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)     

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.     

Regulation of Glyoxysomal Enzyme Expression in Maize

The activity levels of three glyoxysomal enzymes (catalase, isocitric lyase, and malate synthase) were measured in the scutellum following germination of the inbred lines W64A, R6-67, and A16. In W64A, as in most maize lines examined, germination was accompanied by a rapid and synchronous increase in the activities of all three enzymes, and reached a peak at about day 4 and declined thereafter. In R6-67, catalase activity continues to increase past day 4 and reaches its highest activity level on later days. In A16, catalase activity is very low due to the lack of expression of the Cat2 gene. Despite these significant differences in catalase expression, the levels of the other two glyoxysomal enzymes did not differ in these inbred lines. Artificial inhibition of catalase in W64A by exogenous application of 10^–4 M aminotriazole did not inhibit germination, nor did it alter the levels of the other two glyoxysomal enzymes. Similarly, application of 10^–4 M itaconate to W64A seeds inhibited the appearance of isocitric lyase, but did not inhibit germination or alter the levels of malate synthase or catalase. Comparative cell fractionation and immunological studies were conducted with W64A and A16 and their microbodies were observed under the electron microscope. Cell fractionation studies were also conducted with W64A seeds germinated in the presence of aminotriazole or itaconate. Thus, our results suggest that the expression of these three glyoxysomal enzymes is not regulated coordinately in the maize scutellum.     

Evidence for processing of maize catalase 2 and purification of its messenger RNA aided by translation of antibody-bound polysomes

Two-dimensional gel analysis of the in vitro and in vivo labeled catalase 2 (CAT-2) isozyme protein of Zea mays L. and western gel analysis of native CAT-2 and in vitro labeled CAT-2 indicated that the protein is processed from a precursor to a lower molecular weight form in the scutellum. The CAT-2 from each source appeared on two-dimensional gels as one major species and two to three subspecies of the same molecular weight. We have also purified the mRNA encoding CAT-2 from scutella of line R6-67 using the procedure of polysome immunoadsorption. As a midcourse check on the progress of purification, we translated a small portion of the purified Cat2 mRNA-containing polysomes while they were still complexed with CAT-2 antibodies and bound to protein A-Sepharose. This revealed the presence of highly purified Cat2 polysomes. The final mRNA could not be translated in the wheat germ system but was highly active in the reticulocyte lysate system. The translation product had a molecular weight of 56 000, compared to that of 54 000 for purified CAT-2 protein. We have also enriched for Cat2 mRNA by size selection on methylmercury-agarose gels. The Cat2 resided with and slightly above the 18S ribosomal contaminant band of the total poly(A+) mRNA. It is therefore about 1805 bases long, which is 224 bases longer than the calculated coding length of 1581 bases.     

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.     

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     

Nitrate reductase activity and uptake of nitrate and oxygen as affected by nitrate supply to detached maize organs

Supply of 1, 2, 5, 10 or 20 mM nitrate to detached roots, scutella or shoots from 5- to 6-d-old Zea mays L. seedlings increased in vitro nitrate reductase (NR) activity in all the organs and NADPH specific NR (NADPH:NR) activity in roots and scutella but not in the shoots. Usually 2 to 5 mM nitrate supported maximum enzyme activity, the higher concentration did not increase it further. The protein content in the roots, scutella and shoots increased up to 5, 2 and 20 mM medium nitrate, respectively. Nitrate uptake also increased with increasing nitrate concentration in roots and shoots, but it increased only slightly in the scutella. In both roots and scutella, methionine sulfoximine had no effect, while cycloheximide and tungstate abolished nitrate induced NADH:NR activity completely and NADPH:NR partially. Methionine sulfoximine increased nitrate uptake by roots and scutella slightly, but other inhibitors had no effect. The depletion of dissolved oxygen from the medium was lower in the presence of nitrate than in its absence or in the presence of ammonium, especially in the scutella. This revised version was published online in July 2006 with corrections to the Cover Date.     

Non-Coordinate Genetic Alterations in the Expression of Catalase and other Glyoxysomal Enzymes during Maize Development

In the scutellum of maize during post-germinative development,the primary form of catalase expressed is the product of theCat2 structural gene, CAT-2. The developmental time-course ofCAT-2 protein follows a rapid increase with a peak at approximately4–5 d alter germination and a subsequent decline. An inbredstrain of maize, A337, has been found to exhibit a similar generalizedprofile with the significant exception that the level of CAT-2protein present in the scutellum is far above that in the ‘typical’maize lines exemplified by W64A. Our data suggest that the higherlevels of CAT-2 exhibited in A337 are due to increased synthesisand accumulation of more CAT-2 protein, and not merely to enzymeactivation. A comparison of A337 and W64A showed that the twolines are similar with respect to number of glyoxysomes andwith the exception of catalase, other microbody associated enzymesexhibit similar activity levels and developmental profiles.Thus, the results presented suggest that the catalasc developmentalprogramme characteristic of line A337 is not due to a concurrentincrease and subsequent decline in the number of glyoxysomesformed in the scutellum during this developmental period butis instead due to a greater level of CAT-2 protein. The datafurther support our earlier findings that the genes coding forglyoxysomal enzymes in maize are non-coordinately regulated. Key words: Gene regulation, glyoxysomes, catalase, glyoxysomal enzymes     

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.     

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.     

Purification and characterization of an isozyme of catalase with enhanced-peroxidatic activity from leaves of Nicotiana sylvestris

Two isozymes of catalase (EC 1.11.1.6), one with typically low peroxidatic activity (CAT-1) and the other with enhanced-peroxidatic activity (EP-CAT or CAT-3) have been purified to electrophoretic homogeneity from tobacco (Nicotiana sylvestris) seedlings and antibodies prepared against each. The isozyme proteins showed no immunological cross-reactivity. The subunit Mr was 55,300 +/- 750 for CAT-1 and 53,300 +/- 850 for CAT-3 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In the catalatic reaction, the apparent Km values for CAT-1 and CAT-3 were 0.057 and 0.054 M, respectively, and the kcat values were 4.8 x 10(7) and 3.0 x 10(6) min-1, respectively. In the peroxidatic reaction, both have similar apparent Km's for H2O2. The apparent Km values for CAT-3 for the series methyl, ethyl, propyl, butyl, and allyl alcohols were 2.48, 5.6, 38.6, 429, and 16.3 mM, respectively. For CAT-1, the values were 697, 55.8, no detectable reaction with propyl and butyl, and 163 mM, respectively. Neither isozyme utilized dianisidine or guaiacol in the peroxidatic reaction. Catalase activity (CAT-2) which eluted in an intermediate position between CAT-1 and CAT-3 from a chromatofocusing column was composed of only one subunit whose Mr coincided with CAT-1, and only the antibody to CAT-1 reacted with CAT-2 protein. Thus, CAT-2 and CAT-1 appear closely related while CAT-3 is distinctly different.     

热激对水稻幼苗耐冷性及热激蛋白合成的诱导

萌发的水稻种子经42℃热激处理后其幼苗的耐冷性明显增强,膜伤害程度降低,脯氨酸含量增加,超氧物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)活性和抗氧化物质抗坏血酸含量增加,而膜脂过氧化的关键酶脂氧合酶(LOX)活性及其产物丙二醛(MDA)含量下降.并且热激诱导萌发的水稻胚合成78、70、64、60、46、38、24、17、16kD的热激蛋白(HSP),其中属于HSP70的内质网结合蛋白(BiP)的合成与水稻幼苗耐寒性的提高有关.     

Heat treatment results in a loss of transgene-encoded activities in several tobacco lines.

Heat treatment (37 degrees C) of transgenic tobacco (Nicotiana tabacum) plants led to a reversible reduction or complete loss of transgene-encoded activities in about 40% of 10 independent transformants carrying the luciferase-coding region fused to the 355 cauliflower mosaic virus or the soybean small subunit promoter and the nopaline synthase promoter driving the neomycin phosphotransferase gene, whereas the other lines had temperature-tolerant activities. Temperature sensitivity or tolerance of transgene-encoded activities was heritable. In some of the lines, temperature sensitivity of the transgene-encoded activities depended on the stage of development, occurring in either seedlings (40% luciferase and 50% neomycin phosphotransferase) or adult plants (both 40%). The phenomenon did not correlate with copy numbers or the homo- or hemizygous state of the transgenes. In lines harboring a temperature-sensitive luciferase activity, reduction of bioluminescence was observed after 2 to 3 h at 37 degrees C. Activity was regained after 2 h of subsequent cultivation at 25 degrees C. Irrespective of the reaction to the heat treatment, the level of luciferase RNA was slightly increased at 37 degrees C. Only in lines showing temperature sensitivity of transgene-encoded activities was the amount of luciferase and neomycin phosphotransferase strongly reduced. In sterile culture, heat treatment for 15 d did not cause visible damage or changes in plant morphology. In all plants tested a slight induction of the heat-shock response was observed at 37 degrees C.     

Effects of temperature and salinity on nitrogenous excretion by Litopenaeus vannamei juveniles

Excretion rates of ammonia-N, nitrite-N, nitrate-N, and dissolved organic nitrogen (DON) for juvenile Litopenaeus vannamei (3.85+/-0.83 g) were quantified in response to nine different combinations of temperature (24, 28, and 32 degrees C) and salinity (10, 25, and 40 ppt) under laboratory conditions. Results indicated that L. vannamei is ammonotelic, with ammonia-N accounting for 61.9-84.3% of total nitrogen (TN) excretion. There were significant effects of temperature and salinity, but no significant interaction between them, on ammonia-N excretion rate (R(AN)). R(AN) increased with increasing temperature, over the interval 24-32 degrees C. R(AN) was lower at 25 ppt than at 10 and 40 ppt, at all temperatures. DON excretion rate (R(DON)) was not significantly influenced by either temperature or salinity; the overall mean R(DON) was about 5.24 μg-N g -1 h -1. However, the percentages of DON in TN (P(DON)) varied from 15.4 to 36.4% under the various temperature-salinity combinations. P(DON) at 28 and 32 degrees C was significantly lower than at 24 degrees C, and P(DON) at 10 ppt was significantly lower than at 25 and 40 ppt. Only very small amounts of nitrogen were excreted by L. vannamei as nitrite-N and nitrate-N.