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Musaceae

Musaceae is a family of monocotyledonous flowering plants in the order Zingiberales, consisting of three genera—Musa, Ensete, and Musella—and approximately 91 species, primarily giant herbaceous perennials native to the tropical regions of Africa, Southeast Asia, and the western Pacific.^[1] These plants are characterized by their large size, with pseudostems formed from tightly overlapping leaf sheaths that can reach heights of up to 10 meters, broad spirally arranged leaves with parallel venation and often torn margins, and terminal inflorescences bearing colorful bracts that protect unisexual flowers leading to fleshy, seed-filled berry fruits.^[2] Most genera exhibit a monocarpic growth habit, where the plant flowers once before dying, and relies on rhizomatous suckers for propagation, thriving in humid, lowland forest habitats from sea level to elevations of about 2,000 meters. Taxonomically, Musaceae was established by Antoine Laurent de Jussieu in 1789 and forms a basal lineage within Zingiberales, with genera distinguished by floral morphology such as tepal fusion, stigma shape, and inflorescence structure: Musa (about 70–80 species) features bilateral symmetry in inner tepals and is dominant in Asia and Oceania; Ensete (about 8 species) has capitate stigmas and occurs mainly in Africa; and the monotypic Musella (Musella lasiocarpa) is known from southwestern China with unique radial symmetry and persistent bracts.^[3] Native distributions reflect ancient biogeographical patterns, with Musa centered in Indo-Malesia and extending to northern Australia and the Pacific, Ensete in tropical Africa including Madagascar, and Musella restricted to montane areas in Yunnan Province, though human cultivation has spread many species worldwide.^[1] Morphologically, members of Musaceae are not true trees but the largest herbaceous plants, lacking secondary woody growth and instead developing robust underground rhizomes that store nutrients; their leaves, up to 3 meters long, provide ecological roles in shading forest floors and supporting epiphytes, while the inflorescences—often pendulous with female flowers below and male above—display adaptations like fused stamens and nectar-producing structures for pollination by birds, bats, and insects. Ecologically, these plants contribute to tropical biodiversity by stabilizing soils in humid environments and serving as pioneer species in disturbed areas, though many wild species face threats from habitat loss and hybridization with cultivated forms.^[2] Economically, Musaceae holds immense global importance, particularly through domesticated Musa hybrids like the Cavendish banana and plantains, which supply over 100 million tons annually and support food security for millions in developing regions, with cultivation dating back at least 7,000 years in New Guinea; other uses include fiber from pseudostems for textiles, leaves for thatching and wrapping, and Ensete for fermented food staples in Ethiopia. Conservation efforts focus on wild relatives to combat pests like Panama disease and maintain genetic diversity for breeding resilient varieties, underscoring the family's role in agriculture and cultural practices across the tropics.^[1]

Description

Vegetative structure

Members of the Musaceae family are large perennial monocotyledonous herbs that attain heights of up to 15 meters, exhibiting a treelike appearance despite their herbaceous nature. Unlike true trees, they lack woody trunks and instead develop pseudostems formed by the tightly overlapping basal sheaths of the leaves, which provide structural support and can reach diameters of 30-60 cm at the base. These pseudostems are unbranched and emerge from an underground corm or short rhizome, enabling rapid vertical growth in tropical conditions.^[4]^[5]^[6] The root system is rhizomatous, consisting of a compact corm that produces fibrous roots for anchorage and nutrient uptake, along with adventitious roots along the pseudostem. Vegetative propagation occurs primarily through suckers—lateral shoots arising from buds on the rhizome—which emerge near the parent plant and develop into new pseudostems, forming dense clumps that enhance resilience in disturbed habitats. This clonal growth habit allows for efficient colonization of suitable sites without reliance on seeds.^[4]^[7] Leaves are produced basally in a spiral phyllotaxy, typically numbering 10-15 per mature pseudostem, and are differentiated into a clasping sheath, an elongated petiole, and a broad blade. The blades, which can measure up to 5 meters in length and 0.5-1 meter in width in the largest species, feature a prominent midrib from which parallel lateral veins diverge, optimizing light interception and photosynthesis in shaded understory or open tropical settings. In representative species like Musa acuminata, the leaves emerge tightly rolled before unfurling, contributing to the plant's efficient resource allocation during growth.^[4]^[8]^[9]^[10] Certain species within Musaceae, notably those in the genus Musa, possess laticifers—specialized cells that produce milky latex originating from the rhizome—which exude upon tissue damage to deter herbivores and seal wounds. This adaptation provides chemical and physical defense in herbivore-rich tropical ecosystems, though it is absent in genera like Ensete.^[11]^[12]

Reproductive features

Members of the Musaceae family display a monocarpic lifecycle, in which the primary pseudostem flowers once, produces fruit, and subsequently dies, while new growth arises from offsets or suckers produced by the rhizome, ensuring the colony's persistence.^[13]^[14] The inflorescence emerges terminally from the pseudostem apex as a large, pendulous, indeterminate spike or raceme, comprising a central axis bearing successive clusters of flowers subtended and protected by large, colorful, boat-shaped bracts that are deciduous.^[13]^[15] These bracts unfold sequentially, exposing monochasial cymes of 12–20 flowers each, with female flowers typically proximal and male flowers distal in the monoecious arrangement.^[15] Flowers are zygomorphic and usually unisexual, though bisexual forms occur; the perianth consists of six petaloid tepals in two whorls of three, with the outer whorl free and the inner whorl often fused into a tube bearing five lobes plus one larger, free, petaloid posterior tepal (labellum).^[16]^[14] The androecium features six stamens, of which five are fertile with dithecous anthers and one is a staminode; the gynoecium includes an inferior, tricarpellary, syncarpous ovary that is three-locular with axile placentation and numerous anatropous ovules, a single filiform style, and a three-lobed stigma.^[15]^[14]^[13] Fruits develop as fleshy, indehiscent berries that are oblong to cylindrical, three-locular, and leathery, often elongated and banana-shaped in familiar taxa; cultivated bananas are parthenocarpic and seedless, while wild fruits contain numerous hard seeds embedded in pulp.^[13]^[15] In wild species, seeds possess a hard testa, copious endosperm and perisperm, a straight embryo, and often an aril that aids in animal-mediated dispersal.^[16] Pollination in wild Musaceae occurs primarily through bats, birds such as sunbirds or hummingbirds, or insects, with some self-pollination reported.^[13] Seed dispersal is mainly zoocorous, facilitated by animals consuming the arillate seeds or fruits.^[16]

Taxonomy

Classification history

The family Musaceae was first formally described by Antoine Laurent de Jussieu in his 1789 publication Genera Plantarum, where he established it as a distinct group based on floral and vegetative characteristics of banana-like plants.^[2] Prior to this, Carl Linnaeus had described the genus Musa in Species Plantarum in 1753, placing bananas within broader Linnaean classes, but subsequent botanists initially grouped Musaceae within the order Scitamineae alongside gingers and other monocots due to shared features like inferior ovaries and petaloid bracts.^[17] By the early 19th century, as natural classification systems advanced, Musaceae was recognized as a separate family within the emerging order Zingiberales, reflecting its unique combination of herbaceous growth and large inflorescences.^[18] During the 19th and early 20th centuries, taxonomic revisions focused on the genus Musa, with John Gilbert Baker providing a seminal synopsis in 1893 that organized species into informal groups based on seed morphology, inflorescence structure, and geographic distribution, laying the groundwork for sectional divisions. Baker's work highlighted the diversity within Musa, including wild and cultivated forms, but treated Ensete species as part of Musa. In the mid-20th century, E.E. Cheesman further refined this in a series of papers from 1947 to 1949, elevating Ensete to generic status due to its strictly monocarpic habit, functional male flowers, and seed differences, while dividing Musa into four sections (Eumusa, Rhodochlamys, Callimusa, and Australimusa) primarily on chromosome number and floral traits.^[19] These revisions resolved much of the confusion arising from hybridization and polyploidy in cultivated bananas but left some infrageneric boundaries tentative. The advent of molecular phylogenetics in the 1990s transformed understanding of Musaceae's position, confirming its basal placement within Zingiberales through analyses of chloroplast and nuclear DNA sequences. Studies such as those by Kress et al. (2001) integrated morphological and molecular data to support Musaceae as the earliest-diverging family in the order, sister to the clade comprising the remaining seven families of Zingiberales, evidenced by shared synapomorphies like inferior ovaries and raphide crystals but distinct inflorescence evolution.^[20] This phylogeny underscored the ancient divergence of Musaceae around the early Eocene, aligning with fossil evidence of tropical monocot radiations. Subsequent multi-gene analyses, including those using exon capture, have reinforced these relationships with high bootstrap support, resolving earlier uncertainties in rooting the order.^[21] Debates on generic boundaries persisted into the late 20th and early 21st centuries, particularly regarding monotypic or aberrant taxa. For instance, the Chinese species formerly classified as Musa lasiocarpa had the genus Musella established for it in 1978 by C.Y. Wu ex H.W. Li, based on its unique compact inflorescence, persistent bracts forming a "lotus-like" structure, and molecular distinctiveness from Musa and Ensete; this classification was adopted in the 2001 Flora of China, marking a refinement in recognizing three genera within the family.^[22] These adjustments, driven by combined morphological and phylogenetic evidence, continue to inform ongoing taxonomic stability in Musaceae.^[23]

Genera and species

The Musaceae family comprises three recognized genera: Musa, Ensete, and Musella, encompassing approximately 94 accepted species according to current taxonomic assessments.^[2] These genera are distinguished by morphological traits such as inflorescence structure, bract coloration, and fruit characteristics, with most wild species being diploids (2n ≈ 20–22) and cultivated forms often polyploid due to hybridization and selection.^[24] Infrageneric classifications align with phylogenetic analyses supporting the Angiosperm Phylogeny Group IV framework for the Zingiberales order.^[25] The largest genus, Musa, includes about 85 species, many of which are wild progenitors of edible bananas, native primarily to Southeast Asia and the Pacific.^[26] It is divided into two main sections based on chromosome number, inflorescence type, and geographic distribution: section Musa (2n = 22; incorporating the former section Rhodochlamys), featuring wild diploids such as M. acuminata and M. balbisiana, which are key to domestication, and ornamental species with brightly colored bracts; and section Callimusa (2n = 20; incorporating the former sections Australimusa and Callimusa), with species from Pacific islands, northern Australia, and Asia.^[17] Cultivated bananas, including AAA (e.g., Cavendish), AAB, and ABB (e.g., plantains) cultivars, originate from hybridizations between M. acuminata (A genome) and M. balbisiana (B genome), resulting in sterile triploid (3n = 33) or higher polyploid forms propagated vegetatively.^[27] Ensete consists of around 8 species, often termed false bananas, characterized by herbaceous growth and robust pseudostems.^[28] The most notable, E. ventricosum, is cultivated in Ethiopia for its edible pseudostem and corm, which are processed into fermented starch products like kocho, providing a staple food for millions despite inedible fruits.^[29] Musella is monotypic, represented solely by M. lasiocarpa, the golden lotus banana, a low-growing herbaceous shrub (up to 1.5 m tall) endemic to southwestern China and northern Vietnam, prized for its persistent yellow bracts forming a lotus-like inflorescence that persists for months.^[30]^[31] Overall, wild Musaceae species are predominantly diploid, while polyploidy in cultivation enhances vigor and seedlessness but limits genetic diversity.^[32]

Distribution and ecology

Geographic range

The Musaceae family is native to the paleotropics, encompassing tropical and subtropical regions of Southeast Asia, tropical Africa, Madagascar, northern Australia, and Pacific islands. The genus Musa originated in northern Indo-Burma during the early Eocene and diversified starting in the late Eocene, serving as a primary center of diversity in the Indo-Malesian region. Ensete species are concentrated in tropical Africa, with a notable hotspot in the Ethiopian highlands where domestication has occurred, while a single species, Ensete perrieri, is endemic to Madagascar.^[33]^[34]^[35]^[36] Diversity within Musaceae is highest for Musa in Malesia and New Guinea, where the genus exhibits its greatest species richness and morphological variation, reflecting the region's role as a diversification hub. Ensete shows elevated endemism in East Africa, particularly around Ethiopia, supporting local agroecosystems. The monotypic genus Musella is strictly endemic to the mountainous regions of Yunnan Province in southwestern China. Approximately 90-100 wild species occur naturally across these paleotropical areas as of 2025, underscoring the family's biogeographic concentration.^[37]^[38]^[39]^[13]^[2] Through human cultivation, Musaceae have been introduced worldwide, achieving a pantropical distribution in plantations and gardens. Bananas (Musa spp.) reached the Americas in the 16th century via Portuguese traders from West Africa, establishing commercial production across Latin America and the Caribbean. Today, cultivated forms dominate tropical agriculture globally, far exceeding native ranges, though wild populations remain confined to paleotropical origins.^[40]^[41] Biogeographically, Musaceae exhibit disjunct distributions between Asian and African lineages, attributable to ancient dispersal events following their Eocene origin in Southeast Asia, rather than direct vicariance from Gondwanan fragmentation. These patterns highlight the family's adaptation to humid tropical environments across fragmented paleotropical landmasses, with subsequent human-mediated spread amplifying its global presence.^[33]^[18]

Habitat and interactions

Members of the Musaceae family thrive in humid tropical lowlands at elevations typically ranging from sea level to 1500 meters, where they favor well-drained soils rich in organic matter and cannot tolerate frost or prolonged dry periods.^[42]^[43] These conditions support their growth as large herbaceous perennials, with some species extending to higher elevations up to 2000 meters in suitable microhabitats.^[42] In natural settings, Musaceae plants often occupy understory positions in evergreen broad-leaved rainforests or more open savanna woodlands, where juvenile stages exhibit notable shade tolerance that facilitates establishment beneath taller vegetation.^[33]^[44] Ecologically, Musaceae serve as keystone species by providing abundant fruit resources that sustain frugivorous animals, including fruit bats and birds, thereby supporting biodiversity in tropical forest understories.^[45] Their large pseudostems and broad leaves offer structural habitat for epiphytes in forest ecosystems. Additionally, the family's extensive rhizomatous root systems contribute to soil stabilization by binding substrates and preventing erosion in humid, sloping terrains. Key biotic interactions include pollination primarily by bats, such as the long-tongued fruit bat (Macroglossus sobrinus) and flying foxes, alongside birds like sunbirds (Arachnothera longirostris), which visit flowers during peak nectar production periods at dawn, midday, and night.^[46] Seed dispersal occurs mainly through mammals, with bats like Cynopterus sphinx acting as primary agents by carrying seeds over distances of 100–1000 meters, while rodents such as Rattus tanezumi contribute to secondary dispersal or predation depending on habitat density.^[47] However, Musaceae are vulnerable to fungal pathogens, notably Fusarium oxysporum f. sp. cubense tropical race 4, which spreads rapidly in monoculture plantations due to reduced genetic diversity and persistent soil survival.^[48] Symbiotic relationships further enhance their adaptation to nutrient-poor soils, particularly through arbuscular mycorrhizal fungi (AMF) associations that improve phosphorus and other mineral uptake.^[49] Species like Glomus etunicatum and Glomus intraradices colonize roots effectively, boosting growth and nutrient efficiency in low-fertility conditions common to tropical understories.^[49] These symbioses underscore the family's role in nutrient cycling within diverse forest ecosystems.

Uses and cultivation

Economic and food uses

Musaceae, particularly species in the genus Musa, represent one of the world's leading fruit crops by production volume, with global output of bananas and plantains reaching approximately 140 million metric tons in 2023, primarily from tropical regions in Asia, Africa, and Latin America.^[50] This scale underscores their economic importance as a staple food and export commodity, supporting livelihoods for millions of smallholder farmers and contributing significantly to international trade, with annual exports around 20 million tons.^[51] Edible bananas derive mainly from hybrids of Musa acuminata and Musa balbisiana, including dessert varieties consumed fresh and plantains that are typically cooked or processed into dishes such as chips, porridges, or baked goods.^[52] These parthenocarpic fruits are seedless, enhancing their palatability and ease of consumption worldwide.^[53] In addition to the fruits, pseudostems and leaves serve as animal fodder, providing nutritional value for livestock in farming systems.^[54] A related staple in Ethiopia is Ensete ventricosum, where the fermented pseudostem and corm are processed into kocho bread, a key carbohydrate source sustaining over 20 million people in highland regions.^[55] Nutritionally, bananas and plantains are valued for their high potassium content—around 422 mg per medium fruit—along with significant levels of vitamins A and C, supporting heart health, immune function, and vision.^[56] These attributes make them an accessible, nutrient-dense food in diets across developing countries. Cultivation of Musaceae relies on vegetative propagation using suckers or tissue-cultured plantlets to maintain desirable traits, requiring annual rainfall of 2000–2500 mm and well-drained, fertile soils for optimal growth.^[57] Harvest typically occurs 9–12 months after planting, when fruit bunches reach maturity, allowing for year-round production in suitable climates.^[52]

Ornamental and medicinal applications

Several species within the Musaceae family are prized for ornamental purposes due to their striking foliage, colorful bracts, and overall tropical aesthetic in gardens and landscapes. Musa ornata, for instance, is widely cultivated for its handsome, upright leaves and pinkish inflorescences, making it suitable for mixed tropical plantings and as a focal point in warm-climate gardens.^[58] Similarly, Musa coccinea is valued for its brilliant red bracts and compact growth, often grown for cut flowers or as an accent plant in humid, shaded environments.^[44] These species enhance biodiversity in ornamental settings without producing edible fruit, emphasizing their decorative role over utility. Beyond aesthetics, Musaceae contribute to industrial applications through fiber extraction. Abaca (Musa textilis), primarily grown in the Philippines, yields Manila hemp from its leaf sheaths—a durable natural fiber renowned for its strength and resistance to saltwater degradation. This fiber is processed into ropes, specialty papers (such as tea bags and currency notes), and textiles, supporting a significant export industry.^[59]^[60] In traditional medicine, various parts of Musaceae plants exhibit therapeutic potential. Banana inflorescences (Musa spp.) are employed in Ayurvedic practices to treat ulcers, owing to their antiulcerogenic compounds that promote mucosal healing.^[61] Banana peels, rich in phenolic antioxidants and carotenoids, offer protective effects against oxidative stress and inflammation, supporting their use in remedies for related ailments.^[62] Additional non-food uses highlight the cultural and practical versatility of Musaceae. Banana leaves serve as eco-friendly wrappers in cooking, imparting subtle flavors to steamed or grilled foods in Southeast Asian and South Indian cuisines. In Hindu rituals, such as ancestral offerings, banana leaves are laid out to hold food during ceremonies, symbolizing purity and abundance.^[63] These applications underscore the family's role in sustainable and traditional practices worldwide.

Conservation

Threats and challenges

Musaceae species, particularly wild relatives of cultivated bananas, face significant threats from habitat loss driven by deforestation and agricultural expansion in tropical regions. In Southeast Asia and the Pacific, where many wild Musa species are endemic, deforestation for logging, palm oil plantations, and shifting cultivation has led to substantial declines in suitable habitats, with reports indicating that tropical forest cover in these areas has decreased significantly since 2000, with Southeast Asia losing approximately 12% of its forest cover between 2000 and 2020.^[64]^[65]^[36]^[66] In Papua New Guinea, wild banana populations are at risk from ongoing deforestation and fires, which could result in the loss of genetic diversity essential for breeding disease-resistant cultivars. Similarly, in India and Madagascar, habitat fragmentation due to forest clearance threatens endemic species such as Musa indandamanensis and the critically endangered Musa itinerans var. itinerans.^[65]^[36]^[66] Climate change poses additional challenges by altering rainfall patterns, increasing drought frequency, and intensifying extreme weather events like cyclones, which damage banana plantations and wild populations. Rising temperatures and erratic precipitation are projected to reduce suitable growing areas for bananas, with one study estimating a global decrease of 19% by 2050 under climate change scenarios.^[67] Cyclones causing leaf shedding that impairs photosynthesis and fruit development. Drought stress, compounded by climate variability, further limits water availability for Musaceae species, which are highly sensitive to soil moisture deficits, leading to reduced yields and heightened susceptibility to pests. In Ethiopia, land conversion for agriculture has contributed to the decline of wild Ensete ventricosum populations, a staple crop relative, through overexploitation of natural stands for food and fiber.^[68]^[69] Pests and diseases represent a major anthropogenic threat, with fungal pathogens severely impacting both cultivated and wild Musaceae. Panama disease, caused by the Fusarium oxysporum f. sp. cubense Tropical Race 4 (TR4), has devastated Cavendish banana plantations, the dominant export variety comprising about 40-50% of global production, leading to complete yield losses in affected fields across Asia, Australia, and Latin America since its emergence in the 1990s. Black Sigatoka, induced by Mycosphaerella fijiensis, causes up to 50% yield reductions through leaf necrosis and premature ripening, affecting over 80% of banana-producing areas worldwide and requiring intensive fungicide applications that strain resources for smallholder farmers. These diseases exploit the genetic uniformity of commercial clones, amplifying their spread in monoculture systems.^[70]^[71]^[72] Overexploitation through collection of wild Musa species for breeding programs and local use further endangers populations, particularly in biodiversity hotspots like India and Vietnam, where wild bananas are harvested for genetic material to combat diseases in cultivars. Genetic erosion arises from the heavy reliance on a few susceptible clones in commercial cultivation, reducing overall diversity and increasing vulnerability to pests, as seen in the near-extinction of the Gros Michel variety due to earlier Panama disease strains. In introduced ranges, such as Hawaii, some Musaceae species exhibit invasive tendencies, outcompeting native flora and complicating conservation efforts. According to IUCN assessments, over 20 Musaceae species are classified as vulnerable or endangered, with examples including the critically endangered Musa kattuvazhana in India's Western Ghats and Musa rubinea in China, primarily due to these combined threats.^[73]^[74]^[72]^[75]^[76]

Protection efforts

Protection efforts for Musaceae focus on both in situ and ex situ strategies to preserve biodiversity and promote sustainable cultivation. In situ conservation protects wild populations within their natural habitats, such as in Gunung Halimun Salak National Park in Indonesia, where diverse wild Musa acuminata accessions exhibit morphological variation and resistance to Fusarium oxysporum f. sp. cubense tropical race 4, contributing to ecosystem resilience.^[77] In Ethiopia, field genebanks maintained by the Institute of Biodiversity Conservation and Research safeguard Ensete ventricosum landraces, which have recalcitrant seeds unsuitable for orthodox storage, ensuring on-farm diversity for food security.^[78] Ex situ conservation complements these efforts through centralized collections, notably the International Musa Germplasm Transit Centre (ITC) in Belgium, which holds over 1,500 accessions of edible and wild Musa species in vitro and cryopreserved conditions to facilitate safe global exchange.^[79] CGIAR breeding programs, such as those at the International Institute of Tropical Agriculture (IITA), develop disease-resistant varieties by incorporating traits from wild relatives, enhancing resilience against threats like Fusarium wilt.^[80] Sustainable agricultural practices further support long-term protection by minimizing environmental impacts. Integrated pest management (IPM) in banana production systems, including cultural and biological controls, has reduced pesticide use by up to 65% in regions like the French West Indies while maintaining yields.^[81] Agroforestry systems integrate bananas with shade trees, such as in organic plantations, to improve soil health, biodiversity, and carbon sequestration.^[82] Policy frameworks and research advancements guide these initiatives. The Convention on Biological Diversity (CBD) targets emphasize conserving crop wild relatives like Musa species to bolster food security, with global strategies promoting complementary in situ and ex situ approaches.^[83] Genomic sequencing, including the 2012 draft genome of Musa acuminata, enables marker-assisted breeding for resilient varieties by identifying key genetic loci. Recent 2024 research highlights the need for expanded genebanks and habitat protection for wild Musa relatives to preserve biodiversity essential for future breeding.^[84]^[85] Success stories demonstrate practical outcomes, such as in Malawi, where tissue culture propagation produced disease-free plantlets, reviving banana farming in areas devastated by banana bunchy top virus and restoring livelihoods for smallholders.^[86]

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Feb 1, 2016 · The banana family originated and diversified during the early Eocene in northern Indo-Burma. In a time span of < 10 Ma after the origin of the ...
[37]
Musella lasiocarpa (Franch.) C.Y.Wu ex H.W.Li
The native range of this species is China (W. & S. Yunnan, S. Guizhou) to N. Vietnam. It is a herbaceous shrub and grows primarily in the subtropical biome.
[38]
(PDF) The Dispersal of Bananas (Musa spp.) to the Americas in the ...
Nov 13, 2022 · ... The expansion of the plantains and bananas (Musa spp.) in the Neotropics occurred during the 16th and early 17th centuries, from both the ...
[39]
Musa Balbisiana - an overview | ScienceDirect Topics
Musaceae is a small family comprises on six genera (Strelitzia, Ravenala, Musa, Orchidantha, Ensete and Heliconia) and 130 species whereas some phanerogamists ...
[40]
[PDF] Musa species (bananas and plantains) - Growables
Infection occurs through roots and progresses to the pseudostem. Symptoms are internal stem necrosis. (reddish or reddish-brown xylem), root and rhizome rot,.
[41]
Musa velutina H. Wendl. & Drude
Habitat, Occur in forests, woodlands, savanna, shrublands, inland, elevation range between 0 – 1500m. Cultivation, Propagate by seeds, suckers or division ...
[42]
ENH-568/ST409: Musa spp.: Banana - University of Florida
Growing best on fertile, moist soil, bananas will thrive in full sun or partial shade and should be protected from both wind and cold.
[43]
Seasonal variation in food availability and relative importance of ...
Apr 15, 2019 · Through their feeding interactions with plants, many fruit bat species provide vital ecosystem services and are, therefore, regarded as keystone ...
[44]
Musa acuminata Colla (Musaceae) from Tripura, Northeast India
Jan 23, 2018 · The most specialized species compensate for their lack of access to earth soil with devices and mechanisms that in the case of nutrition ...Missing: stabilization | Show results with:stabilization
[45]
Ornithophilous and Chiropterophilous Pollination in Musa itinerans ...
Jun 1, 2002 · It was found that both long-tongued fruit bats (Macroglossus sobrinus) and sunbirds (Arachnothera longirostris) were effective pollinators of M.
[46]
Spatial and temporal effects on seed dispersal and seed predation ...
Aug 6, 2025 · This study was conducted to analyze animal-seed interactions and their effects on the seed fate of a wild banana species (Musa acuminata) in ...
[47]
The Advance of Fusarium Wilt Tropical Race 4 in Musaceae of Latin ...
Race 4 of the fungus poses significantly high risks to the world supply of Musaceae since it can directly affect the production of bananas and plantains. In Foc ...
[48]
(PDF) Benefits and potential use of Arbuscular Mycorrhizal Fungi ...
Oct 12, 2025 · Some AMF species appear to be better than others with regard to their effects on banana growth, nutrient uptake and control of root damage by ...
[49]
Banana Production by Country (2023) - Voronoi
Jun 24, 2025 · According to Food and Agriculture Organization of the United Nations (FAO) statistics, worldwide banana production totaled 139.637 million ...
[50]
Bananas | Markets and Trade
World banana trade has recorded comparatively high levels of around 20 million tonnes per annum in recent years. Key drivers of trade include supply growth in ...
[51]
All About Bananas | Producers, Where They're Grown & Why They ...
Bananas are grown in more than 150 countries, and 105 million tonnes of fruit are produced each year.<|control11|><|separator|>
[52]
Banana & Plantain - International Institute of Tropical Agriculture (IITA)
Musa are rich in vitamin C, B6, minerals and dietary fibre. They are also a rich energy source, with carbohydrates accounting for 22% and 32% of fruit weight ...<|separator|>
[53]
Banana | Land & Water
The time from planting to shooting (vegetative) is about 7 to 9 months, but with lower temperatures at higher altitudes or in the subtropics, up to 18 months.
[54]
Microbial and Physicochemical Dynamics of Kocho, Fermented ...
Oct 19, 2023 · Over 20 million Ethiopians depend on enset (Ensete ventricosum) as a staple or costaple food. “Kocho,” “Bulla,” and “Amicho” are the three main ...
[55]
Bananas Nutrition Facts and Possible Health Benefits - Healthline
Bananas are high in potassium , a mineral that promotes heart health and normal blood pressure. One medium-sized banana contains around 422 mg of potassium.Nutrition · Vitamins and minerals · Health benefits
[56]
https://www.healthline.com/nutrition/foods/bananas
[57]
Musa ornata - Plant Finder - Missouri Botanical Garden
Uses. In St. Louis, bananas are grown for ornamental purposes. Fruit rarely appears. Whether grown outdoors in the landscape or indoors as a houseplant ...
[58]
Musa textilis - View crop
USES It is grown as a fiber crop. The fiber was once used for marine cordage because of its durability in salt water. Demand for the fiber as a pulp product has ...Missing: production | Show results with:production
[59]
Sequencing and de Novo Assembly of Abaca (Musa textilis Née) var ...
Aug 2, 2021 · Abaca is considered to be the strongest of all the natural fibers and has been largely used for the production of cordage, textile and paper ...
[60]
Cancer Preventive and Therapeutic Potential of Banana and Its ...
Jul 7, 2021 · Banana possesses numerous pharmacological activities, such as antioxidant, immunomodulatory, antimicrobial, antiulcerogenic, hypolipidemic, ...Missing: inflorescence Ayurveda
[61]
Banana (Musa spp) from peel to pulp: ethnopharmacology, source ...
Feb 3, 2015 · Banana's pulp and peel can be used as natural sources of antioxidants and pro-vitamin A due to their contents in carotenoids, phenolics, and amine compounds.
[62]
Sacred Leftovers: Hosting and Eating after the Ancestors
Feb 1, 2024 · On the floor before the altar, my mother laid a large banana leaf from the trees in the garden. In the center, she piled a mound of cooked rice.
[63]
Wild Bananas from Papua New Guinea Boost Food Security for All
Jan 28, 2021 · However, these potential saviors of the world's most popular fruit are themselves at risk from deforestation and habitat loss, which is why ...
[64]
Musa indandamanensis L. J. Singh: A New Species (Musaceae ...
Aug 5, 2025 · Conservation efforts are urgently needed for the endangered species M. paramjitiana and M. indandamanensis for utilization (Singh, 2014) ...<|control11|><|separator|>
[65]
Climate crisis threatens the banana, the world's most popular fruit ...
May 12, 2025 · They are sensitive to storms, which can cause a banana plant to shed leaves, making it much harder for the crop to photosynthesize. While there ...
[66]
How climate change could affect production of the world's favorite ...
Sep 8, 2025 · According to the study, climate change and other associated factors may significantly limit the production of export bananas in the future.
[67]
A Perspective Review on Understanding Drought Stress Tolerance ...
Banana production is also hugely affected by the complex biotic and abiotic stresses around the globe [5], including drought, low soil fertility, heat, and ...
[68]
Enset‐based agricultural systems in Ethiopia: A systematic review of ...
Jan 3, 2020 · Here, we review historical production data to show that the area of land under enset production in Ethiopia has reportedly increased 46% in two ...
[69]
Editorial: Fusarium Wilt of Banana, a Recurring Threat to Global ...
Dec 11, 2020 · TR4 affects Cavendish cultivars grown in large scale export-oriented plantations and confronts major banana companies with a recurrent disease ...
[70]
Black Sigatoka, an Important Disease of Banana
Jan 1, 2001 · Black Sigatoka, which is also known as black leaf streak, causes significant reductions in leaf area, yield losses of 50% or more, and premature ripening.
[71]
https://www.apsnet.org/edcenter/apsnetfeatures/Pages/BlackSigatoka.aspx
[72]
Brief overview of diversity of wild Indian Musaceae | Request PDF
Aug 5, 2025 · A total of ca. 37 wild taxa of Musaceae have been reported to occur in these regions (Sabu et al., 2016) . Recently, new taxa have been ...
[73]
Genetic diversity and structure of Musa balbisiana populations in ...
Jun 23, 2021 · In this study, we for the first time quantify the genetic variation in Vietnamese populations of the banana crop wild relative Musa balbisiana.Taxon Sampling · Genetic Structure · Fig 4. Isolation By Distance...<|separator|>
[74]
Conservation status assessment of banana crop wild relatives using ...
Feb 4, 2021 · Here, we construct a dataset on the distribution of wild banana species (Musa spp.) and assess their risk and conservation status.
[75]
Musa kattuvazhana (Musaceae): Rediscovery and additional notes ...
Jul 26, 2021 · Musa kattuvazhana (Musaceae): Rediscovery and additional notes on a critically endangered species from Western Ghats of Tamil Nadu, India.
[76]
(PDF) The Diversity of Wild Musa acuminata Originated from Mount ...
Aug 6, 2025 · Gunung Halimun-Salak National Park is one of the tropical forest which has richness and diversity of its flora. Wild Musa acuminata is ...
[77]
(PDF) Ethiopian Crop Gene Bank - ResearchGate
May 12, 2025 · The Ethiopian Gene Bank (seed storage facility) holds over 85,000 accessions of 201 crop species. As crops with recalcitrant seeds cannot be ...
[78]
International Musa Germplasm Transit Centre
The collection, which contains more than 1,700 accessions of edible and wild species of banana, is hosted at KU Leuven, Belgium. · The ITC collection is also ...
[79]
Improving the prospects for breeding better bananas - CGIAR
Jan 18, 2021 · The main goal for banana breeders is to improve resistance to pests and diseases by crossing resistant wild varieties with productive cultivated ...
[80]
Integrated pest management approaches developed in the french ...
Different approaches based on IPM have been developed in the French West Indies in banana cultivation and have led to a 65% decrease in pesticide use over the ...
[81]
Banana Production Systems: Identification of Alternative Systems for ...
The organic agroforestry banana production system is characterized by small farm size, diversity of crop and tree species, the use of organic fertilizers, low ...
[82]
[PDF] Global Conservation Strategy for Musa (Banana and Plantain)
Mar 8, 2006 · A proposal is under development to coordinate conservation efforts using complementary in situ and ex situ mechanisms. 4.4 Use of genetic ...
[83]
The banana (Musa acuminata) genome and the evolution ... - Nature
Jul 11, 2012 · Here we describe the draft sequence of the 523-megabase genome of a Musa acuminata doubled-haploid genotype, providing a crucial stepping-stone for genetic ...
[84]
Private-Sector Agripreneur Spurs Banana Revival in Malawi - CNFA
Oct 9, 2020 · Banana bunchy top virus (BBTV) caused significant loss. A farmer used tissue culture to produce BBTV-free plantlets, and a lab was established ...