Organ distribution of auxin-binding protein 1 in the etiolated maize seedling

The auxin-binding protein designated ABP1 has been proposed to mediate auxin-induced cellular changes such as cell expansion. Its exact mode of action is unknown, but currently several approaches to elucidate its function are being pursued. One of these approaches, described here, is to determine the organ distribution of this putative auxin receptor in order to correlate spatially the abundance of the protein with some auxin-regulated activity such as cell elongation. The absolute and relative amounts of ABP1 were determined along the entire etiolated shoot, the root, and within the caryopsis of maize. ABP1 can be detected immunologically in all extracts of the etiolated maize seedling except the tip of the primary root and the endosperm. Within the shoot, but excluding the leaf roll, the highest levels compared on a fresh weight basis are in the apical mesocotyl and basal coleoptile regions, the areas of the most rapid cell elongation and the areas where there is the greatest capacity for auxin-induced growth. The relative abundance of ABP1 compared on a fresh weight basis changed more than fivefold in this organ. When compared on a total protein basis, the relative change in ABP1 abundance was approximately two-fold, which is less than the relative change in auxin-induced growth rate along the shoot. Differences in shoot growth rate among varieties of maize were compared with the relative amounts of ABP1 within the apical mesocotyl and basal coleoptile. A statistically significant but not perfect correlation was found between the auxin-induced growth rate of the apical mesocotyl and ABP1 abundance. These results demonstrate a general correlation between the amount of ABP1 and growth along the shoot and within maize hybrid varieties.Abbreviations ABP1 auxin-binding protein 1 - NAA naphthalene-1-acetic acid - SDS sodium dodecyl sulfate - PAGE poly-acrylamide gel electrophoresis.     

The mitigating role of environmental factors in seedling injury and chill-dependent depression of catalase activity in maize leaves

In pot experiments performed on maize seedlings chilled at 5 °C, leaf injury was diminished by the application of elevated temperature (1 or 5 h at 15 or 20°C, “warm breaks” treatment) in a dose-dependent manner. The lower the injury count, the higher the catalase (CAT) activity. In a separate experiment, the application of 100 % relative humidity also protected the plants from chilling injury and water loss, increased their gas exchange and variable to maximum chlorophyll fluorescence ratio (F_v/F_m), but did not influence CAT activity. Another protective environmental factor, elevated atmospheric CO₂ concentration [700 μmol(CO₂) mol⁻¹(air)] diminished CAT activity inhibition, but only in plants of chilling-resistant cultivar. The positive impact of specific environmental factors accompanying chilling is not obviously related to the suppression of the inhibition of CAT activity, although the enzyme is considered as chilling-sensitive.     

盐胁迫条件下γ-氨基丁酸对玉米幼苗SOD、POD及CAT活性的影响

逆境下植物体内积累氨基丁酸(GABA)。盐胁迫严重影响玉米种子的萌发,而加入外源GABA可明显提高玉米种子的萌发率。外源GABA能迅速提高SOD、POD、和CAT这三种酶的活性。鉴于超氧化物歧化酶、过氧化氢酶和过氧化物酶是植物抗氧化保护系统中重要的组成部分,推测,盐胁迫条件下,GABA可通过提高保护酶系统活性而缓解盐胁迫对植物的伤害。     

Modified protein kinase activity and isozyme distribution in adenocarcinoma of the human colon

Protein kinase activity and histone kinase isozyme distribution have been determined in soluble extracts of adenocarcinoma of the human colon and compared to adjacent normal mucosa. The results show an enhancement in endogenous protein kinase activity and the presence of an additional isozyme (PKI) for histone kinase activity in the tumour tissue. PKI activity exhibited a peculiar behaviour in comparison to the isozyme. PKII present in both carcinoma and normal mucosa after dialysis of the soluble extracts. It is suggested that alteration of intracellular regulatory processes involved in PKI activity might be related to the maintenance of the proliferate state in human colon carcinoma.     

Flavonoid and isoflavonoid distribution in developing soybean seedling tissues and in seed and root exudates

The distribution of flavonoids, isoflavonoids, and their conjugates in developing soybean (Glycine max L.) seedling organs and in root and seed exudates has been examined. Conjugates of the isoflavones daidzein and genistein are major metabolites in all embryonic organs within the dry seed and in seedling roots, hypocotyl, and cotyledon tissues at all times after germination. Primary leaf tissues undergo a programmed shift from isoflavonoid to flavonoid metabolism 3 days after germination and become largely predominated by glycosides of the flavonols kampferol, quercetin, and isorhamnetin by 5 days. Cotyledons contain relatively constant and very high levels of conjugates of both daidzein and genistein. Hypocotyl tissues contain a third unidentified compound, P19.3, also present in multiple conjugated forms. Conjugates of daidzein, genistein, and P19.3 are at their highest levels in the hypocotyl hook and fall off progressively down the hypocotyl. These isoflavones also undergo a programmed and dramatic decrease between 2 and 4 days in the hypocotyl hook. All root sections are predominated by daidzein and its conjugates, particularly in the root tip, where they reach the highest levels in the seedling. Light has a pronounced effect on the distribution of the isoflavones; in the dark, isoflavone levels in the root tips are greatly reduced, while those in the cotyledons are higher. Finally, the conjugates of daidzein and genistein and several unidentified aromatic metabolites are selectively excreted into root and seed exudates. Analysis of seed exudates suggests that this is a continuous, but saturable event.     

Enhanced-peroxidatic activity in specific catalase isozymes of tobacco, barley, and maize

Separation of catalase isozymes from leaf extracts of three diverse plant species (Nicotiana sylvestris, Zea mays, Hordeum vulgare L.) revealed a distinct isozyme with enhanced peroxidatic activity (30-, 70-, 28-fold over typical catalase, respectively) which constituted 10 to 20% of the total catalase activity. In maize this isozyme is the product of the Cat3 gene, which is expressed only in mesophyll cells (AS Tsaftaris, AM Bosabalidis, JG Scandalios [1983] Proc Natl Acad Sci USA 80: 4455-4459). A mutation in barley reducing levels of peroxisomal catalase (AC Kendall et al. [1983] Planta 159: 505-511) does not reduce the amount of the isozyme with enhanced peroxidatic activity. Similarly, this isozyme is unaffected in dark-grown barley in spite of a 75% decrease in total catalase activity. These results suggest that this catalase isozyme is under separate genetic control in barley. This may also be the case in tobacco where the catalase isozyme with enhanced peroxidatic activity is an immunologically distinct protein (EA Havir, NA McHale [1989] Plant Physiol 89: 952-957).     

Elaboration of the method for immunocytochemical studying cytokinin-binding protein CBP70 localization in maize seedling tissues

Some approaches for the elaboration of the method for immunocytochemical detection of labile protein on sections prepared from maize (Zea mays L.) seedling tissues are outlined. The effects of severe chemical reagents applied during tissue pretreatment (fixatives, inhibitors of endogenous enzymes, solutions blocking nonspecific antibody binding) on labile protein immunoreactivity in extracts were assessed in preliminary experiments. The procedure was elaborated with a triple control, which provided for the lowest background staining on plant tissue sections and the high level of antibody specific binding.     

The distribution and characteristics of nitrate reductase and glutamate dehydrogenase in the maize seedling

In a study on 3-day maize (Zea mays) seedlings, grown on nitrate, requirements were established for the maximum extraction and optimum stabilization of nitrate reductase in vitro. With the primary root, 5 mm cysteine were required in the extraction medium, but for the scutellum, which has a high level of endogenous thiol, the use of additional thiol resulted in a reduced yield of a more labile enzyme. Activity of the root and scutella nitrate reductase was obtained with either NADH or NADPH, but that of the root enzyme with NADPH was only demonstrated in the absence of phosphate.Before leaf expansion, the nitrate reductase in the maize seedling was mainly in the scutellum. The enzyme present in the primary root was predominantly in the apical region (0-2 mm). In contrast, glutamate dehydrogenase was concentrated in the mature basal region of the root (30-60 mm). A high level of nitrate (approximately 100 mm) was required to saturate the induction of nitrate reductase in the root tip, mature root, and scutellum. The concentration of nitrate required to give half the maximum level of enzyme induced was the same for each region (29 mm).After leaf expansion, more than 90% of the nitrate reductase was in the shoot, mainly in the leaf blade, and a marked decrease occurred in the level of the enzyme in the scutellum. A large proportion of the glutamate dehydrogenase was still found in the root.     

Characterization and distribution of invertase activity in developing maize (Zea mays) kernels

Invertase ( β -fructofuranoside fructohydrolase, EC 3.2.1.26) activity in developing maize ( Zea mays L. inbred W64A) was separated into soluble and particulate forms. The particulate form was solubilized by treatment with 1 M NaCl or with other salts. However, CaCl₂ inhibited invertase activity, and neither detergents nor 0.5 M methyl mannoside were effective in solubilizing the invertase activity. The soluble and particulate invertases were both glycoproteins, both had pH optima of 5.0 and K_m values for sucrose of 2.83 and 1.84 m M , respectively. The apparent molecular weight of salt-solubilized invertase was 40 kDa. Gel filtration of the soluble invertase showed multiple peaks with apparent molecular weights ranging from 750 kDa to over 9 000 kDa. Histochemical staining of cell wall preparations for invertase activity suggested that the particulate invertase is associated with the cell wall. Also, nearly all the invertase activity was localized in the basal endosperm and pedicel tissues, which are sites of sugar transport. No invertase activity was found in the upper endosperm, the embryo or in the placento-chalazal tissue. In contrast, sucrose synthase (EC 2.4.1.13) activity was found primarily in the embryo and the upper endosperm, which are areas of active biosynthesis of storage compounds.     

小鼠组织中过氧化氢酶的活性与年龄的关系

为观察小鼠组织中过氧化氢酶的活性与年龄的关系,采用高锰酸钾滴定法测定不同年龄(1、4、18月龄)小鼠肝、肾、肺、心、脾、胃、脑组织中过氧化氢酶的活性。结果显示:小鼠过氧化氢酶在不同组织中活性不同,活性高低顺序基本表现为:肝>肾>肺>心、脾、胃>脑;小鼠肺、心、脾、胃、脑各组织中过氧化氢酶的活性在1～4月龄间随年龄增加而增加,在4～18月龄间随年龄增加而降低;小鼠肝、肾组织中过氧化氢酶的活性在1～4月龄间与年龄相关性不显著,在4～18月龄间随年龄增加而降低。结果表明,小鼠肝、肾、肺、心、脾、胃、脑等组织中过氧化氢酶的活性随年龄变化而变化,机体过氧化氢酶活性的降低与机体衰老密切相关。     

Activity and distribution of nitrogen-metabolism enzymes in the developing maize kernel

The activities of glutamine synthetase (EC 6.3.1.2), glutamate dehydrogenase (EC 1.4.1.2), aspartate aminotransferase (EC 2.6.1.1), alanine aminotransferase (EC 2.6.1.2) and soluble protein content in the developing endosperm and embryo of normal (Oh-43) and mutant (Oh-430₂) maize were investigated. Maize inbred lines were grown under field conditions and all plants were self-pollinated. Ears for experiments were harvested over the period of 15 lo 45 days after pollination. After pollination kernel capacity for soluble protein synthesis is located mainly in the endosperm. This progressively decreases and about 40 days after pollination soluble protein synthesis is taken over by the embryo. Comparative data on the activity of the investigated enzymes in the embryo and endosperm indicate that the capacity for synthesis of glutamine and glutamate predominates in the embryo tissue, whereas transamination processes at the initial stages of the embryo development are less intensive than their counterparts in the endosperm. The roles of embryo and endosperm subsequently interchange. Biosynthetic processes of soluble precursors for protein synthesis in the embryo and endosperm of the developing kernel are mutually coordinated.     

Ketose reductase activity in developing maize endosperm

Ketose reductase (NAD-dependent polyol dehydrogenase EC 1.1.1.14) activity, which catalyzes the NADH-dependent reduction of fructose to sorbitol (d-glucitol), was detected in developing maize (Zea mays L.) endosperm, purified 104-fold from this tissue, and partially characterized. Product analysis by high performance liquid chromatography confirmed that the enzyme-catalyzed reaction was freely reversible. In maize endosperm, 15 days after pollination, ketose reductase activity was of the same order of magnitude as sucrose synthase activity, which produces fructose during sucrose degradation. Other enzymes of hexose metabolism detected in maize endosperm were present in activities of only 1 to 3% of the sucrose synthase activity. CaCl₂, MgCl₂, and MnCl₂ stimulated ketose reductase activity 7-, 6-, and 2-fold, respectively, but had little effect on NAD-dependent polyol dehydrogenation (the reverse reaction). The pH optimums for ketose reductase and polyol dehydrogenase reactions were 6.0 and 9.0, respectively. K_m values were 136 millimolar fructose and 8.4 millimolar sorbitol. The molecular mass of ketose reductase was estimated to be 78 kilodaltons by gel filtration. It is postulated that ketose reductase may function to metabolize some of the fructose produced during sucrose degradation in maize endosperm, but the metabolic fate of sorbitol produced by this reaction is not known.     

Lysine-ketoglutarate reductase activity in developing maize endosperm

Lysine-ketoglutarate reductase activity was detected and characterized in the developing endosperm of maize (Zea mays L.). The enzyme showed specificity for its substrates: lysine, α-ketoglutarate, and NADPH. Formation of the reaction product saccharopine was demonstrated. The pH optimum of the enzyme was close to 7, and the K_m for lysine and α-ketoglutarate were 5.2 and 1.8 millimolar, respectively.     

The distribution of the receptor for 1-N-naphthylphthalamic acid in different tissues of maize

Phytotropins with a range of activity, chemistry and stereochemistry were used to detect the presence of the receptor for 1-N-naphthylphthalamic acid (NPA) in leaves, stems, roots and coleoptiles in Zea mays L. cv PX-80 through their ability to bind to the recognition site(s) on the receptor. Their ability to bind to membrane preparations from each of the tissues was found to be very similar. It is concluded that NPA receptors with similar recognition characteristics exist throughout the plant. It is suggested that the data are further evidence in favour of the proposition that NPA receptors are physiologically significant.     

The origin of cornbelt maize: The isozyme evidence

Historical records show t hat the Midwestern dent corns of the United States originated from hybridization of two landraces, Northern Flint and Southern Dent. We examined the origin of Southern and Midwestern Dents by means of isozyme electrophoresis. Isozyme genotypes were determined for 23 loci in 12 plants each of 32 accessions of Southern Dent. Previously published isozyme data for maize landraces of Mexico and North America and for U.S. Midwestern Dents were included for comparative purposes. The data show that Northern Flint and Southern Dent are among the isozymically most divergent maize landraces. Nei’s genetic identities between populations of these two landraces are very low for conspecific populations (ca. 0.80). Southern Dent of the southeastern U.S. appears closely related to similar dent corns of southern Mexico, supporting a previously published hypothesis that U.S. Southern Dent is largely derived from the dent corns of southern Mexico. The Midwestern Dents, which resulted from crosses of Southern Dent and Northern Flint, are much more like Southern Dent than Northern Flint in their isozyme profile. Similarly, public inbreds show greater affinity to Southern Dent with the exception of sweet corn lines, which resemble Northern Flint in their isozyme allele frequencies. North American public inbreds do not contain appreciable isozymic variation beyond that found in Northern Flint and Southern Dent.     

Evaluation of a catalase inhibitor in the developmental regulation of maize catalase

A protein which has been shown to inhibit catalase in vitro appears to vary inversely with catalase activity in the maize scutellum during early sporophytic development when assayed using a catalase inhibition assay. This result suggested that the inhibitor protein may play a direct role in regulating catalase activity during this time period. Four experimental approaches were used to evaluate this putative regulatory role, including immunological quantitation of individual catalase isozymes during germination using rocket immunoelectrophoresis, perturbation of normal catalase expression with hydrogen peroxide or allylisopropylacetamide (AIA), examination of a mutant line with an altered catalase developmental program, and direct radioimmunoassay of the inhibitor protein during germination. The results of these experiments indicate that the quantitative changes in catalase activity during development are not mainly due to changes in the expression of the catalase inhibitor. Other possible roles of this protein in catalase regulation are discussed.     

Tissue zinc distribution in maize seedling roots and its action on growth

Zinc (Zn) distribution over tissues and organs of maize (Zea mays L.) seedlings and its action on root growth, cell division, and cell elongation were studied. Two-day-old seedlings were incubated in the 0.25-strength Hoagland solution containing 2 or 475 μM Zn(NO₃)₂. Zn toxicity was assessed after the inhibition of primary root increment during the first and second days of incubation. The content of Zn was determined by atomic absorption spectrometry in the apical (the first centimeter from the root tip) and basal (the third centimeter from the kernel) root parts. Zn distribution in various tissues was studied by histochemical methods, using a metallochromic indicator zincon and fluorescent indicator Zinpyr-1 and light and confocal scanning fluorescent light microscopy, respectively. To evaluate Zn effects on growth processes, the average length of the meristem; the length of fully elongated cells; the number of meristematic cells in the cortex row; and duration of the cell cycle were measured. When the Zn concentration in the solution was high, the Zn content per weight unit was higher in the basal root part due to its accumulation in lateral root primordial. Zn was also accumulated in both the meristem apoplast and cell protoplasts. In the basal and middle root parts, Zn was detected essentially in all tissues predominantly in the apoplast. Zn inhibited both cell division and elongation. Under Zn influence, the size of the meristem and the number of meristematic cells decreased, which was determined by an increase in the cell cycle duration. The length of the fully elongated cells was also reduced. A comparison of Zn distribution and growth-suppressing activity with other heavy metals studied earlier allows a conclusion that toxic action of heavy metals is mainly determined by physical and chemical properties of their ions and specific patterns of their transport and distribution. As a result, two basic processes determining root growth, e.g., cell division and elongation, could be affected differently.     

Catalase activity in developing seedling of opium poppyPapaver somniferum L

Catalase is an enzyme unique to glyoxysomes in developing poppy seedlings. Catalase activity is very low in endosperm and in embryo of germinating poppy seeds. During postgerminative growth and development the enzyme activity increases rapidly with maximum in endosperm on day 2 and in developing seedling on day 3. A rapid decline of enzyme activity parallells the extension growth of poppy seedlings. Three electrophoretic forms of catalase have been detected in isolated glyoxysomes and partially purified catalase preparation. Electron microscopic observation indicates the presence of catalase in glyoxysomes of parenchyma cells of poppy seedling cotyledons. Numerous lipid bodies and electron-dense deposits in vacuoles are the most characteristic feature of these cells.