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Bambuseae
Bambuseae
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Bambuseae
Bambusa textilis
Scientific classification Edit this classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Monocots
Clade: Commelinids
Order: Poales
Family: Poaceae
Subfamily: Bambusoideae
Tribe: Bambuseae
Kunth ex Dumort. (1829)
Genera

68, see text

Synonyms[1]
  • Arthrostylidieae E. Camus (1913)
  • Baccifereae E. Camus (1913, nom. inval.)
  • Chusqueae E. Camus (1913)
  • Hickelieae A. Camus (1935, nom. inval.)
  • Oxytenanthereae Tzvelev (1987)

The Bambuseae are the most diverse tribe of bamboos in the grass family (Poaceae). They consist of woody species from tropical regions, including some giant bamboos. Their sister group are the small herbaceous bamboos from the tropics in tribe Olyreae, while the temperate woody bamboos (Arundinarieae) are more distantly related. The Bambuseae fall into two clades, corresponding to species from the Neotropics (subtribes Arthrostylidiinae, Chusqueinae, and Guaduinae) and from the Paleotropics (subtribes Bambusinae, Hickeliinae, Melocanninae, and Racemobambosinae).[2]

Subtribes and genera

[edit]

The 73 genera are placed in eleven subtribes:[1]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Bambuseae

View on Grokipedia
from Grokipedia
Bambuseae is a tribe of the bamboo subfamily Bambusoideae within the grass family , one of three tribes alongside the temperate woody Arundinarieae and herbaceous tropical Olyreae, encompassing tropical woody bamboos that include approximately 78 genera and 1,065 species (as of 2025). These , rhizomatous plants range from shrubs to arborescent forms with woody culms up to 30 meters tall, featuring hollow internodes and complex branching patterns. The tribe is distinguished by its two-phase vegetative development, lignified culms, and pseudospikelet inflorescences that often exhibit gregarious monocarpy, where populations flower synchronously after decades or even centuries before dying. Taxonomically, Bambuseae is divided into paleotropical () and neotropical () clades, reflecting its evolutionary divergence in tropical habitats. Native to tropical and subtropical regions across , , the , , and the Pacific islands, species of Bambuseae are most diverse in and the . Ecologically, they form dense stands in forests and grasslands, providing and , while economically, many genera such as Bambusa and Guadua are vital for construction, furniture, and food production globally.

Taxonomy

Phylogenetic Position

Bambuseae is one of the three main tribes within the subfamily Bambusoideae of the grass family , alongside Arundinarieae (temperate woody bamboos) and Olyreae (herbaceous bamboos). This placement reflects the division of Bambusoideae into distinct woody and herbaceous lineages, with Bambuseae encompassing the tropical woody bamboos. Molecular phylogenetic analyses have established a relationship between Bambuseae and Olyreae, supported by chloroplast DNA markers and multi-gene studies. For instance, a multi-gene analysis confirmed this structure, resolving Bambuseae as non-monophyletic when including temperate bamboos, which were later segregated into Arundinarieae. Subsequent work in 2017 using genome-wide RAD sequencing further corroborated these relationships, emphasizing the deep divergence within woody bamboos. Within Bambuseae, phylogenetic evidence divides the tribe into two primary clades: a Neotropical clade and a Paleotropical clade. The Neotropical clade includes lineages adapted to the , while the Paleotropical clade comprises tropical species, reflecting biogeographic patterns of diversification. The tribe was historically established in by Kunth ex Dumortier in their analysis of families. Bambuseae represents the most diverse tribe, comprising approximately 79 genera and around 1,058 species, predominantly in tropical regions.

Subtribes

The tribe Bambuseae is classified into 11 subtribes, reflecting a division into two major phylogenetic : the Neotropical and the Paleotropical , as supported by molecular and morphological analyses. This structure was formalized in the 2017 worldwide phylogenetic classification of , which integrated and nuclear data to delineate subtribal boundaries. Key diagnostic traits across subtribes include variations in morphology (predominantly sympodial pachymorph types) and structures, such as iterauctant pseudospikelets in many Paleotropical groups or determinate racemes in specialized forms. The Neotropical subtribes (as of 2017) encompass Arthrostylidiinae (15 genera, 185 species), characterized by clambering culms and open pseudospikelet inflorescences adapted to forest understories; Chusqueinae (1 genus, 175 species), distinguished by solid internodes and ebracteate pseudospikelets; and Guaduinae (5 genera, 53 species, including ), featuring thick-walled culms and suprafoliar branching. These subtribes exhibit leptomorph to pachymorph transitions, facilitating clonal spread in diverse montane and lowland habitats. Paleotropical subtribes (as of 2017) include Bambusinae (17 genera, 324 species, including Bambusa), marked by large-diameter culms and elongated pseudospikelets in iterauctant inflorescences; Dinochloinae (7 genera, 56 species), with robust forms; Greslaniinae (1 genus, 2 species), specialized cold-tolerant forms adapted via compact growth and reduced leaf sclerenchyma for higher elevations; Hickeliinae (African/Madagascan, 9 genera, 32 species), notable for adaxial midrib projections and scattered distribution; Melocanninae (Indo-Malesian, 9 genera, 99 species), identified by S-shaped leaf keels and glabrous ovaries; Racemobambosinae (Southeast Asian, 3 genera, 31 species), defined by racemose inflorescences and slender, scandent culms; Holttumochloinae (3 genera, 6 species), comprising understory specialists with multiple nodal buds and limited species diversity; and Temburongiinae (1 genus, 1 species). These groupings highlight evolutionary adaptations to tropical climates, with rhizome variations enabling rapid colonization in fragmented landscapes.

Genera

The tribe Bambuseae comprises approximately 79 genera, representing the bulk of woody bamboo diversity with around 1,058 species primarily distributed in tropical and subtropical regions. These genera exhibit a wide range of growth forms, from giant timber bamboos to scrambling vines, and are classified across 11 subtribes based on molecular and morphological evidence. Significant diversity occurs in the Paleotropics, particularly , and the Neotropics, where subtribes such as Arthrostylidiinae, Chusqueinae, and Guaduinae collectively encompass about 21 genera endemic to the . Among the most economically important genera is Bambusa, which includes around 100 species of giant clumping bamboos native to , , and the Pacific, valued for , furniture, and edible shoots. Dendrocalamus, with over 70 species of large-timber bamboos predominantly in , is widely utilized for building materials, paper production, and as a food source due to its fast growth and straight culms reaching up to 30 meters. In the Neotropics, stands out with approximately 30 species, known for its thick-walled culms used in , scaffolding, and bioengineering projects like housing in and . Chusquea, the largest genus with about 150 species of scrambling or vine-like bamboos mainly in the from to , plays key ecological roles in understories and provides materials for crafts and fuel. Recent taxonomic discoveries continue to expand the known diversity within Bambuseae; for instance, rushunii, a new species from Province, , was described in 2025, characterized by culms 8-10 meters tall and slightly zigzag basal parts, adding to the genus's representation in subtropical . Two genera remain within the tribe, including certain African forms with uncertain subtribal affinities, such as representatives exhibiting ambiguous morphological traits that challenge current phylogenetic placements.

Description

Vegetative Morphology

Bambuseae species are woody bamboos characterized by their robust, tree-like and structural reinforcements including silica bodies in the leaf epidermis, which contribute to mechanical support and durability. These tropical and subtropical members of the family exhibit a clumping growth form, distinguishing them from the running habits of temperate bamboos in other tribes. Silica phytoliths, often saddle-shaped or dumbbell-shaped, accumulate in the foliar tissues, enhancing rigidity and resistance to herbivory. The culms, or stems, of Bambuseae are woody, hollow cylinders segmented by prominent nodes, enabling rapid elongation and structural integrity. Culm heights vary widely but can reach up to 30 m in giant species such as , with basal diameters ranging from 10 to 30 cm; for example, achieves 5-10 cm diameters and 30 m heights with thick walls. Internodes between nodes are typically straight and glabrous, often covered in a waxy bloom for protection. These adaptations support the erect or arching posture typical of the tribe. Rhizomes in Bambuseae are primarily pachymorph, featuring short, thick, sympodial structures that promote clumping growth and dense stands, in contrast to the long, running leptomorph rhizomes of temperate bamboos. This rhizome type, with its curved, segments, facilitates to fewer but larger culms, suiting the tropical environments where the tribe predominates. Foliage leaves feature linear to lanceolate blades measuring 5-30 cm in , with distinct membranous ligules at the sheath-blade junction and often well-developed auricles—ear-like projections—that may bear marginal setae. Culm leaves differ, being persistent and sheath-dominated, while branching patterns involve intravaginal above the nodal line, typically producing 3 or more branches per node in tropical forms, with a dominant central axis and lateral subordinates.

Reproductive Morphology

The reproductive morphology of Bambuseae, the largest tribe within the woody bamboo subfamily Bambusoideae, is characterized by adaptations that reflect their tropical diversification and infrequent flowering events. Flowers are typically bisexual and wind-pollinated, enclosed within spikelets that form part of complex inflorescences, while fruits are dry caryopses often dispersed passively or by vertebrates in species with fleshy variants. These structures support the tribe's gregarious, monocarpic flowering strategy, where entire populations synchronize reproduction after long vegetative phases, ensuring establishment in competitive environments. Inflorescences in Bambuseae are highly variable and often terminal on specialized branches, ranging from paniculate or racemose arrangements to more condensed forms, with many taxa featuring pseudospikelets—clusters of spikelets that mimic single spikelets due to prolonged development and protective bracts. For instance, in subtribe Racemobambosinae, inflorescences are racemose with simple spikelets, facilitating exposure in habitats. In contrast, Chusqueinae exhibit spike-like, capitate inflorescences with condensed branching and 1–2-flowered spikelets per node, adapted to neotropical understories. Pseudospikelets are prevalent in Paleotropical subtribes like Bambusinae, where they elongate progressively with multiple florets emerging over time. Arthrostylidiinae show elongated pseudospikelets in loose, open panicles, allowing for extended flowering periods in diverse American habitats. These variations underscore the tribe's evolutionary flexibility in reproductive display. Flower structure follows the typical grass pattern but with subtribe-specific modifications: each floret is bisexual, comprising 3 membranous lodicules that aid , 6 stamens (ranging from 2–3 in some neotropical groups to 15–120 in Melocanninae), and an with 3 (rarely 2) plumose stigmas for capturing . The is superior, ovoid to globose, and often features a basal or hairy apex in subtribes like Racemobambosinae and some Bambusinae, potentially aiding retention or dispersal. Spikelets are 1- to many-flowered, with 2–several glumes; rachilla extension is absent in Chusqueinae but present in others, influencing floret packing. These features promote self-compatibility, though via wind or occurs in some . Fruits are indehiscent caryopses, typically globose, , or oblong, with a linear hilum nearly as long as the ; pericarp fusion to the coat is firm, and embryos are small relative to the . In several subtribes, including Guaduinae and Melocanninae, fruits develop fleshy or berry-like exteriors (baccate), attracting birds and mammals for dispersal, as seen in sarcocarpa or Melocanna baccifera; otherwise, dispersal relies on gravity or water in basic dry forms. Seed viability is generally high post-flowering, supporting rapid population recovery. Flowering in Bambuseae is predominantly gregarious and monocarpic, with individuals or populations dying after set, and cycles spanning 30–120 years in many , though some exhibit shorter intervals of 15–60 years or sporadic patterns. This behavior synchronizes massive production, overwhelming seed predators and enabling , as documented in across subtribes like Bambusinae (e.g., , ~50-year cycles) and Chusqueinae (e.g., Chusquea culeou, ~30 years). Environmental cues, including stress or , likely trigger these events, though precise mechanisms remain under study.

Distribution and Habitat

Global Distribution

Bambuseae, the tribe of tropical woody bamboos within the subfamily Bambusoideae, exhibits a distribution, with native ranges spanning , , , , and , though absent from and . The tribe is phylogenetically divided into two primary clades—the paleotropical lineage encompassing taxa and the neotropical lineage restricted to the —reflecting distinct evolutionary histories shaped by geographic isolation. This clade structure underscores the tribe's bimodal distribution pattern, with no overlap between the two groups in native habitats. Asia serves as the primary center of diversity for Bambuseae, hosting the majority of paleotropical species, estimated at around 500, with hotspots in (over 200 species), (approximately 100 species), and Southeast Asian countries such as , , and . Subtribes like Bambusinae and Dendrocalaminae dominate here, featuring genera such as , Dendrocalamus, and Gigantochloa, many of which display high ; for instance, over 90% of species in Bambusinae are confined to , contributing to the region's unparalleled bamboo richness. In contrast, the neotropical clade accounts for roughly 400 species across 23 genera, primarily in the Andean cordilleras and Amazonian lowlands of , including countries like (over 150 species), , and , where subtribes such as Chusqueinae and Guaduinae predominate. Distribution in Africa remains sparse, with approximately 50 species largely attributable to the subtribe Hickeliinae, which is concentrated in (around 33 species across genera like Cathariostachys and Hickelia, nearly all endemic to the island's eastern rainforests) and extending marginally to the , , and eastern . Mainland supports only a handful of Bambuseae , such as those in Oxytenanthera, restricted to highland regions in and . harbors limited native diversity, with approximately 40 , primarily in genera like Cephalostachyum and Schizostachyum, occurring in and , reflecting peripheral extensions of the paleotropical clade. in the neotropics is moderate, with about 40% of unique to the , often tied to montane habitats. Beyond native ranges, Bambuseae has been extensively introduced through human cultivation, establishing populations in non-native regions worldwide. Genera like Bambusa and Dendrocalamus are commonly grown in Australia, southern Europe, and North America (particularly the southeastern United States and California), where they adapt to Mediterranean and subtropical climates for ornamental, economic, and erosion-control purposes. These introductions, dating back to the 19th century, have led to naturalized stands without significant invasive impacts in most cases. Phylogenetic studies indicate that the historical dispersal of Bambuseae likely involved Gondwanan vicariance during the to early , followed by subsequent long-distance dispersal events that facilitated transoceanic colonization, such as from to around 32–38 million years ago. This pattern aligns with estimates from plastid phylogenies, highlighting a combination of ancient and more recent propagule exchanges via avian or oceanic vectors.

Ecological Preferences

Bambuseae species predominantly thrive in tropical to subtropical climates, characterized by annual rainfall ranging from 1,200 to 4,000 mm and temperatures between 8°C and 36°C. Many exhibit tolerance to seasonal dry periods, particularly in Asian monsoonal regions where precipitation seasonality influences drought resistance. These bamboos favor habitats in the of moist tropical and subtropical forests, including lowland rainforests, riverbanks, and montane cloud forests. For instance, genera like Chusquea dominate Andean cloud forests and high-elevation grasslands up to 3,500 m, often in shaded, humid environments. They also colonize areas and disturbed sites, such as forest gaps and edges. Soil preferences include well-drained, fertile loams, sandy, or loamy types, though some genera demonstrate notable tolerance to poorer conditions. species, for example, adapt to marginal soils like clay-rich or nutrient-limited substrates while maintaining vigorous growth. The altitudinal range of Bambuseae spans from to 4,300 m, with peaking at mid-elevations in montane zones. Key adaptations include high , enabling persistence in forest understories, and rapid vegetative growth that facilitates quick of light gaps and disturbed areas.

Biology and Ecology

Growth and Reproduction

Bambuseae undergo distinct growth phases characterized by rapid culm elongation, where emerging shoots can achieve rates of up to 1 m per day in certain genera such as Dendrocalamus, driven by simultaneous expansion of multiple internodes through and elongation. This explosive growth typically occurs in the , allowing culms to reach full height—often 10–30 m—within 30–60 days, supported by stored non-structural carbohydrates in the system. Expansion occurs via sympodial pachymorph , which produce short, thick, branched that form discrete clumps typically 1–10 m in , enabling localized vegetative spread without invasive running. Reproduction in Bambuseae is predominantly vegetative, with budding and culm cuttings serving as primary propagation methods, though via seeding occurs infrequently. Flowering cycles vary by but often feature mass gregarious events every 32–120 years, as seen in and Dendrocalamus, where synchronized blooming across populations leads to widespread production followed by parental die-off in many cases. Some exhibit irregular or sporadic flowering without full gregariousness, reducing the risk of population collapse. Post-flowering output is voluminous, capable of producing millions of seeds per clump, but viability is generally low, lasting only 3–6 months, which limits natural regeneration and underscores reliance on vegetative means. The lifecycle of Bambuseae is , with individual culms maturing in 3–5 years and persisting for 5–10 years before , while full clump maturity—marked by peak culm density and size—takes 3–5 years from establishment. Environmental stressors, including and high , can trigger flowering as a response, according to physiological studies on and hormonal shifts.

Interactions with Other Organisms

Bambuseae species primarily rely on anemophily, or wind pollination, as their dominant reproductive strategy, with pollen grains dispersed by air currents to facilitate cross-pollination among distant culms. However, insect-mediated pollination also occurs, particularly in genera with more accessible inflorescences, where bees and other pollinators visit flowers, potentially supplementing wind dispersal and enhancing pollen transfer efficiency. Many genera within Bambuseae exhibit self-incompatibility mechanisms, which genetically prevent self-fertilization to promote genetic diversity, though some species like Dendrocalamus membranaceus demonstrate self-compatibility under certain conditions. Seed dispersal in Bambuseae involves a combination of biotic and abiotic agents, with birds and mammals playing key roles in endozoochory by consuming nutrient-rich fruits and excreting viable seeds away from parent plants. For instance, in the genus , species such as G. chacoensis and G. trinii attract frugivorous birds like the saffron toucanet (Baillonius bailloni), which specialize in bamboo seeds during gregarious flowering events, aiding long-distance dispersal. Mammals, including , contribute similarly by caching or transporting seeds, though they can also act as predators. dispersal, or hydrochory, is prominent along riverine habitats, where buoyant caryopses float downstream, enabling colonization of riparian zones in tropical regions. Herbivory significantly influences Bambuseae dynamics. In African and Asian tropics, elephants browse culms and foliage of species like Bambusa spp., potentially shaping stand structure through selective feeding. Fungal pathogens pose additional threats, with bamboo blight caused by Sarocladium oryzae leading to leaf necrosis and culm dieback, particularly in humid environments where spores spread via or , reducing photosynthetic capacity and stand vigor. Mutualistic relationships enhance Bambuseae resilience, including associations with nitrogen-fixing soil microbes in the that improve availability in -poor soils, as observed in Dendrocalamus sinicus plantations where bacterial communities boost N-cycling. These bamboos also provide structural habitat for epiphytes, such as ferns and orchids, which colonize culms in moist tropical forests, and support understory by offering shade and microhabitats for small vertebrates and invertebrates. In invaded ecosystems, however, some genera disrupt these balances; , introduced to non-native tropics like and , forms dense monospecific stands that outcompete native , reducing understory diversity and altering trophic interactions.

Human Uses and Conservation

Economic and Cultural Uses

Bambuseae species, particularly those with robust culms such as , are widely utilized in construction and crafts across tropical regions. In , bamboo serves as a primary material for housing, scaffolding, and furniture due to its high strength-to-weight ratio and seismic resistance, enabling the creation of durable, earthquake-resistant structures like bahareque walls and bridges. Smaller genera within Bambuseae, including Chusquea and , provide flexible culms and leaves suitable for weaving baskets, mats, and handicrafts, supporting local artisan economies in and . Several Bambuseae genera contribute to food and medicinal applications, leveraging their nutritional and therapeutic properties. Young shoots of , known as "sweet bamboo," are harvested as an in , prized for their tender texture and high yield, with the edible portion comprising about 34% of the shoot weight after processing. In traditional Asian medicine, from the subtribe Melocanninae, such as Melocanna baccifera, are used to treat fevers and respiratory ailments through decoctions of leaves and shoots, often combined with for enhanced efficacy. Industrially, Bambuseae bamboos support pulp production for and emerging sectors. Bambusa species, with their high content, are processed into pulp for high-quality manufacturing, serving as a sustainable alternative to wood in regions like and . As a feedstock, bamboo from genera like Dendrocalamus offers for bioethanol and production, with studies highlighting its potential for efficient conversion in 2020s . Recent advancements include bamboo fiber-reinforced composites for automotive and applications, reducing reliance on synthetic materials while maintaining mechanical strength. Culturally, Bambuseae species hold symbolic value in Asian traditions, often representing resilience and despite occasional misattributions. In Chinese and Vietnamese festivals, bamboo culms symbolize good fortune and are used in decorations, though "lucky bamboo" arrangements frequently employ rather than true bamboos. In South American indigenous cultures, Chusquea culeou culms form the trutruca, a ceremonial horn-like played by the people during rituals. The clumping growth habit of many tropical Bambuseae species, such as and Dendrocalamus, makes them ideal for systems, where they integrate with crops to enhance soil stability and provide shade without invasive spread. Global trade in bamboo products, including culms and processed materials from Bambuseae, supports livelihoods in producing countries like and , with annual production exceeding 30 million tons.

Conservation Status

Bambuseae species, comprising the majority of woody bamboos, confront significant threats from driven by , particularly in tropical regions. In the southwestern Amazon, genera like are increasingly vulnerable as and land conversion fragment bamboo-dominated forests, altering ecological dynamics and reducing available habitat. Overharvesting for , furniture, and other commercial purposes further depletes populations, especially in densely populated areas of where demand outpaces sustainable yields. exacerbates these pressures by disrupting synchronized flowering cycles—typically occurring every 20–120 years—which lead to mass die-offs and temporary instability, as seen in recent events affecting and regeneration. The assesses only a limited number of species, with earlier evaluations (as of 1998) listing 37 endangered woody bamboos (20 American, 16 Asian, and 1 African); broader estimates from 2004 indicate that up to 50% of the approximately 1,200 woody species may be vulnerable due to loss, though comprehensive updates remain needed as of 2025. For instance, Chusquea culeou in southern is classified as endangered due to ongoing , , and intensified fire events that hinder its recovery as a keystone understory species. Biodiversity hotspots in and , including the and Southeast Asian s, remain particularly at risk from these combined pressures. Conservation efforts emphasize in-situ protection through designated areas, such as bamboo-rich reserves in like those in and national parks in the , which safeguard diverse populations amid regional deforestation. Ex-situ strategies include collections in botanic gardens, such as those in Xishuangbanna, , and , , which preserve for rare and endemic taxa; ongoing expansions in these programs, including calls for dedicated reviews, aim to address assessment gaps. Recent discoveries, like the 2025 description of rushunii in Guangdong Province, , underscore the urgency of rapid vulnerability assessments for newly identified species in rapidly developing landscapes. Significant knowledge gaps persist, with the majority of Bambuseae species lacking comprehensive IUCN evaluations; a dedicated review program is recommended to prioritize assessments for those in shrinking habitats, as current data cover less than 2% of known woody bamboos adequately.

References

  1. https://onlinelibrary.wiley.com/doi/10.1111/jipb.13909
  2. https://floranorthamerica.org/Poaceae_tribe_Bambuseae
  3. https://bmcecolevol.biomedcentral.com/articles/10.1186/s12862-015-0321-5
  4. https://www.sciencedirect.com/science/article/abs/pii/S1055790313000626
  5. https://link.springer.com/article/10.1007/s10265-008-0192-6
  6. https://www.nature.com/articles/s41598-017-11367-x
  7. https://kelchnerlab.squarespace.com/s/BPG_BambooClassification2012.pdf
  8. https://powo.science.kew.org/
  9. https://onlinelibrary.wiley.com/doi/abs/10.1111/jse.12262
  10. http://bamboo-identification.co.uk/BWG_in_WBC_IX.pdf
  11. https://www.sciencedirect.com/science/article/pii/S2468265920300330
  12. https://www.guaduabamboo.com/blog/bamboo-genera
  13. https://edenbamboo.com/taxonomy-of-bamboo
  14. https://www.bambuturismo.com/wp-content/uploads/2016/07/Ch_1_bamboo-PUBLICADO-2015.pdf
  15. https://www.researchgate.net/publication/350615723_Diversity_distribution_and_classification_of_Neotropical_woody_bamboos_Poaceae_Bambusoideae_in_the_21st_Century
  16. https://phytokeys.pensoft.net/article/143389/
  17. http://taxondiversity.fieldofscience.com/2012/03/bambusoideae.html
  18. https://repository.si.edu/bitstream/handle/10088/7023/scb-0072.pdf
  19. https://bioresources.cnr.ncsu.edu/resources/variation-of-anatomical-characteristics-within-the-culm-of-the-three-gigantochloa-species-from-indonesia/
  20. https://www.govinfo.gov/content/pkg/GOVPUB-SI-PURL-gpo112200/pdf/GOVPUB-SI-PURL-gpo112200.pdf
  21. https://pmc.ncbi.nlm.nih.gov/articles/PMC7180196/
  22. http://www.efloras.org/florataxon.aspx?flora_id=2&taxon_id=20753
  23. http://www.scielo.org.mx/scielo.php?script=sci_arttext&pid=S2007-42982021000200198
  24. https://www.researchgate.net/publication/235946457_Bamboo_biodiversity_Africa_Madagascar_and_the_Americas
  25. https://openknowledge.fao.org/server/api/core/bitstreams/aaa5a089-4d99-411c-a922-b8015e6a5888/content
  26. https://pmc.ncbi.nlm.nih.gov/articles/PMC5499700/
  27. https://doi.org/10.1007/978-981-16-1310-4_1
  28. https://onlinelibrary.wiley.com/doi/10.1111/oik.09229
  29. https://www.tandfonline.com/doi/full/10.1080/17550874.2019.1673847
  30. https://esajournals.onlinelibrary.wiley.com/doi/10.1002/ecm.1621
  31. https://www.sciencedirect.com/science/article/pii/S2351989419304111
  32. https://pmc.ncbi.nlm.nih.gov/articles/PMC10780645/
  33. https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2019.00786/full
  34. https://www.sciencedirect.com/science/article/pii/S277313912400003X
  35. https://bioresources.cnr.ncsu.edu/resources/monopodial-and-sympodial-bamboos-grown-in-tropic-and-sub-tropic-countries-a-review/
  36. https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2020.00381/full
  37. https://www.icfre.org/UserFiles/File/Institute-FRI-2011/2014/Bamboo-Brochure_18Dec14.pdf
  38. https://www.aussiebamboo.com.au/seedlings-to-full-sized-plants-bamboos-life-cycle/
  39. https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2016.01900/full
  40. https://www.researchgate.net/publication/317227373_Breeding_system_and_pollination_of_two_closely_related_bamboo_species
  41. https://www.researchgate.net/publication/229569187_Honeybee-assisted_wind_pollination_in_bamboo_Phyllostachys_nidularia_Bambusoideae_Poaceae
  42. https://pmc.ncbi.nlm.nih.gov/articles/PMC5493747/
  43. https://www.researchgate.net/publication/267918742_Notes_on_birds_consuming_Guadua_bamboo_seeds
  44. https://www.researchgate.net/publication/227684897_Specialization_on_Guadua_Bamboo_Seeds_by_Three_Bird_Species_in_the_Atlantic_Forest_of_Argentina
  45. https://pmc.ncbi.nlm.nih.gov/articles/PMC10587390/
  46. https://www.odishabamboo.org/Bamboo/diseases-of-pests
  47. https://frienvis.nic.in/WriteReadData/UserFiles/file/Content-Page/Books/Bamboo/Diseases-of-Bamboos.pdf
  48. https://pmc.ncbi.nlm.nih.gov/articles/PMC10572720/
  49. https://www.iucngisd.org/gisd/species.php?sc=1399
  50. https://www.bbc.com/future/article/20251028-the-bamboo-buildings-that-sway-in-earthquakes
  51. https://pfaf.org/user/Plant.aspx?LatinName=Chusquea%20culeou
  52. https://tropical.theferns.info/viewtropical.php?id=Dendrocalamus%2Basper
  53. https://pmc.ncbi.nlm.nih.gov/articles/PMC4659479/
  54. https://www.sciencedirect.com/science/article/pii/S2773139124000144
  55. https://onlinelibrary.wiley.com/doi/10.1111/gcbb.13072
  56. https://advanced.onlinelibrary.wiley.com/doi/10.1002/adma.202507844
  57. https://bamboosahihai.com/bamboo/bamboo-in-asian-cultures-symbolism-and-uses/
  58. http://www.agri-synergy.com/uploads/3/0/4/1/3041271/bamboo_multipurpose_agroforestry_crop.pdf
  59. https://juglana.com/blogs/juglanas-stories/the-largest-bamboo-producing-countries-and-leading-manufacturers
  60. https://dev.humanitarianlibrary.org/sites/default/files/2014/02/Bamboo%2520diversity%2520the%2520need%2520for%2520a%2520Red%2520List%2520review.pdf
  61. https://press.un.org/en/2004/unep221.doc.htm
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