乙烯在植物形态发育中的作用(综述)

乙烯对植物生长发育的许多方面,如根的形成、花的诱导、器官衰老脱落均起重要的调节作用。拟南芥根表皮中的乙烯是根毛发育的一个正调控因子。兰花授粉诱导花被萎蔫过程的早期反应是提高了对内源乙烯水平的敏感性。     

Pollination-induced flower senescence: a review

Ethylene has long been implicated in the control of the senescence of many cut flower species, but the control of senescence in relation to wild species has received much less attention. The longevity of individual flowers varies greatly from species to species; in some each flower is open for just a few hours, whilst in others the flower may persist for several weeks, or even months. The functional life of the flower may be terminated by petal wilting, abscission or a colour change of all, or part, of the perianth. In some species pollination appears to reduce floral longevity whilst in others, particularly those species having short-lived flowers, the pattern of flower development and senescence appears unaffected by pollination.Examples of the various pollination-induced strategies shown by plants are presented and the role of ethylene and other potential mediators of senescence in these processes discussed.     

中国科学家在乙烯信号转导领域取得突破性进展

乙烯是一种气态植物激素,在植物生长发育的各个阶段发挥着非常重要的作用。最近,中国科学家在乙烯信号转导的分子机制研究中取得了突破性进展。     

Categories of Petal Senescence and Abscission: A Re-evaluation

In a previous paper (Woltering and van Doorn, 1988, Journalof Experimental Botany39: 1605–1616) we identified threetypes of flower life cessation: by petal wilting or withering,which was either ethylene-sensitive or insensitive, and by abscissionof turgid petals, which was ethylene-sensitive. These categoriestended to be consistent within families. Here we re-examinethese relationships by testing a further 200 species, and anumber of other families. As previously, flowering shoots wereexposed to 3 ppm ethylene for 24 h at 20 °C, in darkness.Most monocotyledonous species tested showed ethylene-insensitivepetal wilting, although ethylene-sensitive wilting occurredin the Alismataceae and Commelinaceae. Petals of the dicotyledonousspecies tested were generally sensitive to ethylene, exceptfor a few groups showing wilting (Crassulaceae, Gentianaceaeand Fumariaceae, and one subfamily in both the Ericaceae andSaxifragaceae). Petal abscission was generally ethylene-sensitive,but ethylene insensitivity was found in some Tulipa cultivarsand three Saxifraga species. In most tulip cultivars tested,the petals wilted and then fell. It is concluded that (a) theresponse to ethylene is often consistent within either familiesor subfamilies; and (b) a fourth category, ethylene-insensitivepetal abscission, exists both in monocotyledons and dicotyledons.Copyright 2001 Annals of Botany Company Ethylene sensitivity, flower longevity, petal abscission, petal wilting, petal withering, petal senescence, taxonomic categories     

Effects of Diazocyclopentadiene (DACP) and Silver Thiosulphate (STS) on Ethylene Regulated Abscission of Sweet Pea Flowers (Lathyrus odoratus L.)

The ethylene production rate of cut sweet pea flower buds increased37-fold during the first 48 h of their vase life. This increasein ethylene production was accompanied by petal wilting at 72h and abscission of the buds 24 h later. Exposure of the cutspikes to the ethylene action inhibitor diazocyclopentadiene(DACP, 170 µI 1^-1) for 18 h under fluorescent lights delayedsubsequent wilting and abscission and promoted bud opening.Silver thiosulphate (0·2 mM) was more effective thanDACP, delaying wilting for longer and preventing abscissionentirely.Copyright 1995, 1999 Academic Press Ethylene, abscission, silver thiosulphate, diazocyclopentadiene, flower senescence, wilting, sweet pea, Lathyrus odoratus L     

POST-POLLINATION PHENOMENA IN ORCHID FLOWERS. IV. EFFECTS OF ETHYLENE

Treatment of Cymbidium (Orchidaceae) flowers with 10/μl/liter ethylene for up to 78 hr induces anthocyanin formation in both gynostemia (columns) and labella (lips). After that, pigment levels decrease. During 24-hr exposures, ethylene concentrations of 0.1, 1, and 10μl/ liter cause increased anthocyanin levels in both lips and columns. Ethylene also brings about color changes in the calli and wilting of the perianth, but it does not cause straightening of gynostemia and stigmatic closure. Emasculation effects are similar to those of ethylene, whereas pollination and NAA induce anthocyanin formation and closing of stigmas, as well as swelling and loss of curvature in gynostemia. The effects of ethylene are correlated with its action in other systems.     

Effects of pollination on floral attraction and longevity

The end of a flower's attraction to pollinators may be due toa range of visible cues such as permanent flower closure, acolour change, and withering or abscission of the petals. Floralattraction may be reduced by pollination. Pollination-inducedconclusion of floral attraction is often due to a colour changeor to flower closure. This may or may not be followed by a reductionin floral longevity, defined as the time to petal withering,wilting or shattering. In a few species floral longevity isincreased following pollination-induced flower closure or apollination-induced change in colour. Floral attraction, therefore,has to be disting uished from floral longevity. A literature survey shows that pollination rapidly reduces floralattraction in numerous orchids, but among other plant familiesonly about 60 genera have been found to show pollination-inducedshortening of floral attraction. Although only a few specieshave been investigated, it was invariably established that theeffect of pollination is blocked by inhibitors of ethylene synthesisor ethylene perception, hence is mediated by ethylene. The flowersthat cease to be attractive to pollinators, shortly followingpollination, tend to be from families that are known mainlyto comprise species in which flower longevity, petal colour,or flower closure, is sensitive to exogenous ethylene. Thisindicates that the effect of pollination on floral attractionis generally mediated by endogenous ethylene. Numerous species reportedly show a decrease in the period offloral attraction after exposure to ethylene, whereas only fora small number of species a decrease in the period of floralattraction induced by pollination has been observed. This discrepancymay be due to the greater attention that has been paid to theeffects of ethylene. Nonetheless, the possibility remains thatendogenous ethylene has a role in changing perianth form andcolour in addition to signalling the occurrence of pollination. Key words: Ethylene sensitivity, flower closure, flower longevity, pollination, petal colour, petal wilting, petal withering, petal abscission     

Environmental and Chemical Control of Vegetative Dormant Bud Production in Hydrilla verticillata

Bud production was investigated using algal-free cultures ofthe aquatic weed, Hydrilla verticillata. Vegetative dormantbud production in hydrilla is stimulated by a shortened photoperiodand is not temperature-dependent between 15 and 30 C. The phytochromesystem appears to be involved in this process and ABA stimulatesbud production. Artificial illumination throughout the nightprevented dormant bud production. Ethylene, applied as ethephon,reduced bud production in greenhouse cultures by 80 per centwhen applied at a level of 0.1 mgl^–1 ethephon at 2-d intervals. Hydrilla verticillata, aquatic plants, dormant buds, ethephon, ethylene, abscisic acid     

Ethylene Production by the Kudzu Strains of Pseudomonas syringae pv. phaseolicola Causing Halo Blight in Pueraria lobata (Willd) Ohwi

Significant amounts of ethylene was produced by Pseudomonassolanacearum (all strains), P. syringae pv. phaseolicola (Kudzustrains isolated from Pueraria lobata) and Erwinia rhapontici(2 strains out of 22) out of 24 species, 3 subspecies and 38pathovars of plant pathogenic bacteria tested in yeast extract-peptonebroth. The bean strains of P. syringae pv. phaseolicola causinghalo blight in kindney bean plants did not produce ethylene.The Kudzu strains produced ethylene at a rate of 7 to 100?10^–9nl cell^–1 h^–1, which was 500 to 1,000 times higherthan that of P. solanacearum and several times higher than thatof Penicillium digitatum, the most potent ethylene producerknown among microorganisms. The presence of living cells was essential for ethylene productionby the Kudzu strains. The bacterium effectively produced ethylenefrom amino acids such as glutamate, aspartate and their amides.Although glucose and succinate were also good substrates forethylene biosynthesis, the rate of ethylene production was significantlysmaller than that with glutamate. Methionine, which is knownas the precursor of ethylene in plants, had no effect on ethyleneproduction by the bacterium. 1-Aminocyclopropane-1-carboxylicacid (ACC) also had no effect on ethylene production, and therewas not enough ACC in the bacterial cells to account for thehigh rate of ethylene production. Ethylene production from glutamatewas inhibited by n-propylgallate and EDTA, but not by aminoethoxyvinylglycine.These results indicate that ACC is not involved as an intermediatein the process of ethylene biosynthesis by the bacterium, suggestingthe presence of a pathway different from that of plant tissues. (Received September 4, 1984; Accepted October 27, 1984)     

Inhibition of Somatic Embryogenesis in Tissue 2Medicago sativa by Aminoethoxyvinylglycine, Amino-oxyacetic acid, 2, 4-Dinitrophenol and Salicylic Acid at Concentrations which do not Inhibit Ethylene Biosynthesis and Growth

Meijer, E. G. M. and Brown, D. C. W. 1988. Inhibition of somaticembryogenesis in tissue cultures of Medicago sativa by aminoethoxyvinylglycine,amino-oxyacetic acid, 2, 4-dinitrophenol and salicylic acidat concentrations which do not inhibit ethylene biosynthesisand growth. J. exp. Bot. 39: 263–270. The effects of aminoethoxyvinyglycine (AVG), amino-oxyaceticacid (AOA), 2, 4-dinitrophenol (DNP) and salicylic acid (SA)on ethylene production, tissue proliferation and somatic embryo-genesisin a recently developed rapid in vitro regeneration system ofMedicago sativa L. were examined. Contrary to numerous publications,AVG, AOA and DNP did not affect the rate of ethylene biosynthesis,while SA even caused an increase in ethylene production. Allfour compounds were, however, potent inhibitors of somatic embryoformation in the M. sativa tissue cultures, even at concentrationswhich did not affect tissue growth. Generally, a 5-d exposureto the inhibitors reduced the number and quality of somaticembryos obtained. It is suggested that the inhibitors may notreach the site of action of enzymes involved in ethylene biosynthesisand may possibly block other biosynthetic pathways which areof crucial importance to somatic embryo development. The resultsindicate that a delicate differentiation process like somaticembryogenesis is very sensitive to metabolic perturbances. Theresults are also discussed in the light of other known effectsof these four compounds on higher plants. Key words: Ethylene, Medicago sativa, somatic embryogenesis, tissue culture     

Rapid Kinetic Analysis of Ethylene Growth Responses in Seedlings: New Insights into Ethylene Signal Transduction

Ethylene is a phytohormone that influences diverse processes in plants. Ethylene causes various changes in etiolated seedlings that differ between species and include reduced growth of shoots and roots, increased diameter of shoots, agravitropic growth, initiation of root hairs, and increased curvature of the apical hook. The inhibition of growth in etiolated seedlings has become widely used to screen for and identify mutants. This approach has led to an increased understanding of ethylene signaling. Most studies use end-point analysis after several days of exposure to assess the effects of ethylene. Recently, the use of time-lapse imaging has re-emerged as an experimental method to study the rapid kinetics of ethylene responses. This review outlines the historical use of ethylene growth kinetic studies and summarizes the recent use of this approach coupled with molecular biology to provide new insights into ethylene signaling.     

Transgenic plants with altered ethylene biosynthesis or perception

The plant hormone ethylene is an essential signaling molecule involved in many plant processes including: germination, flower development, fruit ripening and responses to many environmental stimuli. Moreover, large increases in ethylene levels occur during plant stress responses, fruit ripening and flower wilting. Manipulation of ethylene biosynthesis or perception allows us to modulate these processes and thereby create plants with more robust and/or desirable traits, giving us a glimpse into the role of ethylene in the plant. Here, recent and landmark advances in genetic alteration of members of the ethylene pathway in plants and the physiological consequences of these alterations are examined.     

Regulation of soybean nodulation independent of ethylene signaling

Leguminous plants regulate the number of Bradyrhizobium- or Rhizobium-infected sites that develop into nitrogen-fixing root nodules. Ethylene has been implicated in the regulation of nodule formation in some species, but this role has remained in question for soybean (Glycine max). The present study used soybean mutants with decreased responsiveness to ethylene, soybean mutants with defective regulation of nodule number, and Ag⁺ inhibition of ethylene perception to examine the role of ethylene in the regulation of nodule number. Nodule numbers on ethylene-insensitive mutants and plants treated with Ag⁺ were similar to those on wild-type plants and untreated plants, respectively. Hypernodulating mutants displayed wild-type ethylene sensitivity. Suppression of nodule numbers by high nitrate was also similar between ethylene-insensitive plants, wild-type plants, and plants treated with Ag⁺. Ethylene insensitivity of the roots of etr1-1 mutants was confirmed using assays for sensitivity to 1-aminocyclopropane-1-carboxylic acid and for ethylene-stimulated root-hair formation. Additional phenotypes of etr1-1 roots were also characterized. Ethylene-dependent pathways regulate the number of nodules that form on species such as pea and Medicago truncatula, but our data indicate that ethylene is less significant in regulating the number of nodules that form on soybean.     

Ethylene and vegetative development

The past decade has witnessed a tremendous increase in our understanding of the role of ethylene in plant development. Genes encoding enzymes of the ethylene biosynthesis pathway have been isolated, allowing the manipulation of endogenous ethylene levels in intact plants. In parallel, a collection of ethylene mutants was obtained by using a simple response assay. This resulted in the identification of several genes involved in ethylene signal transduction. The data obtained using these new tools have allowed long-standing hypotheses to be tested, while gaining novel insight into the function of ethylene in development. Recent molecular evidence supported the existence of an intense hormonal cross-talk during plant growth. Numerous processes are controlled by ethylene in a close interaction with auxin, and often it was impossible to differentiate between auxin and ethylene effects. Molecular-genetic tools are now allowing the dissection of these interactions. Ethylene does not seem essential for many developmental processes. Nevertheless, it is of crucial importance for survival in most species as it occupies a key position in the developmental response mechanisms of plants under mechanical stress.     

植物根内通气组织形成的研究进展

植物能否在湿地或淹涝环境中生长,很大程度上取决于植物是否具有健全发达的通气组织。在结合形态学和分子生物学等方面研究的基础上,概述了植物根内通气组织的形成过程,主要涉及生理功能、诱导因子和相关酶等,推测细胞程序性死亡是溶生性通气组织形成的机理,乙烯在整体信号转导网络中起关键性中介作用。     

植物根内通气组织形成机理的研究进展

植物能否在湿地或淹涝环境中生长, 很大程度上取决于植物是否具有健全发达的通气组织。在结合形态学和分子生物学等方面研究的基础上, 概述了植物根内通气组织的形成过程, 主要涉及生理功能、诱导因子和相关酶等, 推测细胞程序性死亡是溶生性通气组织形成的机理, 乙烯在整体信号转导网络中起关键性中介作用。     

Ethylene and 1 -Aminocyclopropane-1-Carboxylic Acid Production in flacca, a Wilty Mutant of Tomato, Subjected to Water Deficiency and Pre-treatment with Abscisic Acid

Neill, S. J., McGaw, B. A. and Horgan, R. 1986. Ethylene and1-aminocyclopropane-l-carboxylic acid production in flacca,a wilty mutant of tomato, subjected to water deficiency andpretreatment with abscisic acid —J. exp. Bot. 37: 535–541. Plants of Lycoperstcon esculentum Mill. cv. Ailsa Craig wildtype and flacca (flc) were sprayed daily with H²O or 2?10^–2mol m^–3 abscisic acid (ABA). ABA treatment effected apartial phenotypic reversion of flc shoots; leaf areas wereincreased and transpiration rates decreased. Leaf expansionof wild type shoots was inhibited by ABA. Indoleacetic acid (IAA), ABA and l-aminocyclopropane-l-carboxylicacid (ACC) concentrations were determined by combined gas chromatography-massspectrometry using deuterium-labelled internal standards ABAtreatment for 30 d resulted in greatly elevated internal ABAlevels, increasing from 1?0 to 4?3 and from 0?45 to 4?9 nmolg^–1 fr. wt. in wild type and flc leaves respectively.Endogenous IAA and ACC concentrations were much lower than thoseof ABA. IAA content ranged from 0?05 to 0?1 nmol g^–1 andACC content from 0?07 to 0?24 nmol g^–1 Ethylene emanationrates were similar for wild type and flc shoots. Wilting of detached leaves induced a substantial increase inethylene and ACC accumulation in all plants, regardless of treatmentor type. Ethylene and ACC levels were no greater in flc leavescompared to the wild type. ABA pretreatment did not preventthe wilting-induced increase in ACC and ethylene synthesis. Key words: ABA, ACC, ethylene, wilting, wilty mutants     

Ethylene action in plants

Ethylene action in plants contains nine articles on the roleof ethylene in plants, the primary focus being on responsesto ethylene. Four articles cover the role of ethylene as a plantgrowth regulator, including articles on the general effectsof ethylene on growth rates and cell enlargement, as well asmore specific effects of ethylene on stem gravitropic curvatureand the development of adventitious roots. Two articles coverthe role of ethylene in the ‘ageing’ of plant tissues,including