Banana
Template:Short description {{#invoke:other uses|otheruses}} Template:Pp-semi-indef Template:Pp-move Template:Good article Template:Use mdy dates Template:Infobox botanical product A banana is an elongated, edible fruit—botanically a berry<ref name="Morton-2013"/>—produced by several kinds of large treelike herbaceous flowering plants in the genus Musa. In some countries, cooking bananas are called plantains, distinguishing them from dessert bananas. The fruit is variable in size, color and firmness, but is usually elongated and curved, with soft flesh rich in starch covered with a peel, which may have a variety of colors when ripe. It grows upward in clusters near the top of the plant. Almost all modern edible seedless (parthenocarp) cultivated bananas come from two wild species Template:NdashMusa acuminata and Musa balbisiana, or their hybrids.
Musa species are native to tropical Indomalaya and Australia; they were probably domesticated in New Guinea. They are grown in 135 countries, primarily for their fruit, and to a lesser extent to make banana paper and textiles, while some are grown as ornamental plants. The world's largest producers of bananas in 2022 were India and China, which together accounted for approximately 26% of total production. Bananas are eaten raw or cooked in recipes varying from curries to banana chips, fritters, fruit preserves, or simply baked or steamed.
Worldwide, there is no sharp distinction between dessert "bananas" and cooking "plantains": this distinction works well enough in the Americas and Europe, but it breaks down in Southeast Asia where many more kinds of bananas are grown and eaten. The term "banana" is applied also to other members of the Musa genus, such as the scarlet banana (Musa coccinea), the pink banana (Musa velutina), and the Fe'i bananas. Members of the genus Ensete, such as the snow banana (Ensete glaucum) and the economically important false banana (Ensete ventricosum) of Africa are sometimes included. Both genera are in the banana family, Musaceae.
Banana plantations can be damaged by parasitic nematodes and insect pests, and to fungal and bacterial diseases, one of the most serious being Panama disease which is caused by a Fusarium fungus. This and black sigatoka threaten the production of Cavendish bananas, the main kind eaten in the Western world, which is a triploid Musa acuminata. Plant breeders are seeking new varieties, but these are difficult to breed given that commercial varieties are seedless. To enable future breeding, banana germplasm is conserved in multiple gene banks around the world.
Description
The banana plant is the largest herbaceous flowering plant.<ref name="INIBAP-2000">Template:Cite book</ref> All the above-ground parts of a banana plant grow from a structure called a corm.Template:Sfn Plants are normally tall and fairly sturdy with a treelike appearance, but what appears to be a trunk is actually a pseudostem composed of multiple leaf-stalks (petioles). Bananas grow in a wide variety of soils, as long as it is at least Template:Convert deep, has good drainage and is not compacted.Template:Sfn They are fast-growing plants, with a growth rate of up to Template:Convert per day.<ref>Template:Cite book</ref>
The leaves of banana plants are composed of a stalk (petiole) and a blade (lamina). The base of the petiole widens to form a sheath; the tightly packed sheaths make up the pseudostem, which is all that supports the plant. The edges of the sheath meet when it is first produced, making it tubular. As new growth occurs in the centre of the pseudostem, the edges are forced apart.Template:Sfn Cultivated banana plants vary in height depending on the variety and growing conditions. Most are around Template:Convert tall, with a range from 'Dwarf Cavendish' plants at around Template:Convert to 'Gros Michel' at Template:Convert or more.<ref name="RHS-2023">Template:Cite web</ref>Template:Sfn Leaves are spirally arranged and may grow Template:Convert long and Template:Convert wide.<ref name="Morton-2013"/> When a banana plant is mature, the corm stops producing new leaves and begins to form a flower spike or inflorescence. A stem develops which grows up inside the pseudostem, carrying the immature inflorescence until eventually it emerges at the top.Template:Sfn Each pseudostem normally produces a single inflorescence, also known as the "banana heart". After fruiting, the pseudostem dies, but offshoots will normally have developed from the base, so that the plant as a whole is perennial.Template:Sfn The inflorescence contains many petal-like bracts between rows of flowers. The female flowers (which can develop into fruit) appear in rows further up the stem (closer to the leaves) from the rows of male flowers. The ovary is inferior, meaning that the tiny petals and other flower parts appear at the tip of the ovary.Template:Sfn
The banana fruits develop from the banana heart, in a large hanging cluster called a bunch, made up of around nine tiers called hands, with up to 20 fruits to a hand. A bunch can weigh Template:Convert.<ref>Template:Cite web</ref> The stalk ends of the fruits connect up to the rachis part of the inflorescence. Opposite the stalk end, is the blossom end, where the remnants of the flower deviate the texture from the rest of the flesh inside the peel.
The fruit has been described as a "leathery berry".<ref name="Smith-1977">Template:Cite book</ref> There is a protective outer layer (a peel or skin) with numerous long, thin strings (Vascular bundles), which run lengthwise between the skin and the edible inner white flesh. The peel is less palatable and usually discarded after peeling the fruit, optimally done from the blossom end, but often started from the stalk end. The inner part of the common yellow dessert variety can be split lengthwise into three sections that correspond to the inner portions of the three carpels by manually deforming the unopened fruit.<ref name="Warkentin-2004">Template:Cite web</ref> In cultivated varieties, fertile seeds are usually absent.<ref name="Simmonds-1962">Template:Cite journal</ref><ref>Template:Cite journal</ref>
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A corm, about Template:Convert across
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Young plant
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Female flowers have petals at the tip of the ovary
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'Tree' showing fruit and inflorescence
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Single row planting
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Inflorescence, partially opened
Evolution
Phylogeny
A 2011 phylogenomic analysis using nuclear genes indicates the phylogeny of some representatives of the Musaceae family. Major edible kinds of banana are shown in boldface.<ref name="Christelová-2011">Template:Cite journal</ref>
- ‡ Many cultivated bananas are hybrids of M. acuminata x M. balbisiana (not shown in tree).<ref name="hybrid"/>
Work by Li and colleagues in 2024 identifies three subspecies of M. acuminata, namely sspp. banksii, malaccensis, and zebrina, as contributing substantially to the Ban, Dh, and Ze subgenomes of triploid cultivated bananas respectively.<ref name="Li-2024">Template:Cite journal</ref>
Taxonomy
The genus Musa was created by Carl Linnaeus in 1753.<ref name="POWO">Template:Cite POWO</ref> The name may be derived from Antonius Musa, physician to the Emperor Augustus, or Linnaeus may have adapted the Arabic word for banana, mauz.<ref name="Hyam-1995">Template:Cite book</ref> The ultimate origin of musa may be in the Trans–New Guinea languages, which have words similar to "#muku"; from there the name was borrowed into the Austronesian languages and across Asia, accompanying the cultivation of the banana as it was brought to new areas, via the Dravidian languages of India, into Arabic as a Wanderwort.<ref>Template:Cite book which (p. 169) cites Template:Cite journal</ref> The word "banana" is thought to be of West African origin, possibly from the Wolof word Template:Lang, and passed into English via Spanish or Portuguese.<ref name="OnlineEtymologyDictionary">Template:Cite web</ref>
Musa is the type genus in the family Musaceae. The APG III system assigns Musaceae to the order Zingiberales, part of the commelinid clade of the monocotyledonous flowering plants. Some 85 species of Musa were recognized by Plants of the World Online Template:As of;<ref name="POWO"/> several produce edible fruit, while others are cultivated as ornamentals.<ref name="Bailey-1916">Template:Cite book</ref>
The classification of cultivated bananas has long been a problematic issue for taxonomists. Linnaeus originally placed bananas into two species based only on their uses as food: Musa sapientum for dessert bananas and Musa paradisiaca for plantains. More species names were added, but this approach proved to be inadequate for the number of cultivars in the primary center of diversity of the genus, Southeast Asia. Many of these cultivars were given names that were later discovered to be synonyms.Template:Sfn
In a series of papers published from 1947 onward, Ernest Cheesman showed that Linnaeus's Musa sapientum and Musa paradisiaca were cultivars and descendants of two wild seed-producing species, Musa acuminata and Musa balbisiana, both first described by Luigi Aloysius Colla.<ref name="Stover-1987">Template:Harvnb</ref> Cheesman recommended the abolition of Linnaeus's species in favor of reclassifying bananas according to three morphologically distinct groups of cultivars – those primarily exhibiting the botanical characteristics of Musa balbisiana, those primarily exhibiting the botanical characteristics of Musa acuminata, and those with characteristics of both.Template:Sfn Researchers Norman Simmonds and Ken Shepherd proposed a genome-based nomenclature system in 1955. This system eliminated almost all the difficulties and inconsistencies of the earlier classification of bananas based on assigning scientific names to cultivated varieties. Despite this, the original names are still recognized by some authorities, leading to confusion.<ref name="Stover-1987"/><ref name="Porcher-2002">Template:Cite web</ref>
The accepted scientific names for most groups of cultivated bananas are Musa acuminata Colla and Musa balbisiana Colla for the ancestral species, and Musa × paradisiaca L. for the hybrid of the two.<ref name="hybrid">Template:Cite POWO</ref>
An unusual feature of the genetics of the banana is that chloroplast DNA is inherited maternally, while mitochondrial DNA is inherited paternally. This facilitates taxonomic study of species and subspecies relationships.<ref name="Donohue-2010">Template:Cite journal</ref>
Informal classification
In regions such as North America and Europe, Musa fruits offered for sale can be divided into small sweet "bananas" eaten raw when ripe as a dessert, and large starchy "plantains" or cooking bananas, which do not have to be ripe. Linnaeus made this distinction when naming two "species" of Musa.Template:Sfn Members of the "plantain subgroup" of banana cultivars, most important as food in West Africa and Latin America, correspond to this description, having long pointed fruit. They are described by Ploetz et al. as "true" plantains, distinct from other cooking bananas.Template:Sfn
The cooking bananas of East Africa belong to a different group, the East African Highland bananas.Template:Sfn Further, small farmers in Colombia grow a much wider range of cultivars than large commercial plantations do,<ref name="Gibert-2009">Template:Cite journal</ref> and in Southeast Asia—the center of diversity for bananas, both wild and cultivated—the distinction between "bananas" and "plantains" does not work. Many bananas are used both raw and cooked. There are starchy cooking bananas which are smaller than those eaten raw. The range of colors, sizes and shapes is far wider than in those grown or sold in Africa, Europe or the Americas.Template:Sfn Southeast Asian languages do not make the distinction between "bananas" and "plantains" that is made in English. Thus both Cavendish dessert bananas and Saba cooking bananas are called pisang in Malaysia and Indonesia, kluai in Thailand and chuối in Vietnam.Template:Sfn Fe'i bananas, grown and eaten in the islands of the Pacific, are derived from a different wild species. Most Fe'i bananas are cooked, but Karat bananas, which are short and squat with bright red skins, are eaten raw.<ref name="Englberger-2003">Template:Cite journal</ref>
History
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Domestication
The earliest domestication of bananas (Musa spp.) was from naturally occurring parthenocarpic (seedless) individuals of Musa banksii in New Guinea. These were cultivated by Papuans before the arrival of Austronesian-speakers. Numerous phytoliths of bananas have been recovered from the Kuk Swamp archaeological site and dated to around 10,000 to 6,500 BP.<ref name="Denham2011">Template:Cite journal</ref><ref name="Perrier2009"/><ref name="Fuller2015">Template:Cite journal</ref> Foraging humans in this area began domestication in the late Pleistocene using transplantation and early cultivation methods.<ref name="Roberts-et-al-2017">Template:Cite journal</ref><ref name="Harris-Hillman-1989">Template:Cite book</ref> Various investigations<ref name="Harris-Hillman-1989" /><ref name="Roberts-et-al-2017"/> – including Denham et al., 2003 – determine that by the early to middle of the Holocene the process was complete.<ref name="Roberts-et-al-2017" />
Ancient spread
Austronesian trade routes
From New Guinea, cultivated bananas spread westward into Island Southeast Asia. They hybridized with other (possibly independently domesticated) subspecies of Musa acuminata as well as M. balbisiana in the Philippines, northern New Guinea, and possibly Halmahera. These hybridization events produced the triploid cultivars of bananas commonly grown today. From Island Southeast Asia, they became part of the staple domesticated crops of the Austronesian peoples and were spread via their ancient seaborne migrations and ancient maritime trading routes into Oceania, Africa, South Asia, and Indochina.<ref name="Perrier 2019">Template:Cite journal</ref>
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Bananas are believed to have been introduced to Africa from Southeast Asia via the Austronesian settlement of Madagascar (Template:Circa).<ref name="Power"/><ref name="Beaujard2011">Template:Cite journal</ref><ref name="Anderson2019">Template:Cite journal</ref> This is supported by relict populations of (accidentally-introduced) seeded Musa acuminata in northeastern Madagasacar and Pemba Island (off Tanzania), as well as the phenotypes of cultivated polyploid bananas, and their distribution; all of which provide the clearest evidence of a Southeast Asian origin.<ref name="Power"/><ref name="Beaujard2011"/> However, the role of Madagascar as a staging board for the dispersal of bananas (and other Asian crops) is unclear. Malagasy people colonized Madagascar from Island Southeast Asia around 600 AD onwards, but contact between East Africa and Island Southeast Asia dates back to at least 300 BC or earlier. The possibility that bananas may have been introduced from earlier Austronesian settlements in the East African coast that pre-date the settlement of Madagascar can not be ruled out.<ref>Template:Cite book</ref>
These ancient introductions resulted in the banana subgroup now known as the "true" plantains, which include the East African Highland bananas and the Pacific plantains (the Iholena and Maoli-Popo'ulu subgroups). Genetic evidence show that East African Highland bananas (AAA) originated from banana populations introduced to Africa from the region between Java, Borneo, and New Guinea. Pacific plantains (AAB), on the other hand, were introduced to the Pacific Islands from banana populations originating from either eastern New Guinea or the Bismarck Archipelago.<ref name="Denham2011"/><ref name="Perrier2009"/>
Another wave of introductions later spread domesticated polyploid bananas to other parts of tropical Asia, particularly Indochina and the Indian subcontinent.<ref name="Denham2011"/><ref name="Perrier2009">Template:Cite journal</ref>
Southeast Asia remains the region of primary diversity of the banana. Areas of secondary diversity are found in Africa, indicating a long history of banana cultivation there.Template:Sfn
Other hypotheses
21st century discoveries of alleged banana phytoliths in Uganda and Cameroon dating to the first millennium BC and earlier triggered a debate about the date of the first introduction of bananas to East Africa.<ref name="Power"/><ref name="Mbida-2000">Template:Cite journal</ref><ref name="Lejju-2005">Template:Cite journal</ref>
However, the identification of the remains in Uganda as phytoliths, much less banana phytoliths, is now considered dubious. The Cameroon phytoliths, on the other hand, are confirmed as Musa, despite early doubts that they may be from Ensete. However, the incongruous early date (all other archaeobotanical remains of bananas in Africa being from at earliest the first millennium AD) remains questionable due to the low number of phytoliths recovered (25), the absence of additional phytoliths in more recent sediments, and the possibility that the apparent date was the result of stratigraphic mixing.<ref name="Power">Template:Cite journal</ref> An introduction date of 2000 to 1000 BC is also unlikely as this was long before there were any evidence of agriculture in East Africa. Polyploid banana cultivars are sterile and do not spread without human cultivation.<ref name="Power"/>
Similarly, phytoliths recovered from the Kot Diji archaeological site in Pakistan were interpreted as evidence that bananas were known to the Indus Valley civilisation. This may indicate very early dispersal of bananas by Austronesian traders by sea from as early as 2000 BCE. But this is still putative, as they may have come from local wild Musa species used for fiber or as ornamentals, not food; and banana phytoliths are absent in other contemporary sites in South Asia.<ref name="Fuller2015"/>
Glucanase and two other proteins specific to Musaceae were found in dental calculus from the early Iron Age (12th century BCE) Philistines in Tel Erani in the southern Levant. However, the authors only tentatively identify it as Musa, as the proteins can also be found in Ensete (cultivated for their edible corms and pseudostems in Africa).<ref>Template:Cite journal</ref>
Arab Agricultural Revolution
The banana may have been present in isolated locations in the Middle East on the eve of Islam. The spread of Islam was followed by far-reaching diffusion. There are numerous references to it in Islamic texts (such as poems and hadiths) from the 9th century onwards. By the 10th century, the banana appeared in texts from Palestine and Egypt. From there, it diffused into North Africa and Al-Andalus (Islamic Spain) during the Arab Agricultural Revolution.<ref name="Watson-1974">Template:Cite journal</ref><ref name="Watson-1983"/> An article on banana tree cultivation is included in Ibn al-'Awwam's 12th-century agricultural work, Kitāb al-Filāḥa (Book on Agriculture).<ref>Template:Cite book (pp. 368–370 (Article XLVIII)</ref> During the Middle Ages, bananas from Granada were considered among the best in the Arab world.<ref name="Watson-1983">Template:Cite book</ref> Bananas were certainly grown in the Christian Kingdom of Cyprus by the late medieval period. Writing in 1458, the Italian traveller and writer Gabriele Capodilista wrote favourably of the extensive farm produce of the estates at Episkopi, near modern-day Limassol, including the area's banana plantations.<ref name="Jennings-1992">Template:Cite book</ref>
Early modern spread
Acta Eruditorum, 1734
In the early modern period, bananas were encountered by European explorers during the Magellan expedition in 1521, in both Guam and the Philippines. Lacking a name for the fruit, the ship's historian Antonio Pigafetta described them as "figs more than one palm long."<ref>Template:Cite journal</ref><ref name="Nowell-1962">Template:Cite book</ref>Template:Rp Bananas were introduced to South America by Portuguese sailors who brought them from West Africa in the 16th century.<ref name="Gibson-2012">Template:Cite web</ref> Southeast Asian banana cultivars, as well as abaca grown for fibers, were introduced to North and Central America by the Spanish from the Philippines, via the Manila galleons.<ref>Template:Cite journal</ref>
Plantation cultivation
In the 15th and 16th centuries, Portuguese colonists started banana plantations in the Atlantic Islands, Brazil, and western Africa.<ref name="Phora-sotoby.com"/> North Americans began consuming bananas on a small scale at very high prices shortly after the Civil War, though it was only in the 1880s that the food became more widespread.<ref name="Koeppel-2008">Template:Cite book</ref> As late as the Victorian Era, bananas were not widely known in Europe, although they were available.<ref name="Phora-sotoby.com">Template:Cite web</ref>
The earliest modern plantations originated in Jamaica and the related Western Caribbean Zone, including most of Central America. Plantation cultivation involved the combination of modern transportation networks of steamships and railroads with the development of refrigeration that allowed more time between harvesting and ripening. North American shippers like Lorenzo Dow Baker and Andrew Preston, the founders of the Boston Fruit Company started this process in the 1870s, with the participation of railroad builders like Minor C. Keith. Development led to the multi-national giant corporations like Chiquita and Dole.<ref name="Koeppel-2008"/> These companies were monopolistic, vertically integrated (controlling growing, processing, shipping and marketing) and usually used political manipulation to build enclave economies (internally self-sufficient, virtually tax exempt, and export-oriented, contributing little to the host economy). Their political maneuvers, which gave rise to the term banana republic for states such as Honduras and Guatemala, included working with local elites and their rivalries to influence politics or playing the international interests of the United States, especially during the Cold War, to keep the political climate favorable to their interests.<ref name="NZHerald-2008"/>
Small-scale cultivation
The vast majority of the world's bananas are cultivated for family consumption or for sale on local markets. They are grown in large quantities in India, while many other Asian and African countries host numerous small-scale banana growers who sell at least some of their crop.Template:Sfn Peasants with smallholdings of 1 to 2 acres in the Caribbean produce bananas for the world market, often alongside other crops.<ref>Clegg, Peter "The Development of the Windward Islands Banana Export Trade: Commercial Opportunity and Colonial Necessity Template:Webarchive," Society for Caribbean Studies Annual Conference Papers 1 (2000)</ref> In many tropical countries, the main cultivars produce green (unripe) bananas used for cooking. Because bananas and plantains produce fruit year-round, they provide a valuable food source during the hunger season between harvests of other crops, and are thus important for global food security.<ref name="d'Hont-2012">Template:Cite journal</ref>
Modern cultivation
Bananas are propagated asexually from offshoots. The plant is allowed to produce two shoots at a time; a larger one for immediate fruiting and a smaller "sucker" or "follower" to produce fruit in 6–8 months.Template:Sfn As a non-seasonal crop, bananas are available fresh year-round.<ref>Template:Cite web</ref> They are grown in some 135 countries.<ref>Template:Cite web</ref>
Cavendish
In global commerce in 2009, by far the most important cultivars belonged to the triploid Musa acuminata AAA group of Cavendish group bananas.<ref>Template:Cite web</ref> Disease is threatening the production of the Cavendish banana worldwide. It is unclear if any existing cultivar can replace Cavendish bananas, so various hybridisation and genetic engineering programs are attempting to create a disease-resistant, mass-market banana. One such strain that has emerged is the Taiwanese Cavendish or Formosana.<ref name="Gittleson-2018">Template:Cite news</ref><ref name="Wang-2021">Template:Cite journal</ref><ref name="Canine-2005">Template:Cite web</ref>
Ripening
Export bananas are picked green, and ripened in special rooms upon arrival in the destination country. These rooms are air-tight and filled with ethylene gas to induce ripening, which mimics the normal production of this gas as a ripening hormone.<ref name="FruitRipening">Template:Cite web</ref><ref name="ArgonneNationalLaboratory"/> Ethylene stimulates the formation of amylase, an enzyme that breaks down starch into sugar, influencing the taste. Ethylene signals the production of pectinase, a different enzyme which breaks down the pectin between the cells of the banana, causing the banana to soften as it ripens.<ref name="FruitRipening"/><ref name="ArgonneNationalLaboratory">Template:Cite web</ref> The vivid yellow color many consumers in temperate climates associate with bananas is caused by ripening around Template:Convert, and does not occur in Cavendish bananas ripened in tropical temperatures (over Template:Convert), which leaves them green.<ref name="Ding-2007">Template:Cite journal</ref><ref name="Sugianti-2024">Template:Cite journal</ref>
Storage and transport
Bananas are transported over long distances from the tropics to world markets.<ref name="Arias-2003">Template:Cite book</ref> To obtain maximum shelf life, harvest comes before the fruit is mature. The fruit requires careful handling, rapid transport to ports, cooling, and refrigerated shipping. The goal is to prevent the bananas from producing their natural ripening agent, ethylene. This technology allows storage and transport for 3–4 weeks at Template:Convert. On arrival, bananas are held at about Template:Convert and treated with a low concentration of ethylene. After a few days, the fruit begins to ripen and is distributed for final sale. Ripe bananas can be held for a few days at home. If bananas are too green, they can be put in a brown paper bag with an apple or tomato overnight to speed up the ripening process.<ref name="Chiquita-2009">Template:Cite web</ref><ref name="Bebber-2023">Template:Cite journal</ref>
Sustainability
The excessive use of fertilizers contributes greatly to eutrophication in streams and lakes, harming aquatic life, while expanding banana production has led to deforestation. As soil nutrients are depleted, more forest is cleared for plantations. This causes soil erosion and increases the frequency of flooding.<ref name="Cohen-2009">Template:Cite web</ref>
Voluntary sustainability standards such as Rainforest Alliance and Fairtrade are being used to address some of these issues. Banana production certified in this way grew rapidly at the start of the 21st century to represent 36% of banana exports by 2016.<ref>Template:Cite report</ref> However, such standards are applied mainly in countries which focus on the export market, such as Colombia, Costa Rica, Ecuador, and Guatemala; worldwide they cover only 8–10% of production.<ref name="Voora-2023">Template:Cite web</ref>
Breeding
Edible bananas are parthenocarpic (seedless). This is important for their edibility, but the lack of seed production makes breeding difficult. Furthermore, cultivated bananas are typically triploid (less commonly diploid, and a few tetraploid). They are typically derived from the wild diploid species M. acuminata and M. balbisiana, although some originate from M. acuminata only.<ref name="jeridi">Template:Cite journal</ref> Unpaired chromosomes in triploids, homoeologous recombination between chromosomes from the two ancestral species, and failures to produce functional reproductive structures (due to selection for parthenocarpy) all combine to cause extremely low frequencies of successful seed production when attempting to breed bananas. Starting in the 1920s, "pedigree breeding" has been employed to try to generate desirable hybrids. Existing triploids are bred against diploids, sometimes wild with a desired characteristic, trying to create a tetraploid by combining a haploid gamete from the diploid parent with a (rare) unreduced triploid gamete from the other. The resulting tetraploid can then be bred against another diploid to produce triploid offspring. More recently, the "reproductive breeding" strategy treats diploids with colchicine to produce tetraploid offspring, which can then be bred against a second diploid to produce triploids.<ref>Template:Cite book</ref>
Mutation breeding can be used in this crop. Aneuploidy is a source of significant variation in allotriploid varieties. For one example, it can be a source of TR4 resistance. Lab protocols have been devised to screen for such aberrations and for possible resulting disease resistances.<ref name="Jankowicz-Cieslak-2022">Template:Cite book</ref> Wild Musa spp. provide useful resistance genetics, and are vital to breeding for TR4 resistance, as shown in introgressed resistance from wild relatives.<ref name="Ismaila-2023">Template:Cite journal</ref>
The Honduran Foundation for Agricultural Research has bred a seedless banana that is resistant to both Panama disease and black Sigatoka disease. The team made use of the fact that "seedless" varieties do rarely produce seeds; they obtained around 15 seeds from some 30,000 cultivated plants, pollinated by hand with pollen from wild Asian bananas.<ref>Template:Cite journal</ref>
Production and export
| Bananas | Plantains | Total | |
|---|---|---|---|
| Template:Flagu | 34.5 | 34.5 | |
| Template:Flagu | 11.8 | 11.8 | |
| Template:Flagu | 10.4 | 10.4 | |
| Template:Flagu | 9.2 | 9.2 | |
| Template:Flagu | 5.9 | 3.1 | 9.0 |
| Template:Flagu | 8.0 | 8.0 | |
| Template:Flagu | 6.1 | 0.9 | 6.9 |
| Template:Flagu | 6.9 | 6.9 | |
| Template:Flagu | 0.8 | 4.9 | 5.7 |
| Template:Flagu | 0.9 | 4.7 | 5.5 |
| Template:Flagu | 2.5 | 2.5 | 5.0 |
| Template:Flagu | 4.8 | 0.3 | 5.0 |
| Template:Flagu | 0.1 | 4.8 | 4.9 |
| Template:Flagu | 4.6 | 4.6 | |
| Template:Flagu | 3.5 | 0.6 | 4.1 |
| Template:Flagu | 2.2 | 0.9 | 3.1 |
| Template:Flagu | 2.5 | 0.1 | 2.6 |
| Template:Flagu | 0.5 | 2.1 | 2.6 |
| Template:Flagu | 2.6 | 2.6 | |
| Template:Flagu | 1.4 | 1.2 | 2.5 |
| Template:Flagu | 2.5 | 2.5 | |
| Template:Flagu | 2.4 | 2.4 | |
| World | 135.1 | 44.2 | 179.3 |
| Source: FAOSTAT of the United Nations<ref name="FAOSTAT-2022">Template:Cite web</ref> Note: Some countries distinguish between bananas and plantains, but four of the top six producers do not, thus necessitating comparisons using the total for bananas and plantains combined. | |||
Template:As of, bananas are exported in larger volume and to a larger value than any other fruit.<ref name="Gittleson-2018"/> In 2022, world production of bananas and plantains combined was 179 million tonnes, led by India and China with a combined total of 26% of global production. Other major producers were Uganda, Indonesia, the Philippines, Nigeria and Ecuador.<ref name="FAOSTAT-2022"/> As reported for 2013, total world exports were 20 million tonnes of bananas and 859,000 tonnes of plantains.<ref name="FAOSTAT-2017">Template:Cite web</ref> Ecuador and the Philippines were the leading exporters with 5.4 and 3.3 million tonnes, respectively, and the Dominican Republic was the leading exporter of plantains with 210,350 tonnes.<ref name="FAOSTAT-2017"/>
Pests
Bananas are damaged by a variety of pests, especially nematodes and insects.<ref name="Padmanaban-2018"/>
Nematodes
Banana roots are subject to damage from multiple species of parasitic nematodes. Radopholus similis causes nematode root rot, the most serious nematode disease of bananas in economic terms.<ref name="Sekora">Sekora, N. S. and W. T. Crow. Burrowing nematode, Radopholus similis. EENY-542. University of Florida IFAS. 2012.</ref> Root-knot is the result of infection by species of Meloidogyne,<ref>Template:Cite journal</ref> while root-lesion is caused by species of Pratylenchus,<ref name="Nyang’au-2021">Template:Cite journal</ref> and spiral nematode root damage is the result of infection by Helicotylenchus species.<ref name="Zuckerman-1963">Template:Cite journal</ref>
Insects
Among the main insect pests of banana cultivation are two beetles that cause substantial economic losses, the banana borer Cosmopolites sordidus and the banana stem weevil Odoiporus longicollis. Other significant pests include aphids and scarring beetles.<ref name="Padmanaban-2018">Template:Cite book</ref>
Diseases
Although in no danger of outright extinction, bananas of the Cavendish group, which dominate the global market, are under threat.<ref name="NewScientist-2006"/> There is a need to enrich banana biodiversity by producing diverse new banana varieties, not just focusing on the Cavendish.<ref name="Karp-2019"/> Its predecessor 'Gros Michel', discovered in the 1820s, was similarly dominant but had to be replaced after widespread infections of Panama disease. Monocropping of Cavendish similarly leaves it susceptible to disease and so threatens both commercial cultivation and small-scale subsistence farming.<ref name="NewScientist-2006">Template:Cite magazine</ref><ref name="Montpellier-2003">Template:Cite magazine</ref> Within the data gathered from the genes of hundreds of bananas, the botanist Julie Sardos has found several wild banana ancestors currently unknown to scientists, whose genes could provide a means of defense against banana crop diseases.<ref>Template:Cite news</ref>
Some commentators have remarked that those variants which could replace what much of the world considers a "typical banana" are so different that most people would not consider them the same fruit, and blame the decline of the banana on monogenetic cultivation driven by short-term commercial motives.<ref name="NZHerald-2008">Template:Cite news</ref> Overall, fungal diseases are disproportionately important to small island developing states.<ref name="Thomas-2020">Template:Cite journal</ref>
Panama disease
Panama disease is caused by a Fusarium soil fungus, which enters the plants through the roots and travels with water into the trunk and leaves, producing gels and gums that cut off the flow of water and nutrients, causing the plant to wilt, and exposing the rest of the plant to lethal amounts of sunlight. Prior to 1960, almost all commercial banana production centered on the Gros Michel cultivar, which was highly susceptible.<ref name="Barker-2008">Template:Cite journal</ref> Cavendish was chosen as the replacement for Gros Michel because, among resistant cultivars, it produces the highest quality fruit. It requires more care during shipping,<ref>Template:Cite magazine</ref> and its quality compared to Gros Michel is debated.<ref name="Lessard-1992">Template:Cite book</ref>
Fusarium wilt TR4
Fusarium wilt TR4, a reinvigorated strain of Panama disease, was discovered in 1993. This virulent form of Fusarium wilt has destroyed Cavendish plantations in several southeast Asian countries and spread to Australia and India.<ref name="Karp-2019">Template:Cite web</ref> As the soil-based fungi can easily be carried on boots, clothing, or tools, the wilt spread to the Americas despite years of preventive efforts.<ref name="Karp-2019"/> Without genetic diversity, Cavendish is highly susceptible to TR4, and the disease endangers its commercial production worldwide.<ref name="IBP-2012">Template:Cite web</ref> The only known defense to TR4 is genetic resistance.<ref name="Karp-2019"/> This is conferred either by RGA2, a gene isolated from a TR4-resistant diploid banana, or by the nematode-derived Ced9.<ref name="Dale-2017"/><ref name="ISAAA-2021"/> This may be achieved by genetic modification.<ref name="Dale-2017">Template:Cite journal</ref><ref name="ISAAA-2021">Template:Cite web</ref>
Black sigatoka
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Black sigatoka is a fungal leaf spot disease first observed in Fiji in 1963 or 1964. It is caused by the ascomycete Mycosphaerella fijiensis. The disease, also called black leaf streak, has spread to banana plantations throughout the tropics from infected banana leaves used as packing material. It affects all main cultivars of bananas and plantains (including the Cavendish cultivars<ref name="Holmes-2013">Template:Cite journal (Also at Template:Cite web)</ref>), impeding photosynthesis by blackening parts of the leaves, eventually killing the entire leaf. Starved for energy, fruit production falls by 50% or more, and the bananas that do grow ripen prematurely, making them unsuitable for export. The fungus has shown ever-increasing resistance to treatment; spraying with fungicides may be required as often as 50 times a year. Better strategies, with integrated pest management, are needed.<ref>Template:Cite journal</ref><ref name="JGI-2013">Template:Cite web</ref>
Banana bunchy top virus
Banana bunchy top virus is a plant virus of the genus Babuvirus, family Nanonviridae affecting Musa spp. (including banana, abaca, plantain and ornamental bananas) and Ensete spp. in the family Musaceae.<ref>National Biological Information Infrastructure & IUCN/SSC Invasive Species Specialist Group. Banana Bunchy Top Virus Template:Webarchive. Global Invasive Species Database. N.p., July 6, 2005.</ref> Banana bunchy top disease symptoms include dark green streaks of variable length in leaf veins, midribs and petioles. Leaves become short and stunted as the disease progresses, becoming 'bunched' at the apex of the plant. Infected plants may produce no fruit or the fruit bunch may not emerge from the pseudostem.<ref name="Thomas-2015">Thomas, J.E. (ed). 2015. MusaNet Technical Guidelines for the Safe Movement of Musa Germplasm Template:Webarchive. 3rd edition. MusaLit, Bioversity International, Rome</ref> The virus is transmitted by the banana aphid Pentalonia nigronervosa and is widespread in Southeast Asia, Asia, the Philippines, Taiwan, Oceania and parts of Africa. There is no cure, but it can be effectively controlled by the eradication of diseased plants and the use of virus-free planting material.<ref>Template:Cite web</ref> No resistant cultivars have been found, but varietal differences in susceptibility have been reported. The commercially important Cavendish subgroup is severely affected.<ref name="Thomas-2015"/>
Banana bacterial wilt
Banana bacterial wilt is a bacterial disease caused by Xanthomonas campestris pv. musacearum.<ref name="Tushemereirwe-2004">Template:Cite journal</ref> First identified on a close relative of bananas, Ensete ventricosum, in Ethiopia in the 1960s,<ref name="Bradbury-1968">Template:Cite journal</ref> The disease was first seen in Uganda in 2001 affecting all banana cultivars. Since then it has been diagnosed in Central and East Africa, including the banana growing regions of Rwanda, the Democratic Republic of the Congo, Tanzania, Kenya, Burundi, and Uganda.<ref name="Mwangi-2007">Template:Cite journal</ref>
Conservation of genetic diversity
Given the narrow range of genetic diversity present in bananas and the many threats via biotic (pests and diseases) and abiotic threats (such as drought) stress, conservation of the full spectrum of banana genetic resources is ongoing.<ref name="Genebank-2018">Template:Cite web</ref> In 2024, the economist Pascal Liu of the FAO described the impact of global warming as an "enormous threat" to the world supply of bananas.<ref name="McGrath-2024">Template:Cite news</ref>
Banana germplasm is conserved in many national and regional gene banks, and at the world's largest banana collection, the International Musa Germplasm Transit Centre, managed by Bioversity International and hosted at KU Leuven in Belgium.<ref name="BioversityInternational-2018">Template:Cite web</ref> Since Musa cultivars are mostly seedless, they are conserved by three main methods: in vivo (planted in field collections), in vitro (as plantlets in test tubes within a controlled environment), and by cryopreservation (meristems conserved in liquid nitrogen at −196 °C).<ref name="Genebank-2018"/>
Genes from wild banana species are conserved as DNA and as cryopreserved pollen.<ref name="Genebank-2018"/> Seeds from wild species are sometimes conserved, although less commonly, as they are difficult to regenerate. In addition, bananas and their crop wild relatives are conserved in situ, in the wild natural habitats where they evolved and continue to do so. Diversity is also conserved in farmers' fields where continuous cultivation, adaptation and improvement of cultivars is often carried out by small-scale farmers growing traditional local cultivars.<ref>Template:Cite web</ref>
Nutrition
A raw banana (not including the peel) is 75% water, 23% carbohydrates, 1% protein, and contains negligible fat. A reference amount of Template:Convert supplies 89 calories, 24% of the Daily Value of vitamin B6, and moderate amounts of vitamin C, manganese, potassium, and dietary fiber, with no other micronutrients in significant content (table).
Although bananas are commonly thought to contain exceptional potassium content,<ref name="Edwards-2019">Template:Cite web</ref><ref>Template:Cite news</ref> their actual potassium content is not high per typical food serving, having only 12% of the Daily Value for potassium (table). The potassium-content ranking for bananas among fruits, vegetables, legumes, and many other foods is medium.<ref name="FoodDataCentralUSDA-2023">Template:Cite web</ref>
Uses
Culinary
Fruit
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Bananas are a staple starch for many tropical populations. Depending upon cultivar and ripeness, the flesh can vary in taste from starchy to sweet, and texture from firm to mushy. Both the skin and inner part can be eaten raw or cooked. The primary component of the aroma of fresh bananas is isoamyl acetate (also known as banana oil), which, along with several other compounds such as butyl acetate and isobutyl acetate, is a significant contributor to banana flavor.<ref name="Mui-2002">Template:Cite journal "Isoamyl acetate (9.6%) imparts the characteristic aroma typical of fresh bananas (13, 17−20), while butyl acetate (8.1%) and isobutyl acetate (1.4%) are considered to be character impact compounds of banana flavor."</ref>
Plantains are eaten cooked, often as fritters.<ref>Template:Cite web</ref> Pisang goreng, bananas fried with batter, is a popular street food in Southeast Asia.<ref name="Kraig-2013">Template:Cite book</ref> Bananas feature in Philippine cuisine, with desserts like maruya banana fritters.<ref>Template:Cite web</ref> Bananas can be made into fruit preserves.<ref>Template:Cite journal</ref> Banana chips are a snack produced from sliced and fried bananas, such as in Kerala.<ref name="Pereira-2013">Template:Cite news</ref> Dried bananas are ground to make banana flour.<ref name="Coghlan-2014">Template:Cite web</ref> In Africa, matoke bananas are cooked in a sauce with meat and vegetables such as peanuts or beans to make the breakfast dish katogo.<ref>Template:Cite web</ref> In Western countries, bananas are used to make desserts such as banana bread.<ref>Template:Cite web</ref>
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Banana curry with lemon, Andhra Pradesh, India
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Pisang goreng fried banana in batter, a popular snack in Indonesia
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Banana in sweet gravy, known as pengat pisang in Malaysia
Flowers
Banana flowers (also called "banana hearts" or "banana blossoms") are used as a vegetable<ref>Template:Cite book</ref> in South Asian and Southeast Asian cuisine. The flavor resembles that of artichoke. As with artichokes, both the fleshy part of the bracts and the heart are edible.<ref>Template:Cite web See also the link on that page for Banana Flower Salad.</ref>
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Banana flowers and leaves on sale in Thailand
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Kilawin na pusô ng saging, a Filipino dish of banana flowers
Leaf
Banana leaves are large, flexible, and waterproof. While generally too tough to actually be eaten, they are often used as ecologically friendly disposable food containers or as "plates" in South Asia and several Southeast Asian countries.<ref>Template:Cite news</ref> In Indonesian cuisine, banana leaf is employed in cooking methods like pepes and botok; banana leaf packages containing food ingredients and spices are cooked in steam or in boiled water, or are grilled on charcoal. Certain types of tamales are wrapped in banana leaves instead of corn husks.<ref>Template:Cite news</ref>
When used so for steaming or grilling, the banana leaves protect the food ingredients from burning and add a subtle sweet flavor.<ref name="Morton-2013"/> In South India, it is customary to serve traditional food on a banana leaf.<ref>Template:Cite web</ref> In Tamil Nadu (India), dried banana leaves are used as to pack food and to make cups to hold liquid food items.<ref name="Kora-2019">Template:Cite journal</ref>
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Banana leaf as disposable plate for chicken satay in Java
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Nicaraguan Nacatamales, in banana leaves, ready to be steamed
Trunk
The tender core of the banana plant's trunk is also used in South Asian and Southeast Asian cuisine.<ref>Template:Cite book</ref> Examples include the Burmese dish mohinga, and the Filipino dishes inubaran and kadyos, manok, kag ubad.<ref name="Polistico-2017a">Template:Cite encyclopedia</ref><ref name="Polistico-2017b">Template:Cite encyclopedia</ref>
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Kaeng yuak, a northern Thai curry of the core of the banana plant
Paper and textiles
Template:Further Fiber harvested from the pseudostems and leaves of the abacá banana (Musa textilis) and other bananas have been used for textiles in the Philippines since ancient times. Archaeological evidence of cloth-weaving tools like spindle whorls date back to the period between 1000 BC and 500 AD in the Philippines. However, the tropical environment and the sparsity of pre-colonial records makes it hard to trace its antiquity.<ref name=Hendrickx/><ref name="Blair">Template:Cite book</ref> Nevertheless, abacá bananas are the main source of fibers for traditional textiles still woven among various ethnic groups of the Philippines. Examples of abacá-based textiles include the t'nalak, made by the Tiboli tribe of South Cotabato, and dagmay, made by the Bagobo people.<ref>Template:Cite web</ref> Traditional abacá cloth collected from the Philippines during the Spanish colonial period is found in museum collections around the world, like the Boston Museum of Fine Arts and the Textile Museum of Canada.<ref name="acl">Template:Cite web</ref>
The oldest surviving example of textile made from banana fibers is the Banton Burial Cloth recovered from a coffin in the sacred Ipot Cave of Banton, Romblon, Philippines, and dated to around the 13th and 14th centuries.<ref name="ocampo"/><ref name="ccp">Template:Cite web</ref><ref>Template:Cite web</ref> Abacá textiles were also mentioned numerous times in Spanish colonial records in the Philippines since the 16th century, eventually acquiring the Philippine Spanish name Template:Lang (entering the contemporary English language as "medrinacks", "medrianacks", "medrianackes", and "medrinacles", among other names) and the English name "Manila hemp". Aside from indigenous clothing for native Filipinos, Template:Lang was also used during the colonial era as canvas for sails and for stiffening clothing like skirts, collars, and doublets.<ref name=Hendrickx/><ref name="Craig">Template:Cite book</ref><ref name="Castro-Baker">Template:Cite book</ref> The inner fibers are also used in the making of hats, including the "Manila hats", hammocks, matting, cordage, ropes, coarse twines, and Manila paper.<ref name="acl"/><ref>Template:Cite web</ref> By the 19th century, abacá fiber had become one of the most important economic exports of the Philippines. They were in demand due to their strength and saltwater-resistance.<ref name=worcester>Template:Cite book</ref>
Outside the Philippines, abacá was first cultivated on a large scale in Sumatra in 1925 under the Dutch, who had observed its cultivation in the Philippines for cordage since the nineteenth century, followed up by plantings in Central America in 1929 sponsored by the U.S. Department of Agriculture.<ref name="eb">Template:Cite encyclopedia</ref> It also was transplanted into India and Guam.<ref name="wood">Template:Cite book</ref>
A similar tradition of weaving banana textiles (from Musa basjoo and Musa balbisiana) also existed among the non-Han minority groups in southern China since at least the Han Dynasty (202 BCTemplate:Snd220 BC). Both fruit-bearing and fibrous banana species have been used.<ref name=Hendrickx>Template:Cite book</ref> This textile tradition along with the banana species Musa basjoo (Japanese bashō, 芭蕉) was introduced to the Ryukyu Islands of Japan at around the 14th century. In the Japanese system of kijōka-bashōfu, leaves and shoots are cut from the plant periodically to ensure softness. Harvested shoots are first boiled in lye to prepare fibers for yarn-making. These banana shoots produce fibers of varying degrees of softness, yielding yarns and textiles with differing qualities for specific uses. For example, the outermost fibers of the shoots are the coarsest, and are suitable for tablecloths, while the softest innermost fibers are desirable for kimono and kamishimo. This traditional Japanese cloth-making process requires many steps, all performed by hand.<ref>Template:Cite web</ref> Banana paper can be made either from the bark of the banana plant, mainly for artistic purposes, or from the fibers of the stem and non-usable fruits. The paper may be hand-made or industrially processed.<ref>Template:Cite book</ref>
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Abacá fibers being stripped using traditional methods in the Philippines
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Weaving looms processing Manila hemp fabric
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A modern Manila hemp bag
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Other uses
The large leaves of bananas are locally used as umbrellas.<ref name="Morton-2013">Template:Cite book</ref> Banana peel may have capability to extract heavy metal contamination from river water, similar to other purification materials.<ref>Template:Cite web</ref><ref>Template:Cite journal</ref> Waste bananas can be used to feed livestock.<ref>Template:Cite web Last updated on March 25, 2016, 10:36</ref> As with all living things, potassium-containing bananas emit radioactivity at low levels occurring naturally from the potassium-40 (K-40) isotope.<ref name="Frame-2009">Template:Cite web</ref> The banana equivalent dose of radiation was developed in 1995 as a simple teaching-tool to educate the public about the natural, small amount of K-40 radiation occurring in everyone and in common foods.<ref name="Mansfield-1995">Template:Cite web</ref><ref name="Edwards-2019"/>
Potential allergic reaction
Individuals with a latex allergy may experience a reaction to handling or eating bananas.<ref name="pollart">Template:Cite journal</ref><ref name="Taylor-2004">Template:Cite journal</ref>
Cultural roles
Arts
The Edo period poet Matsuo Bashō is named after the Japanese word 芭蕉 (Template:Lang) for the Japanese banana. The Template:Lang planted in his garden by a grateful student became a source of inspiration to his poetry, as well as a symbol of his life and home.<ref>Template:Cite book</ref>
The song "Yes! We Have No Bananas" was written by Frank Silver and Irving Cohn and originally released in 1923; for many decades, it was the best-selling sheet music in history. Since then the song has been rerecorded several times and has been particularly popular during banana shortages.<ref name="Shaw-1987">Template:Cite book</ref><ref name="oeppel-2005">Template:Cite journal</ref>
A person slipping on a banana peel has been a staple of physical comedy for generations. An American comedy recording from 1910 features a popular character of the time, "Uncle Josh", claiming to describe his own such incident.<ref>Template:Cite web</ref>
The banana's suggestively phallic shape has been exploited in artworks from Giorgio de Chirico's 1913 painting The Uncertainty of the Poet onwards. In 2019, an exhibition of Natalia LL's video and set of photographs showing a woman "sucking on a banana" at the National Museum in Warsaw was taken down and the museum's director reprimanded.<ref name="Jones-2019">Template:Cite news</ref> The cover artwork for the 1967 debut album of The Velvet Underground features a banana made by Andy Warhol. On the original vinyl LP version, the design allowed the listener to "peel" this banana to find a pink, peeled banana on the inside.<ref name="DeMain-2011">Template:Cite web</ref> In 1989, the feminist Guerilla Girls made a screenprint with two bananas, intentionally reminiscent of Warhol's, arranged to form a "0" to answer the question in the artwork, "How many works by women artists were in the Andy Warhol and Tremaine auctions at Sotheby's?".<ref>Template:Cite web</ref>
Italian artist Maurizio Cattelan created a 2019 concept art piece titled Comedian<ref>Template:Cite news</ref> involving taping a banana to a wall using silver duct tape. The piece was exhibited briefly at the Art Basel in Miami before being removed from the exhibition and eaten without permission in another artistic stunt titled Hungry Artist by New York artist David Datuna.<ref>Template:Cite news</ref>
Religion and folklore
In India, bananas serve a prominent part in many festivals and occasions of Hindus. In South Indian weddings, particularly Tamil weddings, banana trees are tied in pairs to form an arch as a blessing to the couple for a long-lasting, useful life.<ref name="Indian Mirror">Template:Cite web</ref><ref name="EarthstOriez-2017">Template:Cite web</ref>
In Thailand, it is believed that a certain type of banana plant may be inhabited by a spirit, Nang Tani, a type of ghost related to trees and similar plants that manifests itself as a young woman.<ref>Template:Cite web</ref> People often tie a length of colored satin cloth around the pseudostem of the banana plants.<ref>Template:Cite web</ref>
In Malay folklore, the ghost known as Pontianak is associated with banana plants (pokok pisang), and its spirit is said to reside in them during the day.<ref>Template:Cite web</ref>
Racial signifier
In European, British, and Australian sport, throwing a banana at a member of an opposing team has long been used as a form of racial abuse.<ref name="Mills-2016">Template:Cite web</ref><ref name="Jackson-2014">Template:Cite web</ref> The act, which was commonplace in England in the 1980s, is meant to taunt players of Black African ancestry by equating them to apes or monkeys.<ref name="Evans-2016">Template:Cite news</ref>
See also
- Corporación Bananera Nacional
- Domesticated plants and animals of Austronesia
- Orange, another fruit exported and consumed in large quantities
- United Brands Company v Commission of the European CommunitiesTemplate:Clear
References
Bibliography
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