Developmental expression of a catalase inhibitor in maize

The expression of an endogenous catalase inhibitor has been studied during development of Zea mays. In the 3-day seedling, the inhibitor is expressed primarily in the scutellum and in the aleurone layer of the endosperm. These tissues also show the highest catalase activity at this stage. Inhibitor expression has also been studied temporally in the scutellum, roots, and shoot over the first 12 days of germination. Inhibitor expression shows an inverse relationship with catalase activity in the scutellum and in the shoot. The relationship is less rigid in the root, due probably to the low levels of inhibitor found in that tissue. The role of the inhibitor in catalase regulation is discussed.     

Biochemical characterization of a catalase inhibitor from maize

Some biochemical properties of the catalase inhibitor purified from maize scutella are described. The inhibitor is heat-labile and its activity is destroyed by trypsin, indicating that it is a protein. It does not appear to be a lectin nor does the inhibition involve proteolysis. The active inhibitor is a dimer with each subunit having a molecular weight of 5600 as determined by sodium dodecyl sulfate electrophoresis. A kinetic analysis performed in the presence of increasing levels of inhibitor gave unusual Lineweaver-Burk patterns. Possible explanations for these patterns are discussed. The inhibitor is active against all catalases tested from a wide variety of organisms.     

Analysis of variants affecting the catalase developmental program in maize scutellum

Summary The catalase of maize scutella is coded for by two loci, Cat1 and Cat2, which are differentially expressed in this tissue during early seedling growth. Two variant lines have been previously identified in which the developmental program for the expression of the Cat2 structural gene in the scutellum has been altered. Line R6–67 exhibits higher than normal levels of CAT-2 catalase in this tissue after four days of postgerminative growth. This phenotype is controlled by a temporal regulatory gene designated Car1. Line A16 exhibits a CAT-2 null phenotype. Further analysis of Car1 verifies the initial indication that it is trans-acting and exhibits strict tissue (scutellum) specificity. A screen of other available inbred lines uncovered eight additional catalase high-activity lines. All eight lines exhibit significantly higher than normal levels of CAT-2 protein. Two of these lines have been shown to be regulated by Car1 as in R6–67. Another line (A338) uncovered during the screen exhibits a null phenotype for CAT-2 protein and resembles A16. Catalase activity levels are low in the scutellum and no CAT-2 CRM (cross-reacting material) is present in the tissues of this line. Also, unlike most maize lines, CAT-2 cannot be induced in the leaf tissue of A338 upon exposure to light. Finally, a single line (A337), demonstrating a novel catalase developmental program, was identified.     

Abscisic Acid and the developmental regulation of embryo storage proteins in maize

The relationship of abscisic acid (ABA) inhibition of precocious germination and ABA-induced storage protein accumulation was examined over the course of embryogenesis in wild-type and viviparous mutants of maize (Zea mays L.). We show that a high level of embryo ABA and the product of the Viviparous-1 gene are both required in early maturation phase for germination suppression and the accumulation of storage globulins encoded by the gene Glb1. Suppressing precocious germination with a high osmoticum is not sufficient to initiate Glb1 protein synthesis, although continued accumulation is contingent upon this inhibition; germination of immature or mature embryos leads to a decline in synthesis and the degradation of stored globulins. Late in embryogenesis, fragments of Glb1 protein accumulate, coinciding with the loss of ABA sensitivity. These results suggest that ABA influences storage globulin accumulation by initiating synthesis, suppressing degradation, and inhibiting precocious germination.     

Modeling the inhibitor activity and relative binding affinities in enzyme-inhibitor-protein systems: application to developmental regulation in a PG-PGIP system

Within a number of classes of hydrolytic enzymes are certain enzymes whose activity is modulated by a specific inhibitor-protein that binds to the enzyme and forms an inactive complex. One unit of a specific inhibitor-protein activity is often defined as the amount necessary to inhibit one unit of its target enzyme by 50 %. No objective quantitative means is available to determine this point of 50 % inhibition in crude systems such as those encountered during purification. Two models were derived: the first model is based on an irreversible binding approximation, and the second, or equilibrium, model is based on reversible binding. The two models were validated using the inhibition data for the polygalacturonase-polygalacturonase-inhibiting protein (PG-PGIP) system. Theory and experimental results indicate that the first model can be used for inhibitor protein activity determination and the second model can be used for inhibitor protein activity determination as well as for comparison of association constants among enzymes and their inhibitor-proteins from multiple sources. The models were used to identify and further clarify the nature of a differential regulation of expression of polygalacturonase-inhibiting protein in developing cantaloupe fruit. These are the first relations that provide for an objective and quantitative determination of inhibitor-protein activity in both pure and crude systems. Application of these models should prove valuable in gaining insights into regulatory mechanisms and enzyme-inhibitor-protein interactions.     

Expression of the developmentally regulated catalase (cat) genes in maize

The catalase (H₂O₂:H₂O₂ oxidoreductase; E.C.1.11.1.6; CAT) gene-enzyme system in Zea mays L (maize) represents an ideal model for studying the molecular basis of developmental gene regulation in higher eukaryotes. This system comprises a family of structural genes that are highly regulated, both temporally and spatially, during maize development. In maize, there are four distinct forms (isozymes) of catalase that are readily discernible by convetional separation procedures. Three of the catalases have been studied in detail from a genetic and biochemical viewpoint. The catalases CAT-1, CAT-2, and CAT-3 are encoded by the distinct, unlinked genes Cat1, Cat2, and Cat3, respectively. Each of the structural genes is highly regulated both spatially and temporally in its expression. Cat1 is expressed primarily in the endosperm, aleurone, pericarp, and scutellum of developing kernels, and in the root, shoot, and scutellum of very young seedlings. Cat2 is expressed primarily in the scutellum and leaf during postgerminative sporophytic development. Cat3 is expressed, for the most part, in the shoot and pericarp of young seedlings. A number of regulatory variants have been recovered that affect the developmental program of expression of the catalases. Analysis of one variant allowed for the identification of a temporal regulatory gene (Car1) that specifically alters the developmental program of the Cat2 structural gene by acting to regulate the rate of CAT-2 protein synthesis. Cat1 has been mapped on chromosome 1S, 37 map units (m.u.) from the Cat2 structural gene. Another variant line has been isolated which lacks expression of the Cat2 gene in its tissues at all stages of development. Isolated polysomes from this line (A16) were translated in vitro, and the products were immunoprecipitated with CAT-2-specific antibodies. No CAT-2 was detectable in the A16 labeled immunoprecipitates, whereas CAT-2 was readily detected in the normal line, W64A, under similar conditions. The temporal and spatial expression of the Cat structural genes is not only influenced by genetic factors (as above), but is also responsive to exogenously applied environmental signals: light, hormones, and temperature. The mechanisms by which such signals specifically affect CAT-2 expression will be discussed.     

Glycosylation of catalase inhibitor necessary for activity

A protein isolated from maize scutella which inhibits catalase in vitro has been shown to contain 12% carbohydrate in the form of galactose. This corresponds to four galactose molecules per inhibitor subunit. Removal of the carbohydrate with β-galactosidase or blockage with a galactose-specific lectin abolished activity of the inhibitor.     

Cytochemical localization of catalase in glyoxysomes isolated from maize scutella

The localization of catalase in isolated maize scutellum glyoxysomes was investigated by means of the diaminobenzidine histochemical reaction. Only the membranes of the glyoxysomes become heavily stained after incubation with diaminobenzidine and H₂O₂. If the glyoxysomes are lysed with Tricine buffer at pH 9, 70% of the catalase is solubilized, while the remaining 30% is tightly bound to an insoluble fraction formed mostly by glyoxysomal membranes. This suggests that catalase may be present also in the matrix of the glyoxysomes. The lack of staining of the matrix with diaminobenzidine is probably due to the high concentration of catalase in the membranes of the organelles.     

Spatial regulation of developmental signaling by a serpin

An extracellular serine protease cascade generates the ligand that activates the Toll signaling pathway to establish dorsoventral polarity in the Drosophila embryo. We show here that this cascade is regulated by a serpin-type serine protease inhibitor, which plays an essential role in confining Toll signaling to the ventral side of the embryo. This role is strikingly analogous to the function of the mammalian serpin antithrombin in localizing the blood-clotting cascade, suggesting that serpin inhibition of protease activity may be a general mechanism for achieving spatial control in diverse biological processes.     

An inhibitor of catalase induced by cold in chilling-sensitive plants

An inhibitor of catalase accumulated when leaves of chilling-sensitive species were stored in the dark at 0°C. The inhibitor could be removed from crude extracts by passing them through a column of Sephadex G-25. After this treatment, the catalase activity of extracts of chilled tissues was found to be equal to that of extracts from unchilled leaves. When chilled tissues were incubated at 20°C, the inhibitor of catalase was lost, unless the tissues had been irreversibly damaged. It specifically inhibited plant catalase, and had no effect on mammalian catalase, plant malic dehydrogenase, or plant superoxide dismutase.

Despite the presence of catalase inhibitor in extracts of chilled plants, no increase in the level of H₂O₂ in chilled tissues was found, suggesting either that the inhibitor is compartmentalized and not in contact with catalase in vivo, or that the level of H₂O₂ is controlled by means other than through catalase activity. Plant tissues normally contain H₂O₂ which is destroyed by catalase when they are damaged. After chilling, H₂O₂ leaking from already injured cells would not be so readily removed by the inhibited catalase, and could contribute to further injury by acting as a source of free radical oxidants.