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.     

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.     

Genetic and biochemical characterization of a Cat2 catalase null mutant of zea mays

Summary In all maize inbred lines examined to date, the Cat2 gene which codes for the CAT-2 catalase is expressed primarily in the scutellum upon seed imbibition. The activity of CAT-2 increases dramatically during the initial four days after germination and subsequently declines. In contrast, we have recently identified and inbred strain (A16) of maize which does not express the Cat2 gene (i.e., the CAT-2 catalase is undetectable). Electrophoretic and immunological analyses indicate that the CAT-2 protein is not present in either an active or inactive form in line A16. Genetic analysis suggests that the absence of CAT-2 expression in line A16 is due to a null allele at the Cat2 gene locus although the possibility of a mutation at a regulatory locus, closely linked to the structural gene has not been excluded. Two other enzymes involved in H₂O₂ metabolism (superoxide dismutase and peroxidase) were also compared in W64A and A16 with no significant differences being observed. Aminotriazole (AT), a known inhibitor of catalase, has been used to simulate the A16 phenomenon by inhibiting catalase activity in line W64A (which has normal expression of CAT-2). AT, in very low concentrations, effectively inhibits the expression of CAT-2 in the scutellum. This inhibition of catalase by AT does not result in changes of the developmental time-course of superoxide dismutase and peroxidase.Research supported by National Institutes of Health Grant No. GM 22733-05 to J.G.S.Paper No. 6601 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC     

Cat3, a third gene locus coding for a tissue-specific catalase in maize: Genetics, intracellular location, and some biochemical properties

Summary A new and unique catalase isozyme, CAT-3, has been found in Zea mays. It is encoded in the Cat3 nuclear structural gene which is distinct from the two previously described catalase structural genes, Cat1 and Cat2. The Cat3 gene is both tissue- and time-dependent in its expression, being expressed primarily in young leaves and in the pericarp of nearly mature kernels. Cell fractionation experiments, utilizing epicotyl (coleoptile+primary leaf) and mesocotyl cells, suggest that CAT-3 is associated with the mitochrondria where it may play a role in the alternate oxidase pathway. CAT-3 was purified and characterized with respect to some of its biochemical properties. While CAT-3 differs in some of its properties from CAT-1 and CAT-2, it is similar to these and to other catalases in most respects.Research supported by National Institutes of Health Grant No. GM 22733 to JGS.Paper No. 5255 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC.     

Separate molecular mechanisms regulate CAT2 gene expression before and after glyoxysome maturation in two genetic lines of maize

The temporal expression pattern of the CAT-2 catalase isozyme in scutella of Zea mays seedlings normally coincides with that of other major glyoxysomal enzymes. In standard genetic lines (e.g., W64A), the CAT-2 enzyme is synthesized de novo after imbibition, reaches a peak at approximately 4 days later, and then declines steadily. In a high CAT-2 genetic line, R6-67, the enzyme accumulates in a linear fashion for at least 8 days after imbibition and reaches a level 3-fold higher than in W64A. During the first 9 days of early seedling growth in W64A, the correlation between Cat2 mRNA levels and CAT-2 protein suggests that pretranslational control governs Cat2 gene expression. In R6-67, the steady rise in CAT-2 protein appears to result from a pretranslational control mechanism in which Cat2 mRNA apparently never declines to levels which would limit the rate of accumulation of CAT-2 protein. In addition, the amount of Cat2 mRNA bound to polysomes is 3-fold higher in R6-67 at day 9, relative to W64A at day 9, reflecting a much greater capacity to synthesize CAT-2 later in development. Despite substantial differences in Cat2 mRNA levels between genetic lines, early CAT-2 protein accumulation is similar until day 5, when other glyoxysomal enzymes also attain maximal activity levels. The early increase in CAT-2, between day 2 and day 5 post-imbibition, occurs despite a sharp decline in polysomal Cat2 mRNA. This is related to a transient decline in total extractable polysomes which paradoxically coincides with the peak in glyoxysomal enzyme activities.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning,characterization and expression analysis of two catalase isozyme genes in barley

Clones representing two distinct barley catalase genes, Cat1 and Cat2, were found in a cDNA library prepared from seedling polysomal mRNA. Both clones were sequenced, and their deduced amino acid sequences were found to have high homology with maize and rice catalase genes. Cat1 had a 91% deduced amino acid sequence identity to CAT-1 of maize and 92% to CAT B of rice. Cat2 had 72 and 79% amino acid sequence identities to maize CAT-2 and-3 and 89% to CAT A of rice. Barley, maize or rice isozymes could be divided into two distinct groups by amino acid homologies, with one group homologous to the mitochondria-associated CAT-3 of maize and the other homologous to the maize peroxisomal/glyoxysomal CAT-1. Both barley CATs contained possible peroxisomal targeting signals, but neither had favorable mitochondrial targeting sequences. Cat1 mRNA occurred in whole endosperms (aleurones plus starchy endosperm), in isolated aleurones and in developing seeds, but Cat2 mRNA was virtually absent. Both mRNAs displayed different developmental expression patterns in scutella of germinating seeds. Cat2 mRNA predominated in etiolated seedling shoots and leaf blades. Barley genomic DNA contained two genes for Cat1 and one gene for Cat2. The Cat2 gene was mapped to the long arm of chromosome 4, 2.9 cM in telomeric orientation from the mlo locus conferring resistance to the powdery mildew fungus (Erysiphe graminis f.sp. hordei).     

Analysis of gene expression in microspores,pollen, and silks of Zea mays L.

Summary During pollen formation within anthers of Zea mays, post-meiotic expression of the cat-3 gene was observed from soon after microspore release from the tetrads until microspore mitosis; from the binucleate stage to maturity the cat-1 gene was expressed instead. Gene expression during pollen function, i.e., germination and tube growth, was determined by means of a new approach based on the in vivo comparative analysis of pollinated and non-pollinated silks. In the early autotrophic stage of germinating pollen ADH-1, CAT-1, and GOT-1 were expressed, whereas during further tube elongation only GOT-1 was detected. Pollination did not give rise to pollen-style hybrid enzymatic molecules nor to the induction of new enzymes on either partner. Silks, even when non-pollinated, showed the expression of additional alcohol dehydrogenase and catalase enzymatic activities, specifically ADH-2 and CAT-3. These data support the view that expression of the catalase system in the male gametophyte is stage specific, and suggest that the style may provide support to the elongating pollen tube at the functional as well as at the nutritional level.     

Regulation of Catalase Activity in Leaves of Nicotiana sylvestris by High CO(2)

The effect of high CO₂ (1% CO₂/21% O₂) on the activity of specific forms of catalase (CAT-1, -2, and -3) (EA Havir, NA McHale [1987] Plant Physiol 84: 450-455) in seedling leaves of tobacco (Nicotiana sylvestris, Nicotlana tabacum) was examined. In high CO₂, total catalase activity decreased by 50% in the first 2 days, followed by a more gradual decline in the next 4 days. The loss of total activity resulted primarily from a decrease in CAT-1 catalase. In contrast, the activity of CAT-3 catalase, a form with enhanced peroxidatic activity, increased 3-fold in high CO₂ relative to air controls after 4 days. Short-term exposure to high CO₂ indicated that the 50% loss of total activity occurs in the first 12 hours. Catalase levels increased to normal within 12 hours after seedlings were returned to air. When seedlings were transferred to air after prolonged exposure to high CO₂ (13 days), the levels of CAT-1 catalase were partially restored while CAT-3 remained at its elevated level. Levels of superoxide dismutase activity and those of several peroxisomal enzymes were not affected by high CO₂. Total catalase levels did not decline when seedlings were exposed to atmospheres of 0.04% CO₂/5% O₂ or 0.04% CO₂/1% O₂, indicating that regulation of catalase in high CO₂ is not related directly to suppression of photorespiration. Antibodies prepared against CAT-1 catalase from N. tabacum reacted strongly against CAT-1 catalase from both N. sylvestris and N. tabacum but not against CAT-3 catalase from either species. This observation, along with the rapid changes in CAT-1 and the much slower changes in CAT-3 suggest that one form is not directly derived from the other.