Two temporally synthesized charge subunits interact to form the five isoforms of cottonseed (Gossypium hirsutum) catalase.

Five charge isoforms of tetrameric catalase were isolated from cotyledons of germinated cotton (Gossypium hirsutum L.) seedlings. Denaturing isoelectric focusing of the individual isoforms in polyacrylamide gels indicated that isoforms A (most anodic) and E (most cathodic) consisted of one subunit of different charge, whereas isoforms B, C and D each consisted of a mixture of these two subunits. Thus the five isoforms apparently were formed through combinations of two subunits in different ratios. Labelling cotyledons in vivo with [35S]methionine at three daily intervals in the dark, and translation in vivo of polyadenylated RNA isolated from cotyledons at the same ages, revealed synthesis of two different subunits. One of the subunits was synthesized in cotyledons at all ages studied (days 1-3), whereas the other subunit was detected only at days 2 and 3. This differential expression of two catalase subunits helped explain previous results from this laboratory showing that the two anodic forms (A and B) found in maturing seeds were supplemented with three cathodic forms (C-E) after the seeds germinated. These subunit data also helped clarify our new findings that proteins of isoforms A, B and C (most active isoforms) accumulated in cotyledons of plants kept in the dark for 3 days, then gradually disappeared during the next several days, whereas isoforms D and E (least active isoforms) remained in the cells. This shift in isoform pattern occurred whether seedlings were kept in the dark or exposed to continuous light after day 3, although exposure to light enhanced this process. These sequential molecular events were responsible for the characteristic developmental changes (rise and fall) in total catalase activity. We believe that the isoform changeover is physiologically related to the changeover in glyoxysome to leaf-type-peroxisome metabolism.     

Dissociation of bovine and bacterial catalases by sodium n-dodecyl sulfate

The dissociation of beef liver and bacterial (Micrococcus lysodeikticus) catalases by the action of sodium n-dodecyl sulfate (SDS) has been investigated as a function of SDS concetration and time by ultracentrifugation. The rate of dissociation of beef liver catalase is found to be much faster than that for bacterial catalase in 25 mM SDS at pH 7.0. Beef liver catalase is dissociated into its four subunits after 24 h, whereas bacterial catalase is not completely dissociated after 36 days of incubation. The binding of SDS to beef liver catalase obeys a Hill equation with a cooperativity exponent of 2.0 and a binding constant of 440. The initial interaction of SDS with beef liver catalase can be detected by microcalorimetry, whereas the mixing of SDS with bacterial catalase is athermal. Bacterial catalase retains enzymic activity in the presence of SDS, whereas beef liver catalase is completely deactivated at SDS concentrations above 5 mM. Beef liver catalase is more sensitive to acid denaturation than bacterial catalase, and the rate of dissociation for both catalases is sixth-order in proton concentration. Comparison of the amino acid analysis of the two catalases shows that bacterial catalase has a smaller number of lysyl residues and a larger number of glutamyl residues than beef liver catalase. Taken together these structural differences could lead to a reduced affinity of bacterial catalase for the binding of SDS as observed.     

Presence of a high-molecular-weight form of catalse in enzyme purified from mouse liver.

Ultracentrifugation studies of purified mouse hepatic catalase revealed that 5-7% of the total material consists of a form with a higher molecular weight than the bulk of the catalase. The two components were separated by sucrose-gradient centrifugation. Polyacrylamide-gel electrophoresis (in borate buffer) demonstrated that high-molecular-weight catalase is enriched in a more slowly migrating component, and sodium dodecyl sulphate/polyacrylamide gel-electrophoresis demonstrated that the molecular weight of the subunits of the high-molecular-weight material is identical with that of the subunits of the major form. These results suggest that high-molecular-weight catalase consists of subunits that are not markedly distinct from those present in the normal catalase tetramer.     

Tissue-Specific Isoforms of Catalase Subunits in Castor Bean Seedlings

Catalases purified from endosperm glyoxysomes and non-specializedmicrobodies from hypocotyls of castor bean seedlings differedin their specific activity [90–164 and 0.89–4.9kunits (mg protein)^–1, respectively] and in their constituentsubunits [two subunits of 54 and 56 kDa for the endosperm enzymeand only one of 56 kDa for the hypocotyl enzyme]. Immunoblotanalysis also showed that particulate fractions from the endospermsand from etiolated and green cotyledons contained two catalasesubunits of 54 and 56 kDa, whereas such fractions from the hypocotylsand roots contained only the 56-kDa subunit. Leaf peroxisomesfrom green leaves had two catalase subunits of around 55 kDaeach. Results of translation in vitro indicated that the 54-and 56-kDa subunits were translated from distinct mRNAs andlevels of both mRNAs increased in the endosperms during germination,prior to increases in levels of catalase proteins. In the hypocotyls,the 56-kDa subunit seemed to be synthesized constitutively. ¹Present addresses: YO, Toyota Central Institute, 31-9 Musashizuka,Nagabuchi, Nagakute, Aichi 480-11, Japan     

Peroxidase activity of succinylated catalase

The catalase succinylation by succinic anhydride excess results in an almost complete dissociation of the enzyme into subunits possessing no catalase activity. The catalase subunits show the peroxidatic activity on o-dianisidine oxidation. The oxidation kinetics of this substrate by the succinylated enzyme was studied at various temperatures. The activation energy for this process is 10.1 kcal/mole. Within the temperature range of 31-65.5 degrees, the succinylated enzyme thermostability was studied by monitoring the peroxidatic activity decrease upon o-dianisidine oxidation. The activation energy for the succinylated catalase thermoinactivation equals to 15.5 kcal/mole. The peroxidatic activity of catalase subunits obtained by enzyme succinylation and acidic solution treatment was compared to that of horseradish peroxidase in the oxidation of the same substrate, i.e., o-dianisidine.     

Fodrin is the general spectrin-like protein found in most cells whereas spectrin and the TW protein have a restricted distribution

Spectrin and related proteins are made up of a common calmodulin-binding subunit tightly associated with a variant subunit. We have analyzed the distribution of the variant subunits in various cell types using subunit-specific antibodies in immunofluorescence as well as western blotting and in some cases have compared the subunits by two-dimensional peptide mapping. We have found that in the majority of cell types (lymphocytes, hepatocytes, neurons, fibroblasts) fodrin 235 K is present in the absence of the other two variant subunits, spectrin 220 K and TW260. Two cell types were found (skeletal muscle and erythrocytes) which contained only the spectrin variant. Two cell types display two distinct variant subunits. Both fodrin 235 K and spectrin 220 K are detected in cardiac muscle whereas TW260 is present in addition to fodrin 235 K in intestinal epithelial cells. During the early stages of embryonic development of the chicken intestine, fodrin 235 K is expressed in the epithelial cells whereas TW260 and spectrin are not detectable. TW260 is expressed relatively late in development (15-16 days) and is inserted only in the apical (brush border) membrane compartment whereas fodrin 235 K is present in these same cells and underlies the entire plasma membrane. These results suggest that fodrin provides the general linkage system between microfilaments and the membrane in nonerythroid and nonmuscle cells.     

Properties of erythrocyte catalase from homozygotes and heterozygotes for Swiss-type acatalasemia

The unstable catalase variant found in the blood of individuals homozygous for Swiss-type acatalasemia and the enzyme species present in heterozygous carriers of this rare defect have been further characterized. The mutant enzyme isolated from acatalasemic red cells is considerably more heat labile and differs in electrophoretic mobility from the normal enzyme. Catalase preparations obtained from heterozygotes consist of an apparently uniform enzyme species, probably representing a molecular hybrid, with properties intermediate to those of the normal and the variant enzyme. However, antigenic identity of catalase from all three sources is observed. Model experiments indicate that hybrid catalase molecules can be produced by recombining normal and variant dimer subunits. Fractionation of erythrocytes according to density and age shows that most of the residual catalase activity is localized in juvenile acatalasemic cells, whereas in normal and heterozygous individuals the catalase activity level does not alter significantly during the life span of the red cells. These findings agree with the observation that there is no gene dosage in heterozygotes, their catalase activity values falling within the normal range.     

Crystal structure of manganese catalase from Lactobacillus plantarum

BACKGROUND: Catalases are important antioxidant metalloenzymes that catalyze disproportionation of hydrogen peroxide, forming dioxygen and water. Two families of catalases are known, one having a heme cofactor, and the other, a structurally distinct family containing nonheme manganese. We have solved the structure of the mesophilic manganese catalase from Lactobacillus plantarum and its azide-inhibited complex. RESULTS: The crystal structure of the native enzyme has been solved at 1.8 A resolution by molecular replacement, and the azide complex of the native protein has been solved at 1.4 A resolution. The hexameric structure of the holoenzyme is stabilized by extensive intersubunit contacts, including a beta zipper and a structural calcium ion crosslinking neighboring subunits. Each subunit contains a dimanganese active site, accessed by a single substrate channel lined by charged residues. The manganese ions are linked by a mu1,3-bridging glutamate carboxylate and two mu-bridging solvent oxygens that electronically couple the metal centers. The active site region includes two residues (Arg147 and Glu178) that appear to be unique to the Lactobacillus plantarum catalase. CONCLUSIONS: A comparison of L. plantarum and T. thermophilus catalase structures reveals the existence of two distinct structural classes, differing in monomer design and the organization of their active sites, within the manganese catalase family. These differences have important implications for catalysis and may reflect distinct biological functions for the two enzymes, with the L. plantarum enzyme serving as a catalase, while the T. thermophilus enzyme may function as a catalase/peroxidase.     

Effect of cobalt on the synthesis and degradation of hepatic catalse in vivo

1. The administration of CoCl(2) to rats caused a decrease in hepatic catalase activity as well as a decrease in the amount of catalase protein as measured by immunological assay. The mitochondrial enzyme decreased progressively over 2 days, whereas the cytosol enzyme decreased over 12h and then remained essentially unchanged for 2 days after a single injection of cobalt. 2. Incorporation of [(14)C]glycine into catalase haem was dramatically decreased by a single injection of cobalt, but that into catalase protein remained essentially unaltered. 3. Incorporation of [(3)H]leucine into liver protein increased in rats in a steady state receiving a daily injection of cobalt, which was in contrast with a marked inhibition observed in 5-amino[(3)H]laevulinate incorporation. 4. The initial rate of [(3)H]leucine incorporation into mitochondrial and cytosol catalase did not alter or was slightly depressed in the cobalt-treated animals, whereas the incorporation of 5-amino[(3)H]laevulinate into mitochondrial and cytosol catalase was conspicuously decreased, indicating that haem synthesis was limiting catalase formation. 5. The degradation rate of catalase protein, as measured by a double-labelling method, was not changed by the cobalt treatment.     

Purification and enzymatic properties of lysyl hydroxylase from fetal porcine skin.

Lysyl hydroxylase from fetal porcine skin is shown to bind in a highly specific manner to aminoethyl-Sepharose 4B. When coupled to ammonium sulfate fractionation and DEAE-cellulose chromatography, chromatography of lysyl hydroxylase preparations on aminoethyl-Sepharose 4B has yielded a highly purified (greater than 95%) preparation of lysyl hydroxylase. The enzyme consists of two subunits with molecular weights of 70 000 and 115 000. The overall recovery of activity was 2.5%, yielding approximately to 3.5 mg of purified enzyme from 900 g of fetal porcine skin. The enzyme is more active at 30 degrees C than at 37 degrees C and has a pH optimum near 8.0. Both catalase and bovine serum albumin are required by the enzyme for maximum activity. The sulfhydryl reagents p-(chloromercuri)-benzoate, N-ethylmaleimide, and iodoacetamide are potent inhibitors of the enzyme, whereas dithiothreitol appears to be an activator.     

Turnover of enzymes of peroxisomal β-oxidation in rat liver

Male Wistar rats were given a diet containing 2% (w/w) di-(2-ethylhexyl)-phthalate (DEHP), a peroxisomal proliferator, for 4 weeks. The activities of enzymes of peroxisomal β-oxidation and of catalase were markedly increased by the DEHP administration. The time required to reach halfway to the maximal induction for enzymes of peroxisomal β-oxidation was 5–7 days, whereas that for catalase was 3 days. A separate DEHP group was placed on the control diet after 14 days of feeding with the DEHP diet. On the withdrawal of DEHP, activities of enzymes of the β-oxidation system and of catalase decreased to the control levels with a half-life of 2–3 days. Responses of some mitochondrial enzymes involved in fatty acid oxidation are also described.     

Catalase Is Differentially Expressed in Dividing and Nondividing Protoplasts

Based on our previous results that peroxidase is induced in dividing tobacco protoplasts but it is not expressed in the nondividing grapevine (Vitis vinifera L.) protoplasts during culture (C.I. Siminis, A.K. Kanellis, K.A. Roubelakis-Angelakis [1993] Physiol Plant 87: 263-270), we further tested the hypothesis that oxidative stress may be implicated in the recalcitrance of plant protoplasts. The expression of catalase, a major defense enzyme against cell oxidation, was studied during isolation and culture of mesophyll protoplasts from the recalcitrant grapevine and regenerating tobacco (Nicotiana tabacum L.). Incubation of tobacco leaf strips with cell wall-degrading enzymes resulted in a burst of catalase activity and an increase in its immunoreactive protein; in contrast, no such increases were found in grapevine. The cathodic and anodic catalase isoforms consisted exclusively of subunits [alpha] and [beta], respectively, in tobacco, and of subunits [beta] and [alpha], respectively, in grapevine. The catalase specific activity increased only in grapevine protoplasts during culture. The ratio of the enzymatic activities to the catalase immunoreactive protein declined in dividing tobacco protoplasts and remained fairly constant in nondividing tobacco and grapevine protoplasts during culture. Also, in dividing tobacco protoplasts the de novo accumulation of the catalase [beta] subunit gave rise to the acidic isoenzymes, whereas in nondividing tobacco and grapevine protoplasts, after 8 d in culture, only the basic isoenzymes remained due to de novo accumulation of the [alpha] subunit. The pattern of catalase expression in proliferating tobacco leaf cells during callogenesis was similar to that in dividing protoplasts. The different responses of catalase expression in dividing and nondividing tobacco and grapevine mesophyll protoplasts may indicate a specificity of catalase related to induction of totipotency.     

Catalase is encoded by a multigene family in Arabidopsis thaliana (L.) Heynh.

The catalase multigene family in Arabidopsis includes three genes encoding individual subunits that associate to form at least six isozymes that are readily resolved by nondenaturing gel electrophoresis. CAT1 and CAT3 map to chromosome 1, and CAT2 maps to chromosome 4. The nucleotide sequences of the three coding regions are 70 to 72% identical. The amino acid sequences of the three catalase subunits are 75 to 84% identical and 87 to 94% similar, considering conservative substitutions. Both the individual isozymes and the individual subunit mRNAs show distinct patterns of spatial (organ-specific) expression. Six isozymes are detected in flowers and leaves and two are seen in roots. Similarly, mRNA abundance of the three genes varies among organs. All three mRNAs are highly expressed in bolts, and CAT2 and CAT3 are highly expressed in leaves.     

Study of the subunit structure of catalase from Penicillium vitale

A molecule of Penicillium vitale catalase is shown to dissociate into subunits with the molecular weight 75-80 kDalton. When hemin is splitted off the molecule also disintegrates into subunits equalling 1/4 of the enzyme molecule. The amino acid composition and fingerprints of the catalase subunits were studied. It is supposed that N-terminal residue of the subunit is blocked.     

The peroxidatic and catalatic activity of catalase in normal and acatalasemic mouse liver

Monomeric, dimeric and tetrameric forms of mouse liver catalase have been shown to express peroxidatic activity while the tetrameric form expresses the catalic activity. Autosomally inherited acatalasemia, produced by X-ray irradiation of mice results in almost complete loss of catalic activity of catalase but has no effect on the peroxidatic activity. Liver catalase from normal and acatalasemic mice was purified by following the catalic and peroxidatic activity, respectively. Antiserum produced in rabbit against catalase from normal mouse completely precipitated the catalatic and peroxidatic activity from normal liver, and peroxidatic activity from the acatalasemic liver homogenate. Similar results were obtained when antiserum against peroxidase from acatalasemic mice was used. These studies indicate that acatalasemia in mice is due to a structural gene mutation which leads to synthesis of structurally altered catalase subunits. The altered subunits express peroxidatic activity but do not combine to form a tetramer which expresses catalatic activity.     

Some properties of human eosinophil peroxidase, a comparison with other peroxidases

Eosinophil peroxidase (donor:hydrogen peroxide oxidoreductase, EC 1.11.1.7) was isolated from outdated human white blood cells. The purified enzyme has a molecular weight of 71000 +/- 1000. The enzyme is composed of two subunits, of Mr 58000 and 14000, in a 1:1 stoichiometry. Amino-acid analyses showed that eosinophil peroxidase has a high content of the amino acids arginine, leucine and aspartic acid. The millimolar absorbance coefficient of the Soret band at 412 nm of eosinophil peroxidase was determined. Three independent methods yield a value for epsilon 412nm of 110 +/- 4 mm-1 X cm-1. Purified eosinophil peroxidase showed a homogeneous high-spin EPR signal with rhombic symmetry (gx = 6.50; gy = 5.40; gz = 1.982) for the haem group. EPR spectroscopy of low-spin cyanide and azide derivatives of eosinophil peroxidase, lactoperoxidase, myeloperoxidase and catalase revealed that the haem-ligand structure of eosinophil peroxidase is closely related to lactoperoxidase, whereas that of myeloperoxidase shows great resemblance to catalase.     

Peroxidase activity of catalase with respect to aromatic amines

The catalase dissociation into subunits has been studied at pH less than 3.5 and greater than 11.0. This process is characterized by pseudo-first order rate constants, depending on the initial concentrations of the enzyme and H+. At pH 2.85, the steady-state kinetics of five aromatic amines oxidation by catalase monomers has been studied for orthodianisidine (o-DA), 3,5,3',5'-tetramethylbenzidine (TMB), ortho- and para-phenylene diamine (p-PDA) and 5-aminosalycilic acid. The optimal substrates for catalase in acidic solutions are o-DA, TMB and p-PDA. A comparison has been carried out for the catalase peroxidative activity, and the catalytic characteristics of horseradish peroxidase in the oxidation of the same substrate. The mechanisms of peroxidatic amines oxidation by catalase and horseradish peroxidase are discussed.     

Beneficial effect of catalase treatment on growth of Clostridium perfringens.

Several common plating media were tested for their ability to support growth of Clostridium perfringens after storage of the plates for 1 to 10 days at 4 and 25 degrees C with and without subsequent addition of catalase. Liver-veal (LV) agar and brain heart infusion (BHI) agar quickly become incapable of supporting growth after storage without added catalase, whereas Shahidi Ferguson perfringens (SFP) agar and Brewer anaerobic (BA) agar were less affected. Plate counts of C. perfringens on untreated LV and BHI agars stored 3 days at 25 degrees C showed a reduction of 98.2%, whereas counts on SFP and BA agars were reduced by 13.6% and 46.2%, respectively. Addition of 1,500 U of beef liver catalase to the surface of the 3-day-old agars before incubation resulted in substantial restoration of their growth-promoting ability. Counts of colonies on LV, GHI, SFP, and BA agars with added catalase were usually 20 to 90% higher than untreated controls. Similar results were obtained using purified catalase, fungal catalase, and horseradish peroxidase. These results suggest that inhibition may be due to peroxide formed during storage and incubation and that additon of catalase provides near optimum conditions for growth of C. perfringens on these media.