Effect of stimulating maize germination on cell cycle proteins

The germination process can be accelerated if seeds are stimulated either by adding cytokinins or by osmopriming. Under these conditions, cells in maize ( Zea mays ) embryo axes shorten the time at which the first round of DNA replication and mitosis takes place, thus advancing the cell cycle. Using heterologous antibodies against different cell cycle proteins, we have followed the behaviour of several markers for G1 phase (cyclin D, E2F and p53) and a marker of G2 phase (cyclin B) under either control or "accelerated" germination conditions. The results showed two classes of behaviour: either there was no variation in the amount of the protein present under control or accelerated germination conditions, represented by cyclin Band E2F‐type proteins, or the amount of the proteins was drastically reduced, more rapidly under accelerated germination, as was the case for cyclin D‐ and p53‐type proteins. Although the cyclin D‐type protein was synthesized de novo during germination, the balance was towards degradation so that there was no cyclin D detected 15 h after germination in benzyladenine‐treated and osmoprimed seeds. A Cdk4‐type protein seemed to be present in cyclin D immunoprecipitates and its kinase activity paralleled the fluctuations of the cyclin amount during germination. These data are discussed in the context of early seed germination.     

Influence of phosphorus and formononetin on isozyme expression in the Zea mays‐Glomus intraradices symbiosis

Maize (Zea mays L. cv. Great Lakes 586) plants were either inoculated with the vesicular-arbuscular mycorrhizal (VAM) fungus Glomus intraradices Schenck and Smith, or grown in the presence of the isoflavone formononetin or were provided with both G. intraradices and formononetin. All plants were grown in soil containing one of five levels of inorganic P (between 8 and 110 µg g^?1 soil). By 3 weeks there were significant differences in a number of enzyme activities and in the pattern of isoenzymes in roots colonized by the VAM fungus or treated with formononetin. One NAD-malate dehydrogenase (MDH) isozyme was expressed only in mycorrhizal roots, whether treated or not with formononetin. Despite differences in the soil P level, the expression of this isozyme was not observed in non-mycorrhizal roots, indicating specific expression in the mycorrhizae. We suggest that MDH isozyme could serve as a specific, early indicator of the Zea-Glomus symbiosis. Differences in the esterase (EST) isozyme pattern were not detectable between VAM and non-VAM roots, suggesting that this enzyme system is not a good parameter for the evaluation of mycorrhizal colonization. As available P in the soil increased, total EST activity appeared to increase as well. Interestingly, total peroxidase (POX) activity increased along with P suggesting that as plant P nutrition improved, both cell wall ramification and the quantity of defense peroxidases increased as well. Total POX activity from mycorrhizal roots was inversely correlated with root colonization, indicating that there was suppression of POX activity by the host under low soil P. Most interestingly, formononetin further decreased POX activity regardless of the level of P or mycorrhizal status. This may suggest one mechanism by which formononetin enhances root VAM colonization. The presence of this isoflavone suppressed POX activity in mycorrhizal roots allowing a rapid penetration and spread of the fungus in the root cortex. The interplay between host root, soil P levels, secondary metabolites and endogenous host enzyme activities and a particular VAM fungus has a profound effect on the efficiency, duration and functioning of an endomycorrhizal symbiosis.     

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.     

Dehydrins: Emergence of a biochemical role of a family of plant dehydration proteins

A number of proteins have been identified that typically accumulate in plants in response to any environmental stimulus that has a dehydrative component or is temporally associated with dehydration. This includes drought, low temperature, salinity and seed maturation. Among the induced proteins, dehydrins (late embryogenesis abundant [LEA] D-II family) have been the most commonly observed, yet we still have an incomplete knowledge of their fundamental biochemical role in the cell. Current research trends are changing this situation: immunolocalization and in vitro biochemical analyses are, through analogies to other more fully characterized proteins and molecules, shaping our understanding. In brief, dehydrins may be structure stabilizers with detergent and chaperone-like properties and an array of nuclear and cytoplasmic targets. Recent progress on the mapping of dhn genes and the inheritance of freezing tolerance in barley and other Triticeae species tentatively points to dehydrins as key components of dehydration tolerance.     

Pigments in mesocotyls of corn (Zea mays) and oats (Avena sativa) in darkness, and after irradiation and treatment with 5-aminolevulinic acid

The aim of the study was to clarify the pigment content and light-induced pigment formation in the grass mesocotyl (oats, Avena sativa L. cv. Seger I, and corn, Zea mays L. cv. Seneca). This organ, localized between root and coleoptile, only develops in darkness. To date, there are no data on its pigment content in the literature. The data found indicate a close relationship with conditions in roots, particularly with respect to the importance of yellow pigments as bleaching-preventing agents and response to red and blue light. The mesocotyl contained small amounts of both Pchl_628–632 and Pchl_636–642 with a dominance of the former. Occasionally minute amounts of Pchl_650–652 were present, particularly in corn. The highest pigment concentration was found in the zone around the primordia of the pair of roots, which after several days in darkness protruded from the upper part of the mesocotyl close to the attachment to the coleoptile. Carotenoids were not detectable with absorption spectrophotometry. All pigments present in darkness were rapidly bleached in daylight and in strong red and blue light, and no more were synthesized under continuous irradiation. In continuous weak red and blue light small amounts of chlorophyll were formed at the same time as the protochlorophylls disappeared. Red light seemed to be somewhat more effective than blue, at least in corn. This chlorophyll biosynthesis stopped at very low values. The mesocotyls never became visibly green. Normal chloroplasts with grana did not develop. Mesocotyls, which had been irradiated for a short time, with no additional pigment formed, synthesized small amounts of Pchl when placed in darkness. ALA treatment of dark-grown mesocotyls yielded Pchl_628–632 to a higher degree than did irradiation.     

The influence of chlorsulfuron and metsulfuron methyl on root growth and on the ultrastructure of root tips of germinating maize seeds

Seeds of Zea mays L., germinating in soil, were exposed to very low doses of the sulfonylurea herbicides chlorsulfuron and metsulfuron methyl. At a concentration of 0.012 mg L^–1, chlorsulfuron caused 72% and metsulfuron methyl 55% growth reduction of the young primary roots. Both herbicides also caused obvious injuries to the root tips. Scanning electron microscopic observations of the root tip surfaces indicated an inhibition of slime secretion at a herbicide concentration of 1.5 mg L^–1. Transmission electron microscopy revealed obvious changes to the nuclei and deformation of radial cell walls in the primary root cortex at 0.012 and 1.5 mg L^–1 for both herbicides. Moreover, the secretory cells of the root cap periphery showed partially irregular deposition of premature cell wall or slime material at a concentration of 0.012 mg L^–1 of both herbicides.From the results of our electron microscopic observations we conclude that the primary roots of maize seedlings are seriously affected by extremely low concentrations of even those herbicides which (as chlorsulfuron and metsulfuron methyl) have been developed to inhibit the growth of dicotyledonous weeds. Moreover, we suggest that the frequently observed growth retardation of crop seedlings is a consequence of early root tip injuries caused by herbicide residues in the soil. ei]H Lambers     

Effects of air-filled soil porosity and aeration on the initiation and growth of secondary roots of maize (Zea mays)

We studied the possibility whether the initiation of secondary roots is regulated by the air-filled porosity in soil, i.e. the availability of oxygen in the soil. Maize plants were grown in long PVC tubes (1 m long and 12 cm diameter) and were unwatered for different numbers of days so that variations of soil water content with depth were achieved on the same date with plants at the same age. The plants were harvested when their root systems were established in the whole soil column and watering had been withheld for 0, 15, 20, 25 days. A decrease of soil water content was significantly correlated with an increase of air-filled porosity in soil. The number of secondary lateral roots from segments of primary adventitious roots increased dramatically when soil water content decreased from field capacity to about 0.05 g water g^-1 dried soil. The total dried mass of roots at different soil depths was also positively correlated with soil air-filled porosity. It was observed that the elongation of the initiated secondary roots responded differently to the variations of soil air-filled porosity. The length of secondary roots increased initially when the soil was dried from field capacity to 0.18 g g^-1 dried soil (water potential at about−0.2 MPa, air-filled porosity 0.26 cm³ cm^-3), but was drastically reduced when the soil was dried further. Obviously elongation of secondary roots was inhibited when soil water potential began to deviate substantially from an optimum value. The present results suggested that the initiation of secondary roots was greatly promoted by the increase of air-filled soil porosity, i.e. availability of oxygen. This conclusion was further verified in a separate experiment where solution-cultured maize seedlings were subjected to different aeration treatments. An obvious increase in secondary root initiation was found in plants which were aerated with normal air (21% O₂) than in plants which were either not aerated or aerated with 5% O₂ air. ei]Section editor: B E Clothier     

Effect of nitrate on water transfer across roots of nitrogen pre-starved maize seedlings

The addition of 10 mM KNO₃ to the solution bathing the roots of young nitrogen-starved seedlings of Zea mays L. enhanced root water transfer within 15 h, compared with 10 mM KCl addition. The free exudation flux was 2.2–3.9 times higher in excised KNO₃-treated roots than in KCl-treated ones. Cryo-osmometry data for xylem sap suggested that, compared with chloride, nitrate treatment increased the steady solute flux into the xylem, but did not modify the osmotic concentration of sap. Root growth was not significantly modified by nitrate within 15 h. Root hydraulic conductances were measured by using either hydrostatic-pressure or osmotic-gradient methods. During hydrostatic experiments, the conductance (k_p), which is thought to refer mainly to the apoplasmic pathway, was 1.6 times larger in KNO₃-than in KCl-treated plants. From experiments in which polyethylene glycol (PEG) 8000 was used as external osmolyte, osmotic conductances (k_s) were found to be smaller by 5–20 times than k_p for the two kinds of plants. The KCl-treated roots were characterized by a low k_s which was the same for influx or efflux of water. By contrast, KNO₃-treated roots exhibited two distinct conductances k_s1 and k_s2, indicating that influx of water was easier than efflux when the water flow was driven by the osmotic pressure gradient. Infiltration of roots with KNO₃ solution supported the idea that nitrate might enhance the efficiency of the cell-to-cell pathway. The low k_s value of KCl-treated roots and the existence of two contrasting k_s values (k_s1 and k_s2) for KNO₃-treated roots are discussed in terms of reversible closing of water channels.     

Energetics of photosynthesis in Zea mays. I. Studies of the flash-induced electrochromic shift and fluorescence induction in bundle sheath cells

Bundle sheath strands free of mesophyll contamination were isolated from 3–4-week-old leaves of maize (Zea mays L.). Patterns of electron flow in the preparations were studied in the presence of physiological substrates. Relative electron flow rates were estimated from the flash-induced electrochromic band shift changes (P-518) and cytochrome f turnover. Induction of chlorophyll fluorescence was also measured. Little Photosystem II activity was found to be present, the principal pathway of electron flow being Photosystem I-driven cyclic electron transfer. The latter was activated through reductive poising by NADPH, generated via malate decarboxylation or (less efficiently) from dihydroxyacetone phosphate. The actions of these electron donors and of oxygen, nitrite and methyl viologen as electron acceptors in redox poising the Photosystem I-driven cycle were investigated and are discussed in relation to the regulation of photosynthesis in the bundle sheath.     

Dehydrogenase and urease activities of maize (Zea mays L.) field soils

Summary Dehydrogenase and urease activities, bacterial and fungal populations and physicochemical characteristics of maize (Zea mays L.) field soils have been studied for one crop cycle. A comparison has been made among soils of three different agricultural systemsviz permanent agriculture on plain lands in valleys, recently introduced terrace land agriculture and age old ‘slash and burn’ type of shifting agriculture on slopes. Results demonstrate that the enzyme activities, microbial population as well as most of the physico-chemical characteristics of soils followed the trend permanent agriculture on plain lands>terrace land agriculture>‘slash and burn’ type of shifting agriculture. Moisture and nutrient levels and topography of the lands were found to be major factors responsible for the trend.