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Wikipedia

Ethylene (plant hormone)

February 16, 2024

Ethylene (CH
2=CH
2) is an unsaturated hydrocarbon gas (alkene) acting as a naturally occurring plant hormone.[1] It is the simplest alkene gas and is the first gas known to act as hormone.[2] It acts at trace levels throughout the life of the plant by stimulating or regulating the ripening of fruit, the opening of flowers, the abscission (or shedding) of leaves[3] and, in aquatic and semi-aquatic species, promoting the 'escape' from submergence by means of rapid elongation of stems or leaves.[4] This escape response is particularly important in rice farming.[5] Commercial fruit-ripening rooms use "catalytic generators" to make ethylene gas from a liquid supply of ethanol. Typically, a gassing level of 500 to 2,000 ppm is used, for 24 to 48 hours. Care must be taken to control carbon dioxide levels in ripening rooms when gassing, as high temperature ripening (20 °C; 68 °F)[6] has been seen to produce CO2 levels of 10% in 24 hours.[7]

An ethylene signal transduction pathway. Ethylene permeates the cell membrane and binds to a receptor on the endoplasmic reticulum. The receptor releases the repressed EIN2. This then activates a signal transduction pathway which activates regulatory genes that eventually trigger an ethylene response. The activated DNA is transcribed into mRNA which is then translated into a functional enzyme that is used for ethylene biosynthesis.

History edit

Ethylene has a long history of use in agriculture. Ancient Egyptians would gash figs in order to stimulate ripening (wounding stimulates ethylene production by plant tissues). The ancient Chinese would burn incense in closed rooms to enhance the ripening of pears. In the 19th century, city dwellers noticed that gas leaks from street lights led to stunting of growth, death of flowers and premature leaf fall.[6] In1874, it was discovered that smoke caused pineapple fields to bloom. Smoke contains ethylene, and once this was realized the smoke was replaced with ethephon or naphthalene acetic acid, which induce ethylene production.[8]

The scientific study of ethylene as a factor in plant physiology started in the late 19th century. In 1896, Russian botanist Dimitry Neljubow studied the response pea to illuminating gas to which they showed movement. He discovered ethylene as the active component in the light source that stimulated pea behaviour.[2] He reported his discovery in 1901.[9] Sarah Doubt also showed in 1917 that ethylene from illuminating gas stimulated abscission.[10] Farmers in Florida would commonly get their crops to ripen in sheds by lighting kerosene lamps, which was originally thought to induce ripening from the heat. In 1924, Frank E. Denny discovered that it was the molecule ethylene emitted by the kerosene lamps that induced the ripening.[11] Reporting in the Botanical Gazette, he wrote:

Ethylene was very effective in bringing about the desired result, concentrations as low as one part (by volume) of ethylene in one million parts of air being sufficient to cause green lemons to turn yellow in about six to ten days... Furthermore, coloring with either ethylene or gas from the kerosene stoves caused the loss of the "buttons" (calyx, receptacle, and a portion of the peduncle)... Yellowing of the ethylene treated fruit became visible about the third or fourth day, and full yellow color was developed in six to ten days. Untreated fruit remained green during the same period of time.[12]

The same year, Denny published the experimental details separately,[13] and also experimentally showed that use of ethylene was more advantageous than that of kerosene.[14] In 1934, British biologist Richard Gane discovered that the chemical constituent in ripe bananas could cause ripening of green bananas, as well as faster growth of pea. He showed that the same growth effect could be induced by ethylene.[15] Reporting in Nature that ripe fruit (in this case Worcester Pearmain apple) produced ethylene he said:

The amount of ethylene produced [by the apple] is very small—perhaps of the order of 1 cubic centimetre during the whole life-history of the fruit; and the cause of its prodigious biological activity in such small concentration is a problem for further research. Its production by apple ceases or is very much reduced in the absence of oxygen.[16]

He subsequently showed that ethylene was produced by other fruits as well, and that obtained from apple could induce seed germination and plant growth in different vegetables (but not in cereals).[17] His conclusions were not universally accepted by other scientists.[2] They became more convincing when William Crocker, Alfred Hitchcock, and Percy Zimmerman reported in 1935 that ethylene acts similar to auxins in causing plant growth and senescence of vegetative tissues. This established that ethylene is a plant hormone.[18][19]

Ethylene biosynthesis in plants edit

 
The Yang cycle

Ethylene is produced from essentially all parts of higher plants, including leaves, stems, roots, flowers, fruits, tubers, and seeds. Ethylene production is regulated by a variety of developmental and environmental factors. During the life of the plant, ethylene production is induced during certain stages of growth such as germination, ripening of fruits, abscission of leaves, and senescence of flowers. Ethylene production can also be induced by a variety of external aspects such as mechanical wounding, environmental stresses, and certain chemicals including auxin and other regulators.[20] The pathway for ethylene biosynthesis is named the Yang cycle after the scientist Shang Fa Yang who made key contributions to elucidating this pathway.

Ethylene is biosynthesized from the amino acid methionine to S-adenosyl-L-methionine (SAM, also called Adomet) by the enzyme Met adenosyltransferase. SAM is then converted to 1-aminocyclopropane-1-carboxylic acid (ACC) by the enzyme ACC synthase (ACS). The activity of ACS determines the rate of ethylene production, therefore regulation of this enzyme is key for the ethylene biosynthesis. The final step requires oxygen and involves the action of the enzyme ACC-oxidase (ACO), formerly known as the ethylene forming enzyme (EFE). Ethylene biosynthesis can be induced by endogenous or exogenous ethylene. ACC synthesis increases with high levels of auxins, especially indole acetic acid (IAA) and cytokinins.

Ethylene perception in plants edit

Ethylene is perceived by a family of five transmembrane protein dimers such as the ETR1 protein in Arabidopsis. The genes encoding ethylene receptors have been cloned in the reference plant Arabidopsis thaliana and many other plants. Ethylene receptors are encoded by multiple genes in plant genomes. Dominant missense mutations in any of the gene family, which comprises five receptors in Arabidopsis and at least six in tomato, can confer insensitivity to ethylene.[21] Loss-of-function mutations in multiple members of the ethylene-receptor family result in a plant that exhibits constitutive ethylene responses.[22] DNA sequences for ethylene receptors have also been identified in many other plant species and an ethylene binding protein has even been identified in Cyanobacteria.[1]

Ethylene response to salt stress edit

A large portion of the soil has been affected by over salinity and it has been known to limit the growth of many plants. Globally, the total area of saline soil was 397,000,000 ha and in continents like Africa, it makes up 2 percent of the soil.[23] The amount of soil salinization has reached 19.5% of the irrigated land and 2.1% of the dry-land agriculture around the world.[24] Soil salinization affects the plants using osmotic potential by net solute accumulation. The osmotic pressure in the plant is what maintains water uptake and cell turgor to help with stomatal function and other cellular mechanisms.[24] Over generations, many plant genes have adapted, allowing plants’ phenotypes to change and built distinct mechanisms to counter salinity effects.

The plant hormone ethylene is a combatant for salinity in most plants. Ethylene is known for regulating plant growth and development and adapted to stress conditions through a complex signal transduction pathway. Central membrane proteins in plants, such as ETO2, ERS1 and EIN2, are used for ethylene signaling in many plant growth processes. ETO2, Ethylene overproducer 2, is a protein that, when mutated, will gain a function to continually produce ethylene even when there is no stress condition, causing the plant to grow short and stumpy. ERS1, Ethylene response sensor 1, is activated when ethylene is present in the signaling pathway and when mutated, it loses a function and cannot bind to ethylene. This means a response is never activated and the plant will not be able to cope with the abiotic stress. EIN2, Ethylene insensitive 2, is a protein that activates the pathway and when there is a mutation here the EIN2 will block ethylene stimulation and an ethylene response gene will not be activated. Mutations in these proteins can lead to heightened salt sensitivity and limit plant growth. The effects of salinity have been studied on Arabidopsis plants that have mutated ERS1 and EIN4 proteins.[25] These proteins are used for ethylene signaling again certain stress conditions, such as salt and the ethylene precursor ACC is allowing suppress of any sensitivity to the salt stress.[25] Mutations in these pathways can cause lack of ethylene signaling, causing stunt in plant growth and development.

Environmental and biological triggers of ethylene edit

Environmental cues such as flooding, drought, chilling, wounding, and pathogen attack can induce ethylene formation in plants. In flooding, roots suffer from lack of oxygen, or anoxia, which leads to the synthesis of 1-aminocyclopropane-1-carboxylic acid (ACC). ACC is transported upwards in the plant and then oxidized in leaves. The ethylene produced causes nastic movements (epinasty) of the leaves, perhaps helping the plant to lose less water in compensation for an increase in resistance to water transport through oxygen-deficient roots.[26]

Corolla senescence edit

The corolla of a plant refers to its set of petals. Corolla development in plants is broken into phases from anthesis to corolla wilting. The development of the corolla is directed in part by ethylene, though its concentration is highest when the plant is fertilized and no longer requires the production or maintenance of structures and compounds that attract pollinators.[27][28] The role of ethylene in the developmental cycle is as a hormonal director of senescence in corolla tissue. This is evident as ethylene production and emission are maximized in developmental phases post-pollination, until corolla wilting.[27] Ethylene-directed senescence of corolla tissue can be observed as color change in the corolla or the wilting/ death of corolla tissue. At the chemical level, ethylene mediates the reduction in the amount of fragrance volatiles produced. Fragrance volatiles act mostly by attracting pollinators. Ethylene's role in this developmental scenario is to move the plant away from a state of attracting pollinators, so it also aids in decreasing the production of these volatiles.

Ethylene production in corolla tissue does not directly cause the senescence of corolla tissue, but acts by releasing secondary products that are consistent with tissue ageing. While the mechanism of ethylene-mediated senescence are unclear, its role as a senescence-directing hormone can be confirmed by ethylene-sensitive petunia response to ethylene knockdown. Knockdown of ethylene biosynthesis genes was consistent with increased corolla longevity; inversely, up-regulation of ethylene biosynthesis gene transcription factors were consistent with a more rapid senescence of the corolla.[27]

List of plant responses to ethylene edit

  • Seedling triple response, thickening and shortening of hypocotyl with pronounced apical hook.[29]
  • Stimulation of Arabidopsis hypocotyl elongation [30]
  • In pollination, when the pollen reaches the stigma, the precursor of the ethylene, ACC, is secreted to the petal, the ACC releases ethylene with ACC oxidase.
  • Stimulates leaf senescence
  • Controls root growth inhibition in compacted soils [31]
  • Stimulates senescence of mature xylem cells in preparation for plant use
  • Induces leaf abscission[32]
  • Induces seed germination
  • Induces root hair growth — increasing the efficiency of water and mineral absorption
  • Induces the growth of adventitious roots during flooding
  • Stimulates survival under low-oxygen conditions (hypoxia) in submerged plant tissues [33][34][35][36]
  • Controls adaptive Translation (biology) dynamics during plant submergence [37][38]
  • Stimulates epinasty — leaf petiole grows out, leaf hangs down and curls into itself
  • Stimulates fruit ripening
  • Induces a climacteric rise in respiration in some fruit which causes a release of additional ethylene.
  • Affects gravitropism
  • Stimulates nutation
  • Inhibits stem growth and stimulates stem and cell broadening and lateral branch growth outside of seedling stage (see Hyponastic response)
  • Interference with auxin transport (with high auxin concentrations)
  • Inhibits shoot growth and stomatal closing except in some water plants or habitually submerged species such as rice, Callitriche (e.g., C. platycarpa), and Rumex, where the opposite occurs to achieve an adaptive escape from submergence.[39]
  • Induces flowering in pineapples
  • Inhibits short day induced flower initiation in Pharbitus nil[40] and Chrysanthemum morifolium[41]

Commercial issues edit

Ethylene shortens the shelf life of many fruits by hastening fruit ripening and floral senescence. Ethylene will shorten the shelf life of cut flowers and potted plants by accelerating floral senescence and floral abscission. Flowers and plants which are subjected to stress during shipping, handling, or storage produce ethylene causing a significant reduction in floral display. Flowers affected by ethylene include carnation, geranium, petunia, rose, and many others.[42]

Ethylene can cause significant economic losses for florists, markets, suppliers, and growers. Researchers have developed several ways to inhibit ethylene, including inhibiting ethylene synthesis and inhibiting ethylene perception. Aminoethoxyvinylglycine (AVG), Aminooxyacetic acid (AOA), and silver salts are ethylene inhibitors.[43][44] Inhibiting ethylene synthesis is less effective for reducing post-harvest losses since ethylene from other sources can still have an effect. By inhibiting ethylene perception, fruits, plants and flowers don't respond to ethylene produced endogenously or from exogenous sources. Inhibitors of ethylene perception include compounds that have a similar shape to ethylene, but do not elicit the ethylene response. One example of an ethylene perception inhibitor is 1-methylcyclopropene (1-MCP).

Commercial growers of bromeliads, including pineapple plants, use ethylene to induce flowering. Plants can be induced to flower either by treatment with the gas in a chamber, or by placing a banana peel next to the plant in an enclosed area.

Chrysanthemum flowering is delayed by ethylene gas,[45] and growers have found that carbon dioxide 'burners' and the exhaust fumes from inefficient glasshouse heaters can raise the ethylene concentration to 0.05 ppmv, causing delay in flowering of commercial crops.

References edit

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Further reading edit

  • Chang C, Stadler R (July 2001). "Ethylene hormone receptor action in Arabidopsis". BioEssays. 23 (7): 619–627. doi:10.1002/bies.1087. PMID 11462215. S2CID 6640353.
  • Millenaar FF, van Zanten M, Cox MC, Pierik R, Voesenek LA, Peeters AJ (2009). "Differential petiole growth in Arabidopsis thaliana: photocontrol and hormonal regulation". New Phytologist. 184 (1): 141–152. doi:10.1111/j.1469-8137.2009.02921.x. PMID 19558423.
  • Schaller GE (February 2012). "Ethylene and the regulation of plant development". BMC Biology (published 20 February 2012). 10 (9): 9. doi:10.1186/1741-7007-10-9. PMC 3282650. PMID 22348804.

External links edit

  • International Chemical Safety Card 0475

February 16, 2024
ethylene, plant, hormone, ethylene, unsaturated, hydrocarbon, alkene, acting, naturally, occurring, plant, hormone, simplest, alkene, first, known, hormone, acts, trace, levels, throughout, life, plant, stimulating, regulating, ripening, fruit, opening, flower. Ethylene CH2 CH2 is an unsaturated hydrocarbon gas alkene acting as a naturally occurring plant hormone 1 It is the simplest alkene gas and is the first gas known to act as hormone 2 It acts at trace levels throughout the life of the plant by stimulating or regulating the ripening of fruit the opening of flowers the abscission or shedding of leaves 3 and in aquatic and semi aquatic species promoting the escape from submergence by means of rapid elongation of stems or leaves 4 This escape response is particularly important in rice farming 5 Commercial fruit ripening rooms use catalytic generators to make ethylene gas from a liquid supply of ethanol Typically a gassing level of 500 to 2 000 ppm is used for 24 to 48 hours Care must be taken to control carbon dioxide levels in ripening rooms when gassing as high temperature ripening 20 C 68 F 6 has been seen to produce CO2 levels of 10 in 24 hours 7 An ethylene signal transduction pathway Ethylene permeates the cell membrane and binds to a receptor on the endoplasmic reticulum The receptor releases the repressed EIN2 This then activates a signal transduction pathway which activates regulatory genes that eventually trigger an ethylene response The activated DNA is transcribed into mRNA which is then translated into a functional enzyme that is used for ethylene biosynthesis Contents 1 History 2 Ethylene biosynthesis in plants 3 Ethylene perception in plants 4 Ethylene response to salt stress 5 Environmental and biological triggers of ethylene 6 Corolla senescence 6 1 List of plant responses to ethylene 6 2 Commercial issues 7 References 8 Further reading 9 External linksHistory editEthylene has a long history of use in agriculture Ancient Egyptians would gash figs in order to stimulate ripening wounding stimulates ethylene production by plant tissues The ancient Chinese would burn incense in closed rooms to enhance the ripening of pears In the 19th century city dwellers noticed that gas leaks from street lights led to stunting of growth death of flowers and premature leaf fall 6 In1874 it was discovered that smoke caused pineapple fields to bloom Smoke contains ethylene and once this was realized the smoke was replaced with ethephon or naphthalene acetic acid which induce ethylene production 8 The scientific study of ethylene as a factor in plant physiology started in the late 19th century In 1896 Russian botanist Dimitry Neljubow studied the response pea to illuminating gas to which they showed movement He discovered ethylene as the active component in the light source that stimulated pea behaviour 2 He reported his discovery in 1901 9 Sarah Doubt also showed in 1917 that ethylene from illuminating gas stimulated abscission 10 Farmers in Florida would commonly get their crops to ripen in sheds by lighting kerosene lamps which was originally thought to induce ripening from the heat In 1924 Frank E Denny discovered that it was the molecule ethylene emitted by the kerosene lamps that induced the ripening 11 Reporting in the Botanical Gazette he wrote Ethylene was very effective in bringing about the desired result concentrations as low as one part by volume of ethylene in one million parts of air being sufficient to cause green lemons to turn yellow in about six to ten days Furthermore coloring with either ethylene or gas from the kerosene stoves caused the loss of the buttons calyx receptacle and a portion of the peduncle Yellowing of the ethylene treated fruit became visible about the third or fourth day and full yellow color was developed in six to ten days Untreated fruit remained green during the same period of time 12 The same year Denny published the experimental details separately 13 and also experimentally showed that use of ethylene was more advantageous than that of kerosene 14 In 1934 British biologist Richard Gane discovered that the chemical constituent in ripe bananas could cause ripening of green bananas as well as faster growth of pea He showed that the same growth effect could be induced by ethylene 15 Reporting in Nature that ripe fruit in this case Worcester Pearmain apple produced ethylene he said The amount of ethylene produced by the apple is very small perhaps of the order of 1 cubic centimetre during the whole life history of the fruit and the cause of its prodigious biological activity in such small concentration is a problem for further research Its production by apple ceases or is very much reduced in the absence of oxygen 16 He subsequently showed that ethylene was produced by other fruits as well and that obtained from apple could induce seed germination and plant growth in different vegetables but not in cereals 17 His conclusions were not universally accepted by other scientists 2 They became more convincing when William Crocker Alfred Hitchcock and Percy Zimmerman reported in 1935 that ethylene acts similar to auxins in causing plant growth and senescence of vegetative tissues This established that ethylene is a plant hormone 18 19 Ethylene biosynthesis in plants edit nbsp The Yang cycleEthylene is produced from essentially all parts of higher plants including leaves stems roots flowers fruits tubers and seeds Ethylene production is regulated by a variety of developmental and environmental factors During the life of the plant ethylene production is induced during certain stages of growth such as germination ripening of fruits abscission of leaves and senescence of flowers Ethylene production can also be induced by a variety of external aspects such as mechanical wounding environmental stresses and certain chemicals including auxin and other regulators 20 The pathway for ethylene biosynthesis is named the Yang cycle after the scientist Shang Fa Yang who made key contributions to elucidating this pathway Ethylene is biosynthesized from the amino acid methionine to S adenosyl L methionine SAM also called Adomet by the enzyme Met adenosyltransferase SAM is then converted to 1 aminocyclopropane 1 carboxylic acid ACC by the enzyme ACC synthase ACS The activity of ACS determines the rate of ethylene production therefore regulation of this enzyme is key for the ethylene biosynthesis The final step requires oxygen and involves the action of the enzyme ACC oxidase ACO formerly known as the ethylene forming enzyme EFE Ethylene biosynthesis can be induced by endogenous or exogenous ethylene ACC synthesis increases with high levels of auxins especially indole acetic acid IAA and cytokinins Ethylene perception in plants editEthylene is perceived by a family of five transmembrane protein dimers such as the ETR1 protein in Arabidopsis The genes encoding ethylene receptors have been cloned in the reference plant Arabidopsis thaliana and many other plants Ethylene receptors are encoded by multiple genes in plant genomes Dominant missense mutations in any of the gene family which comprises five receptors in Arabidopsis and at least six in tomato can confer insensitivity to ethylene 21 Loss of function mutations in multiple members of the ethylene receptor family result in a plant that exhibits constitutive ethylene responses 22 DNA sequences for ethylene receptors have also been identified in many other plant species and an ethylene binding protein has even been identified in Cyanobacteria 1 Ethylene response to salt stress editA large portion of the soil has been affected by over salinity and it has been known to limit the growth of many plants Globally the total area of saline soil was 397 000 000 ha and in continents like Africa it makes up 2 percent of the soil 23 The amount of soil salinization has reached 19 5 of the irrigated land and 2 1 of the dry land agriculture around the world 24 Soil salinization affects the plants using osmotic potential by net solute accumulation The osmotic pressure in the plant is what maintains water uptake and cell turgor to help with stomatal function and other cellular mechanisms 24 Over generations many plant genes have adapted allowing plants phenotypes to change and built distinct mechanisms to counter salinity effects The plant hormone ethylene is a combatant for salinity in most plants Ethylene is known for regulating plant growth and development and adapted to stress conditions through a complex signal transduction pathway Central membrane proteins in plants such as ETO2 ERS1 and EIN2 are used for ethylene signaling in many plant growth processes ETO2 Ethylene overproducer 2 is a protein that when mutated will gain a function to continually produce ethylene even when there is no stress condition causing the plant to grow short and stumpy ERS1 Ethylene response sensor 1 is activated when ethylene is present in the signaling pathway and when mutated it loses a function and cannot bind to ethylene This means a response is never activated and the plant will not be able to cope with the abiotic stress EIN2 Ethylene insensitive 2 is a protein that activates the pathway and when there is a mutation here the EIN2 will block ethylene stimulation and an ethylene response gene will not be activated Mutations in these proteins can lead to heightened salt sensitivity and limit plant growth The effects of salinity have been studied on Arabidopsis plants that have mutated ERS1 and EIN4 proteins 25 These proteins are used for ethylene signaling again certain stress conditions such as salt and the ethylene precursor ACC is allowing suppress of any sensitivity to the salt stress 25 Mutations in these pathways can cause lack of ethylene signaling causing stunt in plant growth and development Environmental and biological triggers of ethylene editEnvironmental cues such as flooding drought chilling wounding and pathogen attack can induce ethylene formation in plants In flooding roots suffer from lack of oxygen or anoxia which leads to the synthesis of 1 aminocyclopropane 1 carboxylic acid ACC ACC is transported upwards in the plant and then oxidized in leaves The ethylene produced causes nastic movements epinasty of the leaves perhaps helping the plant to lose less water in compensation for an increase in resistance to water transport through oxygen deficient roots 26 Corolla senescence editThe corolla of a plant refers to its set of petals Corolla development in plants is broken into phases from anthesis to corolla wilting The development of the corolla is directed in part by ethylene though its concentration is highest when the plant is fertilized and no longer requires the production or maintenance of structures and compounds that attract pollinators 27 28 The role of ethylene in the developmental cycle is as a hormonal director of senescence in corolla tissue This is evident as ethylene production and emission are maximized in developmental phases post pollination until corolla wilting 27 Ethylene directed senescence of corolla tissue can be observed as color change in the corolla or the wilting death of corolla tissue At the chemical level ethylene mediates the reduction in the amount of fragrance volatiles produced Fragrance volatiles act mostly by attracting pollinators Ethylene s role in this developmental scenario is to move the plant away from a state of attracting pollinators so it also aids in decreasing the production of these volatiles Ethylene production in corolla tissue does not directly cause the senescence of corolla tissue but acts by releasing secondary products that are consistent with tissue ageing While the mechanism of ethylene mediated senescence are unclear its role as a senescence directing hormone can be confirmed by ethylene sensitive petunia response to ethylene knockdown Knockdown of ethylene biosynthesis genes was consistent with increased corolla longevity inversely up regulation of ethylene biosynthesis gene transcription factors were consistent with a more rapid senescence of the corolla 27 List of plant responses to ethylene edit Seedling triple response thickening and shortening of hypocotyl with pronounced apical hook 29 Stimulation of Arabidopsis hypocotyl elongation 30 In pollination when the pollen reaches the stigma the precursor of the ethylene ACC is secreted to the petal the ACC releases ethylene with ACC oxidase Stimulates leaf senescence Controls root growth inhibition in compacted soils 31 Stimulates senescence of mature xylem cells in preparation for plant use Induces leaf abscission 32 Induces seed germination Induces root hair growth increasing the efficiency of water and mineral absorption Induces the growth of adventitious roots during flooding Stimulates survival under low oxygen conditions hypoxia in submerged plant tissues 33 34 35 36 Controls adaptive Translation biology dynamics during plant submergence 37 38 Stimulates epinasty leaf petiole grows out leaf hangs down and curls into itself Stimulates fruit ripening Induces a climacteric rise in respiration in some fruit which causes a release of additional ethylene Affects gravitropism Stimulates nutation Inhibits stem growth and stimulates stem and cell broadening and lateral branch growth outside of seedling stage see Hyponastic response Interference with auxin transport with high auxin concentrations Inhibits shoot growth and stomatal closing except in some water plants or habitually submerged species such as rice Callitriche e g C platycarpa and Rumex where the opposite occurs to achieve an adaptive escape from submergence 39 Induces flowering in pineapples Inhibits short day induced flower initiation in Pharbitus nil 40 and Chrysanthemum morifolium 41 Commercial issues edit Ethylene shortens the shelf life of many fruits by hastening fruit ripening and floral senescence Ethylene will shorten the shelf life of cut flowers and potted plants by accelerating floral senescence and floral abscission Flowers and plants which are subjected to stress during shipping handling or storage produce ethylene causing a significant reduction in floral display Flowers affected by ethylene include carnation geranium petunia rose and many others 42 Ethylene can cause significant economic losses for florists markets suppliers and growers Researchers have developed several ways to inhibit ethylene including inhibiting ethylene synthesis and inhibiting ethylene perception Aminoethoxyvinylglycine AVG Aminooxyacetic acid AOA and silver salts are ethylene inhibitors 43 44 Inhibiting ethylene synthesis is less effective for reducing post harvest losses since ethylene from other sources can still have an effect By inhibiting ethylene perception fruits plants and flowers don t respond to ethylene produced endogenously or from exogenous sources Inhibitors of ethylene perception include compounds that have a similar shape to ethylene but do not elicit the ethylene response One example of an ethylene perception inhibitor is 1 methylcyclopropene 1 MCP Commercial growers of bromeliads including pineapple plants use ethylene to induce flowering Plants can be induced to flower either by treatment with the gas in a chamber or by placing a banana peel next to the plant in an enclosed area Chrysanthemum flowering is delayed by ethylene gas 45 and growers have found that carbon dioxide burners and the exhaust fumes from inefficient glasshouse heaters can raise the ethylene concentration to 0 05 ppmv causing delay in flowering of commercial crops References edit a b Lin Z Zhong S Grierson D 2009 Recent advances in ethylene research Journal of Experimental Botany 60 12 3311 3336 doi 10 1093 jxb erp204 PMID 19567479 a b c Bakshi Arkadipta Shemansky Jennifer M Chang Caren Binder Brad M 2015 History of Research on the Plant Hormone Ethylene Journal of Plant Growth Regulation 34 4 809 827 doi 10 1007 s00344 015 9522 9 S2CID 14775439 Jackson MB Osborne DJ March 1970 Ethylene the natural regulator of leaf abscission Nature 225 5237 1019 22 Bibcode 1970Natur 225 1019J doi 10 1038 2251019a0 PMID 16056901 S2CID 4276844 Musgrave A Jackson MB Ling E 1972 Callitriche Stem Elongation is controlled by Ethylene and Gibberellin Nature New Biology 238 81 93 96 doi 10 1038 newbio238093a0 ISSN 2058 1092 Jackson MB January 2008 Ethylene promoted elongation an adaptation to submergence stress Annals of Botany 101 2 229 248 doi 10 1093 aob mcm237 PMC 2711016 PMID 17956854 a b Dahll R K 2013 Ethylene in the Post Harvest Quality Management of Horticultural Crops A Review Research and Reviews A Journal of Crop Science and Technology 2 via Researchgate External Link to More on Ethylene Gassing and Carbon Dioxide Control Archived 2010 09 14 at the Wayback Machine ne postharvest com Annual Plant Reviews Plant Hormone Signaling Peter Hedden Stephen G Thomas John Wiley amp Sons Apr 15 2008 Neljubov D 1901 Uber die horizontale Nutation der Stengel von Pisum sativum und einiger anderen Pflanzen Beih Bot Zentralbl 10 128 139 Doubt SL 1917 The Response of Plants to Illuminating Gas Botanical Gazette 63 3 209 224 doi 10 1086 332006 hdl 2027 mdp 39015068299380 JSTOR 2469142 S2CID 86383905 Chamovitz D 2012 What A Plant Knows United States of America Scientific American pp 29 30 ISBN 978 0 374 28873 0 Denny F E 1924 Effect of Ethylene Upon Respiration of Lemons Botanical Gazette 77 3 322 329 doi 10 1086 333319 JSTOR 2469953 S2CID 85166032 Denny F E 1924 Hastening the Coloration of Lemons Journal of Agricultural Research 27 10 757 769 Chace I M Denny F E 1924 Use of Ethylene in the Coloring of Citrus Fruit Industrial amp Engineering Chemistry 16 4 339 340 doi 10 1021 ie50172a003 Gane R 1935 Department of Scientific and Industrial Research Report of the Food Investigation Board for 1934 The Analyst 60 715 122 123 Bibcode 1935Ana 60 687 doi 10 1039 an9356000687 ISSN 0003 2654 Gane R 1934 Production of ethylene by some fruits Nature 134 3400 1008 Bibcode 1934Natur 134 1008G doi 10 1038 1341008a0 S2CID 4090009 Gane R 1935 The Formation of Ethylene by Plant Tissues and its Significance in the Ripening of Fruits Journal of Pomology and Horticultural Science 13 4 351 358 doi 10 1080 03683621 1935 11513459 Crocker W Hitchcock AE Zimmerman PW 1935 Similarities in the effects of ethlyene and the plant auxins Contrib Boyce Thompson Inst Auxins Cytokinins IAA Growth substances Ethylene 7 231 248 Arshad Muhammad Frankenberger William T 2002 The Plant Hormone Ethylene Ethylene Boston MA Springer US pp 1 9 doi 10 1007 978 1 4615 0675 1 1 ISBN 978 1 4613 5189 4 retrieved 2021 06 10 Yang SF Hoffman NE 1984 Ethylene biosynthesis and its regulation in higher plants Annu Rev Plant Physiol 35 155 89 doi 10 1146 annurev pp 35 060184 001103 Bleecker AB Esch JJ Hall AE Rodriguez FI Binder BM September 1998 The ethylene receptor family from Arabidopsis structure and function Philosophical Transactions of the Royal Society of London Series B Biological Sciences 353 1374 1405 12 doi 10 1098 rstb 1998 0295 PMC 1692356 PMID 9800203 Hua J Meyerowitz EM July 1998 Ethylene responses are negatively regulated by a receptor gene family in Arabidopsis thaliana Cell 94 2 261 71 doi 10 1016 S0092 8674 00 81425 7 PMID 9695954 S2CID 15437009 More information on Salt affected soils FAO Food and Agriculture Organization of the United Nations www fao org Retrieved 2017 05 02 a b Azevedo Neto AD Prisco JT Eneas Filho J Lacerda CF Silva JV Costa PH et al 2004 04 01 Effects of salt stress on plant growth stomatal response and solute accumulation of different maize genotypes Brazilian Journal of Plant Physiology 16 1 31 38 doi 10 1590 S1677 04202004000100005 ISSN 1677 0420 a b Lei G Shen M Li ZG Zhang B Duan KX Wang N et al October 2011 EIN2 regulates salt stress response and interacts with a MA3 domain containing protein ECIP1 in Arabidopsis Plant Cell amp Environment 34 10 1678 92 doi 10 1111 j 1365 3040 2011 02363 x PMID 21631530 Explaining Epinasty planthormones inf a b c Wang H Chang X Lin J Chang Y Chen JC Reid MS Jiang CZ 2018 Transcriptome profiling reveals regulatory mechanisms underlying corolla senescence in petunia Horticulture Research 5 16 16 doi 10 1038 s41438 018 0018 1 PMC 5878830 PMID 29619227 Underwood BA Tieman DM Shibuya K Dexter RJ Loucas HM Simkin AJ et al May 2005 Ethylene regulated floral volatile synthesis in petunia corollas Plant Physiology 138 1 255 66 doi 10 1104 pp 104 051144 PMC 1104180 PMID 15849311 Kieber Joseph J Schaller G Eric 2019 07 01 Behind the Screen How a Simple Seedling Response Helped Unravel Ethylene Signaling in Plants The Plant Cell 31 7 1402 1403 doi 10 1105 tpc 19 00342 ISSN 1040 4651 PMC 6635871 PMID 31068448 Debatosh Das Ethylene and shade induced hypocotyl elongation share transcriptome patterns and functional regulators Plant Physiology 21 06 2016 Pandey Bipin K Huang Guoqiang Bhosale Rahul Hartman Sjon Sturrock Craig J Jose Lottie Martin Olivier C Karady Michal Voesenek Laurentius A C J Ljung Karin Lynch Jonathan P Brown Kathleen M Whalley William R Mooney Sacha J Zhang Dabing Bennett Malcolm J 15 January 2021 Plant roots sense soil compaction through restricted ethylene diffusion Science 371 6526 276 280 Bibcode 2021Sci 371 276P doi 10 1126 science abf3013 PMID 33446554 S2CID 231606782 Jackson MB Osborne DJ March 1970 Ethylene the natural regulator of leaf abscission Nature 225 5237 1019 22 Bibcode 1970Natur 225 1019J doi 10 1038 2251019a0 PMID 16056901 S2CID 4276844 Hartman S Liu Z van Veen H Vicente J Reinen E Martopawiro S et al September 2019 Ethylene mediated nitric oxide depletion pre adapts plants to hypoxia stress Nature Communications 10 1 4020 Bibcode 2019NatCo 10 4020H doi 10 1038 s41467 019 12045 4 PMC 6728379 PMID 31488841 van Veen H Mustroph A Barding GA Vergeer van Eijk M Welschen Evertman RA Pedersen O Visser EJ Larive CK Pierik R Bailey Serres J Voesenek LA Sasidharan R November 2013 Two Rumex species from contrasting hydrological niches regulate flooding tolerance through distinct mechanisms The Plant Cell 25 11 4691 707 doi 10 1105 tpc 113 119016 PMC 3875744 PMID 24285788 Hartman S Sasidharan R Voesenek LA December 2019 The role of ethylene in metabolic acclimations to low oxygen New Phytologist 229 1 64 70 doi 10 1111 nph 16378 PMC 7754284 PMID 31856295 Hartman Sjon van Dongen Nienke Renneberg Dominique M H J Welschen Evertman Rob A M Kociemba Johanna Sasidharan Rashmi Voesenek Laurentius A C J August 2020 Ethylene Differentially Modulates Hypoxia Responses and Tolerance across Solanum Species Plants 9 8 1022 doi 10 3390 plants9081022 PMC 7465973 PMID 32823611 Cho Hsing Yi Chou Mei Yi Ho Hsiu Yin Chen Wan Chieh Shih Ming Che 3 June 2022 Ethylene modulates translation dynamics in Arabidopsis under submergence via GCN2 and EIN2 Science Advances 8 22 eabm7863 Bibcode 2022SciA 8M7863C doi 10 1126 sciadv abm7863 PMC 9166634 PMID 35658031 Maric Aida Hartman Sjon 17 August 2022 Ethylene controls translational gatekeeping to overcome flooding stress in plants The EMBO Journal 41 19 e112282 doi 10 15252 embj 2022112282 PMC 9531296 PMID 35975893 Metraux Jean Pierre Kende Hans 1983 06 01 The Role of Ethylene in the Growth Response of Submerged Deep Water Rice 1 Plant Physiology 72 2 441 446 doi 10 1104 pp 72 2 441 ISSN 0032 0889 PMC 1066253 PMID 16663022 Wilmowicz E Kesy J Kopcewicz J December 2008 Ethylene and ABA interactions in the regulation of flower induction in Pharbitis nil Journal of Plant Physiology 165 18 1917 1928 doi 10 1016 j jplph 2008 04 009 PMID 18565620 Cockshull KE Horridge JS 1978 2 Chloroethylphosphonic Acid and Flower Initiation by Chrysanthemum morifolium Ramat In Short Days and in Long Days Journal of Horticultural Science amp Biotechnology 53 2 85 90 doi 10 1080 00221589 1978 11514799 van Doorn WG June 2002 Effect of ethylene on flower abscission a survey Annals of Botany 89 6 689 93 doi 10 1093 aob mcf124 PMC 4233834 PMID 12102524 Cassells AC Gahan PB 2006 Dictionary of plant tissue culture Haworth Press p 77 ISBN 978 1 56022 919 3 Constabel F Shyluk JP 1994 1 Initiation Nutrition and Maintenance of Plant Cell and Tissue Cultures Plant Cell and Tissue Culture Springer p 5 ISBN 978 0 7923 2493 5 van Berkel N July 1987 Injurious effects of low ethylene concentrations on Chrysanthemum morifolium Ramat Acta Horticulturae 197 43 52 doi 10 17660 actahortic 1987 197 4 ISSN 0567 7572 Further reading editChang C Stadler R July 2001 Ethylene hormone receptor action in Arabidopsis BioEssays 23 7 619 627 doi 10 1002 bies 1087 PMID 11462215 S2CID 6640353 Millenaar FF van Zanten M Cox MC Pierik R Voesenek LA Peeters AJ 2009 Differential petiole growth in Arabidopsis thaliana photocontrol and hormonal regulation New Phytologist 184 1 141 152 doi 10 1111 j 1469 8137 2009 02921 x PMID 19558423 Schaller GE February 2012 Ethylene and the regulation of plant development BMC Biology published 20 February 2012 10 9 9 doi 10 1186 1741 7007 10 9 PMC 3282650 PMID 22348804 External links editInternational Chemical Safety Card 0475 Retrieved from https en wikipedia org w index php title Ethylene plant hormone amp oldid 1197074344, wikipedia, wiki, book, books, library,

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