8 alpha, 9 alpha-Epoxyhexahydrocannabinol formation from delta 8-tetrahydrocannabinol by mouse liver microsomes

8α,9α-Epoxyhexahydrocannabinol ( EHHC ) was formed from Δ⁸-tetrahydrocannabinol ( THC ) by mouse liver microsomes. The reaction required O₂, and partially inhibited by CO. The optimal pH for the epoxide formation was from 7.4 to 8.0. EDTA did not affect the epoxide formation, but SKF 525-A, α-naphthoflavone and CCl₄ caused a significant inhibition. In addition, the rate of epoxidation increased significantly after treatment. with phenobarbital and 3-methylcholanthrene, but decreased after CoCl₂ treatment. 8β,9β-EHHC, a stereoisomer of 8α,9α-EHHC, was not found under all the conditions used in this study. These results indicate that 8α,9α-EHHC formation is mediated by monooxygenase system involving cytochrome P-450.     

Immunochemical evidence for a role of cytochrome P-450 in liver microsomal ethanol oxidation

Antibodies to cytochrome P-450 isozyme 3a, the ethanol-inducible isozyme in rabbit liver, were used to determine the role of this enzyme in the microsomal oxidation of alcohols and the p-hydroxylation of aniline. P-450 isozymes, 2, 3b, 3c, 4, and 6 did not crossreact with anti-3a IgG as judged by Ouchterlony double diffusion, and radioimmunoassays indicated a crossreactivity of less than 1%. Greater than 90% of the activity of purified form 3a toward aniline, ethanol, n-butanol, and n-pentanol was inhibited by the antibody in the reconstituted system. The catalytic activity of liver microsomes from control or ethanol-treated rabbits was unaffected by the addition of either desferrioxamine (up to 1.0 mM) or EDTA (0.1 mM), suggesting that reactions involving the production of hydroxyl radicals from H2O2 and any contaminating iron in the system did not make a significant contribution to the microsomal activity. The addition of anti-3a IgG to hepatic microsomes from ethanol-treated rabbits inhibited the metabolism of ethanol, n-butanol, n-pentanol, and aniline by about 75, 70, 80, and 60%, respectively, while the inhibition of the activity of microsomes from control animals was only about one-half as great. The rate of microsomal H2O2 formation was inhibited to a lesser extent than the formation of acetaldehyde, thus suggesting that the antibody was acting to prevent the direct oxidation of ethanol by form 3a. Under conditions where purified NADPH-cytochrome P-450 reductase-catalyzed substrate oxidations was minimal, the P-450 isozymes other than 3a had low but significant activity toward the four substrates examined. The residual activity at maximal concentrations of the antibody most likely represents the sum of the activities of P-450 isozymes other than 3a present in the microsomal preparations. The results thus indicate that the enhanced monooxygenase activity of liver microsomes from ethanol-treated animals represents catalysis by P-450 isozyme 3a.     

Separation, purification and characterization of three isoenzymes of UDP-glucuronyltransferase from rat liver microsomes

Three isoenzymes of UDP-glucuronyltransferase (UDPGT) have been separated and purified from liver microsomes of untreated female rats or female rats pretreated with 3-methylcholanthrene. The UDPGT isoenzymes were purified utilizing Chromatofocusing, column isoelectric focusing, and UDP-hexanolamine Sepharose 4B affinity chromatography. UDPGT activities could also be separated during UDP-hexanolamine affinity chromatography by elution with different UDPGA (UDP-glucuronic acid) concentrations. One isoenzyme exhibits a subunit molecular weight of 56,000 and is capable of conjugating p-nitrophenol, 1-naphthol, and 4-methylumbelliferone. This isoenzyme is inducible by 3-methylcholanthrene treatment and requires high UDPGA concentrations for elution from the UDP-hexanolamine affinity column in contrast to the other UDPGT isoenzymes. A second isoenzyme was purified and displayed a subunit molecular weight of 50,000. This isoenzyme was not induced by 3-methylcholanthrene and was active towards testosterone, the 17-OH position of beta-estradiol, p-nitrophenol, and 1-naphthol. A third isoenzyme was also purified and exhibited a subunit molecular weight of 52,000. This isoenzyme conjugated androsterone and etiocholanolone and was not induced by 3-methylcholanthrene treatment. This study reports the purification of two separate and distinct rat liver UDPGT isoenzymes capable of conjugating p-nitrophenol, only one of which is inducible by 3-methylcholanthrene treatment. Also, this is the first report of the purification of a UDPGT isoenzyme active towards the 3-OH position of androgens.     

Immunochemical analysis of the membrane proteins of rat liver and Zajdela hepatoma mitochondria

The contents of mitochondrial inner membrane protein complexes were compared in normal liver and in Zajdela hepatoma mitochondria by the immunotransfer technique. Antibodies against core proteins 1 and 2, cytochrome c1, the iron-sulfur protein of Complex III, subunits I and II of cytochrome oxidase, and the alpha and beta subunits of the F1-ATPase were used. In addition, antibodies against a primary dehydrogenase, beta-hydroxybutyrate dehydrogenase, as well as the outer membrane pore protein were used. The results indicate that the components of the cytochrome chain and porin are greatly enriched in hepatoma mitochondria compared to normal rat liver mitochondria. This enrichment was also reflected in the rates of respiration in tumor mitochondria using a variety of substrates. Enrichment of porin may partially account for increased hexokinase binding to tumor mitochondria. In contrast to the respiratory chain components, the F1-ATPase and F0 (measured by DCCD binding) were not increased in tumor mitochondria. Thus, Zajdela hepatoma mitochondria components are nonstoichiometric, being enriched in oxidative capacity but relatively deficient in ATP synthesizing capacity. Finally, beta-hydroxybutyrate dehydrogenase, which is often decreased in hepatoma mitochondria, was shown here by immunological methods to be decreased by only 40%, whereas enzyme activity was less than 5% of that in normal rat liver.     

Solubilization and characterization of vitamin K epoxide reductase from normal and warfarin-resistant rat liver microsomes

Two procedures have been developed for the solubilization of vitamin K epoxide reductase from rat liver microsomal membranes using the detergent Deriphat 160 at pH 10.8. The methods are applicable to both normal and Warfarin-resistant-strain rat liver microsomes and yield material suitable for further purification. The preparations retain dithiothreitol-dependent vitamin K quinone reductase activity as well as vitamin K epoxide reductase and are free of vitamin K-dependent carboxylase and epoxidase activities. Optimal epoxide reductase activity is obtained at 0.1 M KCl and pH 9 in the presence of sodium cholate. Artifactual formation of vitamin K metabolites was eliminated through the use of mercuric chloride to remove excess dithiothreitol prior to extraction and metabolite assay. Using the solubilized enzyme, valid initial velocities were measured, and reproducible kinetic data was obtained. The substrate initial velocity patterns were determined and are consistent with a ping-pong kinetic mechanism. The kinetic parameters obtained are a function of the cholate concentration, but do not vary drastically from those obtained using intact microsomal membranes. At 0.8% cholate, the enzymes solubilized from normal Warfarin-sensitive- and Warfarin-resistant-strain rat livers exhibit respective values of Vmax = 3 and 0.75 nmol/min/g liver; Km for vitamin K epoxide = 9 and 4 microM; and Km for dithiothreitol of 0.6 and 0.16 mM.     

Comparative chemical and immunological characterization of five lipolytic enzymes (carboxylesterases) from rat liver microsomes

The chemical and immunological properties of five closely related microsomal serine hydrolases (carboxylesterases) from rat liver have been compared to evaluate whether they are variants of a single protein or independent proteins. These enzymes represent medium-chain-length acylcarnitine hydrolase, palmitoyl carnitine hydrolase, medium-chain-length monoglyceride hydrolase, and two long-chain monoglyceride hydrolases. All enzymes have similar subunit Mr's (58,000-61,000) and bear one active site per protein subunit, as could be shown by active sites with radioactive bis(4-nitrophenyl)phosphate, and have subsequently been cleft by proteases or by BrCN. The patterns of radioactive peptides obtained after electrophoresis or thin-layer chromatography indicated that the two long chain monoglyceride hydrolases were closely related, while all other hydrolases differed from these and from each other. The two long-chain monoglyceride hydrolases also had identical N- and C-termini that differed from those of the other hydrolases. All hydrolases contain low amounts of hexoses. It is concluded that the hydrolases investigated represent four independent enzymes with differing amino acid sequences. Three of the four hydrolases were microheterogenous. These results were confirmed with an immunological study using rabbit antisera against three of the hydrolases. Heparin-releasable liver lipase was not cross-reactive with the lipolytic enzymes investigated here.     

Low-level luminescence from microsomes exposed to enzymatic systems that generate triplet species

Microsomes exposed to the propanal/horseradish peroxidase/O₂ system develop a weak chemiluminescence. The underlying process is distinct from that occurring during lipid peroxidation because the emission intensity peaks at around 560 nm, rather than in the red, and no malonaldehyde is formed. Triplet acetaldehyde appears to be responsible for the induction of the process, which in turn leads to excitation of a component in microsomes, possibly a flavoprotein.     

Guanidoacetate methyltransferase from rat liver: Purification,properties, and evidence for the involvement of sulfhydryl groups for activity

Guanidoacetate methyltransferase (EC 2.1.1.2) has been purified about 800-fold from rat liver. The purified preparation shows a single protein band on polyacrylamide gel electrophoresis in the presence and absence of sodium dodecyl sulfate. The molecular weight of the enzyme is estimated to be 25,000 and 26,000 by Sephadex gel molecular-exclusion chromatography and by electrophoresis in polyacrylamide gradient gel, respectively. The sodium dodecyl sulfate-denatured enzyme also has a molecular weight of 26,000; thus, the enzyme is a monomeric protein. Guanidoacetate methyltransferase as isolated is catalytically inactive, but is readily reactivated by incubation with a thiol. The reactivated enzyme, which contains 3 mol of sulfhydryl groups/mol of enzyme, is again inactivated by oxidized glutathione. This inactivation is accompanied by the disappearance of two sulfhydryl residues. The relationship between the loss of enzyme activity and the number of residues disappeared indicates that the integrity of these sulfhydryl residues is critical for activity. The oxidized enzyme fails to bind the substrate S-adenosylmethionine as evidenced by the equilibrium dialysis study. Alkylation of the nonoxidizable sulfhydryl by N-ethylmaleimide shows that this residue is also essential for activity. UV absorption, fluorescence, and CD spectra show no difference between the reduced and oxidized enzymes, but the former is more susceptible to proteolytic attack by trypsin. The enzyme has an isoelectric pH of 5.3, and is most active at pH 9.0. From the CD spectrum, an α helix content of 15% is calculated. The K_m values for guanidoacetate and S-adenosylmethionine are 97.5 and 6.73 μm, respectively, at pH 8.0 and 37 °C.     

Studies on the pathway of methane formation from procarbazine,a 2-methylbenzylhydrazine derivative,by rat liver microsomes

The oxidative metabolism of procarbazine, its azo, hydrazone, and two azoxy derivatives, and methylhydrazine by hepatic microsomes from phenobarbital-pretreated rats was investigated to elucidate the pathway of metabolism that resulted in methane formation from procarbazine. When incubated with microsomal reaction mixtures fortified with NADPH, all of the compounds, except the azoxy isomers, were metabolized to yield methane. A lag phase in methane formation was noted for procarbazine, but not for the other compounds. Kinetic and inhibition studies utilizing methimazole and ethylhydrazine precluded methylhydrazine as an intermediate in methane formation from procarbazine. When the azo derivative was oxidatively metabolized in the presence of liver microsomes, no hydrazone tautomer was detected. Upon monitoring the production of the azo and hydrazone metabolites formed during microsomal metabolism of procarbazine, the azo derivative was formed in sufficient quantities to account for the majority of the methane produced. In addition, small amounts of hydrazone were also detected. It was concluded that both the azo and hydrazone metabolites of procarbazine contribute to methane formation from the terminal methyl group of the hydrazine with the azo derivative being the predominant source and the hydrazone derivative being a minor source of methane. Consideration of the chemical and enzymatic pathways of procarbazine oxidation and the implication of a methyl radical intermediate in methane formation are discussed.     

Specificity of purified monoacylglycerol lipase, palmitoyl-CoA hydrolase, palmitoyl-carnitine hydrolase, and nonspecific carboxylesterase from rat liver microsomes

The comparative substrate specificities of five purified serine hydrolases from rat liver microsomes have been investigated, especially their action upon natural lipoids. All enzymes had high carboxylesterase activities with simple aliphatic and aromatic esters and thioesters. The broad pH optima were in the range of pH 6-10. Synthetic amides were less potent substrates. The hydrolytic activities towards palmitoyl-CoA and monoacyl glycerols were generally high, whereas phospholipids and palmitoyl carnitine were cleaved at moderate rates. Acetyl-CoA, acetyl carnitine, and ceramides were not cleaved at all. The closely related hydrolases with the highest isoelectric points (pI 6.2 and 6.4) were most active with palmitoyl-CoA and palmitoyl glycerol. One of these enzymes might also be responsible for the low cholesterol oleate-hydrolyzing capacity of rat liver microsomes. Among the other hydrolases, that with pI 6.0 showed significant activities with simple butyric acid esters, 1-octanoyl glycerol, and octanoylamide. The esterase with pI 5.6 had the relatively highest activities with palmitoyl carnitine and lysophospholipids. The purified enzyme with pI 5.2 showed some features of the esterase pI 5.6, but generally had lower specific activities, except with 4-nitrophenyl acetate. The lipoid substrates competitively inhibited the arylesterase activity of the enzymes. The varying activities of the individual hydrolases were influenced in parallel by a variety of inhibitors, indicating that the purified hydrolases possessed a relatively broad specificity and were not mixtures of more specific enzymes. The nomenclature of the purified hydrolases is discussed.     

Characteristics of b-type cytochromes in brain microsomes: Comparison with liver microsomes

Biochemical aspects of b-type cytochromes in swine cerebral microsomes were different from those of cytochrome b₅ in liver microsomes, as well as the difference in absorption spectra. First, the kinetic constants, K_m and V_max, in rotenone-insensitive NADH-cytochrome c reductase activity were different from those of liver microsomes, and the activity of cerebral microsomes was higher than that of liver microsomes. Second, midpoint potentials (E_m) of b-type cytochromes in cerebral microsomes were measured and compared with liver microsomal cytochrome b₅. In cerebral microsomes two components of b-type cytochromes were resolved, and showed E_m's of ?30 and +50 mV, respectively, in the presence of 2 mm KCN. On the other hand, the E_m of liver microsomal cytochrome b₅ was ?6 mV. The high-potential component of cerebral microsomal b-type cytochromes was identified as brain-b′₅ [S. Yoshida, T. Yubisui, and M. Takeshita (1983)Biochem. Int. 7, 291–298] and the low-potential component as brain-b₅. The significance of the difference between cerebral and liver microsomal b-type cytochromes was discussed.     

The role of iron chelates in hydroxyl radical production by rat liver microsomes,NADPH-cytochrome P-450 reductase and xanthine oxidase

Uninduced rat liver microsomes and NADPH-Cytochrome P-450 reductase, purified from phenobarbital-treated rats, catalyzed an NADPH-dependent oxidation of hydroxyl radical scavenging agents. This oxidation was not stimulated by the addition of ferric ammonium sulfate, ferric citrate, or ferric-adenine nucleotide (AMP, ADP, ATP) chelates. Striking stimulation was observed when ferric-EDTA or ferric-diethylenetriamine pentaacetic acid (DTPA) was added. The iron-EDTA and iron-DTPA chelates, but not unchelated iron, iron-citrate or iron-nucleotide chelates, stimulated the oxidation of NADPH by the reductase in the absence as well as in the presence of phenobarbital-inducible cytochrome P-450. Thus, the iron chelates which promoted NADPH oxidation by the reductase were the only chelates which stimulated oxidation of hydroxyl radical scavengers by reductase and microsomes. The oxidation of aminopyrine, a typical drug substrate, was slightly stimulated by the addition of iron-EDTA or iron-DTPA to the microsomes. Catalase inhibited potently the oxidation of scavengers under all conditions, suggesting that H₂O₂ was the precursor of the hydroxyl radical in these systems. Very high amounts of superoxide dismutase had little effect on the iron-EDTA-stimulated rate of scavenger oxidation, whereas the iron-DTPA-stimulated rate was inhibited by 30 or 50% in microsomes or reductase, respectively. This suggests that the iron-EDTA and iron-DTPA chelates can be reduced directly by the reductase to the ferrous chelates, which subsequently interact with H₂O₂ in a Fenton-type reaction. Results with the reductase and microsomal systems should be contrasted with results found when the oxidation of hypoxanthine by xanthine oxidase was utilized to catalyze the production of hydroxyl radicals. In the xanthine oxidase system, ferric-ATP and -DTPA stimulated oxidation of scavengers by six- to eightfold, while ferric-EDTA stimulated 25-fold. Ferric-desferrioxamine consistently was inhibitory. Superoxide dismutase produced 79 to 86% inhibition in the absence or presence of iron, indicating an iron-catalyzed Haber-Weiss-type of reaction was responsible for oxidation of scavengers by the xanthine oxidase system. These results indicate that the ability of iron to promote hydroxyl radical production and the role that superoxide plays as a reductant of iron depends on the nature of the system as well as the chelating agent employed.     

Use of monoclonal antibody probes against rat hepatic cytochromes P-450c and P-450d to detect immunochemically related isozymes in liver microsomes from different species

Nine distinct monoclonal antibodies raised against purified rat liver cytochrome P-450c react with six different epitopes on the antigen, and one of these epitopes is shared by cytochrome P-450d. None of these monoclonal antibodies recognize seven other purified rat liver isozymes (cytochromes P-450a, b, and e-i) or other proteins in the cytochrome P-450 region of "Western blots" of liver microsomes. Each of the monoclonal antibodies was used to probe "Western blots" of liver microsomes from untreated, or 3-methylcholanthrene-, or isosafrole-treated animals to determine if laboratory animals other than rats possess isozymes immunochemically related to cytochromes P-450c and P-450d. Two protein-staining bands immunorelated to cytochromes P-450c and P-450d were observed in all animals treated with 3-methylcholanthrene (rabbit, hamster, guinea pig, and C57BL/6J mouse) except the DBA/2J mouse, where no polypeptide immunorelated to cytochrome P-450c was detected. The conservation of the number of rat cytochrome P-450c epitopes among these species varied from as few as two (guinea pig) to as many as five epitopes (C57BL/6J mouse and rabbit). The relative mobility in sodium dodecyl sulfate-gels of polypeptides immunorelated to cytochromes P-450c and P-450d was similar in all species examined except the guinea pig, where the polypeptide related to cytochrome P-450c had a smaller Mr than cytochrome P-450d. With the use of both monoclonal and polyclonal antibodies, we were able to establish that purified rabbit cytochromes P-450 LM4 and P-450 LM6 are immunorelated to rat cytochromes P-450d and P-450c, respectively.     

Isolation of copper thionein from rat liver

The inducible Cu-binding protein from adult rat liver previously referred to as Cu-chelatin has been purified and shown to be Cu-thionein. The Cu-protein was purified to homogeneity by gel filtration and thiopropyl-Sepharose chromatography. The Cu-thionein exhibited an amino acid composition similar but not identical to that of the two forms of rat liver Cd,Zn-thionein. The polypeptide-chain molecular weight of Cu-thionein was indistinguishable from that of Cd,Zn-thionein. The identification of the Cu-protein as metallothionein was substantiated by the complete immunological cross-reactivity with antisera prepared against purified rat liver Cd,Zn-thionein. Purified Cu-thionein bound 9–11 g atoms of Cu per mole of protein in an electron paramagnetic resonance nondetectable form. The $\text{Cu}\text{Zn}$ ratio of the protein is about 100. Ion-exchange chromatography resolved the Cu-protein into three polymorphic forms which differed from the polymorphism of Cd,Zn-thionein.     

Immunochemical cross reactivity of the antibody elicited against L-histidine decarboxylase purified from the whole bodies of fetal rats with the enzyme from rat brain

Rat cytosolic glutathione S-transferases catalyzed the conjugation of phenethyl chloride and phenethyl bromide with glutathione. The reaction proceeded with a high degree of stereoselectivity. The glutathione conjugate possessing the (R,S,S)- absolute configuration was formed in major quantities from the racemic substrates. The use of the enantiomers of the phenethyl chloride substrates indicated that the (S)-phenethyl chloride was conjugated in preference to the (R)-enantiomer. The conjugation proceeded with inversion of configuration at the benzylic carbon consistent with an SN₂-type mechanism. The stereoselectivity was greater for phenethyl chloride than for phenethyl bromide. Varying the substrate or enzyme concentration had no effect upon the observed stereoselectivity. The diastereomeric glutathione conjugates were separated by high performance liquid chromatography. These findings represent the first demonstration of the substrate stereoselectivity of the glutathione S-transferases.     

Purification of squalene epoxidase from rat liver microsomes

Squalene epoxidase was purified from rat liver microsomes by DEAE-cellulose, alumina C_ν gel, hydroxylapatite, CM-Sephadex C-50 and Cibacron Blue Sepharose 4B in the presence of Triton X-100. The specific activity was increased 50 fold with a yield of about 10%. On SDS-polyacrylamide gel electrophoresis, the preparation gave one major band and one minor band with apparent molecular weights of 47,000 and 27,000 daltons, respectively. The protein of 47,000 was the most probable candidate for squalene epoxidase. Squalene epoxidase activity could be reconstituted in the squalene epoxidase preparation with the addition of NADPH-cytochrome P-450 reductase, FAD, and Triton X-100.     

Kinetic properties of arachidonoyl-coenzyme A synthetase in rat brain microsomes

Free arachidonic acid is released rapidly in the brain at the onset of ischemia and during convulsions. The transient nature of this phenomenon indicates the existence of an active reacylation system for this fatty acid, likely an arachidonoyl-CoA synthetase-arachidonoyl transferase. The first of these enzymatic activities in brain microsomes was studied and it was found that [1-14C]arachidonic acid is rapidly activated and shows an absolute requirement for ATP and CoA. MgCl2 enhances this activity 10-fold. The optimum pH is 8.5, and the apparent Km values for the radiolabeled substrate, ATP, CoA, and MgCl2 are 36, 154, 8, and 182 microM, respectively. The apparent Vmax is 32.4 nmol/min/mg protein for arachidonic acid. The presence of Triton X-100 (0.1%) in the assay medium caused a significant reduction in apparent Km (9.4 microM) and Vmax (25.7 nmol/min/mg protein) values. The enzymatic activity is thermolabile with a T1/2 of less than 1 min at 45 degrees C and a maximal activity at 40 degrees C. The breaking point or transition temperature is 25 degrees C in an Arrhenius plot. The activation energies were 95 kJ/mol from 0 to 25 degrees C and 30 kJ/mol from 25 to 40 degrees C. Fatty acid competition studies showed inhibition by unlabeled docosahexaenoic and arachidonic acids with a Ki of 31 and 37 microM, respectively, in the absence and 18 and 7.7 microM in the presence of Triton X-100. Palmitic acid and oleic acid slightly inhibited the reaction whereas linoleic acid inhibited it to a moderate extent. It is concluded that this very active enzyme can activate arachidonic acid as well as docosahexaenoic acid in brain microsomes. In addition, this reaction may be involved in regulating the pool size of these free fatty acids in brain by rapid removal through activation, thus limiting eicosanoid formation. Moreover, the rapid formation of polyenoic acyl-coenzyme A may participate in the retention of essential fatty acids in the central nervous system.     

Direct evidence for de novo synthesis of rat liver phenylalanine: pyruvate transaminase after glucagon treatment.

A specific antibody to phenylalanine:pyruvate transaminase has been used to show that the number of enzyme molecules and the rate of enzyme synthesis are increased by glucagon and N⁶,O^2′-dibutyryl cyclic AMP. Cycloheximide given simultaneously with glucagon or dibutyryl cyclic AMP blocked the increase in [³H]leucine incorporation when it was injected along with glucagon, but had no effect when given 4 h after the glucagon. This finding suggests that the mRNA synthesis for phenylalanine:pyruvate transaminase may be completed in 4 h.     

Binding of the rat liver 7-8 S dexamethasone receptor to deoxyribonucleic acid

The 7-8 S form of the [3H]dexamethasone (9 alpha-fluoro-11 beta,17,21-trihydroxy-16 alpha-methylpregna-1,4-diene-3, 20-dione) receptor from rat liver cytosol can be converted to the 3-4 S form by RNase treatment or high salt, suggesting a salt-sensitive association between the receptor protein and RNA. In DNA-cellulose column assays, the gradient-purified 3-4 S form bound DNA more efficiently than the 7-8 S form, though the 7-8 S form was also capable of binding to DNA-cellulose to a significant extent. Activated 7-8 S dexamethasone receptor could be released from its association with soluble DNA by treatment with DNase I. Sucrose gradient analysis showed that the released receptor sedimented as the 7-8 S form and was sensitive to RNase treatment, which induced a conversion to the 3-4 S form. Activated RNase-generated 3-4 S receptor again displayed a higher degree of binding to soluble DNA and was recovered in the 3-4 S form following DNase extraction. The fact that the 3-4 S form bound immobilized or soluble DNA more efficiently suggests that the associated RNA of the 7-8 S form interferes directly or indirectly with the receptor association with DNA. The observation that the receptor binds to DNA in its 7-8 S form suggests that the receptor complex is capable of binding RNA and DNA concurrently.     

Regulation of glucose 6-phosphatase in hepatic microsomes by thyroid and corticosteroid hormones

The regulation of glucose 6-phosphatase in hepatic microsomes by thyroid and corticosteroid hormones has been studied following the administration of 3,3',5-triiodo-L-thyronine and/or triamcinolone to hypophysectomized rats. The apparent Km for glucose-6-P in isolated ("intact") microsomes increased following administration of either hormone; there was little or no difference in the apparent Km when microsomes were treated with sodium deoxycholate ("disrupted"). In intact microsomes, triiodothyronine caused a 2.3-fold increase in the Vmax of glucose 6-phosphatase; triamcinolone, a 4-fold increase; and both hormones together, a 4.4-fold increase. Corresponding values for disrupted microsomes were: triiodothyronine, 3.7-fold; triamcinolone, 1.8-fold; both hormones, 3.3-fold. After triiodothyronine treatment, disruption of microsomes caused an over 5-fold increase in Vmax; after triamcinolone treatment, the increase was only 1.5-fold. This difference could not be explained by a change in the energy of activation of glucose 6-phosphatase in either intact or disrupted microsomes following hormone treatment. Glucose 6-phosphatase was localized by a cytochemical procedure; the reaction product was associated with 90% of the profiles in all microsomal preparations, except for those from triiodothyronine-treated rats, where less than 50% contained lead precipitate. Vesicles free of lead phosphate were isolated from sucrose gradients and accounted for less than 10% of the protein and glucose 6-phosphatase in all preparations, again except for those from triiodothyronine-treated rats, where they represented 40% of both the protein and glucose 6-phosphatase. The results are consistent with a model for glucose 6-phosphatase in which the substrate is transported across the microsomal membrane by a specific carrier before hydrolysis within the cisternae by a phosphohydrolase. It is suggested that the effect of triiodothyronine is mainly on the activity of the phosphohydrolase, and triamcinolone, on that of the carrier.