Taxon Details: Couroupita guianensis Aubl.
Taxon Profile:
Family:
Lecythidaceae (Magnoliophyta)
Lecythidaceae (Magnoliophyta)
Scientific Name:
Couroupita guianensis Aubl.
Couroupita guianensis Aubl.
Accepted Name:
This name is currently accepted.
This name is currently accepted.
Synonyms:
Pekea couroupita Juss. ex DC.
Lecythis bracteata Willd.
Couroupita surinamensis Mart. ex O.Berg
Couroupita guianensis var. surinamensis (Mart. ex O.Berg) Eyma
Couroupita peruviana O.Berg
Couroupita membranacea Miers
Couroupita antillana Miers
Couroupita venezuelensis R.Knuth
Couroupita froesii R.Knuth
Couroupita saintcroixiana R.Knuth
Couroupita acreensis R.Knuth
Couroupita idolica Dwyer
Pekea couroupita Juss. ex DC.
Lecythis bracteata Willd.
Couroupita surinamensis Mart. ex O.Berg
Couroupita guianensis var. surinamensis (Mart. ex O.Berg) Eyma
Couroupita peruviana O.Berg
Couroupita membranacea Miers
Couroupita antillana Miers
Couroupita venezuelensis R.Knuth
Couroupita froesii R.Knuth
Couroupita saintcroixiana R.Knuth
Couroupita acreensis R.Knuth
Couroupita idolica Dwyer
Common Names:
cannon-ball tree, bola de cañon, granadillo de las huacas, Coco sachapura, maraco, coco de mono, mamey hediondo, muco, taparo de monte, boskalebas, iwadaballi, kaupe, kouroupitoumou, castanha de macaco, bala de cañón, bala de cañon
cannon-ball tree, bola de cañon, granadillo de las huacas, Coco sachapura, maraco, coco de mono, mamey hediondo, muco, taparo de monte, boskalebas, iwadaballi, kaupe, kouroupitoumou, castanha de macaco, bala de cañón, bala de cañon
Description:
Author: Scott A. Mori & Ghillean T. Prance
Type: French Guiana. Without locality, no date (st), Aublet s.n. (lectotype, BM; isolectotype, S, designated Mori & Prance, 1990).
Description: Trees, to 35 m tall, unbuttressed. Bark not fissured. Leaves in clusters at ends of branches; petioles 5-30 mm long; blades (6-)8-31(-57) x 3-10 cm, usually narrowly obovate to obovate, sometimes elliptic, glabrous adaxially, pubescent on veins abaxially, often but not always with a tuft of trichomes (possibly domatia) in axils of secondary veins, the trichomes simple the base cuneate, the margins entire, the apex generally acute or acuminate; secondary veins in 15-25 pairs, the tertiary veins weakly percurrent, prominulous, the higher order venation prominulous, forming well-defined areoles. Inflorescences cauline, usually unbranched racemes, sometimes branched and paniculate, sometimes covering entire trunk; pedicel/hypanthium 12-60 mm long. Flowers zygomorphic, 5-6 cm diam.; calyx-lobes 6, broadly ovate, 4-5 x 4-6, the bases slightly imbricate, the margins ciliate; petals 6, most commonly yellow toward apices and pink to red toward bases abaxially, pink to red except for white bases adaxially, some Peruvian collections with more yellow in petals; androecium prolonged on one side into flat hood, with stamen free area between staminal ring and hood proper, the hood white or pale yellow tinged with pink externally, the ring stamens with white filaments and white or pale yellow anthers, the hood staminodes often white at very base, pink for most of length, and yellow at apex, sometimes white for most of length and yellow at apex, the stamens with lateral dehiscence; ovary 6-locular. Fruits indehiscent, globose, 12-25 cm diam., the supracalyzine zone rounded, the infracalycine zone rounded to base, falling from tree at maturity. Seeds embedded in pulp, the pulp oxidizing bluish-green when exposed to air, the testa with trichomes; embryo with 2 foliaceous cotyledons.
Common names: English: Cannon-ball tree. Spanish: bola de cañon. Panama: granadillo de las huacas, coco sachapura. Colombia: maraco. Venezuela: coco de mono, mamey hediondo, muco, taparo de monte. Surinam: boskalebas, iwadaballi, kaupe. French Guiana: kouroupitoumou. Brazil: abrico de macaco, castanha de macaco (monkey nut). Peru: ayahuma, ayahúman (Smith et al., 2007).
Distribution: Amazonian Colombia, northern Venezuela, Guyana, Surinam, French Guiana, Amazonian Ecuador, Amazonian Peru, and eastern and southwestern Amazonian Brazil. This species has been collected in Mesoamerica but these collections most likely come from cultivated trees. In Brazil, the collections from Pará (Pires 1644) and Goiás (Heringer & Valmira 18415) have been checked by S. A. Mori and definitely represent this species and appear to have been made from native trees. In South America, Couroupita guianensis is found mostly around the periphery of the Amazon Basin, displaying a distribution pattern called peri-Amazonian by Granville (1992). This species is frequently planted as a botanical curiosity in tropical and subtropical botanical gardens in many parts of the world.
Ecology: We know of no ecological studies of C. guianenensis in which frequency, density, dominance, and habitat preferences have been reported. This species is most frequently found in wet areas of lowland forests but is not a species of periodically flooded forests. In fruit, C. guianensis can be easily mistaken for C. subsessilis which may actually be the species accounting for some of the reports of C. guianensis growing in flood plain forests.
Phenology: Poiteau (1825) observed that trees of this species growing in their native habitat in sandy soils on the Ile de Cayenne, French Guiana lost their leaves in March and again in September, remained 18 days almost leafless, and then flowered and flushed new leaves. Ormond et al. (1985) made observations on leaf fall, leaf flush, flowering, and fruiting during five-years on 13 trees of Couroupita guianensis growing outside their native range in the botanical garden of the Museu Nacaional in Rio de Janeiro. These trees dropped and flushed new leaves two to three times a year. The leaves turn yellow, fall to the ground, and flush leaves within 15 days after the old leaves have fallen. Leaves were most frequently flushed just before the onset of flowering and there was little synchrony in leaf fall and flush among the trees they observed. The trees flowered from November through May with a peak in January and February with any given tree flowering one to three times during this period. The trunks of some trees were covered by flowering inflorescences that reached as long as 80 cm. and a given tree held as many as 1000 open flowers per day. Fruits in this area fell from October through April.
Pollination: The morphology and development of the flowers of C. guianensis have been well illustrated by Thompson (1921). In addition to being showy, its flowers are strongly and pleasantly aromatic. Ormond et al. (1981, 1982) determined that the osmphores of this species are most abundant on the hood filaments and less common on the adaxial surface of the petals. Oil droplets are found in the cells of the epidermal and stomatal guard cells of the osmophores. In addition, the cells of the mesophyll of these structures are rich in starch. After anthesis, oil droplets and starch are not nearly as plentiful. The internal temperature of the flowers at anthesis is seven degrees above ambient temperature. Ormond et al. (1981, 1982) suggest that the oil droplets volatilize to yield the pleasant aroma and that the starch in the adjacent cells provides the energy for this process. The aroma, at least in some individuals, is dominated by monoterpene hydrocarbons (Knudsen & Mori, 1996). The apices of the hood filaments are yellow, a color that attracts bees. Moreover, UV light is only reflected from the hood and has perhaps evolved to attract pollinators to rewards found in that part of the flower. The sweet aroma of these flowers is strongest in the early morning and bees have been recorded visiting the flowers as early as 5:00 a.m.; the petals and androecium drop from the flowers around 12:00 p.m. (Ormond et al., 1981). Yarsick et al. (1986) report that the flowers of a cultivated Venezuelan tree open gradually between 7:00 and 8:30 p.m. with the hood and ring anthers opening simultaneously. These authors confirm observations that the hood anthers are larger than the ring anthers - the former have an average of 2,850 tetrads and the latter 450 monads per anther. The flowers of C. guianensis are without nectar and are mostly visited by bees in search of pollen.Xylocopa brasilianorum has been reported to be the principal pollinator outside of the native range of C. guianensis in the botanical garden of the Museu Nacional in Rio de Janeiro. Dahlgren (1924) states "The large black bumble-bees that visit the flowers force their way under the tip of the hood, between the two sets of stamens, and become thoroughly dusted with pollen." It is likely that the bees observed by Dahlgren also represent a species of Xylocopa. Yarsick et al. (1986) report bees, wasps, and a flower fly visiting the flowers, but note that Xylocopa frontalis and a species of Bombus appear to be the most efficient pollinators. Carpenter bees of the genus Xylocopa have also been observed pollinating cultivated trees of C. guianensis in India (Aluri & Reddi, 1990). Ormond et al. (1981) have demonstrated that bagged flowers do not set fruit nor do the flowers in the bags end up with pollen on their stigmas. They demonstrated that two percent of artificially self pollinated flowers produce fruit whereas artificially cross-pollinated and naturally pollinated flowers yield 6% and 4% fruit respectively. In their study, they observed a tree flowering out of phase with the other trees set fruit, and there are other unsubstantiated reports of cultivated trees growing in isolation producing fruit. Thus, it appears that C. guianensis is self-compatible, but that there are more fruits set if out crossing takes place. Poiteau (1825) observed that the pollen of the hood was larger and yellow and that of the staminal ring smaller and white. Thompson (1927) was the first to suggest that pollen from the hood does not germinate on the stigma, but it was Jacques (1965) who first observed that the ring and hood pollen are different. This observation has been confirmed by Mori et al. (1980), Ormond et al. (1981), and Yarsick et al. (1986). These authors have demonstrated that the pollen of the staminal ring is found in monads and has a smooth exine while that of the hood is in tetrads and has a rougher exine. Ormond et al. (1981) add that the ring pollen is covered with droplets of a lipid substance whereas that of the hood is dry. Examination of the stigma shows that monad pollen dominates the surface while tetrad pollen is rarely found there. The ring pollen shows a high degree of both in vitro and in vivo germination whereas not a single pollen grain from the hood anthers germinates (Mori et al., 1980; Ormond et al., 1981). In conclusion, it has been clearly demonstrated that there are two types of pollen in the flower of Couroupita guianensis and that the most likely pollinators are species of large bees, such as Bombus and Xylocopa, which are rewarded for their efforts with non-germinating pollen that they collect from the hood.
Dispersal: Fruits from different trees of C. guianensis display considerable variation in size, ranging from 12 to 25 cm in diameter with smaller ones having as few as 65 and larger ones as many as 550 seeds (Ormond et al., 1985; Schoenberg, 1983a). The number of fruits produced per tree ranges from 50 to 150. Fruits reach maturity in about 12 months (Ormond et al., 1985), but Dahlgren (1824) noted that it takes as long as 18 months for fruits of this species to mature in Guyana. The number of flowers and fruits produced by individuals of C. guianensis vary from one flowering period to the next, sometimes there is a major flowering and other times the flowering is minor. Fruit set is 0.8% following a major flowering and 3.4% after minor flowering, but major and minor flowering events usually yield about the same number of fruits produced because of the greater number of flowers available during a major flowering period (Ormond et al., 1985). The anatomy and morphology of the fruits of Couroupita guianensis have been described in detail by Schoenberg (1983a, 1983b). The cannon-ball like fruits of Couroupita guianensis fall and often crack open upon hitting the ground. The seeds are embedded in a six-segmented fleshy pulp that oxidizes bluish-green when exposed to the air. Peccaries and domestic animals, such as chickens and pigs, are reported to eat the pulp and in so doing swallow the seeds. Prance and Mori (1979) report an observation made by H. W. Koepcke who studied a tree of this species over a three-week period. A paca (Agouti paca) has been filmed at the Los Amigos Biological Station in Peru carrying a fruit it its mouth. The ground under the tree was covered by many fruits which remained untouched until a herd of peccaries passed by and broke open the fruits and consumed the pulp. The seeds of species of Couroupita have exotestal trichomes which may protect the seeds and facilitate their passage through the digestive tracts of animals (Tsou & Mori, 2002).
Predation: No observations recorded.
Field characters: The combination of tufts of trichomes in the axils of the secondary veins; conspicuous inflorescences arising from the trunk; showy aromatic flowers with the petals tinged with various degrees of pink or red; a flat androecial hood; cannon-ball like fruits; and seeds embedded in a pulp that oxidize bluish-green when exposed to the air separate this species from all other Lecythidaceae. It can only be mistaken for the other two species of the genus, C. subsessilis found along Amazonian rivers and the Central American/northwestern South American C. nicaraguarensis. See "Taxonomic notes" below.
Taxonomic notes: Leaf and fruit collections of the three species of Couroupita are difficult to distinguish from one another. However, in flower they are easily separated. Both C. subsessilis and C. nicaraguarensis have white or pale yellow petals and bright, yellow-orange anthers in the staminal ring. In addition, C. nicaraguarensis has stamens that run from the staminal ring all of the way onto the hood (see comparison of androecial hoods in attached image). C. subsessilis sometimes has a notched androecial hood, especially in populations further up the Amazon. There is considerable variation in flower color and size as well as in fruit size and shape. Some trees have much more yellow in their flowers than found in the flowers of other trees (e.g., collections from Madre de Dios, Peru). Most fruits are globose and resemble a cannon ball, but some fruits are longer than wide. Other possible differences among the species of this genus are: the size of the fruits, the position of the calycine ring, the color of the pulp, and the number of seeds per locule. The fruits are multi-layered and complex in structure probably because they are derived from the hypanthium and the ovary.
Conservation: IUCN Red List: lower Risk/least concern, ver 2.3 (assessed in 1998) (IUCN, 2009). Plantas Raras do Brasil: not on list (Giulietti et al., 2009).
Uses: Couroupita guianensis is widely planted in tropical and subtropical botanical gardens and as an ornamental throughout the tropics and subtropics; it does well under cultivation as far north as the Fairchild Tropical Botanical Gardens in Florida. The pulp of the fruit of C. guianensis is used to feed animals such as chickens, muscovy ducks, turkeys, and pigs but it is not consumed by humans (Smith et al., 2007). Some of the reports of this species may actually have been misidentifications of C. subsessilis which is found along large rivers in the Brazilian Amazon. However, the fruits of the three species of Couroupita are identical and are all expected to have the potential to be used in the same way. In the last 15 years numerous studies have demonstrated that extracts from this species are bioactive and might be useful for treating various ailments in humans or as pesticides. References to papers on this topic and other topics involving this species can be found by searching for Couroupita guianensis in the Literature Module of this website.
Etymology: This species is named after the geographic location of the type collection.
Source: Based on Prance in Mori and Prance (1990).
Acknowledgements: We are grateful to B. Angell, X. Cornejo, R. Foster, C. A. Gracie, A. Vasco-Gutierrez, J. Janovec, T. Paine, and W. W. Thomas for allowing us to use their images to illustrate the characters of this species.
Author: Scott A. Mori & Ghillean T. Prance
Type: French Guiana. Without locality, no date (st), Aublet s.n. (lectotype, BM; isolectotype, S, designated Mori & Prance, 1990).
Description: Trees, to 35 m tall, unbuttressed. Bark not fissured. Leaves in clusters at ends of branches; petioles 5-30 mm long; blades (6-)8-31(-57) x 3-10 cm, usually narrowly obovate to obovate, sometimes elliptic, glabrous adaxially, pubescent on veins abaxially, often but not always with a tuft of trichomes (possibly domatia) in axils of secondary veins, the trichomes simple the base cuneate, the margins entire, the apex generally acute or acuminate; secondary veins in 15-25 pairs, the tertiary veins weakly percurrent, prominulous, the higher order venation prominulous, forming well-defined areoles. Inflorescences cauline, usually unbranched racemes, sometimes branched and paniculate, sometimes covering entire trunk; pedicel/hypanthium 12-60 mm long. Flowers zygomorphic, 5-6 cm diam.; calyx-lobes 6, broadly ovate, 4-5 x 4-6, the bases slightly imbricate, the margins ciliate; petals 6, most commonly yellow toward apices and pink to red toward bases abaxially, pink to red except for white bases adaxially, some Peruvian collections with more yellow in petals; androecium prolonged on one side into flat hood, with stamen free area between staminal ring and hood proper, the hood white or pale yellow tinged with pink externally, the ring stamens with white filaments and white or pale yellow anthers, the hood staminodes often white at very base, pink for most of length, and yellow at apex, sometimes white for most of length and yellow at apex, the stamens with lateral dehiscence; ovary 6-locular. Fruits indehiscent, globose, 12-25 cm diam., the supracalyzine zone rounded, the infracalycine zone rounded to base, falling from tree at maturity. Seeds embedded in pulp, the pulp oxidizing bluish-green when exposed to air, the testa with trichomes; embryo with 2 foliaceous cotyledons.
Common names: English: Cannon-ball tree. Spanish: bola de cañon. Panama: granadillo de las huacas, coco sachapura. Colombia: maraco. Venezuela: coco de mono, mamey hediondo, muco, taparo de monte. Surinam: boskalebas, iwadaballi, kaupe. French Guiana: kouroupitoumou. Brazil: abrico de macaco, castanha de macaco (monkey nut). Peru: ayahuma, ayahúman (Smith et al., 2007).
Distribution: Amazonian Colombia, northern Venezuela, Guyana, Surinam, French Guiana, Amazonian Ecuador, Amazonian Peru, and eastern and southwestern Amazonian Brazil. This species has been collected in Mesoamerica but these collections most likely come from cultivated trees. In Brazil, the collections from Pará (Pires 1644) and Goiás (Heringer & Valmira 18415) have been checked by S. A. Mori and definitely represent this species and appear to have been made from native trees. In South America, Couroupita guianensis is found mostly around the periphery of the Amazon Basin, displaying a distribution pattern called peri-Amazonian by Granville (1992). This species is frequently planted as a botanical curiosity in tropical and subtropical botanical gardens in many parts of the world.
Ecology: We know of no ecological studies of C. guianenensis in which frequency, density, dominance, and habitat preferences have been reported. This species is most frequently found in wet areas of lowland forests but is not a species of periodically flooded forests. In fruit, C. guianensis can be easily mistaken for C. subsessilis which may actually be the species accounting for some of the reports of C. guianensis growing in flood plain forests.
Phenology: Poiteau (1825) observed that trees of this species growing in their native habitat in sandy soils on the Ile de Cayenne, French Guiana lost their leaves in March and again in September, remained 18 days almost leafless, and then flowered and flushed new leaves. Ormond et al. (1985) made observations on leaf fall, leaf flush, flowering, and fruiting during five-years on 13 trees of Couroupita guianensis growing outside their native range in the botanical garden of the Museu Nacaional in Rio de Janeiro. These trees dropped and flushed new leaves two to three times a year. The leaves turn yellow, fall to the ground, and flush leaves within 15 days after the old leaves have fallen. Leaves were most frequently flushed just before the onset of flowering and there was little synchrony in leaf fall and flush among the trees they observed. The trees flowered from November through May with a peak in January and February with any given tree flowering one to three times during this period. The trunks of some trees were covered by flowering inflorescences that reached as long as 80 cm. and a given tree held as many as 1000 open flowers per day. Fruits in this area fell from October through April.
Pollination: The morphology and development of the flowers of C. guianensis have been well illustrated by Thompson (1921). In addition to being showy, its flowers are strongly and pleasantly aromatic. Ormond et al. (1981, 1982) determined that the osmphores of this species are most abundant on the hood filaments and less common on the adaxial surface of the petals. Oil droplets are found in the cells of the epidermal and stomatal guard cells of the osmophores. In addition, the cells of the mesophyll of these structures are rich in starch. After anthesis, oil droplets and starch are not nearly as plentiful. The internal temperature of the flowers at anthesis is seven degrees above ambient temperature. Ormond et al. (1981, 1982) suggest that the oil droplets volatilize to yield the pleasant aroma and that the starch in the adjacent cells provides the energy for this process. The aroma, at least in some individuals, is dominated by monoterpene hydrocarbons (Knudsen & Mori, 1996). The apices of the hood filaments are yellow, a color that attracts bees. Moreover, UV light is only reflected from the hood and has perhaps evolved to attract pollinators to rewards found in that part of the flower. The sweet aroma of these flowers is strongest in the early morning and bees have been recorded visiting the flowers as early as 5:00 a.m.; the petals and androecium drop from the flowers around 12:00 p.m. (Ormond et al., 1981). Yarsick et al. (1986) report that the flowers of a cultivated Venezuelan tree open gradually between 7:00 and 8:30 p.m. with the hood and ring anthers opening simultaneously. These authors confirm observations that the hood anthers are larger than the ring anthers - the former have an average of 2,850 tetrads and the latter 450 monads per anther. The flowers of C. guianensis are without nectar and are mostly visited by bees in search of pollen.Xylocopa brasilianorum has been reported to be the principal pollinator outside of the native range of C. guianensis in the botanical garden of the Museu Nacional in Rio de Janeiro. Dahlgren (1924) states "The large black bumble-bees that visit the flowers force their way under the tip of the hood, between the two sets of stamens, and become thoroughly dusted with pollen." It is likely that the bees observed by Dahlgren also represent a species of Xylocopa. Yarsick et al. (1986) report bees, wasps, and a flower fly visiting the flowers, but note that Xylocopa frontalis and a species of Bombus appear to be the most efficient pollinators. Carpenter bees of the genus Xylocopa have also been observed pollinating cultivated trees of C. guianensis in India (Aluri & Reddi, 1990). Ormond et al. (1981) have demonstrated that bagged flowers do not set fruit nor do the flowers in the bags end up with pollen on their stigmas. They demonstrated that two percent of artificially self pollinated flowers produce fruit whereas artificially cross-pollinated and naturally pollinated flowers yield 6% and 4% fruit respectively. In their study, they observed a tree flowering out of phase with the other trees set fruit, and there are other unsubstantiated reports of cultivated trees growing in isolation producing fruit. Thus, it appears that C. guianensis is self-compatible, but that there are more fruits set if out crossing takes place. Poiteau (1825) observed that the pollen of the hood was larger and yellow and that of the staminal ring smaller and white. Thompson (1927) was the first to suggest that pollen from the hood does not germinate on the stigma, but it was Jacques (1965) who first observed that the ring and hood pollen are different. This observation has been confirmed by Mori et al. (1980), Ormond et al. (1981), and Yarsick et al. (1986). These authors have demonstrated that the pollen of the staminal ring is found in monads and has a smooth exine while that of the hood is in tetrads and has a rougher exine. Ormond et al. (1981) add that the ring pollen is covered with droplets of a lipid substance whereas that of the hood is dry. Examination of the stigma shows that monad pollen dominates the surface while tetrad pollen is rarely found there. The ring pollen shows a high degree of both in vitro and in vivo germination whereas not a single pollen grain from the hood anthers germinates (Mori et al., 1980; Ormond et al., 1981). In conclusion, it has been clearly demonstrated that there are two types of pollen in the flower of Couroupita guianensis and that the most likely pollinators are species of large bees, such as Bombus and Xylocopa, which are rewarded for their efforts with non-germinating pollen that they collect from the hood.
Dispersal: Fruits from different trees of C. guianensis display considerable variation in size, ranging from 12 to 25 cm in diameter with smaller ones having as few as 65 and larger ones as many as 550 seeds (Ormond et al., 1985; Schoenberg, 1983a). The number of fruits produced per tree ranges from 50 to 150. Fruits reach maturity in about 12 months (Ormond et al., 1985), but Dahlgren (1824) noted that it takes as long as 18 months for fruits of this species to mature in Guyana. The number of flowers and fruits produced by individuals of C. guianensis vary from one flowering period to the next, sometimes there is a major flowering and other times the flowering is minor. Fruit set is 0.8% following a major flowering and 3.4% after minor flowering, but major and minor flowering events usually yield about the same number of fruits produced because of the greater number of flowers available during a major flowering period (Ormond et al., 1985). The anatomy and morphology of the fruits of Couroupita guianensis have been described in detail by Schoenberg (1983a, 1983b). The cannon-ball like fruits of Couroupita guianensis fall and often crack open upon hitting the ground. The seeds are embedded in a six-segmented fleshy pulp that oxidizes bluish-green when exposed to the air. Peccaries and domestic animals, such as chickens and pigs, are reported to eat the pulp and in so doing swallow the seeds. Prance and Mori (1979) report an observation made by H. W. Koepcke who studied a tree of this species over a three-week period. A paca (Agouti paca) has been filmed at the Los Amigos Biological Station in Peru carrying a fruit it its mouth. The ground under the tree was covered by many fruits which remained untouched until a herd of peccaries passed by and broke open the fruits and consumed the pulp. The seeds of species of Couroupita have exotestal trichomes which may protect the seeds and facilitate their passage through the digestive tracts of animals (Tsou & Mori, 2002).
Predation: No observations recorded.
Field characters: The combination of tufts of trichomes in the axils of the secondary veins; conspicuous inflorescences arising from the trunk; showy aromatic flowers with the petals tinged with various degrees of pink or red; a flat androecial hood; cannon-ball like fruits; and seeds embedded in a pulp that oxidize bluish-green when exposed to the air separate this species from all other Lecythidaceae. It can only be mistaken for the other two species of the genus, C. subsessilis found along Amazonian rivers and the Central American/northwestern South American C. nicaraguarensis. See "Taxonomic notes" below.
Taxonomic notes: Leaf and fruit collections of the three species of Couroupita are difficult to distinguish from one another. However, in flower they are easily separated. Both C. subsessilis and C. nicaraguarensis have white or pale yellow petals and bright, yellow-orange anthers in the staminal ring. In addition, C. nicaraguarensis has stamens that run from the staminal ring all of the way onto the hood (see comparison of androecial hoods in attached image). C. subsessilis sometimes has a notched androecial hood, especially in populations further up the Amazon. There is considerable variation in flower color and size as well as in fruit size and shape. Some trees have much more yellow in their flowers than found in the flowers of other trees (e.g., collections from Madre de Dios, Peru). Most fruits are globose and resemble a cannon ball, but some fruits are longer than wide. Other possible differences among the species of this genus are: the size of the fruits, the position of the calycine ring, the color of the pulp, and the number of seeds per locule. The fruits are multi-layered and complex in structure probably because they are derived from the hypanthium and the ovary.
Conservation: IUCN Red List: lower Risk/least concern, ver 2.3 (assessed in 1998) (IUCN, 2009). Plantas Raras do Brasil: not on list (Giulietti et al., 2009).
Uses: Couroupita guianensis is widely planted in tropical and subtropical botanical gardens and as an ornamental throughout the tropics and subtropics; it does well under cultivation as far north as the Fairchild Tropical Botanical Gardens in Florida. The pulp of the fruit of C. guianensis is used to feed animals such as chickens, muscovy ducks, turkeys, and pigs but it is not consumed by humans (Smith et al., 2007). Some of the reports of this species may actually have been misidentifications of C. subsessilis which is found along large rivers in the Brazilian Amazon. However, the fruits of the three species of Couroupita are identical and are all expected to have the potential to be used in the same way. In the last 15 years numerous studies have demonstrated that extracts from this species are bioactive and might be useful for treating various ailments in humans or as pesticides. References to papers on this topic and other topics involving this species can be found by searching for Couroupita guianensis in the Literature Module of this website.
Etymology: This species is named after the geographic location of the type collection.
Source: Based on Prance in Mori and Prance (1990).
Acknowledgements: We are grateful to B. Angell, X. Cornejo, R. Foster, C. A. Gracie, A. Vasco-Gutierrez, J. Janovec, T. Paine, and W. W. Thomas for allowing us to use their images to illustrate the characters of this species.
Narratives:
Painting by F. W. Horne of Couroupita guianensis Aubl.
Flower morphology and anatomy of Couroupita guianensis
Painting by F. W. Horne of Couroupita guianensis Aubl.
Flower morphology and anatomy of Couroupita guianensis
Flora and Monograph Treatment(s):
Couroupita guianensis Aubl.: [Manuscript] Britton, Nathaniel L. Flora Borinqueña.
Couroupita guianensis Aubl.: [Article] Mori, S. A. & Prance, Ghillean T. 1990. Lecythidaceae - Part II: The zygomorphic-flowered New World genera (Couroupita, Corythophora, Bertholletia, Couratari, Eschweilera, & Lecythis). With a study of secondary xylem of Neotropical Lecythidaceae by Carl de Zeeuw. Fl. Neotrop. Monogr. 21: 1-376.
Couroupita guianensis Aubl.: [Manuscript] Britton, Nathaniel L. Flora Borinqueña.
Couroupita guianensis Aubl.: [Article] Mori, S. A. & Prance, Ghillean T. 1990. Lecythidaceae - Part II: The zygomorphic-flowered New World genera (Couroupita, Corythophora, Bertholletia, Couratari, Eschweilera, & Lecythis). With a study of secondary xylem of Neotropical Lecythidaceae by Carl de Zeeuw. Fl. Neotrop. Monogr. 21: 1-376.
Related Objects:
• J. B. Walker 657, United States of America
• T. A. Zanoni 16877, Dominican Republic
• N. L. Britton 182, Virgin Islands (U.S.)
• Armando Grijalva 225, Ecuador
• M.-F. Prévost 4720, French Guiana
• N. Xena 671, Venezuela
• H. T. Beck 1277, United States of America
• R. Jaramillo Mejía 1271, Colombia
• R. Jaramillo Mejía 1271, Colombia
• M. J. P. Pires-O'Brien 1744, Brazil
• B. C. Bennett 3874, Ecuador
• H. T. Beck 1197, United States of America
• N. A. Zamora Villalobos 1773, Costa Rica
• R. A. Howard 19451, Guadeloupe
• SEF 10273, Ecuador
• B. B. Klitgaard 633, Ecuador
• J. T. Knudsen 116, Ecuador
• J. T. Knudsen 135, Ecuador
• R. Rojas 135, Peru
• J. G. Wessels Boer 1773, Venezuela
• J. G. Wessels Boer 1773, Venezuela
• J. G. Wessels Boer 1773, Venezuela
• SEF 10273, Ecuador
• R. Rojas 135, Peru
• See Collection Notes s.n., Colombia
• M. Silveira 837, Brazil
• Á. J. Pérez 4352, Ecuador
• R. A. A. Oldeman 1012, French Guiana
• J. K. Small, United States of America
• J. K. Small, United States of America
• W. Morawetz 19161085, Peru
• M. Silveira 1478, Brazil
• M. Silveira 1478, Brazil
• J. L. Hage 1964, Brazil
• J. L. Hage 1964, Brazil
• L. A. Mattos Silva 3085, Brazil
• S. A. Mori 24256, French Guiana
• S. A. Mori 25516, French Guiana
• S. A. Mori 22153, Panama
• D. Cárdenas-López 6631, Colombia
• J. F. Pruski 2727, United States of America
• R. Callejas Posada 5916, Colombia
• R. Aguilar 11962, Costa Rica
• B. W. Nelson 1154, Brazil
• B. W. Nelson 1154, Brazil
• J. R. Maciel 1533, Brazil
• C. A. Cid Ferreira 2960, Brazil
• G. S. Bunting 10541, Venezuela
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• E. L. Little Jr. 16310, Puerto Rico
• E. L. Little Jr. 13744, Puerto Rico
• E. L. Ekman 18613, Cuba
• S. R. Lowrie 475, Brazil
• S. R. Lowrie 475, Brazil
• S. R. Lowrie 615, Brazil
• E. P. Heringer 18415, Brazil
• E. P. Heringer 18415, Brazil
• E. P. Heringer 18415, Brazil
• H. Lugo Sanchez 2207, Ecuador
• H. Lugo Sanchez 2227, Ecuador
• H. Lugo Sanchez 2248, Ecuador
• H. Lugo Sanchez 5329, Ecuador
• H. Lugo Sanchez 5330, Ecuador
• H. Lugo Sanchez 5366, Ecuador
• W. A. Palacios 471, Ecuador
• C. Reynel 1087, Peru
• R. Ferreyra: Lima, Magnoliophyta; South America
• G. Stahel 100, Suriname
• G. Stahel 100, Suriname
• N. L. Britton 100, Trinidad and Tobago
• F. W. Johnson 1196, Barbados
• L. Aristeguieta 5302, Venezuela
• J. J. Wurdack 43773, Colombia
• L. Marcano-Berti 64277, Venezuela
• G. S. Bunting 9313, Venezuela
• G. S. Bunting 9313, Venezuela
• J. J. Wurdack 43773, Colombia
• G. S. Bunting 9305, Venezuela
• G. S. Bunting 9305, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10097, Venezuela
• H. Jiménez Saa. s.n., Venezuela
• H. Jiménez Saa. 1329, Venezuela
• G. S. Bunting 5031, Venezuela
• G. S. Bunting 5031, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10541, Venezuela
• S. R. Lowrie 475, Brazil
• I. Cabrera-Rodríguez 3523, Colombia
• S. R. Lowrie 615, Brazil
• C. A. Cid Ferreira 2960, Brazil
• C. A. Cid Ferreira 2960, Brazil
• C. A. Cid Ferreira 3007, Brazil
• W. A. Egler 45925, Brazil
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 21159, Brazil
• G. T. Prance 21159, Brazil
• G. T. Prance 16569, Suriname
• G. T. Prance 16569, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 28159, Venezuela
• G. T. Prance 28159, Venezuela
• G. T. Prance 28159, Venezuela
• G. T. Prance 24705, Peru
• G. T. Prance 16546, United States of America
• G. T. Prance 16544, United States of America
• G. T. Prance 7764, Brazil
• G. T. Prance 7764, Brazil
• X. Cornejo 8030, Ecuador
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• L. J. Dorr 7407, Venezuela
• J. C. Betancur B. 1538, Colombia
• M. H. Nee 3578, Panama
• M. H. Nee 3578, Panama
• M. H. Nee 4075, Venezuela
• M. H. Nee 4075, Venezuela
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 1236, Brazil
• R. A. Pursell 8100, Venezuela
• R. A. Pursell 8100, Venezuela
• A. H. G. Alston 6085, Venezuela
• J. A. Steyermark 101959, Venezuela
• J. A. Steyermark 101959, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 61484, Venezuela
• J. A. Steyermark 122889, Venezuela
• J. A. Steyermark 122889, Venezuela
• J. A. Steyermark 123443, Venezuela
• J. A. Steyermark 123443, Venezuela
• J. Cuatrecasas 7598, Colombia
• G. Klug 4357, Peru
• G. Klug 2835, Peru
• D. C. Daly 8004, Brazil
• F. Ayala 2957, Peru
• H. F. Pittier 6339, Venezuela
• H. F. Pittier 11724, Venezuela
• R. L. Liesner 11168, Venezuela
• A. Ortega U. 267, Ecuador
• A. Ortega U. 201, Ecuador
• H. H. Smith 1516, Saint Vincent and the Grenadines
• T. G. Yuncker 17482, Jamaica
• T. G. Yuncker 18608, Jamaica
• B. A. Krukoff 4741, Peru
• B. A. Krukoff 4741, Peru
• A. H. Liogier 31907, Puerto Rico
• M. M. Mejía Pimentel 7691, Puerto Rico
• A. H. Gentry 18719, Peru
• A. H. Gentry 18719, Peru
• A. H. Gentry 11038, Venezuela
• A. H. Gentry 14842, Venezuela
• G. Davidse 5468, Colombia
• J. Revilla 2138, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• A. H. Gentry 25840, Peru
• R. Ferreyra: Lima, Magnoliophyta; South America
• K. R. Young 184, Peru
• D. E. Atha 819, Puerto Rico
• D. Naranjo 206, Ecuador
• D. Naranjo 206, Ecuador
• E. Freire 5049, Ecuador
• Couroupita guianensis Aubl.
• Couroupita guianensis Aubl.
• P. Mendoza Troya 300, Ecuador
• S. A. Mori s.n., Panama
• Bernardi 1172, Venezuela
• Bernardi 1172, Venezuela
• C. Diaz 933, Peru
• Aubreville, French Guiana
• B. A. Krukoff 5677, Brazil
• J. Batista 1312, Panama
• D. C. Daly 11232, Brazil
• J. Lau 1832, United States of America
• P. C. Hutchison 2842, United States of America
• O. Degener 3327, United States of America
• T. A. Zanoni 16877, Dominican Republic
• N. L. Britton 182, Virgin Islands (U.S.)
• Armando Grijalva 225, Ecuador
• M.-F. Prévost 4720, French Guiana
• N. Xena 671, Venezuela
• H. T. Beck 1277, United States of America
• R. Jaramillo Mejía 1271, Colombia
• R. Jaramillo Mejía 1271, Colombia
• M. J. P. Pires-O'Brien 1744, Brazil
• B. C. Bennett 3874, Ecuador
• H. T. Beck 1197, United States of America
• N. A. Zamora Villalobos 1773, Costa Rica
• R. A. Howard 19451, Guadeloupe
• SEF 10273, Ecuador
• B. B. Klitgaard 633, Ecuador
• J. T. Knudsen 116, Ecuador
• J. T. Knudsen 135, Ecuador
• R. Rojas 135, Peru
• J. G. Wessels Boer 1773, Venezuela
• J. G. Wessels Boer 1773, Venezuela
• J. G. Wessels Boer 1773, Venezuela
• SEF 10273, Ecuador
• R. Rojas 135, Peru
• See Collection Notes s.n., Colombia
• M. Silveira 837, Brazil
• Á. J. Pérez 4352, Ecuador
• R. A. A. Oldeman 1012, French Guiana
• J. K. Small, United States of America
• J. K. Small, United States of America
• W. Morawetz 19161085, Peru
• M. Silveira 1478, Brazil
• M. Silveira 1478, Brazil
• J. L. Hage 1964, Brazil
• J. L. Hage 1964, Brazil
• L. A. Mattos Silva 3085, Brazil
• S. A. Mori 24256, French Guiana
• S. A. Mori 25516, French Guiana
• S. A. Mori 22153, Panama
• D. Cárdenas-López 6631, Colombia
• J. F. Pruski 2727, United States of America
• R. Callejas Posada 5916, Colombia
• R. Aguilar 11962, Costa Rica
• B. W. Nelson 1154, Brazil
• B. W. Nelson 1154, Brazil
• J. R. Maciel 1533, Brazil
• C. A. Cid Ferreira 2960, Brazil
• G. S. Bunting 10541, Venezuela
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• K. Lems 64091401, Costa Rica
• E. L. Little Jr. 16310, Puerto Rico
• E. L. Little Jr. 13744, Puerto Rico
• E. L. Ekman 18613, Cuba
• S. R. Lowrie 475, Brazil
• S. R. Lowrie 475, Brazil
• S. R. Lowrie 615, Brazil
• E. P. Heringer 18415, Brazil
• E. P. Heringer 18415, Brazil
• E. P. Heringer 18415, Brazil
• H. Lugo Sanchez 2207, Ecuador
• H. Lugo Sanchez 2227, Ecuador
• H. Lugo Sanchez 2248, Ecuador
• H. Lugo Sanchez 5329, Ecuador
• H. Lugo Sanchez 5330, Ecuador
• H. Lugo Sanchez 5366, Ecuador
• W. A. Palacios 471, Ecuador
• C. Reynel 1087, Peru
• R. Ferreyra: Lima, Magnoliophyta; South America
• G. Stahel 100, Suriname
• G. Stahel 100, Suriname
• N. L. Britton 100, Trinidad and Tobago
• F. W. Johnson 1196, Barbados
• L. Aristeguieta 5302, Venezuela
• J. J. Wurdack 43773, Colombia
• L. Marcano-Berti 64277, Venezuela
• G. S. Bunting 9313, Venezuela
• G. S. Bunting 9313, Venezuela
• J. J. Wurdack 43773, Colombia
• G. S. Bunting 9305, Venezuela
• G. S. Bunting 9305, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10097, Venezuela
• H. Jiménez Saa. s.n., Venezuela
• H. Jiménez Saa. 1329, Venezuela
• G. S. Bunting 5031, Venezuela
• G. S. Bunting 5031, Venezuela
• G. S. Bunting 10097, Venezuela
• G. S. Bunting 10541, Venezuela
• S. R. Lowrie 475, Brazil
• I. Cabrera-Rodríguez 3523, Colombia
• S. R. Lowrie 615, Brazil
• C. A. Cid Ferreira 2960, Brazil
• C. A. Cid Ferreira 2960, Brazil
• C. A. Cid Ferreira 3007, Brazil
• W. A. Egler 45925, Brazil
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 16541, United States of America
• G. T. Prance 21159, Brazil
• G. T. Prance 21159, Brazil
• G. T. Prance 16569, Suriname
• G. T. Prance 16569, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 16570, Suriname
• G. T. Prance 28159, Venezuela
• G. T. Prance 28159, Venezuela
• G. T. Prance 28159, Venezuela
• G. T. Prance 24705, Peru
• G. T. Prance 16546, United States of America
• G. T. Prance 16544, United States of America
• G. T. Prance 7764, Brazil
• G. T. Prance 7764, Brazil
• X. Cornejo 8030, Ecuador
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• J. L. Luteyn 4895, Colombia
• L. J. Dorr 7407, Venezuela
• J. C. Betancur B. 1538, Colombia
• M. H. Nee 3578, Panama
• M. H. Nee 3578, Panama
• M. H. Nee 4075, Venezuela
• M. H. Nee 4075, Venezuela
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 5176, Brazil
• B. A. Krukoff 1236, Brazil
• R. A. Pursell 8100, Venezuela
• R. A. Pursell 8100, Venezuela
• A. H. G. Alston 6085, Venezuela
• J. A. Steyermark 101959, Venezuela
• J. A. Steyermark 101959, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 102046, Venezuela
• J. A. Steyermark 61484, Venezuela
• J. A. Steyermark 122889, Venezuela
• J. A. Steyermark 122889, Venezuela
• J. A. Steyermark 123443, Venezuela
• J. A. Steyermark 123443, Venezuela
• J. Cuatrecasas 7598, Colombia
• G. Klug 4357, Peru
• G. Klug 2835, Peru
• D. C. Daly 8004, Brazil
• F. Ayala 2957, Peru
• H. F. Pittier 6339, Venezuela
• H. F. Pittier 11724, Venezuela
• R. L. Liesner 11168, Venezuela
• A. Ortega U. 267, Ecuador
• A. Ortega U. 201, Ecuador
• H. H. Smith 1516, Saint Vincent and the Grenadines
• T. G. Yuncker 17482, Jamaica
• T. G. Yuncker 18608, Jamaica
• B. A. Krukoff 4741, Peru
• B. A. Krukoff 4741, Peru
• A. H. Liogier 31907, Puerto Rico
• M. M. Mejía Pimentel 7691, Puerto Rico
• A. H. Gentry 18719, Peru
• A. H. Gentry 18719, Peru
• A. H. Gentry 11038, Venezuela
• A. H. Gentry 14842, Venezuela
• G. Davidse 5468, Colombia
• J. Revilla 2138, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• R. Vásquez 9388, Peru
• A. H. Gentry 25840, Peru
• R. Ferreyra: Lima, Magnoliophyta; South America
• K. R. Young 184, Peru
• D. E. Atha 819, Puerto Rico
• D. Naranjo 206, Ecuador
• D. Naranjo 206, Ecuador
• E. Freire 5049, Ecuador
• Couroupita guianensis Aubl.
• Couroupita guianensis Aubl.
• P. Mendoza Troya 300, Ecuador
• S. A. Mori s.n., Panama
• Bernardi 1172, Venezuela
• Bernardi 1172, Venezuela
• C. Diaz 933, Peru
• Aubreville, French Guiana
• B. A. Krukoff 5677, Brazil
• J. Batista 1312, Panama
• D. C. Daly 11232, Brazil
• J. Lau 1832, United States of America
• P. C. Hutchison 2842, United States of America
• O. Degener 3327, United States of America