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Classification System: APG IV

Superregnum: Eukaryota
Regnum: Plantae
Cladus: Angiosperms
Cladus: Eudicots
Cladus: Core eudicots
Cladus: Asterids
Cladus: Lamiids
Ordo: Lamiales

Familia: Bignoniaceae
Tribus: BignonieaeCatalpeaeColeeaeCrescentieaeJacarandeaeOroxyleaeTecomeaeTourrettieae

Genera: AdenocalymmaAmphilophiumAmphitecnaAnemopaegmaArgyliaAstianthusBignoniaCallichlamysCampsidiumCampsisCatalpaCatophractesChilopsisColeaCrescentiaCuspidariaCybistaxDelostomaDeplancheaDigomphia – Dinklageodoxa – DistictellaDolichandraDolichandroneEccremocarpus – Ekmanianthe – FernandoaFridericiaGodmania – Handroanthus – Heterophragma – HierisIncarvilleaJacarandaKigelia – Lamiodendron – LundiaManaosellaMansoaMarkhamiaMartinella – Mayodendron – Millingtonia – Neojobertia – NeosepicaeaNewbouldia – Niedzwedzkia – NyctocalosOphiocoleaOroxylumPachypteraPajaneliaPandoreaParatecomaParmentiera – Pauldopia – Perianthomega – Perichlaena – PhyllarthronPhyllocteniumPleonotoma – Podranea – PyrostegiaRadermacheraRhigozumRhodocolea – Romeroa – Roseodendron – Santisukia – SparattospermaSpathodeaSphingiphila – Spirotecoma – StereospermumStizophyllumTabebuiaTanaeciumTecomaTecomantheTecomellaTourrettiaTynanthusXylophragmaZeyheria

Name

Bignoniaceae Juss. (1789), nom. cons.

Type genus: Bignonia L.

Synonyms

Crescentiaceae Dumort., Anal. Fam. Pl.: 20, 24. 1829.

References

Jussieu, A.L. de (1789) Gen. Pl. 137.
Olmstead, R.G., Zjhra, M.L., Lohmann, L.G., Grose, S.O. & Eckert, A.J. 2009. A molecular phylogeny and classification of Bignoniaceae. American Journal of Botany 96(9): 1731–1743. DOI: 10.3732/ajb.0900004 PDF Reference page.
Olmstead, R.G. (ed.) 2016. A Synoptical Classification of the Lamiales. Version 2.6.2 (in prog.). 20 pp. PDF (Internet Archive) Reference page.

Links

Govaerts, R. et al. 2019. Bignoniaceae in World Checklist of Selected Plant Families. The Board of Trustees of the Royal Botanic Gardens, Kew. Published online. Accessed: 2019 Apr. 26. Reference page.
International Plant Names Index. 2019. Bignoniaceae. Published online. Accessed: Apr. 26 2019.
The Plant List 2013. Bignoniaceae in The Plant List Version 1.1. Published online. Accessed: 2019 Apr. 26.
Tropicos.org 2019. Bignoniaceae. Missouri Botanical Garden. Published online. Accessed: 26 Apr. 2019.
USDA GRIN Taxonomy for Plants[1]

Vernacular names
العربية: بنيونية
беларуская: Бігноніевыя
বাংলা: বিগ্নোনিয়াসি
català: Bignoniàcies
čeština: Trubačovité
dansk: Trompettræ-familien
Deutsch: Trompetenbaumgewächse
Esperanto: Bignoniacoj
eesti: Bignoonialised
فارسی: پیچ‌اناریان
suomi: Bignoniakasvit
עברית: ביגנוניים
hrvatski: Katalpovke
magyar: Szivarfafélék
հայերեն: Բիգնոնիազգիներ
ქართული: ბიგნონიასებრნი
перем коми: Бигнония котыр
한국어: 능소화과
kurdî: Famîleya pelgoşaran
коми: Бигнония котыр
lietuvių: Bignonijiniai
മലയാളം: ബിഗ്നോണിയേസീ
Nederlands: Trompetboomfamilie
norsk: Trompettrefamilien
polski: Bignoniowate
پنجابی: توتنی بوٹے
Runa Simi: Waranway yura rikch'aq ayllu
română: Bignoniacee
русский: Бигнониевые
svenska: Katalpaväxter
తెలుగు: బిగ్నోనియేసి
ไทย: วงศ์แคหางค่าง
українська: Бігнонієві
oʻzbekcha/ўзбекча: Bignoniyadoshlar
Tiếng Việt: Họ Chùm ớt
中文: 紫葳科

Bignoniaceae is a family of flowering plants in the order Lamiales commonly known as the bignonias.[3] It is not known to which of the other families in the order it is most closely related.[4]

Nearly all of the Bignoniaceae are woody plants, but a few are subwoody, either as vines or subshrubs. A few more are herbaceous plants of high-elevation montane habitats, in three exclusively herbaceous genera: Tourrettia, Argylia, and Incarvillea.[5] The family includes many lianas, climbing by tendrils, by twining, or rarely, by aerial roots. The largest tribe in the family, called Bignonieae, consists mostly of lianas and is noted for its unique wood anatomy.[6]

The family has a nearly cosmopolitan distribution, but is mostly tropical, with a few species native to the temperate zones. Its greatest diversity is in northern South America.[6] The family has been covered in some major floristic projects, such as Flora of China, Flora Malesiana, and Flora Neotropica. It has not yet been covered in some others, such as Flora of Australia, and Flora of North America.

Bignoniaceae are most noted for ornamentals, such as Jacaranda, Tabebuia and Spathodea, grown for their conspicuous, tubular flowers.[7] A great many species are known in cultivation.[8] Various other uses have been made of members of this family.[9] Several species were of great importance to the indigenous peoples of the American tropics.[10] Fridericia elegans, Tanaecium bilabiata, and Tanaecium excitosum are poisonous to livestock and have caused severe losses.[10]

According to different accounts, the number of species in the family is about 810[11] or about 860.[6] The last monograph of the entire family was published in 2004.[6] In that work, 104 genera were recognized. Since that time, molecular phylogenetic studies have greatly clarified relationships within the family, and the number of accepted genera is now between 80 and 85.[12]
Bignoniaceae in Bagh-e-Jinnah, Lahore

Description
Tecoma capensis

Members of this family are mostly trees or lianas, sometimes shrubs, and rarely subshrubs or herbs.

Lianas of the tribe Bignonieae have a unique vascular structure, in which phloem arms extend downward into the xylem because certain segments of the cambium cease the production of xylem at an early stage of development. The number of these arms is four or a multiple thereof, up to 32.[13] When four, the phloem arms appear as a cross, hence, the common name "cross vine". The phloem in the arms has wider sieve tubes and less parenchyma than the ordinary phloem.[14]

The leaves are petiolate. Leaf arrangement usually is opposite, or rarely alternate or verticillate (in whorls). Leaves are usually compound, bifoliate, trifoliate, pinnate, or palmate, or rarely simple. Stipules are absent, but persistent; enlarged axillary bud scales (pseudostipules) are often present. Domatia occur in some genera.
Dolichandrone falcata in Hyderabad, India

Flowers are solitary or in inflorescences in a raceme or a helicoid or dichasial cyme. Inflorescences bear persistent or deciduous bracts or bractlets. The flowers are hypogynous, zygomorphic, bisexual, and usually conspicuous. The calyx and corolla are distinct. The calyx is synsepalous, with five sepals. The corolla is sympetalous, with five petals, often bilabiate. Corolla lobes are imbricate in bud, or rarely valvate, and usually much shorter than the corolla tube. Stamens are inserted on the corolla tube, alternating with corolla lobes. The four stamens are didynamous, members of each pair often connivent, the adaxial stamen is usually staminodial or absent; rarely with five fertile stamens or with two fertile and three staminodial stamens. The stigma is bilobed, and usually sensitive; a style is present. The ovary is superior, usually surrounded by a nectary disk, composed of two carpels, bilocular and with a septum, except unilocular in Tourrettia and quadrilocular in Eccremocarpus. Placentation is axile, except parietal in Tourrettia. Ovules are numerous.
Bignoniaceae flower, upper lip removed. Notice the didynamous 4 stamens and the style-stigma, all in dorsal position.

The fruit is usually a bivalved capsule, often with a replum. Dehiscence is septicidal or loculicidal. The three exceptions are the genera Kigelia, Crescentia and its close relatives, and Colea and its close relatives. In these, the fruit is indehiscent, not a capsule, and the seeds are not winged. The fruit is a berry in Colea. Seeds are usually flat and winged. Aril is absent. Endosperm usually absent, and sometimes sparse.[6]

Lapachol, a yellow, skin-irritating naphthoquinone, is often found in the wood. Other naphthoquinones, as well as anthraquinones, are also present in various parts of the plant. Jacaranone is a quinonoid from Jacaranda. True tannins are not present. Pigments are mostly flavones, anthocyanins, and carotenoids.[15] Iridoids are usually present.[16] Other compounds detected in Bignoniaceae include verbascosides, cornoside, quercetin, ursolic acid, saponins, and catalpic acid.

The chromosome number does not vary much in Bignoniaceae. The haploid (base chromosome number) is 20 for nearly every species sampled, but some species have very small chromosomes, making an accurate count difficult.[17] B chromosomes are common in Bignoniaceae.

Pollination is either entomophilous (via insects), ornithophilous (via birds), or cheiropterophilous (via bats).
Taxonomy

The family Bignoniaceae was first validly published in the botanical literature (as Bignonieae) by Antoine Laurent de Jussieu in 1789 in his classic work, Genera Plantarum.[18] The type genus for this family is Bignonia, which was validated by Linnaeus in Species Plantarum in 1753.[19] The name originated with Joseph Pitton de Tournefort, who named it for his benefactor, Jean-Paul Bignon, in 1694, in his influential Eléments de botanique ou méthode pour connaître les plantes.[20]

Important groundwork for future study of the family was laid down from 1789 to 1837, mostly by Jussieu, Kunth, Bojer and G.Don (George Don (1798-1856) not George Don the elder (1764-1814).[9] Bentham and Hooker surveyed the family in their Genera Plantarum in 1876.[21] Karl Moritz Schumann wrote a monograph on Bignoniaceae in 1894 for Engler and Prantl's Die Natürlichen Pflanzenfamilien. After Schumann's monograph, no taxonomic treatment of the entire family was published until 2004.[6]

As the number of known species gradually increased, a great deal of confusion developed over the delimitation of genera. New genera were frequently erected for species that did not clearly belong to any of the previously described genera. This resulted in a proliferation of monotypic genera. Gentry reduced the number of genera in 1973, 1976, and 1979.[13] Nevertheless, the revision of 2004 described 104 genera, 38 of them monotypic.[6]

This problem was especially acute in the tribe Bignonieae. In that tribe, many species of uncertain affinity were assigned to a vaguely defined Arrabidaea, turning that genus into a dumping ground of about 100 species.[13]

Since 2004, molecular phylogenetic studies have shown a substantial revision of the genera is necessary. Much work toward this goal can be viewed online,[12] but little of it has yet been published in scientific papers.

A detailed taxonomic history of Bignoniaceae was published in 1980.[9] A summary of this history was published in 1999.[22]
Classification

In the APG IV system of classification for flowering plants, Bignoniaceae is one of the 24 families in the order Lamiales. (Lamiales has 25 families if Rehmanniaceae are accepted). Within the order, Bignoniaceae is in a group of eight families consisting of Thomandersiaceae, Pedaliaceae, Martyniaceae, Schlegeliaceae, Bignoniaceae, Verbenaceae, Acanthaceae, and Lentibulariaceae.[23] This group is described as a polytomy, meaning no two of its members are known to be more closely related to each other than to any of the others.[4] Statistical support for this group remains weak, indicating insufficient data have been applied, or the group is an artifact of some phylogenetic method.

The composition of Bignoniaceae has been relatively stable and has not varied at all in the 21st century.[24] In the 20th century, the only issues of circumscription were whether Paulowniaceae and Schlegeliaceae should be merged into Bignoniaceae, or accepted as separate families.[5] The Paulowniaceae consist of one to four genera: Paulownia, Shiuyinghua, Wightia, and Brandisia.[11] Whatever their circumscription, Paulowniaceae are now known to be close to Phrymaceae and Orobanchaceae, rather than to Bignoniaceae. The family Schlegeliaceae has been included in Bignoniaceae, as tribe Schlegelieae, as recently as 1980.[9] It is now accepted as a distinct family, but its relationships with several other families remain unresolved.[3]

In molecular phylogenetic analyses, Bignoniaceae has surprisingly weak bootstrap support, given its morphological coherence. The tribe Jacarandeae (Digomphia and Jacaranda) is sister to the rest of the family, which is known as the Core Bignoniaceae. The Core Bignoniaceae is strongly supported in all molecular phylogenetic analyses, but has no known morphological synapomorphy.[5]

No subfamilies have been proposed for Bignoniaceae in recent taxonomy, but in 2004, Fischer et al. divided the family into seven tribes: Tourrettieae, Eccremocarpeae, Tecomeae (sensu lato), Bignonieae, Oroxyleae, Crescentieae, and Coleeae.[6] Since that time, Tourrettieae and Eccremocarpeae have been merged under the name Tourrettieae.[5] Tecomeae sensu lato has been shown to be polyphyletic, consisting of the following groups: Astianthus, Jacarandeae, Argylia, Delostoma, Perianthomega, Catalpeae, Tecomeae sensu stricto, and all of Crescentiina except those genera placed in Crescentieae or Coleeae. All of these groups are monophyletic except Crescentiina pro parte. The whole Crescentiina is monophyletic. Crescentiina is one of a type of name with no definite taxonomic rank.[25] Crescentiina is composed of two strongly supported clades, informally named the Tabebuia alliance and the Paleotropical clade. The tribe Crescentieae is embedded in the Tabebuia alliance and might be expanded to include Spirotecoma.[26] Coleeae sensu Fischer et al. (2004) is polyphyletic because of the inclusion of Kigelia, and it is nested within the Paleotropical clade.[27] Perianthomega has been transferred from Tecomeae sensu stricto to Bignonieae, where it is sister to the remainder of the tribe.[13] Thus, Bignoniaceae can be divided into 10 monophyletic groups.
Phylogeny

The phylogenetic tree shown below is based on the results of four phylogenetic studies.[5][13][26][27] For all clades, posterior probability is at least 0.95 and bootstrap support is at least 70%, except where indicated otherwise.

Bignoniaceae
 Jacarandeae 

Digomphia

Jacaranda

 Core Bignoniaceae 
 Tourrettieae 

Tourrettia

Eccremocarpus

Argylia

Tecomeae

Campsis

Tecoma

Incarvillea

Podranea

Lamiodendron

Deplanchea

Campsidium

Tecomanthe

Pandorea

 63 

Delostoma

 Bignonieae 

Perianthomega

Neojobertia

Adenocalymma

Stizophyllum

Manaosella

Pachyptera

Callichlamys

Tanaecium

Lundia

Xylophragma

Fridericia

Tynanthus

Cuspidaria

Dolichandra

Martinella

Pleonotoma

Bignonia

Distictella

Amphilophium

Mansoa

Pyrostegia

Anemopaegma

 Oroxyleae 

Oroxylum

Hieris

Millingtonia

Nyctocalos

 Catalpeae 

Chilopsis

Catalpa

 Crescentiina 
 Tabebuia alliance 

Sparattosperma

Ekmanianthe

Tabebuia

Cybistax

Godmania

Zeyheria

Roseodendron

Handroanthus

Spirotecoma

Parmentiera

Crescentia

Amphitecna

 Paleotropical clade 

Rhigozum

Catophractes

Spathodea

Tecomella

Radermachera

Kigelia

Stereospermum

Newbouldia

Heterophragma

Fernandoa

Dolichandrone

Markhamia

Rhodocolea

Phylloctenium

Phyllarthron

Ophiocolea

Colea




Genera

In the last taxonomic revision of Bignoniaceae, 104 genera were described in The Families and Genera of Vascular Plants. Twenty-five of these genera, all in the tribe Bignonieae, were later synonymized under other genera, based on a cladistic analysis of DNA sequences, published in 2006.[13] Roseodendron and Handroanthus were resurrected from Tabebuia in 2007.[26][28] Mayodendron and Pachyptera have been resurrected.[12]

In 2009, a phylogenetic study divided Bignoniaceae into 10 monophyletic groups, as shown in the genus list below. Six of these groups have been recognized as tribes at one time or another, and are represented by their tribal names. Two of the groups are monogeneric and are designated by their constituent genera, Argylia and Delostoma. The other two groups are given informal names, pending a formal revision of the infrafamilial classification.

Astianthus has never been sampled for DNA and its systematic position within the family remains obscure. Likewise, the placement of Romeroa in the Tabebuia alliance and the placement of Sphingiphila in Bignonieae are in doubt.

Tecomaria is not included in the list below, and its recognition is controversial. It is monotypic (Tecomaria capensis), and had been long accepted, but was returned to Tecoma in 1980.[9] A molecular phylogenetic study resolved it as sister to another South African genus, Podranea, but with only weak bootstrap support.[5] Tecomaria has not yet been resurrected or transferred to another genus.[12]

The tribe Bignonieae has been the subject of considerable revision since 2006. Fischer et al. placed 46 genera in this tribe.[6] Afterward, Perianthomega was transferred to it from Tecomeae sensu lato[13] and Pachyptera was resurrected from Mansoa. Twenty-five of the genera of Fischer have been subsumed into other genera as follows: Gardnerodoxa into Neojobertia; Memora into Adenocalymma; Leucocalantha into Pachyptera; Pseudocatalpa, Paragonia, Periarrabidaea, Spathicalyx, and Ceratophytum into Tanaecium; Arrabidaea and Piriadacus into Fridericia; Clytostoma, Cydista, Macranthisiphon, Mussatia, Phryganocydia, Potamoganos, Roentgenia and Saritaea into Bignonia; also Distictis, Glaziovia, Haplolophium, and Pithecoctenium into Amphilophium. Thus, 23 genera are now recognized in Bignonieae.[12]

Incertae sedis

Astianthus

Tribe Jacarandeae

Digomphia
Jacaranda

Tribe Tourrettieae

Eccremocarpus
Tourrettia

Genus Argylia
Tribe Tecomeae

Campsidium
Campsis
Deplanchea
Dinklageodoxa
Incarvillea
Lamiodendron
Neosepicaea
Pandorea
Podranea
Tecoma
Tecomanthe

Genus Delostoma

Tribe Bignonieae

Adenocalymma
Amphilophium
Anemopaegma
Bignonia
Callichlamys
Cuspidaria
Distictella
Dolichandra
Fridericia
Lundia
Manaosella
Mansoa
Martinella
Neojobertia
Pachyptera
Perianthomega
Pleonotoma
Pyrostegia
Sphingiphila
Stizophyllum
Tanaecium
Tynanthus
Xylophragma

Tribe Oroxyleae

Hieris
Millingtonia
Nyctcalos
Oroxylum

Tribe Catalpeae

Chilopsis
Catalpa

Crescentiina group, including the Tabebuia alliance and the Paleotropical clade.
Tabebuia alliance

Amphitecna
Crescentia
Cybistax
Ekmanianthe
Godmania
Handroanthus
Paratecoma
Parmentiera
Romeroa
Roseodendron
Sparattosperma
Spirotecoma
Tabebuia
Zeyheria

Paleotropical clade

Catophractes
Colea
Dolichandrone
Fernandoa
Haplophragma
Heterophragma
Kigelia
Markhamia
Mayodendron
Newbouldia
Ophiocolea
Pajanelia
Pauldopia
Perichlaena
Phyllarthron
Phylloctenium
Radermachera
Rhigozum
Rhodocolea
Tecomella
Santisukia
Spathodea
Stereospermum

Obsolete genera

Arrabidaea
Ceratophytum
Clytostoma
Cydista
Distictis
Gardnerodoxa
Glaziovia
Haplolophium
Leucocalantha
Macfadyena
Macranthisiphon
Melloa
Memora
Mussatia
Parabignonia
Paragonia
Periarrabidaea
Phryganocydia
Piriadacus
Pithecoctenium
Potamoganos
Pseudocatalpa
Roentgenia
Saritaea
Spathicalyx

Uses

Many species of Bignoniaceae have some use, either commercially or ethnobotanically, but the most important, by far, are those planted as ornamentals, especially the flowering trees. Jacaranda, Campsis, Pyrostegia, Tabebuia, Catalpa, Roseodendron, Handroanthus and Crescentia all have species of horticultural significance, at least in warm climates.[6][26] Several others, including Tecoma, Podranea, Pandorea, Bignonia and Mansoa are frequently grown as ornamentals, at least in certain areas of the tropics.[7] A great many species are known in cultivation, if only rarely.[8]

Jacaranda mimosifolia is common as an avenue tree. The winged petiole and trifoliate leaf of Crescentia alata resembles a crucifixion cross, so is sometimes planted in the Philippines as a religious symbol.

Handroanthus and the unrelated Guaiacum (Zygophyllaceae) have the hardest, heaviest, and most durable wood of the American tropics. Important timber trees in Handroanthus include H. heptaphyllus, H. serratifolius, H. guayacan, H. chrysanthus, and H. billbergii.[10] Tabebuia rosea (including Tabebuia pentaphylla) is harvested for lumber throughout the New World tropics.[29] Tabebuia heterophylla, and Tabebuia angustata are important sources of lumber for some of the Caribbean islands. Several species of Catalpa are also important timber trees.

Paratecoma was once the most important timber tree of the Rio de Janeiro area, but relentless exploitation has brought it to the verge of extinction.[10] Several of the rare species of Bignoniaceae produce excellent wood, but are often not recognized by lumberjacks.[29]

Several uses of plants in Bignoniaceae are known locally. Parmentiera aculeata is grown for its edible fruit in Central America and southern Mexico. The powdered seeds and sometimes the fruit pulp of Crescentia cujete and Crescentia alata are used in Nicaragua to make a refresco called semilla de jicaro. Onion-scented species of Mansoa and clove-scented species of Tynanthus are used as condiments.[6]

In northern Colombia, shavings of the stems of Dolichandra quadrivalvis are added to bait which is left overnight near the burrows of crabs. The crabs are paralyzed for a few hours after eating the bait and are picked up by crabbers in the morning. The crabs recover before they reach market, and no harm from eating them has been reported.[10]

Tanaecium nocturnum is the source of a hallucinogenic drug.[30] Its crushed leaves and stems are used to enervate bees while gathering honey.

Fridericia chica is the source of a red pigment used in the Amazon Basin for body paint and for dye in basketry.[6] Cybistax antisyphilitica is the source of a blue dye commonly used in Peru. The bark of Sparattosperma leucantha is used in Bolivia to produce a brown dye for staining cotton thread.[10]

Medical claims are innumerable and usually spurious. Gentry describes an especially ludicrous example.[10]

Misidentification of plants, even by botanists, continues to be a big problem for ethnobotany, and it is especially severe for Bignoniaceae. Voucher specimens are often sterile and fragmentary, making them nearly impossible to identify. False medical claims are often based on mistaken identification.[10]

The bark of several species of Handroanthus is sold in South American markets. Similar-looking bark is often fraudulently passed off as Handroanthus. It is used in various ways to relieve certain symptoms of certain cancers.[10] No evidence shows it prevents the disease or slows its progression, as is often claimed.

Adenocalymma flavida has been used to relieve the aching of joints and muscles. A root extract from Martinella is useful in the treatment of conjunctivitis and possibly other conditions of the eye.[31]
References

Wilf, Peter (February 2000). "Late Paleocene-early Eocene climate changes in southwestern Wyoming: Paleobotanical analysis". Geological Society of America Bulletin. 112 (2): 292–307. Bibcode:2000GSAB..112..292W. doi:10.1130/0016-7606(2000)112<0292:LPEECC>2.3.CO;2. Retrieved 15 May 2020.
Angiosperm Phylogeny Group (2009), "An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants: APG III", Botanical Journal of the Linnean Society, 161 (2): 105–121, doi:10.1111/j.1095-8339.2009.00996.x
Vernon H. Heywood, Richard K. Brummitt, Ole Seberg, and Alastair Culham. Flowering Plant Families of the World. Firefly Books: Ontario, Canada. (2007). ISBN 978-1-55407-206-4.
Peter F. Stevens (2001 onwards). "Bignoniaceae" At: Angiosperm Phylogeny Website. At: Botanical Databases At: Missouri Botanical Garden Website. (see External links below)
Olmstead, Richard G.; Zjhra, Michelle L.; Lohmann, Lúcia G.; Grose, Susan O.; Eckert, Andrew J. (2009). "A molecular phylogeny and classification of Bignoniaceae". American Journal of Botany. 96 (9): 1731–1743. doi:10.3732/ajb.0900004. PMID 21622359.
Eberhard Fischer, Inge Theisen, and Lúcia G. Lohmann. 2004. "Bignoniaceae". pages 9-38. In: Klaus Kubitzki (editor) and Joachim W. Kadereit (volume editor). The Families and Genera of Vascular Plants volume VII. Springer-Verlag: Berlin; Heidelberg, Germany. ISBN 978-3-540-40593-1
George W. Staples and Derral R. Herbst. 2005. "A Tropical Garden Flora" Bishop Museum Press: Honolulu, HI, USA. ISBN 978-1-58178-039-0
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Gentry, Alwyn H. (1980). ""Bignoniaceae: Part I (Crescentieae and Tourrettieae)". Flora Neotropica". Monograph. 25 (1): 1–130. JSTOR 4393736.
Gentry, Alwyn H. (1992). "A Synopsis of Bignoniaceae Ethnobotany and Economic Botany". Annals of the Missouri Botanical Garden. 79 (1): 53–64. doi:10.2307/2399809. JSTOR 2399809.
David J. Mabberley. 2008. Mabberley's Plant-Book third edition (2008). Cambridge University Press: UK. ISBN 978-0-521-82071-4
Lúcia G. Lohmann and Carmen U. Ulloa. 2007 onward. Bignoniaceae in iPlants prototype Checklist. (See External links below).
Lohmann, Lúcia G. (2006). "Untangling the phylogeny of neotropical lianas (Bignonieae, Bignoniaceae)". American Journal of Botany. 93 (2): 304–318. doi:10.3732/ajb.93.2.304. PMID 21646191.
Pace, Marcelo R.; Lohmann, Lúcia G.; Angyalossy, Veronica (2011). "Evolution of disparity between the regular and variant phloem in Bignonieae (Bignoniaceae)". American Journal of Botany. 98 (4): 602–618. doi:10.3732/ajb.1000269. PMID 21613161.
Robert Hegnauer. 1989. Chemotaxonomie der Pflanzen 8:128-138. Birkhäuser Verlag: Basel, Switzerland; Boston MA, USA; Berlin, Germany. ISBN 978-3-7643-1895-6
von Poser, Gilsane Lino; Schripsema, Jan; Henriques, Amélia T.; Rosendal Jensen, Soren (2000). "The distribution of iridoids in Bignoniaceae". Biochemical Systematics and Ecology. 28 (4): 351–366. doi:10.1016/s0305-1978(99)00076-9. PMID 10725592.
Goldblatt, Peter; Gentry, Alwyn H. (1979). "Cytology of Bignoniaceae". Botaniska Notiser. 132 (4): 475–482.
James L. Reveal. 2008on. "Bignoniaceae" In: A checklist of suprageneric names for extant vascular plants At: Home page of James L. Reveal & C. Rose Broome. (See External links below).
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Umberto Quattrocchi. 2000. CRC World Dictionary of Plant Names volume I. CRC Press: Boca Raton; New York; Washington, DC;, USA. London, UK. ISBN 978-0-8493-2675-2 (vol. I).
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Russell E. Spangler and Richard G. Olmstead. 1999. "Phylogenetic Analysis of Bignoniaceae Based on the cpDNA Gene Sequences of rbcL and ndhF". Annals of the Missouri Botanical Garden 86(1):33-46. (See External links below).
Schäferhoff, Bastian; Fleischmann, Andreas; Fischer, Eberhard; Albach, Dirk C.; Borsch, Thomas; Heubl, Günther; Müller, Kai F. (2010). "Towards resolving Lamiales relationships: insights from rapidly evolving chloroplast sequences". BMC Evolutionary Biology. 10: 352. doi:10.1186/1471-2148-10-352. PMC 2992528. PMID 21073690.
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Sources

Alwyn H. Gentry. 1992. "Bignoniaceae: Part II (Tecomeae)". Flora Neotropica Monograph 25(2):1-150. (See External links below).

External links

Bignoniaceae in L. Watson and M. J. Dallwitz (1992 onwards), The families of flowering plants.
Distribution Map[permanent dead link] And Genus List At: Bignoniaceae At: Lamiales At: Trees[permanent dead link] At: APweb At: botanical databases At: About Science & Conservation At: Missouri Botanical Garden
Crescentieae and Tourrettieae At: Flora Neotropica 25(1) At: Flora Neotropica At: Organization for Flora Neotropica
tribe Tecomeae At: Flora Neotropica 25(2) At: Flora Neotropica At: Organization for Flora Neotropica
Bignoniaceae economic botany
List of genera in family Bignoniaceae At: Dicotyledons At: List Genera within a Family At: Vascular Plant Families and Genera At: About the Checklist At: World Checklist of Selected Plant Families At: Data Sources At: ePIC At: Scientific Databases At: Kew Gardens
Bignoniaceae At: Advanced Search At: Search Tool At: iplants
section B In: A checklist of suprageneric names (Alphabetical Listing by Genera) At: Home page of James L. Reveal & C. Rose Broome
Bignonia At: Plant Names At: IPNI
CRC World Dictionary of Plant Names: A-C At: Botany & Plant Science At: Life Science At: CRC Press
Bignoniaceae In: Genera Plantarum vol. 2 part 2 (Bentham & Hooker) At: View Record At: Titles beginning with "G" At: Titles At: Biodiversity Heritage Library
Spangler & Olmstead (1999)

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