钙与植物乙烯反应的关系研究

研究了Ca2+ 对番茄(Lycopersicon esculentum Mill cv. Lichun)黄化幼苗乙烯反应的影响.通过测定不同Ca2+ 浓度条件下番茄黄化幼苗的"三重反应"、内源乙烯释放量、乙烯受体基因NEVER-RIPE(NR)表达量及胞内CaM含量的变化,结果发现,随着培养基中Ca2+ 浓度从0 mmol/L增加到3.8 mmol/L,番茄黄化幼苗的"三重反应"表型明显增强,内源乙烯释放量、NR基因的表达量及胞内CaM的含量都有不同程度的增加;当Ca2+ 浓度由3.8 mmol/L进一步增加到10 mmol/L时,番茄黄化幼苗"三重反应"表型受到抑制,内源乙烯释放量、 NR基因的表达量及胞内CaM的含量都有所下降.因此,Ca2+ 对番茄黄化幼苗"三重反应"的影响与Ca2+ 调节内源乙烯合成和乙烯受体基因的表达有关,而且Ca2+ 可能是通过CaM含量的变化来调节乙烯作用的.     

钙与植物乙烯反应的关系研究

研究了Ca2 对番茄 (LycopersiconesculentumMillcv.Lichun)黄化幼苗乙烯反应的影响。通过测定不同Ca2 浓度条件下番茄黄化幼苗的“三重反应”、内源乙烯释放量、乙烯受体基因NEVER_RIPE(NR)表达量及胞内CaM含量的变化 ,结果发现 ,随着培养基中Ca2 浓度从 0mmol/L增加到 3.8mmol/L ,番茄黄化幼苗的“三重反应”表型明显增强 ,内源乙烯释放量、NR基因的表达量及胞内CaM的含量都有不同程度的增加 ;当Ca2 浓度由 3.8mmol/L进一步增加到 10mmol/L时 ,番茄黄化幼苗“三重反应”表型受到抑制 ,内源乙烯释放量、NR基因的表达量及胞内CaM的含量都有所下降。因此 ,Ca2 对番茄黄化幼苗“三重反应”的影响与Ca2 调节内源乙烯合成和乙烯受体基因的表达有关 ,而且Ca2 可能是通过CaM含量的变化来调节乙烯作用的     

Persistence of plant hormone levels in rice shoots grown under microgravity conditions in space: its relationship to maintenance of shoot growth

We investigated the effects of microgravity environment on growth and plant hormone levels in dark‐grown rice shoots cultivated in artificial 1 g and microgravity conditions on the International Space Station (ISS). Growth of microgravity‐grown shoots was comparable to that of 1 g‐grown shoots. Endogenous levels of indole‐3‐acetic acid (IAA) in shoots remained constant, while those of abscisic acid (ABA), jasmonic acid (JA), cytokinins (CKs) and gibberellins (GAs) decreased during the cultivation period under both conditions. The levels of auxin, ABA, JA, CKs and GAs in rice shoots grown under microgravity conditions were comparable to those under 1 g conditions. These results suggest microgravity environment in space had minimal impact on levels of these plant hormones in rice shoots, which may be the cause of the persistence of normal growth of shoots under microgravity conditions. Concerning ethylene, the expression level of a gene for 1‐aminocyclopropane‐1‐carboxylic acid (ACC) synthase, the key enzyme in ethylene biosynthesis, was reduced under microgravity conditions, suggesting that microgravity may affect the ethylene production. Therefore, ethylene production may be responsive to alterations of the gravitational force.     

Calcium balance changes in tip growing plant cells under clinorotation

Calcium is known to play an important role in the regulation of cellular processes as a secondary messenger in signal transduction to a specific response in all eucaryotic cells. Its messenger role is realized by transient changes in the Ca2+ cytosolic concentration induced by variety of external stimuli such as light, hormones and gravity. Recent findings claim the modifications in a calcium balance in plant cells in microgravity and under clinorotation reproducing partially the microgravity effect. Based on these data, the hypothesis is proposed that Ca2+ level changes can trigger the rearrangements in cell metabolism occurring in the conditions of altered gravity. However, the methods used in previous works permit only to determine the relative quantity of intracellular membrane-bound calcium and to observe the localization of free Ca2+. Therefore, it is of essential interest to measure the concentration of free calcium ions ([Ca2+]i) in plant cells under the influence of altered gravity. In this paper results from measurements of the [Ca2+]i in plant cells under clinorotation will be reviewed and discussed in an effort to examine their effectiveness, causes and consequences.     

Cell structure and mobilization of lipids and proteins from cotyledon under microgravity influence

The structural-functional organization of cotyledon parenchyma cells of 6-day soybean (Glycine max L.) seedlings that were grown on board the space Shuttle Columbia (STS-87) have been studied. The purafil (KMnO4) was used in the experiment for the removing of some part of ethylene that secretes out from seedlings. There were four variants of the experiment: ground control (+purafil), ground control (-purafil), microgravity (+purafil) and microgravity (-purafil). The electron microscopy, srereological, and pyroantimonate cytochemical methods have been used. It is established the some indices of changes of storage substances in cotyledon parenchyma cells under influence of microgravity. It is displayed in the change of cell ultrastructure, the decrease of relative volume of storage cytoplasmic lipid bodies, a disappearance of storage protein body into vacuole and the redistribution of ionized calcium in cell. It was supposed that microgravity is influenced on the acceleration of storage substances catabolism.     

钙在植物乙烯生成及信号传递中的生理作用

Ca2+对植物乙烯生成的调节与作用位点有关,胞外Ca2+在维持质膜功能的同时,抑制乙烯生成,延缓衰老;过量Ca2+进入胞质,胞内Ca2+促进乙烯生成和衰老。内源CaM与乙烯生成关系密切,介入了乙烯代谢和外源激素对乙烯的调控。此外,Ca2+是乙烯信号传递所必需的。     

Mechanotransduction in root gravity sensing cells

The analysis of the dose-response curve of the gravitropic reaction of lentil seedling roots has shown that these organs are more sensitive when they have been grown in microgravity than when they have been grown on a 1 g centrifuge in space before gravistimulation. This difference of gravisensitivity is not due to the volume or the density of starch grains of statoliths, which are about the same in both conditions (1 g or microgravity). However, the distribution of statoliths within the statocyte may be responsible for this differential sensitivity, since the dispersion of these organelles is greater in microgravity than in 1 g. When lentil roots grown in microgravity or in 1 g are stimulated at 0.93 g for 22 min, the amyloplasts sediment following two different trajectories. They move from the proximal half of the statocytes toward the lower longitudinal wall in the microgravity grown sample and from the distal half toward the longitudinal wall in the 1 g grown sample. At the end of the stimulation, they reach a similar position within the statocytes. If the roots of both samples are left in microgravity for 3 h, the amyloplasts move toward the cell centre in a direction that makes an average angle of 40 degrees with respect to the lower longitudinal wall. The actin filaments, which are responsible for this movement, may have an overall orientation of 40 degrees with respect to this wall. Thus, when roots grown in microgravity are stimulated on the minicentrifuge the amyloplasts slide on the actin filaments, whereas they move perpendicular to them in 1 g grown roots. Our results suggest that greater sensitivity of seedling roots grown in microgravity should be due to greater dispersion of statoliths, to better contacts between statoliths and the actin network and to greater number of activated mechanoreceptors. One can hypothesize that stretch activated ion channels (SACs) located in the plasma membrane are responsible for the transduction of gravistimulus. These SACs may be connected together by elements of the cytoskeleton lining the plasma membrane and to the actin filaments. They could be stimulated by the action of statoliths on the actin network and/or on these elements of the cytoskeleton which link the mechanoreceptors (SACs).     

Soaking Summer Squash Seeds in Low Concentrations of Cobalt Solution Before Sowing Increased Plant Growth, Femaleness, and Fruit Yield via Increasing Plant Ethylene Level

Soaking summer squash (Cucurbita pepo cv. Eskandarany) seeds in continuously aerated solutions of 0.25, 0.50, and 1.00 ppm Co²⁺ for 48 h before sowing strongly increased plant growth, femaleness, and fruit yield compared with those of water- (control) or 0.5 mm AOA (aminooxyacetic acid)-soaked seeds. Following the same pattern, plants of Co²⁺-soaked seeds produced significantly higher ethylene levels as early as the seedling stage (14 days after seed sowing) up to the onset of flower initiation (OFI) stage (30 days after seed sowing), with more pronounced levels of all measured parameters for plants of 1.00 ppm Co²⁺-soaked seeds. Plants of AOA-soaked seeds, however, behaved in a pattern similar to those of control in all measured parameters. The only exception was the significant ethylene inhibition noticed only at the plant seedling stage with AOA-seed soaking, which indicated the short term of AOA inhibition to ethylene when applied as early as the seed germination stage. When AOA was applied foliarly before and at the OFI stage, the increased plant femaleness obtained with Co²⁺ seed soaking was arrested. It is indicated, therefore, that summer squash plant femaleness is more responsive to plant ethylene-modulated levels before or at the OFI stage than earlier stages. Furthermore, all seed soaking treatments had no effect on plant leaf number or plant and fruit Co²⁺ content, which strongly indicated that the positive impact of Co²⁺ on summer squash plant growth and femaleness was mainly the result of the so-called ``low Co²⁺ level-induced ethylene.' The percentage of fruit yield increase reached about 26, 40, and 56% over the control by 0.25, 0.50, and 1.00 ppm Co²⁺ seed soaking, respectively, whereas AOA seed soaking resulted in only a 4.5% yield reduction. To ensure the permanent positive impact of Co²⁺ on ethylene production as well as the short period of AOA inhibition, seeds were resoaked in water or AOA for 8 h after being soaked in 1.00 ppm Co²⁺ solution for 40 h. The results obtained emphasized the previous findings because AOA inhibition was restricted on ethylene production only at the seedling stage. Meanwhile, all Co²⁺ positive effects were obtained 2 weeks later, even with AOA seed resoaking. These data strongly suggested that the positive impact of Co²⁺ on ethylene production is more permanent than the negative impact of AOA. Hence its application, in low concentrations, as early as the seed germination stage, strongly increased summer squash plant growth, femaleness, and fruit yield by increasing the plant ethylene level. Received July 21, 1997; accepted November 10, 1997     

Ca2+ and intracellular signalling in plant cells: a role in phytochrome transduction.

The role of Ca2+ as a mediator and its participation in intracellular signaling in relation to phytochrome regulatory action are considered. Using the literature data, the non-random distribution of Ca2+ in the plant cell cytoplasm, the mechanisms of Ca2+ homeostasis and the function of putative messengers of Ca2+ are described. On the basis of the data obtained at the author's laboratory, a dual effect of phytochrome on the cytosolic Ca2+ concentration is demonstrated, i.e. phytochrome controls Ca2+ permeability of plasma membrane and induces transient changes in [Ca2+]cyt. Evidence is presented that the endoplasmic reticulum and vacuole are intracellular Ca2+ stores in the plant cell sensitive to phytochrome regulatory action. It is also demonstrated that phytochrome controls the metabolism of a key phosphoinositide in plant cell membranes. It stimulates the hydrolysis of phosphatidyl 4,5-bisphosphate, a precursor of inositol 1,4,5-trisphosphate, the potent mobilizer of Ca2+ in cytoplasm. Finally, the data on the close interactions between Ca2+ and other secondary messengers in the plant cell cytoplasm are presented. Using the transgenic tobacco expressing an apoprotein of Ca(2+)-sensitive photoprotein aequorin, evidence was obtained that cyclic mononucleotides (cGMP, cAMP) control the Ca2+ concentration in the cytoplasm testifying a crosstalk among Ca2+ and cyclic mononucleotides as messengers.     

Effects of gravitropic stress on the development of the primary root of lentil seedlings grown in space

Root growth and cell differentiation were analysed in lentil seedlings grown (1) in microgravity (F microg), (2) on the 1 x g centrifuge (F1 x g), (3) in microgravity and placed on the 1 x g centrifuge for 4 h [F(microg + 1 x g)], (4) on the 1 x g centrifuge and placed in microgravity for 4 h [F(1 x g + microg)]. In microgravity, there were strong oscillations of the root tip, even when the seedlings were grown first on the 1 x g centrifuge [F(1 x g + microg)]. In the [F(microg + 1 x g)] sample, the roots grown in microgravity were oblique with respect to the 1 x g acceleration when the seedlings were placed on the centrifuge. They were therefore gravistimulated. However, root length was similar in the 4 samples after 29 h of growth and growth rate of the root was the same between 25 h and 29 h although it appeared to be slightly greater in the [F(microg + 1 x g)] sample. Cell elongation was analysed as a function of the distance from the root cap junction. Cell length was similar in the seedlings grown in microgravity or on the 1 x g centrifuge. The transfer from the 1 x g centrifuge to microgravity [F(1 x g + microg)] did not modify cell elongation in the roots. Cell length in the roots which were grown in microgravity and gravistimulated [F(microg + 1 x g)] was different from that observed in microgravity but this was only due to gravistimulation. Thus, gravity does not have an effect on cell elongation when the roots are strictly oriented in the vertical position but it does as soon as the root tip deviates from this orientation.     

Ca2+调节剂在乙烯催花中对观赏凤梨CaM基因表达特性的调节作用

凤梨科植物乙烯催花技术自1930年代开始使用,效果显著。但凤梨科植物乙烯催花的机理尚不明确。鉴于Ca2+-CaM在多种植物开花过程中具有一定的调节作用,为了研究Ca2+-CaM系统在乙烯诱导凤梨科植物开花中的作用,本文以紫花擎天凤梨成株为试材,通过乙烯分别和Ca2+调节剂(Ca2+促进剂,Ca2+螯合剂和抑制剂)的组合处理植株后,利用RT-PCR和Northern技术分析了CaM基因表达特性的变化。结果表明,乙烯处理的同时,加入Ca2+促进剂,使CaM表达量峰值出现的时间由24h提前到了6h;而加入Ca2+螯合剂和抑制剂,使CaM基因表达量峰值出现的时间延迟到了48h以后。该结果与相应的开花时间进程一致,即加入Ca2+促进剂,使花器官出现的时间提前约5d,而加入Ca2+螯合剂和抑制剂,使花器官出现的时间有不同程度的延迟,表明Ca2+调节剂对CaM表达特性的调节作用对乙烯诱导凤梨开花也有一定的影响。     

Modulation of statolith mass and grouping in white clover (Trifolium repens) growth in 1-g, microgravity and on the clinostat

Current models of gravity perception in higher plants focus on the buoyant weight of starch-filled amyloplasts as the initial gravity signal susceptor (statolith). However, no tests have yet determined if statolith mass is regulated to increase or decrease gravity stimulus to the plant. To this end, the root caps of white clover (Trifolium repens) grown in three gravity environments with three different levels of gravity stimulation have been examined: (i) 1-g control with normal static gravistimulation, (ii) on a slow clinostat with constant gravistimulation, and (iii) in the stimulus-free microgravity aboard the Space Shuttle. Seedlings were germinated and grown in the BioServe Fluid Processing Apparatus and root cap structure was examined at both light and electron microscopic levels, including three-dimensional cell reconstruction from serial sections. Quantitative analysis of the electron micrographs demonstrated that the starch content of amyloplasts varied with seedling age but not gravity condition. It was also discovered that, unlike in starch storage amyloplasts, all of the starch granules of statolith amyloplasts were encompassed by a fine filamentous, ribosome-excluding matrix. From light micrographic 3-D cell reconstructions, the absolute volume, number, and positional relationships between amyloplasts showed (i) that individual amyloplast volume increased in microgravity but remained constant in seedlings grown for up to three days on the clinostat, (ii) the number of amyloplasts per cell remained unchanged in microgravity but decreased on the clinostat, and (iii) the three-dimensional positions of amyloplasts were not random. Instead amyloplasts in microgravity were grouped near the cell centers while those from the clinostat appeared more dispersed. Taken together, these observations suggest that changing gravity stimulation can elicit feedback control over statolith mass by changing the size, number, and grouping of amyloplasts. These results support the starch-statolith theory of graviperception in higher plants and add to current models with a new feedback control loop as a mechanism for modulation of statolith responsiveness to inertial acceleration.     

Analysis of the ethylene response in the epinastic mutant of tomato

Ethylene can alter plant morphology due to its effect on cell expansion. The most widely documented example of ethylene-mediated cell expansion is promotion of the "triple response" of seedlings grown in the dark in ethylene. Roots and hypocotyls become shorter and thickened compared with controls due to a reorientation of cell expansion, and curvature of the apical hook is more pronounced. The epinastic (epi) mutant of tomato (Lycopersicon esculentum) has a dark-grown seedling phenotype similar to the triple response even in the absence of ethylene. In addition, in adult plants both the leaves and the petioles display epinastic curvature and there is constitutive expression of an ethylene-inducible chitinase gene. However, petal senescence and abscission and fruit ripening are all normal in epi. A double mutant (epi/epi;Nr/Nr) homozygous for both the recessive epi and dominant ethylene-insensitive Never-ripe loci has the same dark-grown seedling and vegetative phenotypes as epi but possesses the senescence and ripening characteristics of Never-ripe. These data suggest that a subset of ethylene responses controlling vegetative growth and development may be constitutively activated in epi. In addition, the epi locus has been placed on the tomato RFLP map on the long arm of chromosome 4 and does not demonstrate linkage to reported tomato CTR1 homologs.     

Early root cap development and graviresponse in white clover (Trifolium repens) grown in space and on a two-axis clinostat.

White clover (Trifolium repens) was germinated and grown in microgravity aboard the Space Shuttle (STS-60, 1994; STS-63, 1995), on Earth in stationary racks and in a slow-rotating two-axis clinostat. The objective of this study was to determine if normal root cap development and early plant gravity responses were dependent on gravitational cues. Seedlings were germinated in space and chemically fixed in orbit after 21, 40, and 72 h. Seedlings 96 h old were returned viable to earth. Germination and total seedling length were not dependent on gravity treatment. In space-flown seedlings, the number of cell stories in the root cap and the geometry of central columella cells did not differ from those of the Earth-grown seedlings. The root cap structure of clinorotated plants appeared similar to that of seedlings from microgravity, with the exception of three-day rotated plants, which displayed significant cellular damage in the columella region. Nuclear polarity did not depend on gravity; however, the positions of amyloplasts in the central columella cells were dependent on both the gravity treatment and the age of the seedlings. Seedlings from space, returned viable to earth, responded to horizontal stimulation as did 1 g controls, but seedlings rotated on the clinostat for the same duration had a reduced curvature response. This study demonstrates that initial root cap development is insensitive to either chronic clinorotation or microgravity. Soon after differentiation, however, clinorotation leads to loss of normal root cap structure and plant graviresponse while microgravity does not.     

Studies on the Growth and Indole-3-Acetic Acid and Abscisic Acid Content of Zea mays Seedlings Grown in Microgravity

Measurements were made of the fresh weight, dry weight, dry weight-fresh weight ratio, free and conjugated indole-3-acetic acid, and free and conjugated abscisic acid in seedlings of Zea mays grown in darkness in microgravity and on earth. Imbibition of the dry kernels was for 17 h prior to launch. Growth was for 5 d at ambient orbiter temperature and at a chronic accelerational force of the order of 3 × 10⁻⁵ times earth gravity. Weights and hormone content of the microgravity seedlings were, with minor exceptions, not statistically different from seedlings grown in normal gravity. The tissues of the shuttle-grown plants appeared normal and the seedlings differed only in the lack of orientation of roots and shoots. These findings, based upon 5 d of growth in microgravity, cannot be extrapolated to growth in microgravity for weeks, months, and years, as might occur on a space station. Nonetheless, it is encouraging, for prospects of bioregeneration of the atmosphere and food production in a space station, that no pronounced differences in the parameters measured were apparent during the 5 d of plant seedling growth in microgravity.     

Transduction of an Ethylene Signal Is Required for Cell Death and Lysis in the Root Cortex of Maize during Aerenchyma Formation Induced by Hypoxia

Ethylene has been implicated in signaling cell death in the lysigenous formation of gas spaces (aerenchyma) in the cortex of adventitious roots of maize (Zea mays) subjected to hypoxia. Various antagonists that are known to modify particular steps in signal transduction in other plant systems were applied at low concentrations to normoxic and hypoxic roots of maize, and the effect on cell death (aerenchyma formation) and the increase in cellulase activity that precedes the appearance of cell degeneration were measured. Both cellulase activity and cell death were inhibited in hypoxic roots in the presence of antagonists of inositol phospholipids, Ca2+- calmodulin, and protein kinases. By contrast, there was a parallel promotion of cellulase activity and cell death in hypoxic and normoxic roots by contact with reagents that activate G-proteins, increase cytosolic Ca2+, or inhibit protein phosphatases. Most of these reagents had no effect on ethylene biosynthesis and did not arrest root extension. These results indicate that the transduction of an ethylene signal leading to an increase in intracellular Ca2+ is necessary for cell death and the resulting aerenchyma development in roots of maize subjected to hypoxia.     

Implications of calcium nutrition on the response of Caesalpinia crista (Fabaceae) to soil salinity

Greenhouse experiments were conducted to assess the effects of supplemental calcium in salinised soil on the response of germination and seedling growth of Caesalpinia crista, L. (Fabaceae). NaCl and CaSO₄·2H₂O were added to the soil and 0:0, !:0, 1:0.25, 1:0.50, 1:0.75, 1:1, 1:1.25, and 1:1.50 Na/Ca ratios were maintained. Salinity significantly retarded the seed germination and seedling growth, but the injurious effects of NaCl on seed germination were ameliorated and seedling growth was restored with calcium supply at the critical level (1:0.50 Na/Ca ratio) to salinised soil. Calcium supply above the critical level further retarded the seed germination and seedling growth due to the increased soil salinity. Salt stress reduced N, P, K and Ca content in plant tissues, but these nutrients were restored by addition of calcium at the critical level to saline soil. The opposite was true for Na⁺. The results are discussed in terms of the beneficial effects of calcium supply on the seedling growth of C. crista grown under saline conditions.     

Ultrastructure of the statocytes and cells of the distal elongation zone of <Emphasis Type="Italic">Arabidopsis Thaliana</Emphasis> under the conditions of clinorotation

This paper presents the results of an electron microscope study of the root apices of 3-, 5- and 7- day-old seedlings of Arabidopsis thaliana grown under the conditions of stationary control and clinorotation. We demonstrated both the similarities with the control group and the differences in the ultrastructure of statocytes and cells of the distal zone of elongation under clinorotation. For the first time it was possible to establish the sensitivity of ER bodies, which are granular endoplasmic reticulum derived organelles containing β-glucosidase, to the influence of simulated microgravity. As a result, an increase in the number and area of ER bodies per section of a cell and in the variability of their forms was detected. The degree of these changes correlated with the duration of clinorotation. The supposition concerning the protective role of ER bodies in plant adaptation to microgravity is based on the data obtained.