On the synthesis and degradation of the multiple forms of catalase in mouse liver

The incorporation of ⁵⁵Fe-labeled ferrous sulfate and ³H-labeled γ-aminolaevulinic acid into the catalase of mouse liver was measured at intervals up to 96 hr after intraperitoneal injection, and the intracellular location of radioactive catalase followed, as well as the distribution of radiolabel between the multiple forms of this enzyme. At 10 min, catalase radioactivity was present in all the cellular fractions studied, but after this time, label began to disappear from the microsomal fraction and from the peroxisomal detergent extract. By comparison, catalase incorporation reached a peak at about 6 hr in the peroxisomal aqueous extract, and rose to a broad peak after about 30 hr in the cytosol fraction. On resolving the multiple forms of catalase in the supernatant fraction by electrophoresis, it was found that label first appeared in the fastest moving heteromorph, and appeared sequentially in the other multiple forms over a period of 96 hr.The sequence of degradation of catalase was also studied by examination of residual catalase activity subsequent to the injection of allyl-isopropyl acetamide, a heme synthesis antagonist which blocks catalase synthesis. Blood catalase levels did not seem to be significantly affected by this treatment, but in the liver, the decay rates of catalase activity were appreciable, and varied significantly between the intracellular pools. The rate of decrease was greatest in the peroxisomal detergent extract, and least in the supernatant fraction.These findings have been discussed in relation to current understanding of the subcellular disposition, multiplicity, and turnover of hepatic catalase.     

Human erythrocyte catalase, isolation with an improved method, characterization and comparison to bovine liver catalase

Catalase enzyme was purified from human erythrocytes. The modified procedure of M?rikofer-Zwez et. al. [Eur. J. Biochem. 11: 49-57, 1969] yielded erythrocyte catalase with high specific activity and with one band on SDS polyacrylamide gel. Its other characteristics (isoelectric point; E405/280, E1%1cm at 280 nm and 405 nm) were in agreement with previously described findings. The results obtained for molecular mass, electrophoretic mobility, chromatographic behaviour on CM-Sepadex gel, addition test, and change of electrophoretic mobility in human serum showed differences between human erythrocyte catalase and bovine liver catalase. These results suggest that human erythrocyte catalase and bovine liver catalase are two distinct catalase forms.     

Purification and properties of recombinant rat catalase produced in Escherichia coli

Catalase is a characteristic enzyme of peroxisomes. To study the molecular mechanisms of the biogenesis of peroxisomes and catalase in a less complex system than rat liver cells, we expressed recombinant rat catalase in Escherichia coli, which has no peroxisomes. The concentration of recombinant catalase produced in E. coli transformed with the expression vector carrying the complete coding region of rat catalase cDNA was about 0.1% of the total soluble protein. The recombinant catalase was purified by DEAE-cellulose column chromatography followed by acidic ethanol precipitations. The properties of rat liver catalase and those of the recombinant were similar with respect to molecular mass, catalytic properties, profiles of absorption spectra, and iron contents. The NH2-terminal amino acid sequence of the purified recombinant catalase, as determined by Edman degradation, was in complete agreement with the amino acid sequence predicted from the nucleotide sequence of rat catalase cDNA, except that the first initiator methionine was not detected. The COOH-terminal amino acid sequence was determined by carboxypeptidase A digestion and the sequence, -Ala-Asn-Leu-OH, matched the predicted COOH-terminal amino acid sequence of rat catalase. Recombinant rat catalase gave almost the same multiple protein bands on native polyacrylamide gel isoelectric focusing as observed with authentic rat liver catalase.     

Purification and characterization of mouse alcohol dehydrogenase from two inbred strains that differ in total liver enzyme activity

Alcohol dehydrogenase activity in mouse liver homogenate-supernatants is 1.7 times greater in the C57BL/10 strain than in the BALB/c strain, regardless of whether activity is expressed in units per gram liver, total liver, or milligram DNA. The K _m values for ethanol and NAD⁺, approximately 0.4 and 0.03mm, respectively, of enzyme purified from both strains are similar. Moreover, the K _i for NADH, 1 µm, the pH optimum for ethanol oxidation, 10.5, and the V _max for ethanol oxidation, 160 min^–1, for ADH from the C57BL/10 and BALB/c strains are similar. Therefore, the difference in ADH activity in the two strains cannot be due to differences in the catalytic properties of the enzyme. The electrophoretic and isoelectric focusing patterns and two-dimensional tryptic peptide maps of the purified enzyme from both strains are identical. Thus the amino acid sequences of enzyme from C57BL/10 and BALB/c mice must also be identical or very similar. The difference in ADH activity in the two strains is most likely the result of genetic differences in the content of ADH protein in liver.Supported by NIAAA Grant AA 04307.     

On the interactions of catalase with subcellular structure

The interaction of mouse liver catalase with subcellular membranes was studied, and an ionic interaction with a variety of membranes, including those derived from the microsomes, was observed. The interaction with microsomal membranes was found to be abolished by pre-treatment of catalase with neuraminidase, indicating a functional significance for catalase-bound sialic acid. Catalase activity was found to be enhanced when bound to membranes, and evidence for a weak association of catalase with peroxisomal structure in mouse liver was also obtained. It is concluded that mouse liver catalase has a capacity to bind to a variety of subcellular membranes in vivo and that this interaction may be consistent with a general protective role for the enzyme, as well as being compatible with a model of peroxisomal biogenesis which involves the interaction of catalase with microsomal membranes.Abbreviations LGF Large Granule Fraction     

Comparative kinetic characterization of catalases of the genusPenicillum

Extracellular catalases produced by fungi of the genusPenicillium, i.e.,P. piceum, P. varians, andP. kapuscinskii, were purified by consecutive filtration of culture liquids. The maximum reaction rate of H₂O₂ decomposition, the Michaelis constants, and specific catalytic activities of isolated catalases were determined. The operational stability was characterized by the effective rate of catalase inactivation during enzymatic reaction (k _in at 30°C). The thermal stability was determined by the rate of enzyme thermal inactivation at 45°C (k _in ^* , s^-1). Catalase fromP. piceum displayed the maximum activity, which was higher than the activity of catalase from bovine liver. The operational stability of catalase fromP. piceum was twofold to threefold higher than the stability of catalase from bovine liver. The physicochemical characteristics of catalases of fungi are better than the characteristics of catalase from bovine liver and intracellular catalase of yeastC. boidinii.     

Comparison of ornithine decarboxylase from rat liver, rat hepatoma and mouse kidney.

Comparisons were made of ornithine decarboxylase isolated from Morris hepatoma 7777, thioacetamide-treated rat liver and androgen-stimulated mouse kidney. The enzymes from each source were purified in parallel and their size, isoelectric point, interaction with a monoclonal antibody or a monospecific rabbit antiserum to ornithine decarboxylase, and rates of inactivation in vitro, were studied. Mouse kidney, which is a particularly rich source of ornithine decarboxylase after androgen induction, contained two distinct forms of the enzyme which differed slightly in isoelectric point, but not in Mr. Both forms had a rapid rate of turnover, and virtually all immunoreactive ornithine decarboxylase protein was lost within 4h after protein synthesis was inhibited. Only one form of ornithine decarboxylase was found in thioacetamide-treated rat liver and Morris hepatoma 7777. No differences between the rat liver and hepatoma ornithine decarboxylase protein were found, but the rat ornithine decarboxylase could be separated from the mouse kidney ornithine decarboxylase by two-dimensional gel electrophoresis. The rat protein was slightly smaller and had a slightly more acid isoelectric point. Studies of the inactivation of ornithine decarboxylase in vitro in a microsomal system [Zuretti & Gravela (1983) Biochim. Biophys. Acta 742, 269-277] showed that the enzymes from rat liver and hepatoma 7777 and mouse kidney were inactivated at the same rate. This inactivation was not due to degradation of the enzyme protein, but was probably related to the formation of inactive forms owing to the absence of thiol-reducing agents. Treatment with 1,3-diaminopropane, which is known to cause an increase in the rate of degradation of ornithine decarboxylase in vivo [Seely & Pegg (1983) Biochem. J. 216, 701-717] did not stimulate inactivation by microsomal extracts, indicating that this system does not correspond to the rate-limiting step of enzyme breakdown in vivo.     

Behavior of rat liver catalase during electrophoresis in a pH gradient.

Investigations were conducted on the distribution of rat liver catalase subsequent to electrofocusing in a pH gradient. Differences were observed depending on the enzyme being extracted from the total mitochondrial fraction, from the supernatant of the homogenate or from purified peroxisomes. Catalase solubilized from the total mitochondrial fraction exhibits an apparent isoelectric point lower than that of catalase derived from the supernatant. Catalase released from purified peroxisomes shows a behavior similar to that of the supernatant catalase. It has been concluded that, in a total mitochondrial fraction, a factor is present that alters the electric charge of the catalase molecule during or after the extraction of the enzyme. This factor is probably associated with lysosomes existing together with peroxisomes and mitochondria in a total mitochondrial fraction. As a matter of fact, the addition of an extract of purified lysosomes to purified peroxisomes or to supernatant will cause a shift towards a more acid pH of catalase distribution subsequent to electrofocalization.     

Proteolytic modification of mouse liver catalase

When catalase was immunoprecipitated from different subfractions of mouse liver homogenates, the enzyme which was obtained from extracts of the large granular fraction exhibited a lower molecular weight than that from either the cytosol or purified peroxisomal fractions, as judged by sodium dodecyl sulphate polyacrylamide gel electrophoresis. This modification of the enzyme could be prevented by the addition of proteolytic inhibitors to extraction buffers; and consequently, unmodified catalase was able to be purified in the presence of 5 mM iodoacetamide. Electrophoretic comparison of the catalases against standards of known molecular sizes indicated that the unmodified enzyme had a subunit mass approximately 2,000 daltons larger than the modified enzyme. The significance of these proteolytic modifications has been discussed in relation to the involvements of catalase and peroxisome turnover.     

Purification of a fluoroacetate-specific defluorinase from mouse liver cytosol

Fluoraocetate-specific defluorinase, an enzyme which catalyzes the release of fluoride ion from the rodenticide fluoroacetate, has been purified 347-fold from mouse liver cytosol and shown to be distinct from multiple cationic and anionic glutathione S-transferase isozymes. Fluoroacetate-specific defluorinase was obtained at a final specific activity of 659 nmol of F-/min/mg of protein and was prepared in an overall yield of 12%. The isoelectric point of this hepatic enzyme was acidic, at pH 6.4, as determined by column chromatofocusing. The molecular weight of the active species was estimated at 41,000, and sodium dodecyl sulfate-polyacrylamide gels of the purified defluorinase demonstrated a predominant subunit, Mr = 27,000. Chromatofocusing completely partitioned the fluoroacetate-specific defluorinase from two separate peaks of murine anionic glutathione S-transferase activity. Rabbit antibodies prepared against the purified hepatic defluorinase quantitatively precipitated native defluorinase from mouse and rat liver, but were unable to immunoprecipitate cationic or anionic glutathione S-transferase enzymes from the same preparation. The evidence presented suggests that fluoroacetate-specific defluorinase and glutathione S-transferase activities are catalyzed by separate proteins present in the cytosol of mouse liver.     

Purification and properties of avian liver p-hydroxyphenylpyruvate hydroxylase.

Avian liver p-hydroxyphenylpyruvate hydroxylase (EC 1.13.11.27) was purified to a 1000-fold increase in specific activity over crude supernatant, utilizing a substrate analogue, o-hydroxyphenylpyruvate, to stabilize the enzyme. The preparation was homogeneous with respect to sedimentation with a sedimentation velocity (s20,w) of 5.3 S. The molecular weight of the enzyme was determined to be 97,000 +/- 5,000 by sedimentation equilibrium, and the molecular weight of the subunits was determined to be 49,000 +/- 3,000 by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Polyacrylamide gel electrophoresis revealed heterogeneity of the purified enzyme. The multiple molecular forms were separable by isoelectric focusing, and their isoelectric points ranged from pH 6.8 to 6.0. The amino acid compositions and tryptic peptide maps of the three forms isolated by isoelectric focusing were very similar. The forms of the enzyme had the same relative activity toward p-hydroxyphenylpyruvate and phenylpyruvate. Conditions which are known to accelerate nonenzymic deamidation of proteins caused interconversion of the multiple molecular forms. Iron was the only transition metal found to be associated with the purified enzyme at significant levels. The amount of enzyme-bound iron present in equilibrium-dialyzed samples was equivalent to 1 atom of iron per enzyme subunit. Purification of the enzyme activity correlated with the purification of the enzyme-bound iron. An EPR scan of the purified enzyme gave a signal at g equal 4.33, which is characteristic of ferric iron in a rhombic ligand field.     

Ontogeny of Mouse Liver Peroxisomes and Catalase Isozymes

PEROXISOMES are cytoplasmic organelles which occur in liver and kidney cells of higher animals and in lower forms of life. They have a unique enzyme composition and function in the oxidation of specific substrates by oxidases¹. Catalase (hydrogen peroxide: hydrogen peroxide oxidoreductase E.C. 1.11.1.6) is an essential component of this oxidizing system which facilitates the catalytic or peroxidatic destruction of hydrogen peroxide. Large granular catalase activity serves as a marker for the organelle and has been used here to describe the ontogeny of peroxisomes in mouse liver. The results indicate that bursts of peroxisomal synthesis occur during the development of the mouse liver, particularly in the early postnatal stages and during maturation.     

On the multiplicity of the enzyme catalase in mammalian liver

Summary The literature on the complex multiplicity of mammlian catalase and the nature of the epigenetic modifications undergone by this enzyme has been reviewed, along with relevant comment on the subcellular localization and biological role of the enzyme.The epigenetic causations of multiplicity are established as being multifactorial and include oxidoreductive conversions of sulphydryl groups, the covalent attachment of carbohydrate, and partial proteolysis of the enzyme. Each of these epigenetic transformations may give rise to sets of multiple forms, and overlaps between these separate sets may give rise to extremely complex multiplicity patterns.It is concluded that any interpretation of catalase multiplicity which places emphasis on a single epigenetic causation is not compatible with the scope and variety of the available data on this enzyme. Instead, a holistic approach is urged — one giving due emphasis to the multiple causation of catalase multiplicity, and the interrelationships of these causations in the cellular situation. Rather than viewing the multiplicity of this enzyme as merely a series of interesting chemical modifications, emphasis is directed towards the fact that catalase heterogeneity povides a sensitive indication of the functional variations which occur within separate compartments of the subcellular structure, and hence becomes an essential element in any satisfactory understanding of the role of this enzyme in cellular processes.     

Studies on the characterization of the sodium-potassium transport adenosine triphosphatase. Purification and properties of the enzyme from the electric organ of Electrophorus electricus

An unspecific carboxylesterase was purified 180-fold from acid-precipitated human liver microsomes. The final preparation was homogeneous on disc electrophoresis and polyacrylamide gel electrophoresis in the presence of 6.25 M urea at pH 3.2. A single symmetrical peak was also found on gel filtration and on velocity sedimentation in the analytical ultracentrifuge, whereas slight heterogeneity was observed on isoelectric focusing.The amino acid composition of the purified enzyme is presented. From the results the partial specific volume (0.745 ml × g^?1) and the minimal molecular weight (60,000) could be calculated. Fingerprint maps of tryptic peptides from the carboxymethylated enzyme are shown.The molecular weight as determined by gel filtration, disc electrophoresis, and analytical ultracentrifugation is in the range of 181,000–186,000. For the molecular weight of the subunits a value of 61,500 has been obtained by sodium dodecylsulfate polyacrylamide gel electrophoresis. The equivalent weight of the enzyme has been estimated to be 62,500 from stoichiometry of its reaction with diethyl-p-nitrophenyl-phosphate. Partial cross-linking of the subunits with dimethyl suberimidate and subsequent sodium dodecylsulfate polyacrylamide gel electrophoresis yielded three bands with molecular weights of 60,000, 120,000, and 180,000.From these results it is concluded that human liver esterase is a trimeric protein. It is composed of three subunits of equal size, and there is one active site per subunit.     

Purification, characterization, and mass spectrometric sequencing of a medium chain acyl-CoA synthetase from mouse liver mitochondria and comparisons with the homologues of rat and bovine

Medium chain acyl-CoA synthetases catalyze the first reaction of amino acid conjugation of many xenobiotic carboxylic acids and fatty acid metabolism. This paper reports studies on purification, characterization, and the partial amino acid sequence of mouse liver enzyme. The medium chain acyl-CoA synthetase was isolated from mouse liver mitochondria. The purified enzyme catalyzes this reaction not only for straight medium chain fatty acids but also for aromatic and arylacetic acids. Maximal activity was found with hexanoic acid. High activities were obtained with benzoic acid having methyl, pentyl, and methoxy groups in the para- or meta-positions of the benzene ring. However, the enzyme was less active with valproic acid and ketoprofen. Salicylic acid exhibited no activity. The medium chain acyl-CoA synthetases from mouse and bovine liver mitochondria were subjected to in-gel tryptic digestion, followed by LC-MS/MS sequence analysis. The amino acid sequence of each tryptic peptide of mouse liver mitochondrial medium chain acyl-CoA synthetase differed from that from bovine liver mitochondria only in one or two amino acids. LC-MS/MS analysis provided the information about these differences in amino acid sequences. In addition, we compared the properties of this protein with the homologues from rat and bovine.     

Purification and characterization of sepiapterin reductase from rat erythrocytes

Sepiapterin reductase from rat erythrocyte hemolysate was purified 2000-fold to apparent homogeneity with 30% yield. The specific activity of the purified enzyme was 18 units/mg protein, and its molecular weight was 55 000. The enzyme consists of two identical subunits, each of which has a molecular weight of 27 500. The enzyme showed a single peak by isoelectric focusing with a pI of 4.9 and partial specific volume of 0.73 cm³/g. The amino acid composition was determined. pH optimum of the enzyme was 5.5. The equilibrium constant of 2.2·10⁹ of the enzyme showed that the equilibrium lies much in favor of dihydrobiopterin formation from sepiapterin in rat erythrocytes. From steady-state kinetic measurements, ordered bi-bi mechanism was proposed to the reaction of sepiapterin reductase in which NADPH binds to free enzyme and sepiapterin binds next. NADP⁺ is released after the release of dihydrobiopterin. The K_m values for sepiapterin and NADPH were 15.4 μM and 1.7 μM, respectively, and the V_max value was 21.7 μmol/min per mg.     

Purification and characterization of liver catalase in acatalasemic beagle dog: comparison with normal dog liver catalase

Catalase from acatalasemic dog liver was purified to homogeneity and its properties were compared with those of normal dog liver catalase. The purified acatalasemic and normal dog liver catalases were found to have the same molecular weight (230,000 Da) and isoelectric point (pI: 6.0-6.2) and both enzymes contained four hematins per molecule. The catalytic activity of catalase from acatalasemic dog was normal. Furthermore, there was no difference between the acatalasemic and normal dog catalases in the binding affinity to NADPH (apparent Kd: 0.11-0.12 microM) and in the sensitivity to oxidative stress by hydrogen peroxide, the normal substrate of catalase. The acatalasemic dog enzyme was stable only in a narrow pH range (pH 6-9) although the normal enzyme was stable in a wide pH range (pH 4-10). Acatalasemic dog liver catalase also showed a slight low thermal stability at 37 degrees C and the heat-lability was remarkable at 45 degrees C, compared to the normal dog enzyme. These results indicated that the acatalasemic dog catalase is catalytically normal although it is associated with an unstable molecular structure.     

Selection of High Ubiquinone 10-Producing Strain of Tobacco Cultured Cells by Cell Cloning Technique

A novel enzyme, which was named N^α-benzyloxycarbonyl amino acid urethane hydrolase, was purified from a cell-free extract of Streptococcus faecalis R ATCC 8043, using N^α-benzyloxycarbonyl glycine as substrate. The enzyme was purified 1300-fold with an activity yield of 8%. The purified enzyme was homogeneous by disc electrophoresis. The molecular weight of the native enzyme is about 220,000 by gel filtration, and a molecular weight of 32,000 was determined for the reduced and denatured enzyme by gel electrophoresis in sodium dodecyl sulfate. The isoelectric point was 4.48. The enzyme was inhibited by p-chloromercuribenzoate. The presence of divalent cations (i.e., Co²⁺ or Zn²⁺) is essential for its activity.     

Detection of Molecular Ions of Cerebroside by Gas Chromatography—Mass Spectrometry

Oxalate oxidase (EC 1.2.3.4) was purified to apparent homogeneity from Pseudomonas sp. OX-53. The molecular weight of the enzyme was about 320,000 by Sephadex G-200 column chromatography and 38,000 by sodium dodecyl sulfate disc electrophoresis. The isoelectric point of the enzyme was pH 4.7 by isoelectric focusing. This enzyme contained 1.12 atoms of manganese and 0.36 atoms of zinc per subunit. Besides oxalic acid, the enzyme oxidized glyoxylic acid and malic acid at lower reaction rates. The Michaelis constant of the enzyme was 9.5 mM for oxalic acid at the optimal pH 4.8. The enzyme was stable from pH 5.5 to 7.0. The enzyme was activated by flavins, phenylhydrazine, and o-phenylenediamine, and inhibited by I^–, Br^–, semicarbazide, and hydroxylamine.     

Two-Step Purification of Mouse Kidney Ornithine Decarboxylase

Abstract

We developed a simple two-step purification procedure for ornithine decarboxylase (ODC, EC 4. 1. 1. 17), consisting of DEAE-Cellulofine chromatography and affinity chromatography on a HO-101 monoclonal anti-rat liver ODC antibody-Affi-Gel 10 column. By this method, ODC was purified 1700-fold to homogeneity with about 80% yield from the kidney of ICR mice treated with testosterone enanthate. The final specific activity range between 1. 0 × 10⁶?1. 4 × 10⁶ nmol/h. mg protein. On SDS-polyacrylamide gel electrophoretic analysis, the final preparations gave a major protein band of Mr 54, 000 and a minor band of Mr 51, 000. Although relative staining intensity of the two bands varied depending on preparations, both bands could be stained by immunoblotting and labeled by a preincubation with [¹⁴C)difluoromethylornithine (DFMO). On Oudin double diffusion immunoanalysis, a single fused precipitin line was formed between purified anti-mouse kidney ODC IgG and both the purified enzyme and crude mouse kidney extract. In contradiction with earlier reports, no significant difference was observed between mouse kidney ODC and rat liver ODC in either final specific activity or specific binding of labeled DFMO.