Cytosol components from human placenta and rat liver in iodothyronine 5- and 5'-deiodination

Using either human placental microsomal 5-deiodinase as enzyme (5-DI) and thyroxine as substrate or rat liver (RL) microsomal 5'-deiodinase (5'DI) as enzyme and reverse [(3'- or 5'-)-125I]triiodo-L-thyronine ([125I]rT3) as substrate, activation of 5'-DI in the presence of NADPH was observed using either human placental or rat liver cytosolic components, but there was no activation of 5-DI. Both could be activated by DTT, with higher concentrations being required for 5-DI than for 5'-DI. Iopanoic acid, dicumarol, and sodium arsenite inhibited 5'-DI and 5-DI activated by DTT. In the presence of DTT, 1 mM 6-propyl-2-thiouracil had no effect on 5-DI but inhibited 5'DI. Thus, human placental and rat liver cytosolic components are interchangeable in activating hepatic 5'-DI in the presence of NADPH. However, if an endogenous cofactor system involved in the activation of human placental 5-DI exists, it probably differs from the activator of liver 5'-DI.     

Properties of cytosolic components activating rat hepatic 5'' [corrected]-deiodination in the presence of NADPH.

The effects of cytosol, NADPH and reduced glutathione (GSH) on the activity of 5'-deiodinase were studied by using washed hepatic microsomes from normal fed rats. Cytosol alone had little stimulatory effect on the activation of microsomal 5'-deiodinase. NADPH had no stimulatory effect on the microsomal 5'-deiodinase unless cytosol was added. 5'-deiodinase activity was greatly enhanced by the simultaneous addition of NADPH and cytosol (P less than 0.001); this was significantly higher than that with either NADPH or cytosol alone (P less than 0.001). GSH was active in stimulating the enzyme activity in the absence of cytosol, but the activity of 5'-deiodinase with 62 microM-NADPH in the presence of cytosol was significantly higher than that with 250 microM-GSH in the presence of the same concentration of cytosol (P less than 0.001). The properties of the cytosolic components essential for the NADPH-dependent activation of microsomal 5'-deiodinase independent of a glutathione/glutathione reductase system were further assessed using Sephadex G-50 column chromatography to yield three cytosolic fractions (A, B and C), wherein A represents pooled fractions near the void volume, B pooled fractions of intermediate Mr (approx. 13 000), and C of low Mr (approx. 300) containing glutathione. In the presence of NADPH (1 mM), the 5'-deiodination rate by hepatic washed microsomes is greatly increased if both A and B are added and is a function of the concentrations of A, B, washed microsomes and NADPH. A is heat-labile, whereas B is heat-stable and non-dialysable. These observations provide the first evidence of an NADPH-dependent cytosolic reductase system not involving glutathione which stimulates microsomal 5'-deiodinase of normal rat liver. The present data are consistent with a deiodination mechanism involving mediation by a reductase (other than glutathione reductase) in fraction A of an NADPH-dependent reduction of a hydrogen acceptor in fraction B, followed by reduction of oxidized microsomal deiodinase by the reduced acceptor (component in fraction B).     

Intermediate Mr cytosolic components potentiate hepatic 5''-deiodinase activation by thiols.

The role in the activation of microsomal 5'-deiodinase (5'-DI) of rat hepatic cytosolic components of Mr approx. 13,000 (Fraction B) was studied in the presence of various concentrations of thiol compounds such as dithiothreitol (DTT), dihydrolipoamide (DHLA), GSH, and 2-mercaptoethanol (2-ME). Although Fraction B (which was prepared by gel filtration to exclude GSH and GSSG) had no intrinsic 5'-DI activity, could not stimulate microsomal 5'-DI activity in the absence of added thiol and did not contain GSH as a mixed disulphide, it could produce a 3-fold increase in the maximal deiodinase activity achievable with DTT as well as other thiols, with the order being the same as the activation potency of these thiols in the absence of Fraction B (i.e. DHLA greater than DTT greater than 2-ME greater than GSH). These observations suggest that: a component of cytosolic Fraction B, designated 'deiodination factor B' (DFB), operates as an efficient intermediary to enhance activation of microsomal 5'-DI by thiols through a mechanism independent of GSH; thiols may participate in a non-specific thiol-disulphide exchange with inactive (oxidized) DFB to convert it into an active form that contains one or more thiol groups and is more effective than GSH or other thiols in facilitating the re-activation of inactive (oxidized) microsomal 5'-DI thiol (ESI) to its active state (ESH).     

Purification and partial characterization of squalene epoxidase from rat liver microsomes

Squalene epoxidase (EC 1.14.99.7, squalene 2,3-monooxygenase (epoxidizing) was purified to an apparent homogeneity from rat liver microsomes. The purification was carried out by solubilization of microsomes by Triton X-100, fractionation with ion exchangers, hydroxyapatite, Cibacron Blue Sepharose 4B, and chromatofocusing column chromatography. A total purification of 143-fold over the first DEAE-cellulose fraction was achieved. The purified enzyme gave a single major band on SDS-polyacrylamide gel electrophoresis and the Mr was estimated to be 51 000 as a single polypeptide chain. The enzyme showed no distinct absorption spectrum in the visible regions. The squalene epoxidase activity was reconstituted with the purified enzyme, NADPH-cytochrome P-450 reductase (EC 1.6.2.4), FAD, NADPH and molecular oxygen in the presence of Triton X-100. The apparent Michaelis constants for squalene and FAD were 13 microM and 5 microM, respectively. The Vmax was about 186 nmol per mg protein per 30 min for 2,3-oxidosqualene. The enzyme activity was not inhibited by potent inhibitors of cytochrome P-450. It is suggested that squalene epoxidase is distinct from cytochrome P-450 isozymes.     

Protease inhibitors but not proteases inhibit the glucose-6-phosphatase of native rat liver microsomes.

Controlled proteolytic digestion by trypsin or bacterial proteases limited to the cytosolic side of the native microsomal membrane is not efficient to inhibit glucose-6-phosphate hydrolysis. Modification of the microsomes with deoxycholate prior to protease treatment is prerequisite to allow accessibility of the integral protein and inhibition of enzyme activity. Glucose-6-phosphatase of native microsomes, however, is rapidly inactivated by micromolar concentrations of TPCK as well as TLCK. In deoxycholate-modified microsomes both reagents do not affect glucose-6-phosphate hydrolysis. These results indicate that in the native, intact microsomal membrane glucose-6-phosphatase is not accessible to proteolytic attack from the cytoplasmic surface. The putative inhibitory effect of some trypsin or bacterial protease preparations on glucose-6-phosphatase of native microsomes observed most possibly is a result of contaminating agents as TPCK or TLCK.     

Resolution of a low molecular weight G protein in neutrophil cytosol required for NADPH oxidase activation and reconstitution by recombinant Krev-1 protein

Activation of the membrane-associated NADPH oxidase in intact human neutrophils requires a receptor-associated heterotrimeric GTP-binding protein that is sensitive to pertussis toxin. Activation of this NADPH oxidase by arachidonate in a cell-free system requires an additional downstream pertussis toxin-insensitive G protein (Gabig, T. G., English, D., Akard, L. P., and Schell, M. J. (1987) (J. Biol. Chem. 262, 1685-1690) that is located in the cytosolic fraction of unstimulated cells (Gabig, T. G., Eklund, E. A., Potter, G. B., and Dykes, J. R. (1990) J. Immunol. 145, 945-951). In the present study, immunodepletion of G proteins from the cytosolic fraction of unstimulated neutrophils resulted in a loss of the ability to activate NADPH oxidase in the membrane fraction. The activity in immunodepleted cytosol was fully reconstituted by a partially purified fraction from neutrophil cytosol that contained a 21-kDa GTP-binding protein. Purified human recombinant Krev-1 p21 also completely reconstituted immunodepleted cytosol whereas recombinant human H-ras p21 or yeast RAS GTP-binding proteins had no reconstitutive activity. Rabbit antisera raised against a synthetic peptide corresponding to the effector region of Krev-1 (amino acids 31-43) completely inhibited cell-free NADPH oxidase activation, and this inhibition was blocked by the synthetic 31-43 peptide. An inhibitory monoclonal antibody specific for ras p21 amino acids 60-77 (Y13-259) had no effect on cell-free NADPH oxidase activation. Activation of the NADPH oxidase in intact neutrophils by stimulation with phorbol myristate acetate caused a marked increase in the amount of membrane-associated antigen recognized by 151 antiserum on Western blot. Thus a G protein in the cytosol of unstimulated neutrophils antigenically and functionally related to Krev-1 may be the downstream effector G protein for NADPH oxidase activation. This system represents a unique model to study molecular interactions of a ras-like G protein.     

Desaturation of polyunsaturated fatty acids in Mucor circinelloides and the involvement of a novel membrane-bound malic enzyme.

1. The component fatty acids of the endogenous phospholipids of microsomal preparations of Mucor, when shaken at 30 degrees C, increased in both chain length and in degree of unsaturation. The net effect was the production of gamma-linolenic acid which, over 2 h, increased from 17% to 32% of total fatty acids present. No further significant changes occurred after this time. 2. The major site for desaturation/elongation reactions was at the sn-2 position of PtdIns. PtdCho and PtdEtn were not implicated. 3. Of numerous metabolites and cofactors added to the microsomes, only malate could prolong the elongation/desaturation reactions for up to 6 h. This effect was shown to be due to a membrane-associated malic enzyme [malate dehydrogenase (decarboxylating) NADP+] with the NADPH produced being used in fatty-acid desaturation. 4. Kinetic analysis of cytosolic and microsomal enzymes [both in 0.1% (mass/vol.) Chaps] could not distinguish between them. However, when the microsomal malic enzyme was dialysed to remove Chaps, it lost 90% of activity, although the cytosolic malic enzyme lost only 20% activity. 5. The structural analogue of malate, tartronic acid, which is an inhibitor of malic enzyme, also inhibited the malate-induced stimulation of fatty-acyl group desaturation and elongation in the microsomal membranes. 6. It is concluded that two distinct malic enzymes exist, one soluble and one membrane bound, with similar active sites. Both have different roles in the production of NADPH, for lipid metabolism. The former will produce NADPH for fatty-acid biosynthesis whilst the latter produces NADPH for fatty-acid desaturation.     

Microsomal membrane permeability and the hepatic glucose-6-phosphatase system. Interactions of the system with D-mannose 6-phosphate and D-mannose.

We have proposed that glucose-6-phosphatase (EC 3.1.3.9) is a two-component system consisting of (a) a glucose-6-P-specific transporter which mediates the movement of the hexose phosphate from the cytosol to the lumen of the endoplasmic reticulum (or cisternae of the isolated microsomal vesicle), and (b) a nonspecific phosphohydrolase-phosphotransferase localized on the luminal surface of the membrane (Arion, W.J., Wallin, B.K., Lange, A.J., and Ballas, L.M. (1975) Mol. Cell. Biochem. 6, 75-83). Additional support for this model has been obtained by studying the interactions of D-mannose-6-P and D-mannose with the enzyme of untreated (i.e. intact) and taurocholate-disrupted microsomes. An exact correspondence was shown between the mannose-6-P phosphohydrolase activity at low substrate concentrations and the permeability of the microsomal membrane to EDTA. The state of intactness of the membrane influenced the kinetics of mannose inhibition of glucose-6-P hydrolysis; uncompetitive and noncompetitive inhibitions were observed for intact and disrupted microsomes, respectively. The apparent Km for glucose-6-P was smaller with intact preparations at mannose concentrations above 0.3 M. Mannose significantly inhibited total glucose-6-P utilization by intact microsomes, whereas D-glucose had a stimulatory effect. Both hexoses markedly enhanced the rate of glucose-6-P utilization by disrupted microsomes. The actions of mannose on the glucose-6-phosphatase of intact microsomes fully support the postulated transport model. They are predictable consequences of the synthesis and accumulation of mannose-6-P in the cisternae of microsomal vesicles which possess a nonspecific, multifunctional enzyme on the inner surface and a limiting membrane permeable to D-glucose, D-mannose, glucose-6-P, but impermeable to mannose-6-P. The latency of the mannose-6-P phosphohydrolase activity is proposed as a reliable, quantitative index of microsomal membrane integrity. The inherent limitations of the use of EDTA permeability for this purpose are discussed.     

Biospecific adsorption of hepatic DT-diaphorase on immobilized dicoumarol. II. Purification of mitochondrial and microsomal DT-diaphorase from 3-methylcholanthrene-treated rats

Liver mitochondrial and microsomal DT-diaphorase have been purified from 3-methylcholanthrene-treated rats. A 1150-fold and 3500-fold purification of mitochondrial and microsomal DT-diaphorase, respectively, is achieved after solubilization of the membranes with deoxycholate followed by affinity chromatography on azodicoumarol Sepharose 6B and subsequent gel filtration on Sephadex G-100. From this purification procedure, 65–70% of mitochondrial DT-diaphorase is recovered and the purified enzyme has a specific activity comparable to that of cytosolic DT-diaphorase; i.e., 50.4 kat/kg protein. Microsomal DT-diaphorase is obtained with a yield of 45% and a specific activity of 15.5 kat/kg protein.Purified mitochondrial DT-diaphorase exhibits an absorption spectrum characteristic of a flavoprotein and very similar to that of the cytosolic enzyme. Purification of both mitochondrial and microsomal DT-diaphorase results in fractions enriched in a polypeptide with a molecular weight of 28,000 which comigrates with purified cytosolic DT-diaphorase on SDS-polyacrylamide gel electrophoresis. Employing antiserum raised against cytosolic DT-diaphorase, immunological identity between DT-diaphorase isolated from the three cell fractions is observed with both the Ouchterlony immunodiffusion technique and fused rocket immunoelectrophoresis. The latter method also reveals that DT-diaphorase isolated from mitochondria and microsomes contains several antigenic forms identical to those observed in purified cytosolic DT-diaphorase. Furthermore, this antiserum inhibits DT-diaphorase to about the same extent whether the enzyme is isolated from mitochondria, microsomes, or cytosol. In addition, this antiserum efficiently inhibits membrane-bound microsomal DT-diaphorase.     

Cytosolic activation of 2-aminoanthracene: implications in its use as diagnostic mutagen in the Ames test.

The metabolic activation of 2-aminoanthracene to mutagens in the Ames test was investigated using hepatic S9, microsomal and cytosolic fractions from control and Aroclor 1254-treated rats as activation systems. Microsomal and S9 preparations from control animals could activate 2-aminoanthracene, but the efficiency of activation was suppressed by pretreatment of animals with Aroclor 1254. Cytosolic fractions from Aroclor 1254-treated rats could readily activate the promutagen more readily than microsomes. The cytosolic activation of 2-aminoanthracene required NADPH and could not be accounted for by possible microsomal contamination. The molybdenum oxygenases appear not to contribute to the cytosolic activation of this promutagen. It is concluded that (a) the microsomal activation of 2-aminoanthracene is catalysed more effectively by enzyme systems other than the P450 I family and (b) an enzyme system capable of activating this carcinogen in vitro is present in the hepatic cytosol. The implications of these findings in the use of 2-aminoanthracene as a positive control in the Ames test are discussed.     

Purification and characterization of the NADPH-cytochrome P-450 (cytochrome c) reductase from higher-plant microsomal fraction.

NADPH-cytochrome P-450 (cytochrome c) reductase (EC 1.6.2.4) was solubilized by detergent from microsomal fraction of wounded Jerusalem-artichoke (Helianthus tuberosus L.) tubers and purified to electrophoretic homogeneity. The purification was achieved by two anion-exchange columns and by affinity chromatography on 2',5'-bisphosphoadenosine-Sepharose 4B. An Mr value of 82,000 was obtained by SDS/polyacrylamide-gel electrophoresis. The purified enzyme exhibited typical flavoprotein redox spectra and contained equimolar quantities of FAD and FMN. The purified enzyme followed Michaelis-Menten kinetics with Km values of 20 microM for NADPH and 6.3 microM for cytochrome c. In contrast, with NADH as substrate this enzyme exhibited biphasic kinetics with Km values ranging from 46 microM to 54 mM. Substrate saturation curves as a function of NADPH at fixed concentration of cytochrome c are compatible with a sequential type of substrate-addition mechanism. The enzyme was able to reconstitute cinnamate 4-hydroxylase activity when associated with partially purified tuber cytochrome P-450 and dilauroyl phosphatidylcholine in the presence of NADPH. Rabbit antibodies directed against plant NADPH-cytochrome c reductase affected only weakly NADH-sustained reduction of cytochrome c, but inhibited strongly NADPH-cytochrome c reductase and NADPH- or NADH-dependent cinnamate hydroxylase activities from Jerusalem-artichoke microsomal fraction.     

5′-Nucleotidase from bovine brain cortex: effect of solubilization on enzyme kinetics and modulation

The kinetic characteristics and the EDTA inhibition of microsomal 5′-nucleotidase from bovine brain cortex were studied and compared with the properties of the enzyme solubilized with Lubrol WX. The K_m value after enzyme solubilization was not significantly different from that of the membrane-bound enzyme. Likewise, di- and trinucleotides performed a similar competitive inhibition of the two forms of the enzyme. In contrast, divalent cations inhibited the intact microsomal enzyme activity at the same concentrations in which they increased the soluble-enzyme activity. The solubilization of microsomal 5′-nucleotidase did not change the progressive and irreversible character of the EDTA inhibition, but the mechanism of the irreversible inhibition was different. The addition of divalent metal cations did not affect the irreversibility of either inhibition, even though the effect on the residual activities was different. The Arrhenius plot of the 5′-nucleotidase activity in intact microsomal fraction exhibited a well-defined break at 31 ± 0.1°C, whereas that of the solubilized enzyme was a straight line. It is concluded then that microsomal 5′-nucleotidase from bovine brain cortex does not require the membrane environment to express its activity, although the influence of this lipidic environment was evident in the differences observed in the enzyme activity modulation by EDTA, cations and temperature.     

NADPH-dependent generation of a cytosolic dithiol which activates hepatic iodothyronine 5''-deiodinase. Demonstration by alkylation with iodoacetamide.

We have assessed a previously proposed mechanism mediating 5'-deiodinase activation involving enzymic reduction of disulphides to thiols in non-glutathione cytosolic components of Mr approx. 13,000 (Fraction B) catalysed by NADPH in the presence of other cytosolic components of Mr greater than 60,000 (Fraction A). The extent of Fraction B reduction under various experimental conditions was monitored by determining the amount of 14C incorporated into chromatographically isolated Fractions B and A after their alkylation with iodo[14C]acetamide. Incorporation of 14C into B was found to require the simultaneous presence of NADPH and A, to be directly proportional to the concentration of NADPH added, and to be unaffected by either propylthiouracil or iopanoate. Activation of 5'-deiodinase attainable using B after its partial reduction by various concentrations of NADPH and subsequent alkylation with non-radioactive iodoacetamide was inversely proportional to the previously added concentration of NADPH. Fraction B was stable at 100 degrees C for 5 min, while similar heat treatment of Fraction A or omission of NADPH resulted in a complete loss of 14C incorporation. A greater than 90% reduction in iodo[14C]acetamide incorporation was revealed when 0.2 mM-sodium arsenite was added after enzymic reduction of B, as well as when NADPH was replaced by NADH. Fraction B could be labelled more extensively after reduction non-specifically, with dithiothreitol or NaBH4, but not by GSH. These observations provide strong evidence for the presence in vivo of a cytosolic disulphide (DFBS2) in Fraction B which can be reduced enzymically to a dithiol [DFB(SH)2] by NADPH and cytosolic components in Fraction A. The degree of activation of hepatic 5'-deiodinase correlated with the amount of available (unalkylated) Fraction B.     

Distribution of 5'-nucleotidase in muscle of some marine fishes.

A preliminary examination for the purification and characterization of 5'-nucleotidase of fish muscle was carried out and the following results were obtained. 1. The activities of 5'-nucleotidase in the muscles of marine vertebrates and invertebrates (total 11 species) were determined. The highest activity of 5'-nucleotidase was found in Blackrock fish Sebastes inermis, which was then used as a material for estimation of subcellular distribution and solubilization of the enzyme. 2. The 5'-nucleotidase of ordinary muscle of the fish Sebastes inermis was found in nuclear, microsomal and cytosolic fractions. About half of the total activity was found in the nuclear fraction, whereas the highest specific activity was observed in the microsomal fraction. 3. Complete solubilization of the enzyme was attained by using a high concentration of detergent such as Triton X-100, CHAPS, octylglucoside, octylthioglucoside and sodium deoxycholate, suggesting that the enzyme was tightly bound to the membrane. 4. Based on the results of solubility and stability tests, Triton X-100 seemed suitable for solubilizing 5'-nucleotidase from the membrane. 5. Microsomal 5'-nucleotidase was an Mg(2+)-activated enzyme, and no inactivation was observed up to 50 mM of Mg2+.     

Hepatic microsomal alcohol-oxidizing system. Affinity for methanol, ethanol, propanol, and butanol.

Oxidation of methanol, ethanol, propanol, and butanol by the microsomal fraction of rat liver homogenate is described. This microsomal alcohol-oxidizing system is dependent on NADPH and molecular oxygen and is partially inhibited by CO, features which are common for microsomal drug-metabolizing enzymes. The activity of the microsomal alcohol-oxidizing system could be dissociated from the alcohol peroxidation via catalase-H2O2 by differences in substrate specificity, since higher aliphatic alcohols react only with the microsomal system, but not with catalase-H2O2. Following solubilization of microsomes by ultrasonication and treatment with deoxycholate, the activity of the microsomal alcohol-oxidizing system was separated from contaminating catalase by DEAE-cellulose column chromatography, ruling out an obligatory involvement of catalase-H2O2 in the activity of the NADPH-dependent microsomal alcohol-oxidizing system. In intact hepatic microsomes, the catalase inhibitor sodium azide slightly decreased the oxidation of methanol and ethanol, but not that of propanol and butanol, indicating a facultative role of contaminating catalase in the microsomal oxidation of lower aliphatic alcohols only. It is suggested that the microsomal alcohol-oxidizing system accounts, at least in part, for that fraction of hepatic alcohol metabolism which is independent of the pathway involving alcohol dehydrogenase activity.     

Topology of glutathione-insulin transhydrogenase in rat liver microsomes

Glutathione-insulin transhydrogenase (EC 1.8.4.2) catalyzes the inactivation of insulin through scission of the disulfide bonds to form insulin A and B chains. In the liver, the transhydrogenase occurs primarily in the microsomal fraction where most of the enzyme is present in a latent (‘inactive’) state. We have isolated rat hepatic microsomes with latent transhydrogenase activity being an integral part of the vesicles. We have used these vesicles to study the topological location of glutathione-insulin transhydrogenase by investigating the effects of detergents (Triton X-100 and sodium deoxycholate), phospholipase A₂ and proteinases (trypsin and thermolysin) on the latent enzyme activity. Treatment of intact vesicles with variable concentrations of detergents and phospholipase A₂ resulted in the unmasking of latent transhydrogenase activity. The extent of unmasking of transhydrogenase activity is dependent upon the concentration of detergent or phospholipase used and is accompanied by a parallel release of the enzyme into the soluble fraction. Activation of the transhydrogenase by phospholipase A₂ is partially inhibited by bovine serum albumin and the extent of inhibition is inversely proportional to the phospholipase concentration. In intact vesicles, latent transhydrogenase activity is resistant to proteolytic inactivation by both trypsin and thermolysin, while in semipermeable and permeable vesicles these proteases inactivate 60 and 25% of the total transhydrogenase activity, respectively. Together these results indicate that in microsomes transhydrogenase is probably weakly bound to membrane phospholipid components and that most of the enzyme is present on the cisternal surface (i.e., the luminal surface of endoplasmic reticulum) of microsomes. Each detergent and phospholipase apparently unmasks glutathione-insulin transhydrogenase activity through disruption of the phospholipid-enzyme interaction followed by translocation of the enzyme to the soluble (cytoplasmic) fraction and not through increases in substrate availability.     

Photoaffinity labeling of insulin-sensitive hexose transporters in intact rat adipocytes. Direct evidence that latent transporters become exposed to the extracellular space in response to insulin

Irradiation of intact rat adipocytes with high intensity ultraviolet light in the presence of 0.5 microM [3H] cytochalasin B results in the labeling of Mr 43,000 and 46,000 proteins that reside in the plasma membrane fraction. In contrast to the Mr 46,000 protein, the Mr 43,000 component is not observed in the microsome fraction and exhibits lower affinity for [3H]cytochalasin B. Photolabeling of the Mr 43,000 protein is inhibited by cytochalasin D, indicating it is not a hexose transporter component. The Mr 46,000 protein exhibits characteristics expected for the glucose transporter such that D-glucose or 3-O-methylglucose but not cytochalasin D inhibits its photolabeling with [3H] cytochalasin B. Furthermore, insulin addition to intact cells either prior to or after photoaffinity labeling of the Mr 46,000 protein causes a redistribution of this component from the low density microsomes to the plasma membrane fraction, as expected for the hexose transporter. Photolabeling of transporters in both the low density microsome and plasma membrane fractions is inhibited when intact cells are equilibrated with 50 mM ethylidene glucose prior to irradiation with [3H]cytochalasin B. Incubation of intact cells with 50 mM ethylidene glucose for 1 min at 15 degrees C leads to an intracellular concentration of only 2 mM. Under these conditions, the photoaffinity labeling in intact cells of hexose transporters that fractionate with the low density microsomes is unaffected, indicating these transporters are not exposed to the extracellular medium. In contrast, photolabeling in intact insulin-treated cells of hexose transporters that fractionate with the plasma membrane is inhibited under these incubation conditions. The results demonstrate that insulin action results in the exposure to the extracellular medium of previously sequestered hexose transporters.     

Ca2+-dependent formation of an L-arginine-derived activator of soluble guanylyl cyclase in bovine lung

In a fraction of cytosolic proteins from bovine lung, soluble guanylyl cyclase was concentration-dependently stimulated by L-arginine but not by D-arginine. Stimulation was up to 20-fold with an EC50 of about 3 x 10(-5) M. Activation of guanylyl cyclase by L-arginine was dependent on NADPH (EC50 about 5 x 10(-7) M) and Ca2+ (EC50 about 1.4 x 10(-6) M). The activation by L-arginine was inhibited by NG-monomethyl-L-arginine and hemoglobin. The effect of L-arginine was dependent on the protein concentration and was not observed in preparations of purified gyanylyl cyclase. These results suggest that bovine lung contains a Ca2+-regulated enzyme or enzyme system which converts L-arginine into an activator of soluble guanylyl cyclase.     

Subcellular distribution of thyroxine 5'-monodeiodinase activity in rabbit kidney

Thyroxine 5'-monodeiodinase is located in the proximal tubules of the rabbit kidney. To estimate the subcellular distribution of 5'-monodeiodinase activity, we prepared subcellular fractions, a basolateral membrane fraction and a brush border membrane fraction, from kidneys of Japanese white rabbits. Each fraction (0.5 mg protein) was incubated at 37 degrees C for 60 min with 0.5 micrograms T4 in the presence of 5 mM DTT. The T3 generated in the reaction mixture was extracted with cold ethanol and measured by RIA. For analysis of propylthiouracil-insensitive thyroxine 5'-monodeiodinase, we examined its kinetic behavior at nanomolar concentrations of the substrate, T4, in the presence of 100 microM propylthiouracil. In order of decreasing activity, basolateral membrane, microsomal fraction, mitochondrial fraction, cytosolic fraction, brush border membrane and nuclear fraction were capable of converting T4 to T3. Upon addition of 10(-5) M propylthiouracil to the reaction mixture, 5'-monodeiodinase activities of basolateral membrane and brush border membrane were inhibited by more than 90%, but that of microsomes was inhibited by only about 50%. In addition, kinetic analysis of microsomal 5'-monodeiodinase activity at nanomolar T4 concentrations in the presence of 10(-4) M propylthiouracil suggested on apparent Km of 3.8 nmol. These results indicate that there is high-Km 5'-monodeiodinase activity (PTU-sensitive) in the basolateral and brush border membranes and also high-Km and low-Km 5'-monodeiodinase (PTU-insensitive) in the microsomes of rabbit kidney.     

NAD (P) H-dependent reduction of nicotinamide N-oxide by an unique enzyme system consisting of liver microsomal NADPH-cytochrome C reductase and cytosolic aldehyde oxidase

NAD (P) H-dependent reduction of nicotinamide N-oxide was investigated with rabbit liver preparations. Microsomes, microsomal NADPH-cytochrome c reductase or cytosolic aldehyde oxidase alone exhibited no nicotinamide N-oxide reductase activity in the presence of NADPH or NADH. However, when the microsomal preparations were combined with the cytosolic enzyme, a significant N-oxide reductase activity was observed in the presence of the reduced pyridine nucleotide. The activity was enhanced by FAD or methyl viologen. Cytosol alone supplemented with NADPH or NADH exhibited only a slight, but when combined with microsomes, a significant N-oxide reductase activity. Based on these facts, we propose a new electron transfer system consisting of NADPH-cytochrome c reductase and aldehyde oxidase, which exhibits nicotinamide N-oxide reductase activity in the presence of the reduced pyridine nucleotide.