Purification of glyoxysomal catalase and immunochemical comparison of glyoxysomal and leaf peroxisomal catalase in germinating pumpkin cotyledons

As a step to study the mechanism of the microbody transition (glyoxysomes to leaf peroxisomes) in pumpkin (Cucurbita sp. Amakuri Nankin) cotyledons, catalase was purified from glyoxysomes. The molecular weight of the purified catalase was determined to be 230,000 to 250,000 daltons. The enzyme was judged to consist of four identical pieces of the monomeric subunit with molecular weight of 55,000 daltons. Absorption spectrum of the catalase molecule gave two major peaks at 280 and 405 nanometers, showing that the pumpkin enzyme contains heme. The ratio of absorption at 405 and 280 nanometers was 1.0, the value being lower than that obtained for catalase from other plant sources. These results indicate that the pumpkin glyoxysomal catalase contains the higher content of heme in comparison with other plant catalase.

The immunochemical resemblance between glyoxysomal and leaf peroxisomal catalase was examined by using the antiserum specific against the purified enzyme preparation from pumpkin glyoxysomes. Ouchterlony double diffusion and immunoelectrophoretic analysis demonstrated that catalase from both types of microbodies cross-reacted completely whereas the immunotitration analysis showed that the specific activity of the glyoxysomal catalase was 2.5-fold higher than that of leaf peroxisomal catalase. Single radial immunodiffusion analysis showed that the specific activity of catalase decreased during the greening of pumpkin cotyledons.

     

Catalase and Superoxide Dismutase of Root-Colonizing Saprophytic Fluorescent Pseudomonads

Root-colonizing, saprophytic fluorescent pseudomonads of the Pseudomonas putida-P. fluorescens group express similar levels of catalase and superoxide dismutase activities during growth on a sucrose- and amino acid-rich medium. Increased specific activities of catalase but not superoxide dismutase were observed during growth of these bacteria on components washed from root surfaces. The specific activities of both enzymes were also regulated during contact of these bacteria with intact bean roots. Increased superoxide dismutase and decreased catalase activities were observed rapidly, by 10 min upon inoculation of cells onto intact bean roots. Catalase specific activity increased with time to peak at 12 h before declining. By 48 h, the cells displayed this low catalase but maintained high superoxide dismutase specific activities. Catalase with a low specific activity and a high superoxide dismutase activity also were present in extracts of cells obtained from 7-day-old roots colonized from inoculum applied to seed. This specific activity of superoxide dismutase of root-contacted cells was about fourfold-higher in comparison to cells grown on rich medium, whereas the specific activity for catalase was reduced about fivefold. A single catalase isozyme, isozyme A, and one isozyme of superoxide dismutase, isozyme 1, were detected during growth of the bacteria on root surface components and during exposure of cells to intact bean roots for 1 h. An additional catalase, isozyme B, was detected from bacteria after exposure to the intact bean roots for 12 h. Catalase isozyme A and superoxide dismutase isozyme 1 were located in the cytoplasm and catalase band B was located in the membrane of P. putida.     

Biochemical and developmental characterization of multiple forms of catalase in tobacco leaves

Leaf extracts of both Nicotiana tabacum and Nicotiana sylvestris contain multiple forms of catalase (H₂O₂:H₂O₂ oxidoreductase, EC 1.11.1.6) which are separable at different pH values by chromatofocusing columns. Marked changes in distribution of these catalases occur during seedling development and leaf maturation. The form of catalase eluting first (peak 1) was predominant during early seedling growth and present at all stages of development. Two more acidic forms (peaks 2 and 3) appeared later and comprised 29% of the total activity by 11 days postgermination. Mature leaves of N. tabacum contained peak 1 catalase, but peaks 2 and 3 represented 62% of the total activity. No interconversion of peaks 1, 2, and 3 was detected. The three forms of catalase differed in thermal stability with peak 1 > peak 2 peak 3. For N. sylvestris, t_½ at 55°C was 31.5 and 3.0 min for peaks 1 and 3, respectively, and for N. tabacum, t_½ was 41.5 and 3.2 min, respectively. All forms of catalase in tobacco show peroxidatic (measured as ethanol to acetaldehyde conversion) as well as catalatic activities. However, for both Nicotiana species the ratio peroxidatic/catalatic activity is at least 30-fold higher in peak 3 than in peaks 1 and 2. Chromatofocusing of extracts from spinach leaves separated at least four peaks of catalase activity, one of which had a 10-fold higher ratio of peroxidatic/catalatic activity than the others. Short-term growth (5 days) of tobacco seedlings under atmospheric conditions suppressing photorespiration (1% CO₂/21% O₂) reduced total catalase activity and caused a decline in peak 1 catalase and a substantial increase in the activity of peaks 2 and 3 relative to air-grown seedlings at the same stage.     

Identification of two catalases in Azotobacter vinelandii: a KatG homologue and a novel bacterial cytochrome c catalase, CCCAv

Azotobacter vinelandii produces two detectable catalases during growth on minimal medium. The heat-labile catalase expressed during exponential growth phase was identified as a KatG homologue by liquid chromatography-tandem mass spectrometry (LC-MS/MS) using a mixed protein sample. The second catalase was heat resistant and had substantial residual activity after treatment at 90°C. This enzyme was purified by anion-exchange and size exclusion chromatography and was found to exhibit strong absorption at 407 nm, which is often indicative of associated heme moieties. The purified protein was fragmented by proteinase K and identified by LC-MS/MS. Some identity was shared with the MauG/bacterial cytochrome c peroxidase (BCCP) protein family, but the enzyme exhibited a strong catalase activity never before observed in this family. Because two putative c-type heme sites (CXXCH) were predicted in the peptide sequence and were demonstrated experimentally, the enzyme was designated a cytochrome c catalase (CCC_Av). However, the local organization of the CCC_Av heme motifs differed significantly from that of the BCCPs as the sites were confined to the C-terminal half of the catalase. A possible Ca²⁺ binding motif, previously described in the BCCPs, is also present in the CCC_Av peptide sequence. Some instability in the presence of EGTA was observed. Expression of the catalase was abolished in cccA mutants, resulting in a nearly 8,700-fold reduction in peroxide resistance in stationary phase.     

An Inducible System for the Hydrolysis and Transport of β-Glucosides in Yeast : I. Characteristics of the β-glucosidase activity of intact and of lysed cells

A strain of bakers'' yeast was isolated which could utilize cellobiose and other β-D-glucosides quantitatively as carbon and energy sources for growth. Cellobiose-grown cells contained a largely cryptic enzyme active against the chromogenic substrate p-nitrophenyl-β-D-glucoside. The patent (intact cell) activity of such cells was inhibited by azide and, competitively, by cellobiose; neither agent inhibited the β-glucosidase activity of lysed cells or of extracts. The enzyme induced by growth in cellobiose medium had no affinity for cellobiose as either substrate or inhibitor; its substrate specificity classifies it as an aryl-β-glucosidase. It was concluded that growth in cellobiose also induced the formation of a stereospecific and energy-dependent system whose function determined the rate at which intact cells could hydrolyze substrates of the intracellular β-glucosidase.     

Effect of calcium ion uptake on Candida albicans morphology

In liquid culture using a synthetic medium, added magnesium but not calcium was required for exponential growth of Candida albicans yeast cells. However, medium without added divalent cations supported 2-3 generations of yeast growth or germ tube induction. The addition of calcium ions (1.0 mM) at any stage during the induction of germ tube formation caused reversion to a yeast mode of growth, in contrast to the effect of zinc and cobalt ions which were toxic to all growth. Inhibition of germ tube formation by calcium was not observed in the presence of either magnesium (10 microM) or manganese (100 microM). The presence of either of these ions caused inhibition of 45Ca uptake in yeast cultures. We conclude that unrestricted calcium uptake resulted in the specific inhibition of C. albicans mycelial growth, indicating a critical role for calcium in the regulation of C. albicans morphogenesis.     

Effect of water stress on the chloroplast antioxidant system: I. Alterations in glutathione reductase activity

The effect of water stress on glutathione reductase and catalase activities was evaluated in leaf blades of field-grown winter wheat (Triticum aestivum L.). Wheat was sown at two seeding rates under both irrigated and dryland conditions. Flag leaves from dryland plants sown at 60 kilograms/hectare showed no change in either glutathione reductase or catalase activities per unit leaf area, while leaves from the basal portion of the canopy exhibited a 273% increase in glutathione reductase activity and a 60% increase in catalase activity. Glutathione reductase activity in dryland plants sown at 120 kilograms/hectare increased 25% in flag leaves and 225% in basal leaves. No change in catalase activity was observed in either flag or basal leaves from these same plants. The increase in glutathione reductase activity in response to water stress was observed when activity was expressed on either a per unit leaf area, protein, or chlorophyll basis. No change in catalase activity was detected when enzyme activity was expressed on a protein basis.     

Human α-N-acetylglucosaminidase: cDNA cryptic site removal and native secretion signal addition significantly enhance enzyme expression and secretion

Human α-N-acetylglucosaminidase (Naglu) is a lysosomal acid hydrolase implicated in Mucopolysaccharidosis type IIIB (MPS IIIB). We utilize a Spodoptera frugiperda (Sf9) system to express Naglu fused to a synthetic protein transduction domain in hopes to facilitate delivery of Naglu across the blood–brain barrier, thus allowing enzyme replacement therapy to treat neurological symptoms.Although human recombinant Naglu was previously produced in Sf9, low expression levels suggested degradation via cryptic mRNA splicing. Two cryptic splice sites discovered within Naglu cDNA were altered by site-directed mutagenesis, reducing Naglu mRNA degradation. A native Naglu secretion-signaling peptide was efficiently recognized by the Sf9 system. Significantly higher enzyme activity was seen from multiple adherent Sf9 cultures stably expressing mutagenized Naglu over those expressing wildtype Naglu (P = 0.000; 3.4-fold average increased specific activity). Suspension cultures demonstrated a 4.0-fold increase in overall enzyme activity secreted post-mutagenesis. Thus elimination of cryptic splicing directly resulted in higher Naglu expression.     

A comparative study of the components of the antioxidant defense system during growth of the mycelium of a wild-type Neurospora crassa strain and mutants, white collar-1 and white collar-2

A comparative study of the changes in the components of the antioxidant defense system (ADS), the activity of superoxide dismutase (SOD) and catalase and the level of extractable SH-groups, during the growth of wild-type and mutant (white collar-1 and white colar-2) Neurospora crassa strains was performed. Oxidative stress developing during spore germination and upon the transition to a stationary growth phase was accompanied in all strains by an increase in the level of extractable SH-groups and SOD activity, whereas the total catalase activity decreased during growth. However, in contrast to the wild-type strain, the activity of the catalase in the mutant strains wc-1 and wc-2 slightly increased upon the transition to the stationary phase. In the wc-2 mutant, SOD activity and the level of extractable SH-groups in the exponential growth phase were always lower than in the wild-type and wc-1 strains. The role of wc-1 and wc-2 genes in the level regulation of reactive oxygen species is discussed.     

Enzyme Profiles in Seedling Development and the Effect of Itaconate, an Isocitrate Lyase-directed Reagent

Changes in levels of isocitrate lyase, malate synthase, and catalase have been investigated during germination of flax (Linum usitatissimum L.) in the presence and absence of itaconate. Germination was accompanied by a rapid increase in these enzymes during the first 3 days. The presence of 38 millimolar itaconate inhibited the incidence of seed germination and the growth of embryo axes as well as the appearance of isocitrate lyase but did not alter the levels of malate synthase, catalase, or NADP⁺-isocitrate dehydrogenase. The specific activity for the latter enzyme was constant throughout germination. Oxalate or succinate, each at 38 millimolar, had no effect upon germination of flax seeds. Itaconate did not inhibit the activities of malate synthase, catalase, or NADP⁺-isocitrate dehydrogenase in vitro but was a potent noncompetitive inhibitor of isocitrate lyase (K_i:17 micromolar at 30 C, pH 7.6). Itaconate (at 38 millimolar) did not alter the appearance of malate synthase but reduced the incidence of germination, onset of germination, and growth of the embryo axis as well as the specific activity of isocitrate lyase in seedlings of Zea mays, Vigna glabra, Glycine hispida, Vigna sinensis, Trigonella foenumgraecum, Lens culinaris, and Medicago sativa. The incidence and onset of germination of wheat seeds were unaltered by the same concentration of itaconate but seedlings did not contain isocitrate lyase or malate synthase. The data suggest that itaconate may be isocitrate lyase-directed in inhibiting the germination of fatty seeds.     

Catalase Synthesis and Turnover during Peroxisome Transition in the Cotyledons of Helianthus annuus L

Based on measurements of total catalase hematin and the degradation constants of catalase hematin, zero order rate constants for the synthesis of catalase were determined during the development of sunflower cotyledons (Helianthus annuus L.). Catalase synthesis reached a sharp maximum of about 400 picomoles hematin per day per cotyledon at day 1.5 during the elaboration of glyoxysomes in the dark. During the transition of glyoxysomes to leaf peroxisomes (greening cotyledons, day 2.5 to 5) catalase synthesis was constant at a level of about 30 to 40 picomoles hematin per day per cotyledon. In the cotyledons of seedlings kept in the dark (day 2.5 to 5) catalase synthesis did not exceed 10 picomoles hematin per day per cotyledon. During the peroxisome transition in the light, total catalase hematin was maintained at a high level, whereas total catalase activity rapidly decreased. In continuous darkness, total catalase hematin decreased considerably from a peak at day 2. The results show that both catalase synthesis and catalase degradation are regulated by light. The turnover characteristics of catalase are in accordance with the concept that glyoxysomes are transformed to leaf peroxisomes as described by the one population model and contradict the two population model and the enzyme synthesis changeover model which both postulate de novo formation of the leaf peroxisome population and degradation of the glyoxysome population.     

The action of ultraviolet radiation on yeast catalase

The effect of prolonged UV irradiation (mostly 2537 A) on the catalase activity of an aqueous yeast suspension was divisible into 4 periods. First, the period during which the cells lost their ability to form colonies, but during which no change in catalase activity was noted. Second, the period during which a considerable rise in catalase activity (Euler effect) occurred. The Euler effect was accompanied by enzyme alteration as shown by the simultaneous decrease in the activation energy of the enzyme-substrate system. However, during the initial phase of this period, as the catalase activity of the suspension began to increase, the activation energy rose to a transient level higher even than that characterizing the unaltered enzyme. Heat accelerated the rate of alteration when applied either during or after the irradiation; the activation energy for the over-all alteration reaction was 24 kcal., a value close to that recorded previously for alteration induced by chemical agents. Nevertheless, the rate-limiting step appeared to be different in the two cases. A model of these events was presented in which the primary photochemical action was on the site at which catalase is located within the cell. Third, a rather long period during which irradiation led to no diminution in the catalase activity of the maximally active suspension. This protection effect was duplicated in intro by a model crystalline catalase-KNA system, or by adding either ribonuclease digestion products of RNA or adenine to a catalase solution prior to irradiation. Evidence was adduced that the protection effect was not a simple screening, but involved some sort of interaction between the enzyme and the nitrogenous components of RNA, an interaction which must likewise occur within the cell. Alteration induced by CHCl₃ did not eliminate the protection effect, but that by butanol did. The onset of photoinactivation was due to modification of protein structure, not of RNA. Fourth, the period of photoinactivation of the intracellular enzyme, which was quite similar to that of the crystalline enzyme in vitro.     

Changes in the content of cyclic AMP and cyclic GMP during the development of Xenopus laevis.

The levels of the three major DNA-dependent RNA polymerases (enzymes I, II and III) present in the dimorphic fungus Mucor rouxii have been investigated during the transition from yeast-like cells to mycelial growth. Increases in the specific activity of crude extracts were observed at 2 h and at 6 h after induction of mycelium formation by aeration of yeast-like cells. These increases could be attributed to changes in the specific activities of enzymes I and II. Alterations were also found in the relative amounts of enzymes I and II: prior to aeration, 31% of the total polymerase activity of crude extracts was present as enzyme I; after 2 h of aeration, the specific activity of this enzyme doubled and the relative amount increased to 64% of the total activity. After 6 h of aeration, the relative amounts of enzymes I and II were 25 and 65%, respectively, and the specific activity of enzyme II had nearly doubled. The amounts and specific activities of enzyme III did not change significantly during the transition.     

Apparent Catalase Synthesis in Sunflower Cotyledons during the Change in Microbody Function: A Mathematical Approach for the Quantitative Evaluation of Density-labeling Data

Density-labeling with 10 mm K¹⁵NO₃/70% ²H₂O has been used to investigate catalase synthesis in different developmental stages of sunflower (Helianthus annuus L.) cotyledons. A mathematical approach is introduced for the quantitative evaluation of the density-labeling data. The method allows, in the presence of preexisting enzyme activity, calculation of this synthesized activity (apparent enzyme synthesis) which results from the balance between actual enzyme synthesis and the degradation of newly synthesized enzyme at a given time. During greening of the cotyledons, when the catalase activity declines and the population of leaf peroxisomes is formed, the apparent catalase synthesis is lower than, or at best equal to, that occurring during a developmental stage when the leaf peroxisome population is established and catalase synthesis and degradation of total catalase are in equilibrium. This result suggests a formation, in fatty cotyledons, of the leaf peroxisomes by transformation of the glyoxysomes rather than by de novo synthesis.     

Regulation of catalase synthesis in Proteus mirabilis]

During the log-phase growth of Proteus mirabilis the specific activity of catalase decreases, while at the beginning of or during the stationary phase an increase takes place which is abolished by inhibitors of nucleic acid or protein synthesis. Glucose in the culture medium has no appreciable effect on the level of enzyme synthesis nor does the passage of bacteria to anaerobiosis bring any noticeable change. Successive additions of hydrogen peroxide up to weak final concentrations (0.2--0.5 mM) stimulate catalase synthesis. Determination of the enzyme in vivo reveals but a weak proportion of the total catalase which can only be titrated after the breakdown of cells. The titrable enzyme in vivo represents, as an order of magnitude, the activity found associated with the cell wall, in an easily released form after the mechanical separation of the inner and outer membranes. Thus, bacteria can act upon exogenous peroxide only through a peripheral catalase while they possess in a masked form an important reserve of cytoplasmic enzyme.     

Acid phosphatase activity of normal and tumor tissue of tobacco grown in vitro and in vivo

Tissue cultures of Nicotiana labacum consisting of green, albino and habituated (normal origin) and teratoma (tomorous origin) were grown under asceptic conditions for 6 to 8 weeks and their extracts were analyzed for phosphatase activity. Comparative enzyme analyses were also made on crude stem extracts of greenhouse-grown normal and tumor tissues of Nicotiana tabacum (var. Wisconsin) and a hybrid (N. glauca × N. langsdorffii).

All the crude extracts showed acid phosphatase activity with a pH optimum at 5.8 to 6.0. The total protein content and enzyme acivity of teratoma tissue (tumor) was higher than that of green, albino or habituated tissue (normal). Similar increased levels were seen in tumor tissue grown in greenhouse in comparison with greenhouse-grown normal tissues. The crude extracts of each of the tissues did not exhibit any qualitative difference in specificity with the 5 different substrates tested; however, differences in the level of activity was observed.

The effect of 4 different culture media was tested on the growth, protein content and acid phosphatase activity of habituated tobacco in tissue culture. Tissues growing in medium containing high salt concentrations showed higher activities than tissues grown in a basal control medium. From the results, it is suggested that although many factors like auxin and other growth factors can influence growth of habituated tobacco tissue, they need not necessarily affect this specific enzyme activity.

     

Effects of Orthophosphate and Adenosine 5'-Phosphate on Threonine Synthase and Cystathionine gamma-Synthate of Lemna paucicostata Hegelm. 6746

Inorganic phosphate (Pi) inhibits threonine synthase of Lemna, and cystathionine γ-synthase less strongly. AMP is an extremely potent and structurally specific inhibitor of threonine synthase. Each inhibition progressively decreases with increasing concentrations of O-phosphohomoserine (OPH). To study the in vivo effects of these inhibitions, Lemna was grown with a range of Pi concentrations. A 25,000-fold increase in Pi concentration in the culture medium caused an increase of only 6-fold in total phosphorus of the plants. This is explained by the fact that a high affinity Pi uptake system is selectively down-regulated during growth with high concentrations of Pi. Pi and AMP in plants grown with various Pi concentrations were determined, and concentrations estimated for chloroplasts, the organelle containing threonine synthase and cystathionine γ-synthase. Calculations indicated that for growth at standard external Pi (0.4 millimolar) or above, if total OPH were uniformly distributed within the plants, activities of the two enzymes in question would be severely inhibited, and each would fall two orders of magnitude below the amount required to provide threonine (plus isoleucine) or methionine adequate for growth. If OPH were restricted to chloroplasts, these inhibitions would be much less severe, resulting in enzyme activities approaching the required physiological amounts. Evidence is presented that even up to 50 millimolar external Pi, this ion does not limit production of threonine or methionine sufficiently to retard growth, consistent with the postulated localization of OPH within chloroplasts.     

Endophytic bacteria isolated from wild jojoba [<Emphasis Type="Italic">Simmondsia chinensis</Emphasis> L. (Schneider)] roots improve in vitro propagation

Endophytic bacteria promote plant growth, reduce stress caused by biotic and abiotic factors, and can trigger active defense reactions in plants. This study aimed to evaluate enzyme activity of in vitro jojoba (Simmondsia chinensis) plants inoculated with endophytic bacteria. In vitro shoots of female and male plants were inoculated with strains of Azospirillum brasilense (Cd), Methylobacterium aminovorans (JRR11), Rhodococcus pyridinivorans (JRR22) or co-inoculated with a mixture of JRR11?+?JRR22. A total of 10 treatments were performed to evaluate shoot and root length; changes in key enzymes involved in plant defense (superoxide dismutase, catalase, peroxidase, ascorbate peroxidase and phenylalanine ammonia lyase) after post-inoculation (45 days). All endophytic bacteria strains used promoted plant growth and rhizogenesis. Differences were found in enzyme activity between female and male plants. The plants inoculated with JRR22 strain, showed the highest enzyme activity suggesting an induced systemic response and a potential increase in plant resistance to pathogen attack.     

Diurnal changes in photosynthesis and antioxidants of Angelica sinensis as influenced by cropping systems

Diurnal dynamics of photosynthetic character of Angelica sinensis, as well as effect of continuous cropping on leaf photosynthetic character, antioxidant enzyme activity and growth of A. sinensis were investigated under field condition. The results showed that the diurnal net photosynthetic rate of A. sinensis in sunny day exhibited a double-peak pattern, and the peaks occurred at 9:45 and 16:45 h, respectively. There was a significant midday depression with A. sinensis, which was caused principally by stomatal factors such as stomatal conductance. The results also showed that net photosynthetic rate (P _N), transpiration rate (E), stomatal conductance (g _s), intercellular CO₂ concentration (C _i), and chlorophyll content (Chl) of A. sinensis plants under continuous cropping were significantly lower than those of the control. The activity of total superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT), and growth parameters of A. sinensis plants were significantly decreased under continuous cropping condition. This study provides evidence of continuous cropping obstacle effect on photosynthesis, antioxidant enzyme activity, and growth parameters of A. sinensis in a field experiment, which partly explained the yield reduction of A. sinensis in the field, when it was cultivated continuously on the same soil.