpha-subunit that had lost an extracellular domain. Both forms of the enzyme occurred in freshly solubilized membrane preparations as well.