Purification and characterization of pig lung carbonyl reductase.

A pyrazole-sensitive carbonyl reductase from pig lung was purified to homogeneity by electrophoretic criteria. Chemical cross-linking study suggested that the native enzyme is a tetramer with a Mr of 103,000, consisting of apparent identical subunits of Mr 24,000. The enzyme reduced aliphatic and aromatic carbonyl compounds with NADPH as a preferable cofactor to NADH and catalyzed the oxidation of secondary alcohols and the aldehyde dismutation in the presence of NAD(P)+. Immunohistochemical study with the antibodies against the enzyme revealed that the enzyme was localized in the ciliated cells, nonciliated bronchiolar cells, Type II alveolar pneumocytes, and the epithelial cells of the ducts of the bronchial glands in the pig lung. In addition to the properties and distribution, the pig lung enzyme was immunochemically similar to the pulmonary enzymes in the guinea pig and mouse. However, the pig enzyme showed the following unusual features. (1) The enzyme exhibited an equatorial specificity in the reduction of 3-ketosteroids; the 4-pro-S hydrogen of NADPH was transferred to the carbonyl carbon atom of 5 alpha- and 5 beta-androstanes, and the respective reduced products were identified as 3 beta- and 3 alpha-hydroxysteroids. (2) Although the NADPH-linked reduction of carbonyl compounds apparently obeyed the Michaelis-Menten kinetics at pH 6.0, the double-reciprocal plots of the velocity vs concentrations of the carbonyl substrates were convex at pH higher than 6.5. The Hill coefficients and [S]0.5 values for the substrates decreased as the pH for reaction increased. The results suggest that the pig enzyme exhibits negative cooperativity with respect to the carbonyl substrates and that the hydrogen ion acts as an allosteric effector abolishing the negative interaction.     

Tissue distribution of mammalian aldose reductase and related enzymes

Activities of aldose reductase (AR) and related NADPH-dependent enzymes were examined in extracts of human, cat, dog, guinea pig, mouse, monkey, pig, rabbit, rat and sheep lenses and a variety of other tissues. The activity of the tissues against DL-glyceraldehyde, D-glucuronic acid, and 3-pyridinecarboxaldehyde (PCA) was determined. High glyceraldehyde:glucuronic acid activity ratios, a characteristic of aldose reductase, were found in all lenses, except from mouse. An analytical thin-layer isoelectric focusing system which separates the mammalian NADPH-dependent enzymes was developed. AR appears to be present as two or more isozymes in all mammalian lenses studied with the exception of mouse. Other tissues contain one or more isozymes which have the same isoelectric point and substrate specificity as the AR present in the lens of that species. This AR activity, however, may represent only a small proportion of the total NADPH reducing activity present. AR and HDH isozymes reduce the aromatic substrate, PCA, and thus have the general characteristics of an aldehyde reductase.     

Cathepsin D-like activity in the release of Gal beta 1-4GlcNAc alpha 2-6sialyltransferase from mouse and guinea pig liver Golgi membranes during the acute phase response

1. Rat Gal beta 1-4GlcNAc alpha 2-6sialyltransferase (E.C. 2.4.99.1) is released from Golgi membranes by cleavage of a portion of the enzyme containing the active site from a membrane anchor; this effect was most dramatic during the acute phase response. The enzyme that cleaved sialyltransferase had the properties of cathepsin D was most active at pH 5.6 and was likely of lysosomal origin (Lammers and Jamieson, 1988). 2. The acute phase response of sialyltransferase in mouse and guinea pig was previously found to differ from that in the rat. Release of sialyltransferase from mouse and guinea pig Golgi membranes has now been studied in order to make a comparison with the rat system. 3. Maximum release of sialyltransferase from mouse and guinea pig Golgi occurred at pH 4.6 and 5.2, respectively; like the rat a cathepsin D-like proteinase was responsible for release of both enzymes. 4. Immunoblot analysis showed that membrane-bound rat and mouse sialyltransferase had Mr 49,000, whereas the guinea pig enzyme had Mr 42,000. The released form of the rat enzyme had Mr 42,000, but released forms of mouse and guinea pig enzymes had Mr 38,000 suggesting a different cleavage site for these two enzymes compared to the rat enzyme.     

Formation of hydrogen peroxide and N-hydroxylated amines catalyzed by pulmonary flavin-containing monooxygenases in the presence of primary alkylamines

In atypical reaction, incubation of purified rabbit pulmonary flavin-containing monooxygenase with certain primary alkylamines results in the oxidation of NADPH and the formation of hydrogen peroxide. In addition, significant amounts of N-hydroxylated primary amine are also generated, as determined by colorimetric assay and GC/MS analysis of n-octylamine metabolites. Similar reactions appear to be catalyzed by the mouse pulmonary enzyme. In contrast, incubation of primary alkylamines with hepatic flavin-containing monooxygenases from rabbit, mouse, or pig does not result in NADPH oxidation or metabolism. Another effect of primary alkylamines is marked activation of the mouse pulmonary and pig hepatic flavin-containing monooxygenases with some substrates. The structural requirements for primary alkylamines to elicit NADPH oxidation by the rabbit pulmonary enzyme or to activate the mouse pulmonary and pig hepatic enzymes are identical. This indicates that different flavin-containing monooxygenases probably have a conserved alkylamine-binding site of defined specificity. In the case of the rabbit pulmonary enzyme, this binding may occur very close to or at the catalytic site resulting in some N-hydroxylation of the alkylamine.     

Characterization of the purified microsomal FAD-containing monooxygenase from mouse and pig liver

The FAD-containing monooxygenase (FMO) has been purified from both mouse and pig liver microsomes by similar purification procedures. Characterization of the enzyme from these two sources has revealed significant differences in catalytic and immunological properties. The pH optimum of mouse FMO is slightly higher than that of pig FMO (9.2 vs. 8.7) and, while pig FMO is activated 2-fold by n-octylamine, mouse FMO is activated less than 20%. Compounds, including primary, secondary and tertiary amines, sulfides, sulfoxides, thiols, thioureas and mercaptoimidazoles were tested as substrates for both the mouse and pig liver FMO. Km- and Vmax-values were determined for substrates representative of each of these groups. In general, the mouse FMO had higher Km-values for all of the amines and disulfides tested. Mouse FMO had Km-values similar to those of pig FMO for sulfides, mercaptoimidazoles, thioureas, thiobenzamide and cysteamine. Vmax-values for mouse FMO with most substrates was approximately equal, indicating that as with pig FMO, breakdown of the hydroxyflavin is the rate limiting step in the reaction mechanism. Either NADPH or NADH will serve as an electron donor for FMO, however, NADPH is the preferred donor. Pig and mouse FMOs have similar affinity for NADPH (Km = 0.97 and 1.1 microM, respectively) and for NADH (Km = 48 and 73 microM, respectively). An antibody, prepared by immunizing rabbits with purified pig liver FMO, reacts with purified pig liver FMO but not with mouse liver FMO, indicating structural differences between these two enzymes. This antibody inhibited pig FMO activity up to 60%.     

Purification and characterization of a soluble phospholipase A2 from guinea pig lung

Guinea pig lung cytosolic phospholipase A2 was purified to near homogeneity by chromatography on a phosphocellulose column, followed by Q-Sepharose, S-Sepharose, gel filtration chromatography and reverse-phase HPLC. The purified enzyme exhibited an apparent molecular weight of 16,700 by SDS-polyacrylamide gel electrophoresis. Active enzyme eluted from the gel at an apparent molecular weight of 16,700. The purified enzyme exhibited a pH optimum of 9.0 and was calcium-dependent. Guinea pig lung phospholipase A2 hydrolyzed phosphatidylcholine and phosphatidylethanolamine equally well. Substrates containing unsaturated fatty acids in the sn-2 position were hydrolyzed preferentially to those containing saturated fatty acids. Anionic detergents stimulated enzyme activity while nonionic detergents inhibited the enzyme. Disulfide reducing agents dithiothreitol, glutathione and 2-mercaptoethanol modestly stimulated enzyme activity. The sulfhydryl aklylating agent n-ethylmaleimide had no effect on enzyme activity and only high concentrations of p-hydroxymercuribenzoic acid inhibited enzyme activity. The histidine modifying agent, bromophenacyl bromide did not inhibit guinea pig lung phospholipase A2 under conditions in which Crotalus adamanteus phospholipase A2 was inhibited 80%. Manoalide inhibited guinea pig lung phospholipase A2 in a concentration-dependent manner (IC50 = 2 microM). Antibodies prepared against porcine pancreatic phospholipase A2 specifically immunoprecipitated guinea pig lung phospholipase A2 suggesting that the major phospholipase A2 in guinea pig lung cytosol is immunologically related to pancreatic phospholipase A2 in agreement with the biochemical properties of the enzyme.     

Purification and characterization of a membrane-bound NADPH-cytochrome c reductase capable of catalyzing menadione-dependent O2- formation in guinea pig polymorphonuclear leukocytes

A membrane-bound NADPH-cytochrome c reductase, which is capable of forming the superoxide anion (O2-) in the presence of menadione, was highly purified from membrane fractions of disrupted guinea pig polymorphonuclear leukocytes by solubilization with 0.2% Triton X-100 and chromatographies on Sephacryl S-300 and 2',5'-ADP-agarose. The overall purification from the membrane fraction was over 110-fold, with a yield of about 6%. The purified preparation did not contain two other pyridine nucleotide-oxidizing enzymes: NADH- and NAD(P)H-oxidizing enzymes (J. Biochem. 94, 931-936, 1983). Besides cytochrome c, the purified enzyme was able to reduce menadione, Nitroblue tetrazolium (NBT) and 2,6-dichlorophenolindophenol. The reduction of menadione alone resulted in the formation of O2-. The purified enzyme preparation contained FAD. When assayed by measuring O2--generation in the presence of menadione, the enzyme showed an optimum pH at 7.0-7.4, and Km values for NADPH, NADH, and menadione were 25, 230, and 5.3 microM, respectively. The enzyme activity was not inhibited by NaN3 or dicumarol, but was by N-ethylmaleimide, EDTA, and quercetin; these inhibition profiles agree with those observed for the NADPH oxidase in the membrane fraction of phorbol-myristate acetate-stimulated leukocytes. Furthermore, when compared by means of the NBT-staining method combined with disc gel electrophoresis, the purified enzyme was electrophoretically indistinguishable from the NADPH-NBT reductase in the plasma membrane as well as phagosomes of the leukocytes. These results suggest that the purified NADPH-cytochrome c reductase is the putative flavoprotein of the NADPH oxidase system responsible for the respiratory burst.     

Monospecific antiserum to rat spermidine synthase and its application to rat tissues and several mammals

Monospecific antiserum to rat spermidine synthase was prepared by immunization of rabbits with purified enzyme protein from rat prostate, and its usefulness for analysis of spermidine synthase protein in not only rat tissues but also several other mammals was demonstrated by Western blotting and immunotitration of the enzyme activity. Application of the antiserum for elucidating the relationship between the enzyme activity and protein in normal rat tissues strongly suggested that marked difference in spermidine synthase activity among rat tissues depends solely on the difference in the amount of enzyme protein. Also, application of the antiserum for analyzing spermidine synthase from liver of mouse, rat, guinea pig, pig, and human, showed that the enzymes had a similar subunit molecular weight of 35,000 and a cross-reactivity with the antiserum, exhibiting almost the same immunoreactivity to mouse enzyme as to rat enzyme. Thus, it was suggested that the antiserum would be useful for further studies of mammalian spermidine synthase from the viewpoints of enzymology and molecular biology.     

Membrane-associated carbonic anhydrase from rat lung. Purification, characterization, tissue distribution, and comparison with carbonic anhydrase IVs of other mammals.

Carbonic anhydrase (CA) IV was purified to homogeneity from rat lung microsomal and plasma membranes. The single N-terminal amino acid sequence showed 55% similarity to that reported for human CA IV. A monospecific antibody to the 39-kDa rat enzyme that cross-reacts on Western blots with CA IVs from other mammalian species was produced in rabbits. Digestion of rat lung enzyme with endoglycosidase (peptide-N-glycosidase F) reduced the Mr to 36,000, suggesting that rat CA contains one N-linked oligosaccharide chain. All of eight additional mammalian CA IVs that were examined also contained oligosaccharide chains, as evidenced by reduction in Mr from 52,000 (cow, sheep, and rabbit), 42,000 (pig, guinea pig, and dog), and 39,000 (mouse and hamster) to 36,000 after treatment of the respective lung microsomal membranes with peptide-N-glycosidase F. The 36-kDa human enzyme showed no change in molecular mass with this treatment. Thus, the human CA IV is the exceptional one in lacking carbohydrate. Rat lung CA IV was found to be relatively resistant to sodium dodecyl sulfate and to be anchored to membranes by a phosphatidylinositol-glycan linkage; both properties were found to be shared by other mammalian CA IVs. Western blot analysis indicated distribution of CA IV in rat tissues other than kidney and lung where it was previously known to be present. CA IV was particularly abundant in rat brain, muscle, heart, and liver, all locations where the CA IV enzyme was not known to be present previously. None was detected in rat skin or spleen.     

Identification of the principal cell type yielding immune RNA capable of transferring tumor-specific cellular cytotoxicity

A search was made for the lymphoid cell type(s) which are the source of immune RNA (I-RNA) capable of transferring tumor-specific cell-mediated cytotoxicity (CMC). Hartley guinea pigs were immunized with syngeneic murine fibrosarcomas (BP-10 or BP-11) induced by 3,4-benzo(a)pyrene in C3H/HeJ mice, and the I-RNA was extracted individually from their spleens, lymph nodes, and peritoneal exudate (PE) cells. All three I-RNA preparations were able to convert normal C3H/HeJ mouse lymphocytes to effector cells significantly cytolytic to the specific syngeneic mouse tumor in vitro. Furthermore, lymphocytes and macrophages were purified from the spleens, lymph nodes, and PE cells of tumor-immunized guinea pigs. I-RNA was extracted from these purified cell populations and also from the pooled guinea pig lymphoid tissues. Normal C3H/HeJ lymphocytes were incubated with each type of I-RNA and tested in vitro for CMC against the specific tumor cells. Significant CMC against BP-10 targets was observed with mouse lymphocytes incubated with I-RNA extracted from pooled lymphoid tissues of BP-10 tumor-immunized guinea pigs. There was a reduced but still significant CMC when mouse lymphocytes were incubated with I-RNA extracted from purified guinea pig lymphocytes, whereas there was a markedly increased CMC when the I-RNA was extracted from purified guinea pig macrophages. As indicated by sucrose density gradient analysis, the lesser effectiveness of lymphocyte I-RNA was not due to RNA degradation resulting from lymphocyte purification or I-RNA extraction. Treatment of all types of I-RNA with RNase abrogated the transfer of CMC, whereas treatment of I-RNA with DNase or pronase did not. RNA extracted from the lymphoid tissues of guinea pigs immunized with complete Freund's adjuvant without tumor was ineffective. Mouse lymphocytes incubated with BP-10 macrophage I-RNA destroyed BP-10 but not BP-11 tumor cells, whereas lymphocytes incubated with BP-11 macrophage I-RNA killed BP-11 but not BP-10 tumor cells, thus indicating tumor specificity of the immunity transferred by macrophage I-RNA. Our results suggest that macrophages are the principal source of I-RNA capable of transferring tumor-specific CMC.     

Studies on the effect of experimental inflammation on sialyltransferase in the mouse and guinea pig

The effect of inflammation on sialyltransferase was studied in the mouse and guinea pig. There was a three-fold increase in mouse liver sialyltransferase activity reaching a maximum at 72 hr after inflammation; serum levels were increased by five-fold at 72 hr after inflammation. The response of guinea pig sialyltransferase was slower and of lower magnitude compared with the response of the mouse enzyme; liver and serum sialyltransferase increased by about 50% reaching a maximum at 96 hr after inflammation. The specificity of the enzyme that responded to inflammation in the mouse and guinea pig was found to be Gal beta 1----4GlcNAc alpha 2----6 sialyltransferase, the same enzyme activity that was shown to be an acute phase reactant in earlier studies in the rat (Kaplan et al., 1983).     

Immunohistochemical localization of histamine N-methyltransferase in guinea pig tissues.

Histamine plays important roles in gastric acid secretion, inflammation, and allergic response. Histamine N-methyltransferase (HMT; EC 2.1.1.8) is crucial to the inactivation of histamine in tissues. In this study we investigated the immunohistochemical localization of this enzyme in guinea pig tissues using a rabbit polyclonal antibody against bovine HMT. The specificity of the antibody for guinea pig HMT was confirmed by Western blotting and the lack of any staining using antiserum preabsorbed with purified HMT. There was strong HMT-like immunoreactivity (HMT-LI) in the epithelial cells in the gastrointestinal tract, especially in the gastric body, duodenum, and jejunum. The columnar epithelium in the gallbladder was also strongly positive. Almost all the myenteric plexus from the stomach to the colon was stained whereas the submucous plexus was not. Other strongly immunoreactive cells included the ciliated cells in the trachea and the transitional epithelium of the bladder. Intermediately immunoreactive cells included islets of Langerhans, epidermal cells of the skin, alveolar cells in the lung, urinary tubules in the kidney, and epithelium of semiferous tubules. HMT-LI was present in specific structures in the guinea pig tissues. The widespread distribution of HMT-LI suggests that histamine has several roles in different tissues.     

Guinea pig liver aromatic aldehyde-ketone reductases identical with 17 beta-hydroxysteroid dehydrogenase isozymes.

Two NADPH-dependent aromatic aldehyde-ketone reductases purified from guinea pig liver catalyzed oxidoreduction of 17 beta-hydroxysteroids and 17-ketosteroids. One enzyme efficiently oxidized 5 beta-androstanes and reduced 17-ketosteroids of A/B cis configuration, whereas the other enzyme efficiently oxidized 5 alpha-androstanes and equally reduced both 5 alpha-and 5 beta-androstanes of 17-ketosteroids. However, aromatic aldehydes and ketones, and 3-ketosteroids were irreversibly reduced by the two enzymes. The two enzymes utilized NADP+ or NADPH as cofactor, but little activity with NAD+ or NADH was found. Phosphate ions enhanced the NAD+-dependent dehydrogenase activity and NADH-dependent reductase activity of the two enzymes, whereas the activities with NADP+ and NADPH were not affected. The ratios of the two activities of ketone reduction and 17 beta-hydroxysteroid oxidation of the two enzymes were almost constant during the purification steps after the two enzymes had been separated by DEAE-cellulose chromatography. By kinetic studies and electrophoresis and isoelectric focusing experiments it was confirmed that both of the two enzymes were responsile for the reduction aldehydes, ketones, and ketosteroids and for the oxidation of 17 beta-hydroxysteroids. These results indicate that 17 beta-hydroxysteroid dehydrogenases may play important roles in the metabolism of exogeneous aldehydes and ketones as well as steroids.     

Mouse-liver glutathione reductase. Purification, kinetics, and regulation.

Glutathione reductase from the liver of DBA/2J mice was purified to homogeneity by means of ammonium sulfate fractionation and two subsequent affinity chromatography steps using 8-(6-aminohexyl)-amino-2'-phospho-adenosine diphosphoribose and N6-(6-aminohexyl)-adenosine 2',5'-biphosphate-Sephadex columns. A facile procedure for the synthesis of 8-(6-aminohexyl)-amino-2'-phospho-adenosine diphosphoribose is also presented. The purified enzyme exhibits a specific activity of 158 U/mg and an A280/A460 of 6.8. It was shown to be a dimer of Mr 105000 with a Stokes radius of 4.18 nm and an isoelectric point of 6.46. Amino acid composition revealed some similarity between the mouse and the human enzyme. Antibodies against mouse glutathione reductase were raised in rabbits and exhibited high specificity. The catalytic properties of mouse liver glutathione reductase have been studied under a variety of experimental conditions. As with the same enzyme from other sources, the kinetic data are consistent with a 'branched' mechanism. The enzyme was stabilized against thermal inactivation at 80 degrees C by GSSG and less markedly by NADP+ and GSH, but not by NADPH or FAD. Incubation of mouse glutathione reductase in the presence of NADPH or NADH, but not NADP+ or NAD+, produced an almost complete inactivation. The inactivation by NADPH was time, pH and concentration dependent. Oxidized glutathione protected the enzyme against inactivation, which could also be reversed by GSSG or other electron acceptors. The enzyme remained in the inactive state even after eliminating the excess NADPH. The inactive enzyme showed the same molecular weight as the active glutathione reductase. The spectral properties of the inactive enzyme have also been studied. It is proposed that auto-inactivation of glutathione reductase by NADPH and the protection as well as reactivation by GSSG play in vivo an important regulatory role.     

Inhibition of 15-hydroxyprostaglandin dehydrogenase by papaverine.

Papaverine was found to inhibit NAD⁺-linked 15-hydroxyprostaglandin dehydrogenase partially purified from guinea pig lung. The inhibition was noncompetitive with prostaglandin E₂, uncompetitive with NAD⁺, and reversible. The Ki was calculated to be 26 μM. Papaverine also inhibited the enzyme from swine lung, chicken and dog heart, and rat and dog kidney. The inhibitory effects of papaverine on the 15-hydroxyprostaglandin dehydrogenase were compared with those on cyclic AMP phosphodiesterases in these tissues.     

Biochemical and Immunological Properties of a Membrane-Bound Brain Metalloendopeptidase: Comparison with Thermolysin-Like Kidney Neutral Metalloendopeptidase

Abstract: Membrane-bound neutral metalloendopeptidase ("enkephalinase") was purified from rabbit brain and compared with a homogeneous preparation of a similar enzyme (EC 3.4.24.11) isolated from rabbit kidney. The two enzymes had the same pH optimum and the same apparent molecular weight. They showed identical specificity toward several synthetic substrates and cleaved both Met- and Leu-enkephalin at the Gly-Phe bond. Minor, but significant, differences were found between the two enzymes in the inhibitory constants determined for phosphoramidon and the N -[1( R,S )-carboxy-2-phenylethyl] derivatives of phenylalanyl and alanyl- p -aminobenzoate. A guinea pig antiserum obtained against the rabbit kidney enzyme showed strong crossreactivity with the rabbit brain enzyme when tested in an anticatalytic immunoinhibition assay. Ouchterlony immunodiffusion experiments gave a pattern of precipitation consistent with partial identity of the two enzymes. The kidney enzyme, however, seemed to contain antigenic determinants not present on the brain enzyme. The data indicate that the two enzymes are identical with respect to specificity, pH optimum, and molecular weight, but show minor, although significant, differences in interaction with active-site-directed inhibitors and specific antisera.     

Increased sensitivity of the enzymatic isotopic assay of histamine: measurement of histamine in plasma and serum.

The use of rat kidney instead of guinea pig brain as the source of histamine-N-methyltransferase for the enzymatic assay of histamine was found to improve the sensitivity of the assay. A partially purified preparation (ammonium sulfate fractionation) of the kidney enzyme was 20- to 50-fold more active than the guinea pig preparation, and sufficient enzyme for 14,000 assays could be prepared from six rats. The kidney enzyme, unlike the guinea pig brain enzyme, was free of interfering enzyme activities and gave low values for assay blanks. The two enzymes otherwise had similar properties. The low blank values permitted direct measurement of histamine in normal plasma without the need to isolate and concentrate histamine from the sample. Plasma histamine levels in normal individuals ranged from 0.2-1.4 (mean 0.6, n = 19) ng/ml.     

Localization of pulmonary carbonyl reductase in guinea pig and mouse: enzyme histochemical and immunohistochemical studies.

We studied the localization of carbonyl reductase (E.C. 1.1.1.184) in guinea pig and mouse lung by enzyme histochemistry and immunohistochemistry, using antibodies against the guinea pig lung enzyme which crossreacted with the lung enzymes of both animals. Carbonyl reductase activity was detectable in the bronchiolar epithelial cells of small airways and in alveolar cells. In the immunohistochemical staining for carbonyl reductase, the reaction was strongest in the non-ciliated bronchiolar cells (Clara cells) and was weak in the ciliated cells and type II alveolar pneumocytes. Injection of a single dose of naphthalene led to significant impairment of carbonyl reductase activity and of microsomal mixed-function oxidase activities in mouse lung, with a marked decrease in both activity and immunoreactive staining in the bronchiolar epithelial cells. The results indicate that carbonyl reductase is localized primarily in the Clara cells, which are known to be sites of pulmonary drug metabolism.     

Isolation of angiotensin-converting enzyme inhibitor from porcine plasma

An inhibitory peptide of angiotensin-converting enzyme was purified from porcine plasma. The final preparation showed IC50 values of 4.2, 0.6, and 0.9 microgram/ml for angiotensin-converting enzymes from guinea pig serum, rabbit lung, and monkey brain, respectively. The amino acid sequence of the inhibitor was determined as leucyl-valyl-leucine by Edman procedure. This structural observation was supported by mass spectrometric analysis.