Two barley catalase genes respond differentially to light

Cloned catalase probes from barley ( Hordeum vulgare L.) and maize ( Zea mays L.) were used to examine catalase gene expression in greened and etiolated leaves of several barley lines. Etiolated leaves had greater levels of an mRNA detected by barley Cat1 , compared with greened leaves, in all lines. In contrast, a Cat2 -like mRNA (homologous to Cat2 of maize) was induced by light and accumulated to high levels in greened leaves, compared to the negligible levels detected in etiolated leaves. This suggests that barley contains light-inducible and light-repressible catalase genes. In the catalase-deficient barley mutant RPr 79/4, no hybridization signal was detected when RNA from greened or etiolated leaves was probed with maize Cat2 , indicating that this mutant is deficient for the light-induced Cat mRNA. In etiolated seedlings of both RPr 79/4 and its motherline, the level of the Cat1 mRNA increased coordinately with a steady increase in catalase activity. Even though the mutant RPr 79/4 was able to grow to maturity in normal air, it sustained chlorosis and significant head sterility, probably due to the lack of a light-inducible catalase. Although the mutant RPr 79/4 is not completely lacking catalase (EC 1.11.1.6), the loss of the CAT-1 isozyme is evidently harmful. This observation underscores the protective role of catalases in plants.     

Effects of synergistic signaling by phytochrome A and cryptochrome1 on circadian clock-regulated catalase expression.

Persistent oscillation in constant conditions is a defining characteristic of circadian rhythms. However, in plants transferred into extended dark conditions, circadian rhythms in mRNA abundance commonly damp in amplitude over two or three cycles to a steady state level of relatively constant, low mRNA abundance. In Arabidopsis, catalase CAT3 mRNA oscillations damp rapidly in extended dark conditions, but unlike catalase CAT2 and the chlorophyll a/b binding protein gene CAB, in which the circadian oscillations damp to low steady state mRNA abundance, CAT3 mRNA oscillations damp to high steady state levels of mRNA abundance. Mutational disruption of either phytochrome- or cryptochrome-mediated light perception prevents damping of the oscillations in CAT3 mRNA abundance and reveals strong circadian oscillations that persist for multiple cycles in extended dark conditions. Damping of CAT3 mRNA oscillations specifically requires phytochrome A but not phytochrome B and also requires the cryptochrome1 blue light receptor. Therefore, we conclude that synergistic signaling mediated through both phytochrome A and cryptochrome1 is required for damping of circadian CAT3 mRNA oscillations in extended dark conditions.     

Catalase activity and hydrogen peroxide levels are inversely correlated in maize scutella during seed germination

Temporal patterns of hydrogen peroxide (H2O2) levels and total catalase activity are presented for post-imbibition scutella from six maize inbred lines expressing variable catalase activity. In all lines examined, H2O2 levels were highest during the initial days post-imbibition (1-2 dpi) and decreased thereafter, while total catalase activity was lowest during early dpi (1-2 dpi) and reached maximal activity at 4-6 dpi. In three of the six lines tested, a simple inverse correlation between catalase activity and H2O2 level was significant by Spearman's rank (P < 0.01). In addition to the general decline in H2O2 level throughout the dpi period, a reproducible increase in H2O2 level was observed at 4-5 dpi in five of six lines examined. Mutant lines lacking CAT-3 activity demonstrated a temporal shift in the occurrence of this increase. The role of total catalase (and individual isozymes) in controlling H2O2 levels during germination and the role of H2O2 as a potential regulator of catalase expression during germination are discussed.     

Phagocytosis by somatic cells from dry cow secretion

Independently of medium in which the process occurred, serum or PBS, phagocytosis and killing of Staphylococcus aureus by somatic cells from dry cow secretion were significantly higher at the early dry period than at the steady state period. Total bacterial survival was highly correlated with phagocytosis and with intracellular survival. Correlations between phagocytosis and intracellular survival were much lower. Percentage of S. aureus phagocytosed after incubation in bovine blood serum showed highly significant variation among samples of cells isolated from secretion of different cows at the early dry period and significant variation among samples of cells isolated from different cows at the steady state period.     

Strong negative feedback from Erk to Raf confers robustness to MAPK signalling

Protein levels within signal transduction pathways vary strongly from cell to cell. Here, we analysed how signalling pathways can still process information quantitatively despite strong heterogeneity in protein levels. We systematically perturbed the protein levels of Erk, the terminal kinase in the MAPK signalling pathway in a panel of human cell lines. We found that the steady‐state phosphorylation of Erk is very robust against perturbations of Erk protein level. Although a multitude of mechanisms exist that may provide robustness against fluctuating protein levels, we found that one single feedback from Erk to Raf‐1 accounts for the observed robustness. Surprisingly, robustness is provided through a fast post‐translational mechanism although variation of Erk levels occurs on a timescale of days.     

Intracellular redox equilibrium is essential for the constitutive expression of AP-1 dependent genes in resting cells: studies on TGF-β1 regulation

The mechanisms involved in the continuous expression of constitutive genes are unclear. We hypothesize that steady state intracellular reactive oxygen species (ROS), which their levels are tightly maintained, could be regulating the expression of these constitutive genes in resting cells. We analyzed the regulation of an important constitutive gene, TGF-β1, after decreasing intracellular ROS concentration in human mesangial cells. Decreased intracellular hydrogen peroxide by catalase addition reduced TGF-β1 protein, mRNA expression and promoter activity. Furthermore, catalase decreased the basal activity of Activated Protein-1 (AP-1) that regulates TGF-β1 promoter activity. This effect disappeared when AP-1 binding site was removed. Similar results were observed with another protein containing AP-1 binding sites in its promoter, such as eNOS, but it was not the case in other constitutive genes without any AP-1 binding site, as COX1 or PKG1. The pharmacological inhibition of the different ROS synthesis sources by blocking NADPH oxidase, the mitochondrial respiratory chain or xanthine oxidase, or the use of human fibroblasts with genetically deficient mitochondrial activity, induced a similar, significant reduction of steady state ROS concentration as the one observed with catalase. Moreover, there was decreased TGF-β1 expression in all the cases excepting the xanthine oxidase blockade. These findings suggest a novel role for the steady state intracellular ROS concentration, where the compartmentalized, different systems involved in the intracellular ROS production, could be essential for the expression of constitutive AP1-dependent genes, as TGF-β1.     

Mitochondrial or cytosolic catalase reverses the MnSOD-dependent inhibition of proliferation by enhancing respiratory chain activity, net ATP production, and decreasing the steady state levels of H(2)O(2)

Manganese superoxide dismutase (MnSOD) overexpression has been shown to reverse the malignant phenotype in a variety of tumor cell lines. The inhibition of proliferation and reversal of the malignant phenotype has been attributed to an increase in H(2)O(2) production as a result of the dismutation reaction. However, direct evidence in support of this hypothesis has not been forthcoming. To evaluate the contribution of H(2)O(2) in the regulation of cell growth in response to MnSOD overexpression, control and MnSOD-overexpressing HT-1080 fibrosarcoma cells were transfected with constructs that direct catalase to either the mitochondrial or cytosolic compartments. Overexpression of catalase in either compartment reversed the proliferative and clonogenic inhibition associated with MnSOD overexpression, blocked the increase in the steady state levels of H(2)O(2) as measured by flow cytometric analysis of 2', 7'-dichlorofluorescein diacetate, and increased protection from the cytotoxicity of H(2)O(2). In addition, mitochondrial or cytosolic catalase enhances respiration through complex I and II in both control and MnSOD overexpressing cell lines and reverses a MnSOD-dependent decrease in net ATP production. Thus, catalase reverses the proliferative inhibition associated with MnSOD overexpression and may also play an important role in metabolic regulation.     

The enhancement of stability of p53 in MTBP induced p53–MDM2 regulatory network

We have modeled an MTBP-MDM2–p53 regulatory network by integrating p53–MDM2 autoregulatory model (Proctor and Gray, 2008) with the effect of a cellular protein MTBP (MDM2 binding protein) which is allowed to bind with MDM2 (Brady et al., 2005). We study this model to investigate the activation of p53 and MDM2 steady state levels induced by MTBP protein under different stress conditions. Our simulation results in three approaches namely deterministic, Chemical Langevin equation and stochastic simulation of Master equation show a clear transition from damped limit cycle oscillation to fixed point oscillation during a certain time period with constant stress condition in the cell. This transition is the signature of transition of p53 and MDM2 levels from activated state to stabilized steady state levels. We present various phase diagrams to show the transition between unstable and stable states of p53 and MDM2 concentration levels and also their possible relations among critical value of the parameters at which the respective protein level reach stable steady states. In the stochastic approach, the dynamics of the proteins become noise induced process depending on the system size. We found that this noise enhances the stability of the p53 steady state level.     

Developmental and tissue-specific control of catalase expression in Drosophila melanogaster: Correlations with rates of enzyme synthesis and degradation

The ontogenetic and tissue-specific expression of catalase (E.C. 1.11.1.6) has been determined in a wild type strain of Drosophila melanogaster derived from a natural population. Two distinct peaks of activity are observed during development with the first peak occurring in late third instar larvae just prior to puparium formation, and the second and larger of the two peaks occurring during metamorphosis. These peaks of catalase activity are coincident with the two major peaks of ecdysone titer. Of the tissues assayed, larval malpighian tubules, gut, and fat body demonstrated the highest specific activities. Adult abdomen exhibited a two- to three-fold higher specific activity than either head or thorax. Of the abdominal tissues assayed, malpighian tubules and abdominal wall had the highest specific activities. Malpighian tubules were the only sexually dimorphic tissue with respect to catalase activity and are apparently largely responsible for an overall increase observed in female abdominal activity. Catalase-specific CRM levels parallel the enzyme activity levels indicating that these tissue-specific activity differences reflect differences in the rate of accumulation of catalase molecules. Turnover studies employing the catalase inhibitor 3-amino-1,2,4-triazole were conducted on head, thorax, and abdomen of male adult flies. Rates of catalase degradation were similar in the three body segments with a slightly higher rate in abdominal tissue. Therefore the different steady state levels observed largely reflect different rates of catalase synthesis.     

Catalase activity and hydrogen peroxide levels are inversely correlated in maize scutella during seed germination

Abstract

Temporal patterns of hydrogen peroxide (H₂O₂) levels and total catalase activity are presented for post-imbibition scutella from six maize inbred lines expressing variable catalase activity. In all lines examined, H₂O₂ levels were highest during the initial days post-imbibition (1–2 dpi) and decreased thereafter, while total catalase activity was lowest during early dpi (1–2 dpi) and reached maximal activity at 4–6 dpi. In three of the six lines tested, a simple inverse correlation between catalase activity and H₂O₂ level was significant by Spearman's rank (P <0.01). In addition to the generaldecline in H₂O₂level throughout the dpi period, a reproducible increase in H₂O₂ level was observed at 4–5 dpi in five of six lines examined. Mutant lines lacking CAT-3 activity demonstrated a temporal shift in the occurrence of this increase. The role of total catalase (and individual isozymes) in controlling H₂O₂ levels during germination and the role of H₂O₂ as a potential regulator of catalase expression during germination are discussed.     

Influence of plant development and environment on transgene expression in potato and consequences for insect resistance

Clonal replicates of different transformed potato plants expressing transgene constructs containing the constitutive Cauliflower Mosaic Virus (CaMV) 35S promoter, and sequences encoding the plant defensive proteins snowdrop lectin (Galanthus nivalis agglutinin; GNA), and bean chitinase (BCH) were propagated in tissue culture. Plants were grown to maturity, at first under controlled environmental conditions, and later in the glasshouse. For a given transgene product, protein accumulation was found to vary between the different lines of clonal replicates (where each line was derived from a single primary transformant plant), as expected. However, variability was also found to exist within each line of clonal replicates, comparable to the variation of mean expression levels observed between the different clonal lines. Levels of GNA, accumulated in different parts of a transgenic potato plant, also showed variation but to a lesser extent than plant–plant variation in expression. With the majority of the clonal lines investigated, accumulation of the transgene product was found to increase as the potato plant developed, with maximum levels found in mature plants. The variation in accumulation of GNA among transgenic plants within a line of clonal replicates was exploited to demonstrate that the enhanced resistance towards larvae of the tomato moth, Lacanobia oleracea L., caused by expression of this protein in potato, was directly correlated with the level of GNA present in the plants, and that conditions under which the plants were grown affect the levels of GNA expression and subsequent levels of insect resistance.     

On the synthesis and degradation of the multiple forms of catalase in mouse liver: effects of aminotriazole and p-chlorophenoxyisobutric acid ethyl ester

Aspects of the synthesis and degradation of the multiple forms of catalase in mouse liver have been investigated. The kinetics of return of catalase after aminotriazole inhibition indicated a product-precursor relationship between the granular and supernatant pools of the enzyme, and electrophoretic resolution of the individual heteromorphs of catalase during this treatment served to substantiate this relationship and indicated, in addition, that aminotriazole-inhibited catalase may be partially reactivated in the cytosol. Changes in the activity of mouse liver and kidney catalases after the administration of chlorophenoxyisobutyric acid ethyl ester (CPIB) were also monitored. After an initial decline in activity, a rapid increase to an elevated steady state occurred, with an approximately threefold increase in the liver and twofold increase in the kidney. Subcellular fractionation of the livers of CPIB-treated mice showed a massive initial increase in the supernatant pool of catalase, accompanied by a steady decrease in the activity of the peroxisomal pools. Activity increased in the peroxisomal pools at later stages of treatment, but even after a new CPIB-induced steady state was achieved, the supernatant pool of catalase remained grossly elevated. Electrophoresis of the individual heteromorphs of catalase in the supernatant after CPIB treatment showed a predominance of the most cathodal migrating forms, and turnover studies demonstrated that catalase in CPIB-treated animals exhibited a substantially lowered rate of degradation by comparison with normal animals. These results have been discussed in relation to the intracellular sequestration and turnover characteristics of catalase.     

Naturally occurring genetic variation affecting the expression of sn-glycerol-3-phosphate dehydrogenase in Drosophila melanogaster

Genetic variation among second and third chromosomes from natural populations of Drosophila melanogaster affects the activity level of sn-glycerol-3-phosphate dehydrogenase (EC 1.1.1.8; GPDH) at both the larval and the adult stages. The genetic effects, represented by differences among chromosome substitution lines with coisogenic backgrounds, are very repeatable over time and are generally substantially larger than environmental and measurement error effects. Neither the GPDH allozyme, the geographic origin, nor the karyotype of the chromosome contributes significantly to GPDH activity variation. The strong relationship between GPDH activity level and GPDH-specific CRM level, as well as our failure to find any thermostability variation among the lines, indicates that most, if not all, of the activity variation is due to variation in the steady-state quantity of enzyme rather than in its catalytic properties. The lack of a strong relationship between adult and larval activity levels suggests the importance of stage- or isozyme-specific effects.     

Catalase, glutathione peroxidase, and superoxide dismutase in the rete mirabile and gas gland epithelium of six species of marine fishes

Rete mirabile and gas gland epithelium from the swim bladders of six species of marine fishes were assayed for catalase, glutathione peroxidase, and superoxide dismutase activity. Correlation of the results of these assays with measurements of the concentration of oxygen in the lumen of the normal steady state swim bladders revealed that swim bladders in species containing higher levels of oxygen also exhibited higher levels of superoxide dismutase activity in the rete mirabile/gas gland epithelium region. There appeared to be no correlation between oxygen concentration and the level of catalase or glutathione peroxidase activity. Induction of the inflatory reflex in Opsanus tau by a single deflation of the swim bladder resulted in an increase in the percent of oxygen in the swim bladder lumen 18 to 24 hours later, but this was not accompanied by any significant increases in antioxidant enzyme activity. Swim bladders that were deflated three times at 24-hour intervals showed further increases in oxygen concentration at the end of the 72-hour period but no alteration in superoxide dismutase activity.