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Climacteric (botany)

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Generally, fleshy fruits can be divided into two groups based on the presence or absence of a respiratory increase at the onset of ripening. This respiratory increase—which is preceded, or accompanied, by a rise in ethylene—is called a climacteric, and there are marked differences in the development of climacteric and non-climacteric fruits.[1] Climacteric fruit can be either monocots or dicots and the ripening of these fruits can still be achieved even if the fruit has been harvested at the end of their growth period (prior to ripening on the parent plant).[2] Non-climacteric fruits ripen without ethylene and respiration bursts, the ripening process is slower, and for the most part they will not be able to ripen if the fruit is not attached to the parent plant.[3] Examples of climacteric fruits include apples, bananas, melons, apricots, tomatoes, as well as most stone fruits. Non-climacteric fruits on the other hand include citrus fruits, grapes, and strawberries (However, non-climacteric melons and apricots do exist, and grapes and strawberries harbor several active ethylene receptors.) Essentially, a key difference between climacteric and non-climacteric fruits (particularly for commercial production) is that climacteric fruits continue to ripen following their harvest, whereas non-climacteric fruits do not. The accumulation of starch over the early stages of climacteric fruit development may be a key issue, as starch can be converted to sugars after harvest.[4]

Overview

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The climacteric stage of fruit ripening is associated with increased ethylene production and a rise in cellular respiration and is the final physiological process that marks the end of fruit maturation and the beginning of fruit senescence. Its defining point is a sudden rise in respiration of the fruit, and normally takes place without any external influences. After the climacteric period, respiration rates (noted by carbon dioxide production) return to or dip below the pre-climacteric rates. The climacteric event also leads to other changes in the fruit, including pigment changes and sugar release. For those fruits raised as food, the climacteric event marks the peak of edible ripeness, with fruits having the best taste and texture for consumption. After the event, fruits are more susceptible to fungal invasion and begin to degrade by cell death. If a fruit were to over-ripen, it could be detrimental to the post harvest of the fruit, meaning the shipment and storage of the fruits for marketing.[5] The over ripening could also lead to a pathogen attack, which can lead to the fruits developing diseases and exhibiting symptoms like necrosis and leaf wilting.[6]

Recent research on ethylene production and perception systems seems to show that this simple classification (fruit ripening that needs ethylene means climacteric vs. fruit ripening that does not need ethylene means non-climacteric) is not completely satisfactory: for example, there are non-climacteric varieties of melon (although almost all of them are climacteric), and grapes (classified as non-climacteric) have many ethylene-sensitive receptors, the expression of which is modulated during ripening.[7]

Ethylene production

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Ethylene is a hormone in plants known for its role in accelerating the ripening of fleshy fruits.[3] There are two systems, depending on the stage of development, for ethylene production in climacteric fruit. The first system occurs in immature climacteric fruit, where ethylene will inhibit the biosynthesis of more ethylene by a negative feedback system. This ensures that the fruit doesn't begin to undergo ripening until it is fully mature. The second system for ethylene production acts in mature climacteric fruit. In this autocatalytic system, the ethylene will promote its own biosynthesis and will make sure that the fruit will ripen evenly after the ripening begins.[8][9] In other words, a small amount of ethylene in mature, climacteric fruits, will cause a burst of ethylene production and induce even ripening.

Ethylene production begins when 1-aminocyclopropane-1-carboxylic acid (the precursor of ethylene) is formed from the amino acid methionine (Met). An adenosylated step takes place to change Met to SAM.[clarification needed] SAM is then metabolized to ACC[clarification needed] and 5ʹ-methylthioadenosine by ACC synthase. 5ʹ-methylthioadenosine is then recycled back into Met.[5] Along with the production and control of ethylene, auxin also plays a major role in climacteric fruit ripening. Auxin, a plant hormone that allows for cell elongation, is accumulated during the initial growing and developmental phases of the plants life cycle. During ethylene gene induction it was found that auxin related genes (aux/IAA and AUX1) represents the transcription factors that induce 1-MCP.[10]

Ripening includes many changes in fleshy fruit including changes in color, texture, and firmness. Additionally, there may be an increase in certain volatiles (metabolites the plant releases into the air) as well as changes in sugar (starch, sucrose, glucose, fructose, etc.) and acid (malic, citric, and ascorbic) balance. These changes, particularly in sugars, are important in determining fruit quality and sweetness.[5]

List of Climacteric and Non-climacteric Fruits

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Climacteric Fruits[11][12][13][14][15]

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  • Apples
  • Apricots
  • Avocados
  • Bananas
  • Cherimoyas
  • Cantaloupes
  • Durians
  • Guavas
  • Kiwifruits
  • Mangos
  • Papayas
  • Passion fruits
  • Pawpaws
  • Peaches (including nectarines)
  • Pears
  • Persimmons
  • Plums
  • Potatoes
  • Tomatoes

Non-climacteric Fruits[12][13][14][15]

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Some fruits can display climacteric or non-climacteric behavior depending on cultivar or genotype, and the two categories may not be able to perfectly distinguish the ripening behaviors of all fruits.[16]

References

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  1. ^ McGlasson, W. B. (1985-02-01). "Ethylene and Fruit Ripening". HortScience. 20 (1): 51–54. doi:10.21273/HORTSCI.20.1.51. ISSN 0018-5345. S2CID 87666814.
  2. ^ Paul, Vijay; Pandey, Rakesh; Srivastava, Girish C. (2012-02-11). "The fading distinctions between classical patterns of ripening in climacteric and non-climacteric fruit and the ubiquity of ethylene—An overview". Journal of Food Science and Technology. 49 (1): 1–21. doi:10.1007/s13197-011-0293-4. ISSN 0022-1155. PMC 3550874. PMID 23572821.
  3. ^ a b Capino, Annabelle; Farcuh, Macarena (2021-07-22). "Ethylene and the Regulation of Fruit Ripening". University of Maryland Extension. Archived from the original on 2022-07-05. Retrieved 2022-08-28.
  4. ^ Chervin, Christian (2020). "Should Starch Metabolism Be a Key Point of the Climacteric vs. Non-climacteric Fruit Definition?". Frontiers in Plant Science. 11: 609189. doi:10.3389/fpls.2020.609189. ISSN 1664-462X. PMC 7738325. PMID 33343608.
  5. ^ a b c Cherian, Sam; Figueroa, Carlos R.; Nair, Helen (2014-07-03). "'Movers and shakers' in the regulation of fruit ripening: a cross-dissection of climacteric versus non-climacteric fruit". Journal of Experimental Botany. 65 (17): 4705–4722. doi:10.1093/jxb/eru280. PMID 24994760. Archived from the original on 2022-08-28. Retrieved 2022-08-28.
  6. ^ "Plant Disease: Pathogens and Cycles". CropWatch. 2016-12-19. Archived from the original on 2021-05-21. Retrieved 2022-05-09.
  7. ^ Chen, Yi; Grimplet, Jérôme; David, Karine; Castellarin, Simone Diego; Terol, Javier; Wong, Darren C. J.; Luo, Zhiwei; Schaffer, Robert; Celton, Jean-Marc; Talon, Manuel; Gambetta, Gregory Alan; Chervin, Christian (November 2018). "Ethylene receptors and related proteins in climacteric and non-climacteric fruits". Plant Science. 276: 63–72. Bibcode:2018PlnSc.276...63C. doi:10.1016/j.plantsci.2018.07.012. ISSN 1873-2259. PMID 30348329. S2CID 53039693.
  8. ^ Xu, Juan; Zhang, Shuqun (2015), Wen, Chi-Kuang (ed.), "Ethylene Biosynthesis and Regulation in Plants", Ethylene in Plants, Dordrecht: Springer Netherlands, pp. 1–25, doi:10.1007/978-94-017-9484-8_1, ISBN 978-94-017-9484-8, archived from the original on 2022-08-28, retrieved 2022-08-28
  9. ^ Barry, Cornelius S.; Giovannoni, James J. (2007-06-06). "Ethylene and Fruit Ripening". Journal of Plant Growth Regulation. 26 (2): 143. doi:10.1007/s00344-007-9002-y. ISSN 0721-7595. S2CID 29519988. Archived from the original on 2022-08-28. Retrieved 2022-08-28.
  10. ^ Busatto, Nicola; Tadiello, Alice; Trainotti, Livio; Costa, Fabrizio (2017-01-02). "Climacteric ripening of apple fruit is regulated by transcriptional circuits stimulated by cross-talks between ethylene and auxin". Plant Signaling & Behavior. 12 (1): e1268312. Bibcode:2017PlSiB..12E8312B. doi:10.1080/15592324.2016.1268312. ISSN 1559-2324. PMC 5289524. PMID 27935411.
  11. ^ "All fruit and vegetables are not created equal when it comes to proper storage conditions". Food Preservation. 2019-01-23. Retrieved 2024-07-12.
  12. ^ a b "Store Fresh Garden Produce Properly". Small Farm Sustainability. Retrieved 2024-07-12.
  13. ^ a b 2012 Production Guide for Storage of Organic Fruits and Vegetables by Cornell University Cooperative Extension, NYS IPM Publication No. 10, https://ecommons.cornell.edu/server/api/core/bitstreams/d6db78d5-6156-47d8-bd21-a558fa5d80a8/content
  14. ^ a b Kitinoja, Lisa; Kader, Adel (November 2015). Small-Scale Postharvest Handling Practices: A Manual for Horticultural Crops. Postharvest Horticulture Series No. 8E (5th ed.). University of California, Davis Postharvest Technology Research and Information Center. p. 222.
  15. ^ a b Perotti, María Florencia; Posé, David; Martín-Pizarro, Carmen (2023-07-14). "Non-climacteric fruit development and ripening regulation: 'the phytohormones show'". Journal of Experimental Botany. 74 (20): 6237–6253. doi:10.1093/jxb/erad271. hdl:10261/352258. ISSN 0022-0957. PMC 10627154. PMID 37449770.
  16. ^ Paul, Vijay; Pandey, Rakesh; Srivastava, Girish C. (2012-02-11). "The fading distinctions between classical patterns of ripening in climacteric and non-climacteric fruit and the ubiquity of ethylene—An overview". Journal of Food Science and Technology. 49 (1): 1–21. doi:10.1007/s13197-011-0293-4. ISSN 0022-1155. PMC 3550874. PMID 23572821.