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Accessory fruit

From Wikipedia, the free encyclopedia
(Redirected from Anthocarp)
A selection of accessory fruits (from left to right: pear, fig, and strawberry)

An accessory fruit is a fruit that contains tissue derived from plant parts other than the ovary. In other words, the flesh of the fruit develops not from the floral ovary, but from some adjacent tissue exterior to the carpel (for example, from receptacles or sepal). As a general rule, the accessory fruit is a combination of several floral organs, including the ovary. In contrast, true fruit forms exclusively from the ovary of the flower.[1]

Accessory fruits are usually indehiscent, meaning that they do not split open to release seeds when they have reached maturity.[2]

Incorporated organs

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The following are examples of accessory fruits listed by the plant organ from which the accessory tissue is derived:[3]

Accessory Fruit Organs
Organ Fruit
Hypanthium apple, pear, rose hip
Involucre pineapple
Peduncle cashew apple
Perianth anthocarps of the Nyctaginaceae
Receptacle fig, mulberry, pineapple, strawberry
Calyx eastern teaberry, rose apple

Fruit with fleshy seeds, such as pomegranate or mamoncillo, are not considered to be accessory fruits.[4]

Examples

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Apples and pears

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Apple section, showing seeds plus papery expression of the ovary, surrounded by tissue formed from ripening of the hypanthium.

The part of apples and pears that is consumed is, in fact, the hypanthium. The ovary is the papery core that surrounds the apple seeds. As the hypanthium ripens it forms the edible tissues.[5]

Roses

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For roses, the hypanthium is the tissue that composes the edible part of rosehips. Roses and apples are both members of the Rosaceae family; the fact that they have similar fruit morphology is a major consideration in placing them in the same taxonomic family.[5]

Strawberries

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On this strawberry, the many pips located on the surface have germinated in a phenomenon known as vivipary. The pips of the strawberry are its true fruit.

The edible part of the strawberry is formed, as part of the ripening process, from the receptacle of the strawberry flower. The true fruits (hence, containing the seeds) are the roughly 200 pips (which are, technically, achenes, a true fruit that contains a single seed from a single ovary). These pips dot the exterior of the strawberry.[6]

Cashew apple

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The cashew 'apple' and its attached drupe, which contains the edible seed.

The cashew apple is an oval- or pear-shaped structure that develops from the pedicel and the receptacle of the cashew flower and is technically called a hypocarpium.[7][8][9] It ripens into a yellow or red structure about 5–11 cm (2–4+14 in) long.[10][8] The true fruit of the cashew tree is a kidney–shaped drupe that grows at the end of the cashew apple; the seed inside this drupe is the cashew nut of commerce.[10]

Pineapple

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Pineapple in flower

The pineapple is formed when 50 to 200 unpollinated flowers coalesce in a spiral arrangement— the flowers form individually and then fuse as a single 'multiple fruit'. The ovaries develop into berries and the fruit forms around an intercalary spike. The intercalary inflorescence (cluster of flowers) results when the terminal cluster of flowers are left behind by the growth of the main axis of the plant. Each polygonal area on the pineapple's surface is an individual flower.[11]

Research

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Current research has proposed that a single class of genes may be responsible for regulating accessory fruit formation and ripening.[12] A study using strawberries concluded that hormone signaling pathways involving gibberellic acid and auxin affect gene expression, and contribute to the initiation of accessory fruit development.[6] Metabolic modifications in different developing accessory fruit tissues are due to the varied distributions of compounds such as triterpenoids and steroids.[13]

See also

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References

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  1. ^ Esau, K. 1977. Anatomy of seed plants. John Wiley and Sons, New York.
  2. ^ "Glossary Details – The William & Lynda Steere Herbarium". sweetgum.nybg.org. Retrieved 2021-03-17.
  3. ^ Merriam Webster Collegiate Dictionary entries for syconium, accessory fruit, core, and strawberry, Merriam-Webster, Inc., 2006
  4. ^ Holland, D.; Hatib, K.; Bar-Ya'akov, I. (2009), "Pomegranate: Botany, Horticulture, Breeding", Horticultural Reviews, John Wiley & Sons, Ltd, pp. 127–191, doi:10.1002/9780470593776.ch2, ISBN 978-0-470-59377-6, retrieved 2021-11-28
  5. ^ a b Michaels, Tom; Clark, Matt; Hoover, Emily; Irish, Laura; Smith, Alan; Tepe, Emily (2022-06-20). "8.1 Fruit Morphology". The Science of Plants.
  6. ^ a b Zhou, Junhui; Sittmann, John; Guo, Lei; Xiao, Yuwei; Huang, Xiaolong; Pulapaka, Anuhya; Liu, Zhongchi (March 2021). "Gibberellin and auxin signaling genes RGA1 and ARF8 repress accessory fruit initiation in diploid strawberry". Plant Physiology. 185 (3): 1059–1075. doi:10.1093/plphys/kiaa087. PMC 8133647. PMID 33793929.
  7. ^ Varghese, T.; Pundir, Y. (1964). "Anatomy of the pseudocarp in Anacardium occidentale L.". Proceedings of the Indian Academy of Sciences, Section B. 59 (5): 252–258. doi:10.1007/BF03052341. S2CID 83230755.
  8. ^ a b James A Duke (1983). "Anacardium occidentale L." Handbook of Energy Crops. (unpublished); In: NewCROP, New Crop Resource Online Program, Center for New Crops and Plant Products, Purdue University. Retrieved 10 December 2019.
  9. ^ "Cashew". Encyclopedia Britannica. 7 April 2020. Retrieved 8 May 2021.
  10. ^ a b Morton, Julia F. (1987). Cashew apple, Anacardium occidentale L. Center for New Crops and Plant Products, Department of Horticulture and Landscape Architecture, Purdue University. pp. 239–240. ISBN 978-0-9610184-1-2. Archived from the original on 15 March 2007. Retrieved 18 March 2007.
  11. ^ "Plant Details – Information about Ananas comosus Plant". efloraofgandhinagar.in. Retrieved 2023-03-18.
  12. ^ Ireland, Hilary; Yao, Jia-Long; Tomes, Sumathi; Sutherland, Paul; Nieuwenhuizen, Niels; Gunaseelan, Kularajathevan; Winz, Robert; David, Karine; Schaffer, Robert (13 December 2012). "Apple SEPALLATA1/2-like genes control fruit flesh development and ripening". The Plant Journal. 73 (6): 1004–1056. doi:10.1111/tpj.12094. PMID 23236986.
  13. ^ Dashbaldan, Soyol; Rogowska, Agata; Pączkowski, Cezary; Szakiel, Anna (25 August 2021). "Distribution of Triterpenoids and Steroids in Developing Rugosa Rose (Rosarugosa Thunb.) Accessory Fruit". Molecules. 26 (17): 5158. doi:10.3390/molecules26175158. PMC 8433923. PMID 34500591.