|Florida strangler fig|
|Florida strangler fig in Deering Park, Florida|
Nutt. 1846, conserved name
Ficus aurea, commonly known as the Florida strangler fig (or simply strangler fig), golden fig, or higuerón, is a tree in the family Moraceae that is native to the U.S. state of Florida, the northern and western Caribbean, southern Mexico and Central America south to Panama. The specific epithet aurea was applied by English botanist Thomas Nuttall who described the species in 1846.
Ficus aurea is a strangler fig. In figs of this group, seed germination usually takes place in the canopy of a host tree with the seedling living as an epiphyte until its roots establish contact with the ground. After that, it enlarges and strangles its host, eventually becoming a free-standing tree in its own right. Individuals may reach 30 m (100 ft) in height. Like all figs, it has an obligate mutualism with fig wasps: figs are only pollinated by fig wasps, and fig wasps can only reproduce in fig flowers. The tree provides habitat, food and shelter for a host of tropical lifeforms including epiphytes in cloud forests and birds, mammals, reptiles and invertebrates. F. aurea is used in traditional medicine, for live fencing, as an ornamental and as a bonsai
Ficus aurea is a tree which may reach heights of 30 m (98 ft). It is monoecious: each tree bears functional male and female flowers. The size and shape of the leaves is variable. Some plants have leaves that are usually less than 10 cm (4 in) long while others have leaves that are larger. The shape of the leaves and of the leaf base also varies—some plants have leaves that are oblong or elliptic with a wedge-shaped to rounded base, while others have heart-shaped or ovate leaves with cordate to rounded bases. F. aurea has paired figs which are green when unripe, turning yellow as they ripen. They differ in size (0.6–0.8 cm [0.2–0.3 in], about 1 cm [0.4 in], or 1.0–1.2 cm [0.4–0.5 in] in diameter); figs are generally sessile, but in parts of northern Mesoamerica figs are borne on short stalks known as peduncles.
With about 750 species, Ficus (Moraceae) is one of the largest angiosperm genera (David Frodin of Chelsea Physic Garden ranked it as the 31st largest genus). Ficus aurea is classified in the subgenus Urostigma (the strangler figs) and the section Americana. Recent molecular phylogenies have shown that subgenus Urostigma is polyphyletic, but have strongly supported the validity of section Americana as a discrete group (although its exact relationship to section Galoglychia is unclear).
Thomas Nuttall described the species in the second volume of the his 1846 work The North American Sylva with specific epithet aurea ('golden' in Latin). In 1768, Scottish botanist Philip Miller described Ficus maxima, citing Carl Linnaeus' Hortus Cliffortianus (1738) and Hans Sloane's Catalogus plantarum quæ in insula Jamaica (1696). Sloane's illustration of the species, published in 1725, depicted it with figs borne singly, a characteristic of the Ficus subgenus Pharmacosycea. As a member of the subgenus Urostigma, F. aurea has paired figs. However, a closer examination of Sloane's description led Cornelis Berg to conclude that the illustration depicted a member of the subgenus Urostigma (since it had other diagnostic of that subgenus), almost certainly F. aurea, and that the illustration of singly borne figs was probably artistic license. Berg located the plant collection upon which Sloane's illustration was based and concluded that Miller's F. maxima was, in fact, F. aurea. In his description of F. aurea, which was based on plant material collected in Florida, Thomas Nuttall considered the possibility that his plants belonged to the species that Sloane had described, but came to the conclusion that it was a new species. Under the rules of botanical nomenclature, the name F. maxima has priority over F. aurea since Miller's description was published in 1768, while Nuttall's description was published in 1846.
In their 1914 Flora of Jamaica, William Fawcett and Alfred Barton Rendle linked Sloane's illustration to the tree species that was then known as Ficus suffocans, a name that had been assigned to it in August Grisebach's Flora of the British West Indian Islands. Gordon DeWolf agreed with their conclusion and used the name F. maxima for that species in the 1960 Flora of Panama. Since this use has become widespread, Berg proposed that the name Ficus maxima be conserved in the way DeWolf had used it, a proposal that was accepted by the nomenclatural committee.
Reassigning the name Ficus maxima did not leave F. aurea as the oldest name for this species, as German naturalist Johann Heinrich Friedrich Link had described Ficus ciliolosa in 1822. Berg concluded that the species Link described was actually F. aurea, and since Link's description predated Nuttall's by 24 years, priority should have been given to the name F. ciliolosa. Since the former name was widely used and the name F. ciliolosa had not been, Berg proposed that the name F. aurea be conserved. In response to this, the nomenclatural committee ruled that rather than conserving F. aurea, that it would be better to reject F. ciliolosa. Conserving F. aurea would mean that precedence would be given to that name over all others. By simply rejecting F. ciliolosa, the committee left open the possibility that the name F. aurea could be supplanted by another older name, if one were to be discovered.
In 1920, American botanist Paul C. Standley described three new species based on collections from Panama and Costa Rica—Ficus tuerckheimii, F. isophlebia and F. jimenezii. DeWolf concluded that they were all the same species, and Berg synonymised them with F. aurea. These names have been used widely for Mexican and Central American populations, and continue to be used by some authors. Berg suspected that Ficus rzedowskiana Carvajal and Cuevas-Figueroa may also belong to this species, but he had not examined the original material upon which this species was based.
Berg considered F. aurea to be a species with at least four morphs. "None of the morphs", he wrote, "can be related to certain habitats or altitudes." Thirty years earlier, William Burger had come to a very different conclusion with respect to Ficus tuerckheimii, F. isophlebia and F. jimenezii—he rejected DeWolf's synonymisation of these three species as based on incomplete evidence. Burger noted that the three taxa occupied different habitats which could be separated in terms of rainfall and elevation.
Reproduction and growthEdit
Figs have an obligate mutualism with fig wasps, (Agaonidae); figs are only pollinated by fig wasps, and fig wasps can only reproduce in fig flowers. Generally, each fig species depends on a single species of wasp for pollination. The wasps are similarly dependent on their fig species in order to reproduce. Ficus aurea is pollinated by Pegoscapus mexicanus (Ashmead).
Figs have complicated inflorescences called syconia. Flowers are entirely contained within an enclosed structure. Their only connection with the outside is through a small pore called ostiole. Monoecious figs like F. aurea have both male and female flowers within the syconium. Female flowers mature first. Once mature, they produce a volatile chemical attractant. Female wasps squeeze their way through the ostiole into the interior of the syconium. Inside the syconium, they pollinate the flowers, lay their eggs in some of them, and die. The eggs hatch and the larvae parasitise the flowers in which they were laid. After four to seven weeks (in F. aurea), adult wasps emerge. Males emerge first, mate with the females, and cut exit holes through the walls of the fig. The male flowers mature around the same time as the female wasps emerge. The newly emerged female wasps actively pack their bodies with pollen from the male flowers before leaving through the exit holes the males have cut and fly off to find a syconium in which to lay their eggs. Over the next one to five days, figs ripen. The ripe figs are eaten by various mammals and birds which disperse the seeds.
Figs flower and fruit asynchronously. Flowering and fruiting is staggered throughout the population. This fact is important for fig wasps—female wasps need to find a syconium in which to lay their eggs within a few days of emergence, something that would not be possible if all the trees in a population flowered and fruited at the same time. This also makes figs important food resources for frugivores (animals that feed nearly exclusively on fruit); figs are one of the few fruit available at times of the year when fruit are scarce.
Although figs flower asynchronously as a population, in most species flowering is synchronised within an individual. Newly emerged female wasps must move away from their natal tree in order to find figs in which to lay their eggs. This is to the advantage of the fig, since it prevents self-pollination. In Florida, individual F. aurea trees flower and fruit asynchronously. Within-tree asynchrony in flowering is likely to raise the probability of self-pollination, but it may be an adaptation that allows the species to maintain an adequate population of wasps at low population densities or in strongly seasonal climates.
|Flowering phenology in Ficus aurea|
|Phase||Description||Duration in F. aurea|
|A (pre-female)||Immature flowers||2 days to >9 months|
|B (female)||Female flowers are receptive to pollination; female wasps lay eggs and pollinate flowers||1 day to 3 weeks|
|C (interfloral)||Fig seeds and wasp larvae develop||4 to 7 weeks|
|D (male)||Male flowers mature; wasps emerge, mate and female wasps disperse||1 to 2 days|
|E (post-floral)||Fruits ripen||1 to 5 days|
Flowering phenology in Ficus has been characterised into five phases. In most figs, phase A is followed almost immediately by phase B. However, in F. aurea immature inflorescences can remain dormant for more than nine months.
Ficus aurea is a fast-growing tree. As a hemiepiphyte it germinates in the canopy of a host tree and begins life as an epiphyte before growing roots down to the ground. F. aurea is also a strangler fig (not all hemiepiphytic figs are stranglers)—the roots fuse and encircle the host tree. This usually results in the death of the host tree, since it effectively girdles the tree. Palms, which lack secondary growth, are not affected by this, but they can still be harmed by competition for light, water and nutrients. Following Hurricane Andrew in 1992, F. aurea trees regenerated from root suckers and standing trees.
Ficus aurea ranges from Florida, across the northern Caribbean to Mexico, and south across Central America. It is present in central and southern Florida and the Florida Keys, The Bahamas, the Caicos Islands, Hispaniola, Cuba, Jamaica, the Cayman Islands, San Andrés (a Colombian possession in the western Caribbean), southern Mexico, Belize, Guatemala, Honduras, Nicaragua, El Salvador, Costa Rica and Panama. It grows from sea level up to 1,800 m (5,500 ft) above sea level, in habitats ranging from Bahamian dry forests, to cloud forest in Costa Rica.
Ficus aurea is found in central and southern Florida as far north as Volusia County; it is one of only two native fig species in Florida. The species is present in a range of south Florida ecosystems, including coastal hardwood hammocks, cabbage palm hammocks, tropical hardwood hammocks and shrublands, temperate hardwood hammocks and shrublands and along watercourses. In The Bahamas, F. aurea is found in tropical dry forests on North Andros, Great Exuma and Bimini. F. aurea occurs in 10 states in Mexico, primarily in the south, but extending as far north as Jalisco. It is found in tropical deciduous forest, tropical semi-evergreen forest, tropical evergreen forest, cloud forest and in aquatic or subaquatic habitats.
Ficus aurea is a strangler fig—it tends to establish on a host tree which it gradually encircles and "strangles", eventually taking the place of that tree in the forest canopy. While this makes F. aurea an agent in the mortality of other trees, there is little to indicate that its choice of hosts is species specific. However, in dry forests on Great Exuma in The Bahamas, F. aurea establishes exclusively on palms, in spite of the presence of several other large trees that should provide suitable hosts. Eric Swagel and colleagues attributed this to the fact that humus accumulates on the leaf bases of these palms and provides a relatively moist microclimate in a dry environment, facilitating seedling survival.
Figs are sometimes considered to be potential keystone species in communities of fruit-eating animals because of their asynchronous fruiting patterns. Nathaniel Wheelwright reports that emerald toucanets fed on unripe F. aurea fruit at times of fruit scarcity in Monteverde, Costa Rica. Wheelwright listed the species as a year-round food source for the resplendent quetzal at the same site. In the Florida Keys, F. aurea is one of five fruit species that dominate the diet fed by white-crowned pigeons to their nestlings. F. aurea is also important in the diet of mammalian frugivores—both fruit and young leaves are consumed by black howler monkeys in Belize.
The interaction between figs and fig wasps is especially well-known (see section on reproduction, above). In addition to its pollinators (Pegoscapus mexicanus), F. aurea is exploited by a group of non-pollinating chalcidoid wasps whose larvae develop in its figs. These include gallers, inquilines and kleptoparasites as well as parasitoids of both the pollinating and non-pollinating wasps.
The invertebrates within F. aurea syconia in southern Florida include a pollinating wasp, P. mexicanus, up to eight or more species of non-pollinating wasps, a plant-parasitic nematode transported by the pollinator, mites, and a predatory rove beetle whose adults and larvae eat fig wasps. Nematodes: Schistonchus aureus (Aphelenchoididae) is a plant-parasitic nematode associated with the pollinator Pegoscapus mexicanus and syconia of F. aurea. Mites: belonging to the family Tarsonemidae (Acarina) have been recognized in the syconia of F. aurea and F. citrifolia, but they have not been identified even to genus, and their behavior is undescribed. Rove beetles: Charoxus spinifer is a rove beetle (Coleoptera: Staphylinidae) whose adults enter late-stage syconia of F. aurea and F. citrifolia. Adults eat fig wasps; larvae develop within the syconia and prey on fig wasps, then pupate in the ground.
As a large tree, F. aurea can be an important host for epiphytes. In Costa Rican cloud forests, where F. aurea is "the most conspicuous component" of intact forest, trees in forest patches supported richer communities of epiphytic bryophytes, while isolated trees supported greater lichen cover.
Florida International University ecologist Suzanne Koptur reported the presence of extrafloral nectaries on F. aurea figs in the Florida Everglades. Extrafloral nectaries are structures which produce nectar but are not associated with flowers. They are usually interpreted as defensive structure and are often produced in response to attack by insect herbivores. They attract insects, primarily ants, which defend the nectaries, thus protecting the plant against herbivores.
The fruit of Ficus aurea is edible and was used for food by the indigenous people and early settlers in Florida; it is still eaten occasionally as a backyard source of native fruit. The latex was used to make a chewing gum, and aerial roots may have been used to make lashings, arrows, bowstrings and fishing lines. The fruit was used to make a rose-coloured dye. F. aurea was also used in traditional medicine in The Bahamas and Florida. Allison Adonizio and colleagues screened F. aurea for anti-quorum sensing activity (as a possible means of anti-bacterial action), but found no such activity.
Individual F. aurea trees are common on dairy farms in La Cruz, Cañitas and Santa Elena in Costa Rica, since they are often spared when forest is converted to pasture. In interviews, farmers identified the species as useful for fence posts, live fencing and firewood, and as a food species for wild birds and mammals.
Ficus aurea is used as an ornamental tree, an indoor tree and as a bonsai. Like other figs, it tends to invade built structures and foundations, and need to be removed to prevent structural damage. Although young trees are described as "rather ornamental", older trees are considered to be difficult to maintain (because of the adventitious roots that develop off branches) and are not recommended for small areas. However, it was considered a useful tree for "enviroscaping" to conserve energy in south Florida, since it is "not as aggressive as many exotic fig species," although it must be given enough space.
- Brummitt, R.K. (2005). "Report of the Committee for Spermatophyta: 56". Taxon. 54 (2): 527–536. doi:10.2307/25065389. JSTOR 25065389.
- "The Plant List".
- Harvey, C. A.; Haber, W. A. (1998). "Remnant trees and the conservation of biodiversity in Costa Rican pastures". Agroforestry Systems. 44 (1): 37–68. doi:10.1023/A:1006122211692.
- Berg, C.C. (2007). "Proposals for treating four species complexes in Ficus subgenus Urostigma section Americanae (Moraceae)". Blumea. 52 (2): 295–312. doi:10.3767/000651907X609034.
- Flora de Nicaragua database. Tropicos. (in Spanish) Retrieved on 2008-07-02
- Bronstein, Judith L.; Patel, Aviva (1992). "Causes and Consequences of Within-Tree Phenological Patterns in the Florida Strangling Fig, Ficus aurea (Moraceae)". American Journal of Botany. 79 (1): 41–48. doi:10.2307/2445195. JSTOR 2445195.
- Gilman, Edward F.; Watson, Dennis G. (December 2006). "Ficus aurea: Strangler Fig". Institute of Food and Agricultural Sciences (ENH409). Retrieved 2008-06-10.
- Frodin, David G. (2004). "History and concepts of big plant genera". Taxon. 53 (3): 753–776. doi:10.2307/4135449. JSTOR 4135449.
- Rønsted, N.; Weiblen, G. D.; Clement, W. L.; Zerega, N. J. C.; Savolainen, V. (2008). "Reconstructing the phylogeny of figs (Ficus, Moraceae) to reveal the history of the fig pollination mutualism" (PDF). Symbiosis. 45 (1–3): 45–56.
- Berg, Cornelis C. (May 2003). "(1587–1590) Proposals to conserve the names Ficus citrifolia against F. caribaea, F. maxima with a conserved type, F. aurea against F. ciliolosa, and F. americana against F. perforata (Moraceae)". Taxon. 52 (2): 368–370. doi:10.2307/3647421. JSTOR 3647421.
- Simpson DP (1979). Cassell's Latin Dictionary (5th ed.). London: Cassell Ltd. p. 883. ISBN 0-304-52257-0.
- Sloane, Hans (1725). A voyage to the islands Madera, Barbados, Nieves, S. Christophers and Jamaica. B.M.
- Grisebach, August (1859). Flora of the British West Indian Islands. 1. London: L. Reeve & Co. Retrieved 2008-07-02.
- DeWolf, Gordon P., Jr. "Ficus (Tourn.) L." in Nevling, Lorin I., Jr. (1960). "Flora of Panama. Part IV. Fascicle II". Annals of the Missouri Botanical Garden. 47 (2): 81–203. doi:10.2307/2394704. JSTOR 2394704.
- Standley, Paul C. (1920). "The Mexican and Central American Species of Ficus". Contributions from the United States National Herbarium. 20 (1): 1–35.
- Burger, William C. (1974). "Ecological Differentiation in Some Congeneric Species of Costa Rican Flowering Plants". Annals of the Missouri Botanical Garden. 61 (2): 297–306. doi:10.2307/2395057. JSTOR 2395057.
- Jousselin, Emmanuelle; Hossaert-Mckey, Martine; Vernet, Didier; Kjellberg, Finn (2001). "Egg deposition patterns of fig pollinating wasps: implications for studies on the stability of the mutualism". Ecological Entomology. 26 (6): 602–608. doi:10.1046/j.1365-2311.2001.00368.x.
- Janzen, Daniel H. (1979). "How to be a fig". Annual Review of Ecology and Systematics. 10: 13–51. doi:10.1146/annurev.es.10.110179.000305.
- Bronstein, Judith L.; Hossaert-McKey, Martine (1995). "Hurricane Andrew and a Florida Fig Pollination Mutualism: Resilience of an Obligate Interaction". Biotropica. 27 (3): 373–381. doi:10.2307/2388922. JSTOR 2388922.
- Broschat, Timothy K.; Alan W. Meerow; Robert J. Black (February 2007). "Enviroscaping to Conserve Energy: Trees for South Florida". Institute of Food and Agricultural Sciences (Circular EES-42). Retrieved 2008-06-10.
- Putz, Francis E.; N. Michele Holbrook (1989). "Strangler Fig Rooting Habits and Nutrient Relations in the Llanos of Venezuela". American Journal of Botany. 76 (6): 781–788. doi:10.2307/2444534. JSTOR 2444534.
- Horvitz, Carol C.; Pascarella, John B.; McMann, Stephen; Freedman, Andrea; Hofstetter, Ronald H. (1988). "Functional Roles of Invasive Non-Indigenous Plants in Hurricane-Affected Subtropical Hardwood Forests". Ecological Applications. 8 (4): 947–974. doi:10.1890/1051-0761(1998)008[0947:FROINI]2.0.CO;2. ISSN 1051-0761.
- Little, Elbert L. Jr. (1978). Atlas of United States Trees, Volume 5: Florida. Washington, D.C.: U.S. Forest Service. OCLC 241660.
- Serrato, Alejandra; Ibarra-Manríquez, Guillermo; Oyama, Ken (March 2004). "Biogeography and conservation of the genus Ficus (Moraceae) in Mexico". Journal of Biogeography. 31 (3): 475–485. doi:10.1046/j.0305-0270.2003.01039.x.
- Ficus aurea Nutt. Flora Mesoamericana: Lista Anotada. (in Spanish) Retrieved on 2008-07-02
- Swagel, Eric N.; Bernhard, A. Van H.; Ellmore, George S. (1997). "Substrate water potential constraints on germination of the strangler fig Ficus aurea (Moraceae)". American Journal of Botany. 84 (5): 716–722. doi:10.2307/2445908. JSTOR 2445908.
- Sillett, Stephen C.; Gradstein, S. Rob; Griffin, Dana, III (1995). "Bryophyte Diversity of Ficus Tree Crowns from Cloud Forest and Pasture in Costa Rica". The Bryologist. 98 (2): 251–260. doi:10.2307/3243312. JSTOR 3243312.
- "Ficus aurea: Distribution Map". Atlas of Florida Vascular Plants. Institute for Systematic Botany, University of South Florid. Retrieved 2008-06-10.
- Bessey, Ernst A. (1908). "The Florida Strangling Figs". Missouri Botanical Garden Annual Report. 1908: 25–33. doi:10.2307/2400063. JSTOR 2400063.
- Ken Rutchey; et al. (2006). "Vegetation Classification for South Florida Natural Areas". United States Geological Survey. Retrieved 2008-06-10. Open-File Report 2006-1240.
- Smith, Inge K.; Vankat, John L. (1992). "Dry Evergreen Forest (Coppice) Communities of North Andros Island, Bahamas". Bulletin of the Torrey Botanical Club. 119 (2): 181–191. doi:10.2307/2997030. JSTOR 2997030.
- Howard, Richard A. (1950). "Vegetation of the Bimini Island Group: Bahamas, B. W. I". Ecological Monographs. 20 (4): 317–349. doi:10.2307/1943569. JSTOR 1943569.
- Terborgh, John (1986). "Keystone plant resources in the tropical forests". In Michael E. Soulé. Conservation Biology: The Science of Scarcity and Diversity. Sunderland, Massachusetts: Sinauer Associates. pp. 330–344. ISBN 978-0-87893-795-0.
- Wheelwright, Nathaniel T. (June 1985). "Competition for dispersers, and the timing of flowering and fruiting in a guild of tropical trees" (PDF). Oikos. 44 (3): 465–477. doi:10.2307/3565788. JSTOR 3565788.
- Wheelwright, Nathaniel T. (1983). "Fruits and the Ecology of Resplendent Quetzals" (PDF). The Auk. 100 (2): 286–301.
- Bancroft, G. Thomas; Reed Bowman (1994). "Temporal Patterns in Diet of Nestling White-Crowned Pigeons: Implications for Conservation of Frugivorous Columbids" (PDF). The Auk. 111 (4): 844–52. doi:10.2307/4088816.
- Silver, S. C.; L. E. T. Ostro; C. P. Yeager; R. Horwich (1999). "Feeding ecology of the black howler monkey (Alouatta pigra) in Northern Belize" (PDF). American Journal of Primatology. 45 (3): 263–279. doi:10.1002/(SICI)1098-2345(1998)45:3<263::AID-AJP3>3.0.CO;2-U. PMID 9651649.
- Bronstein, Judith L. (1999). "Natural History of Anidarnes bicolor (Hymenoptera: Agaonidae), a Galler of the Florida Strangling Fig (Ficus aurea)" (PDF). Florida Entomologist. 82 (3): 454–461. doi:10.2307/3496871. JSTOR 3496871.
- Nadel, Hannah; Frank, J. Howard; Knight, R. J., Jr. (March 1992). "Escapees and Accomplices: The Naturalization of Exotic Ficus and Their Associated Faunas in Florida". Florida Entomologist. 75 (1): 29–38. doi:10.2307/3495478. JSTOR 3495478.
- Decrappeo, N.; Giblin-Davis, R. M. (2001). "Schistonchus aureus n. sp. and S. laevigatus n. sp. (Aphelenchoididae): Associates of native Floridian Ficus spp. and their Pegoscapus pollinators (Agaonidae)". Journal of Nematology. 33 (2–3): 91–103. PMC . PMID 19266003.
- Frank, J. H.; Thomas, M. C. (1997). "A new species of Charoxus (Coleoptera: Staphylinidae) from native figs (Ficus spp.) in Florida". Journal of the New York Entomological Society. 104: 70–78.
- Frank, J. H.; Nadel, Hannah (2012). "Life cycle and behaviour of Charoxus spinifer and Charoxus major (Coleoptera: Staphylinidae: Aleocharinae), predators of fig wasps (Hymenoptera: Agaonidae)". Journal of Natural History. 46 (9–10): 621–635. doi:10.1080/00222933.2011.651641.
- Koptur, Suzanne (1992). "Plants with Extrafloral Nectaries and Ants in Everglades Habitats" (PDF). Florida Entomologist. 75 (1): 38–50. doi:10.2307/3495479. JSTOR 3495479.
- Heil, Martin (2007). "Indirect defence via tritrophic interactions". New Phytologist. 178 (1): 41–61. doi:10.1111/j.1469-8137.2007.02330.x. PMID 18086230.
- Bronstein, Judith L.; Alarcón, Ruben; Geber, Monica (2006). "The evolution of plant–insect mutualisms". New Phytologist. 172 (3): 412–428. doi:10.1111/j.1469-8137.2006.01864.x. PMID 17083673.
- Allen, Ginger M.; Bond, Michael D.; Main, Martin B. (December 2002). "50 Common Native Plants Important In Florida's Ethnobotanical History". Institute of Food and Agricultural Sciences (Circular 1439). Retrieved 2008-06-10.
- Eldridge, Joan (October 1975). "Bush medicine in the Exumas and Long Island, Bahamas. A field study". Economic Botany. 29 (4): 307–332. doi:10.1007/BF02862180.
- Adonizio, Allison L.; Downum, Kelsey; Bennett, Bradley C.; Mathee, Kalai (2006). "Anti-quorum sensing activity of medicinal plants in southern Florida". Journal of Ethnopharmacology. 105 (3): 427–435. doi:10.1016/j.jep.2005.11.025. PMID 16406418.