Ficus maxima

Ficus maxima
Scientific classification
Kingdom: Plantae
(unranked): Angiosperms
(unranked): Eudicots
(unranked): Rosids
Order: Rosales
Family: Moraceae
Genus: Ficus
Species: F. maxima
Binomial name
Ficus maxima
Mill.
Synonyms

Ficus bopiana Rusby
Ficus chaconiana Standl. & L.O. Williams
Ficus citrifolia Lam.
Ficus coybana Miq.
Ficus glaucescens (Liebm.) Miq.
Ficus guadalajarana S.Watson
Ficus guapoi Hassl.
Ficus hernandezii (Liebm.) Miq.
Ficus mexicana (Miq.) Miq.
Ficus murilloi Dugand
Ficus murilloi var cajambrensis Dugand
Ficus myxaefolia Kunth & Bouché
Ficus parkeri Miq.
Ficus picardae Warb.
Ficus plumieri Urb.
Ficus protensa (Griseb.) Hemsl.
Ficus pseudoradula (Miq.) Miq.
Ficus radula Humb. & Bonpl. ex Willd.
Ficus rubricosta Warb.
Ficus sodiroi Rossberg
Ficus subscabrida Warb.
Ficus suffocans Banks ex Griseb.
Ficus ulei Rossberg
Ficus vicencionis Dugand
Pharmacosycea glaucescens Liebm.
Pharmacosycea grandaeva Miq.
Pharmacosycea guyanensis Miq.
Pharmacosycea hernandezii Liebm.
Pharmacosycea mexicana Miq.
Pharmacosycea pseudoradula Miq.
Pharmacosycea radula (Humb. & Bonpl. ex Willd.) Liebm.
Pharmacosycea radula (Humb. & Bonpl. ex Willd.) Miq.
Pharmacosycea rigida Miq.
Urostigma laurifolium (Hort. ex Lam.) Miq.
Urostigma protensum Griseb.[1]

Ficus maxima is a fig tree which is native to Mexico, Central America, the Caribbean and South America south to Paraguay. Figs belong to the family Moraceae. The specific epithet maxima was coined by Scottish botanist Philip Miller in 1768; Miller's name was applied to this species in the Flora of Jamaica, but it was later determined that Miller's description was actually of the species now known as Ficus aurea. To avoid confusion, Cornelis Berg proposed that the name should be conserved for this species. Berg's proposal was accepted in 2005.

Individuals may reach heights of 30 m (98 ft). Like all figs it has an obligate mutualism with fig wasps; F. maxima is only pollinated by the fig wasp Tetrapus americanus, and T. americanus only reproduces in its flowers. F. maxima fruit and leaves are important food resources for a variety of birds and mammals. It is used in a number of herbal medicines across its range.

Description

Ficus maxima is a tree which ranges from 5–30 m (16–98 ft) tall. Leaves vary in shape from long and narrow to more oval, and range from 6–24 (cm) (2–9 in) long and from 2.5–12 cm (0.98–4.72 in) wide.[2] F. maxima is monoecious; each tree bears functional male and female flowers.[3] The figs are borne singly and are 1–2 cm (0.39–0.79 in) in diameter (sometimes up to 2.5 cm [1 in]).[4]

Taxonomy

With about 750 species, Ficus (Moraceae) is one of the largest angiosperm genera. (Frodin ranked it as the 31st largest.)[5] Ficus maxima is classified in subgenus Pharmacosycea,[6] section Pharmacosycea,[3] subsection Petenenses.[7] Although recent work suggests that subgenus Pharmacosycea is polyphyletic, section Pharmacosycea appears to be monophyletic and is a sister group to the rest of the genus Ficus.[8]

Hans Sloane's original illustration of Ficus maxima indica, the earliest illustration of Ficus aurea and the basis of Thomas Miller's Ficus maxima. The unpaired figs in the illustration led to confusion as to the identity of the species described by Miller.

In 1768, Scottish botanist Philip Miller described Ficus maxima,[9] citing Linnaeus' Hortus Cliffortianus (1738) and Hans Sloane's Catalogus plantarum quæ in insula Jamaica (1696). Sloane's illustration of this plant (published in his 1725 A voyage to the islands Madera, Barbados, Nieves, S. Christophers and Jamaica) depicted it with figs borne singly, a characteristic of the Ficus subgenus Pharmacosycea. A closer examination of Sloane's description led Cornelis Berg to conclude that the illustration depicted a member of the subgenus Urostigma, 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.[6]

In 1806 the name Ficus radula was applied to material belonging to this species. The description, based on material collected in Venezuela by German naturalist Alexander von Humboldt and French botanist Aimé Bonpland, was published in Carl Ludwig Willdenow's fourth edition of Linnaeus' Species Plantarum. This is the oldest description that can unequivocally be applied to this species.[6] In 1847 Danish botanist Frederik Michael Liebmann applied the name Pharmacosycea glaucescens to Mexican material belonging to this species.[1] (It was transferred to the genus Ficus by Dutch botanist Friedrich Anton Wilhelm Miquel in 1867.)[1] In 1849 the name Ficus suffocans was applied to Jamaican material belonging to this species in August Grisebach's Flora of the British West Indian Islands.[10]

In their 1914 Flora of Jamaica, William Fawcett and Alfred Barton Rendle linked Sloane's illustration to F. suffocans. Gordon DeWolf agreed with their conclusion and used the name F. maxima for that species in the 1960 Flora of Panama, supplanting F. radula and F. glaucescens.[2] Since this use has become widespread, Berg proposed that the name Ficus maxima be conserved in the way DeWolf had used it with a new type (Krukoff's 1934 collection from Amazonas, Brazil).[6] This proposal was accepted by the nomenclatural committee in 2005.[11]

Common names

Ficus maxima ranges from the northern Caribbean to southern South America, in countries where English, Spanish, Portuguese and a variety of indigenous languages are spoken. Across this range, it is known by a variety of common names.

Common names of Ficus maxima
Common name Usage
Amäk wäm Lacandon Maya in Chiapas, Mexico[12]
Amate Mexico[12]
Caxinguba Brazil[13]
Hicatee Fig Belize[14]
Higillo Honduras[15]
Higueron Ecuador[16]
Maja Tacana of Bolivia[17]
Matapal Trinidad and Tobago[18]
Sàhàshá Paya of Honduras[19]
White fig Jamaica[20]

Reproduction

Figs have an obligate mutualism with fig wasps (Agaonidae); figs are only pollinated by fig wasps, and fig wasps are only able to reproduce in fig flowers. Generally, each fig species depends on a single species of fig wasp for pollination, and each species of fig wasp can only reproduce in the flowers of a single species of fig tree. Ficus maxima is pollinated by Tetrapus americanus,[3] although recent work suggests that the species known as T. americanus is a cryptic species complex of at least two species, which are not sister taxa.[21]

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. maxima have both male and female flowers within the syconium.[22] Female flowers mature first. Once mature, they produce a volatile chemical attractant which is recognised by female wasps belonging to the species Tetrapus americanus. Female wasps of this species are about 2 mm (0.079 in) long and are capable of producing about 190 offspring.[3]

Female fig wasps arrive carrying pollen from their natal tree and squeeze their way through the ostiole into the interior of the syconium. The syncomium bears 500–600 female flowers arranged in multiple layers - those that are closer to the outer wall of the fig have short pedicels and long styles, while those that are located closer to the interior of the chamber have long pedicels and short styles. Female wasps generally lay their eggs in the short-styled flowers, while longer-styled flowers were more likely to be pollinated. The eggs hatch and the larvae parasitise the flowers in which they were laid. Pollinated flowers which have not been parasitised give rise to seeds.[3]

Male wasps mature and emerge before the females. They mate with the females, which have not yet emerged from their galls. Males cut exit holes in the outer wall of the syconium, through which the females exit the fig.[23] The male flowers mature around the same time as the female wasps emerge and shed their pollen on the newly emerged females; like about one third of figs, F. maxima is passively pollinated.[3] The newly emerged female wasps leave through the exit holes the males have cut and fly off to find a syconium in which to lay their eggs. The figs then ripen.[23] The ripe figs are eaten by a variety of mammals and birds which disperse the seeds.

Distribution

Ficus maxima ranges from Paraguay and Bolivia in the south to Mexico in the north, where it is widespread and common. It is found in fourteen states across the southern and central portion of the country. It occurs in tropical deciduous forest, tropical semi-evergreen forest, tropical evergreen forest, oak forest and in aquatic or subaquatic habitats.[24] It is found throughout Central America - in Guatemala, Belize, Honduras, Nicaragua, El Salvador, Costa Rica and Panama. It is present in Cuba and Jamaica in the Greater Antilles, and Trinidad and Tobago in the southern Caribbean. In South America it ranges through Colombia, Venezuela, Guyana, Suriname, French Guiana, Ecuador, Peru, Bolivia, Paraguay and in the Brazilian states of Amapá, Amazonas, Mato Grosso, Minas Gerais, Pará.[25]

Ecology

Figs are sometimes considered to be potential keystone species for communities of fruit-eating animals; their asynchronous fruiting patterns may cause them to be important fruit sources when other food sources are scarce.[26] At Tinigua National Park in Colombia Ficus maxima was an important fruit producer during periods of fruit scarcity in one of three years. This led Colombian ecologist Pablo Stevens to consider it a possible keystone species, but he decided against including it in his final list of potential keystone species at the site.[27]

Ficus maxima fruit are consumed by birds and mammals. These animals act as seed dispersers when the defaecate or regurgitate intact seeds, or when they drop fruit below the parent tree.[28] In Panama, F. maxima fruit were reported to have relatively high levels of protein and low levels of water-soluble carbohydrates in a study of Ficus fruit consumed by bats.[29]

Black howler monkeys in Belize consume fruit and young and mature leaves of F. maxima.[30] In southern Veracruz, Mexico, F. maxima was the third most important food source for a studied population of Mexican howler monkeys; they consumed young leaves, mature leaves, mature fruit and petioles.[31] Venezuelan red howlers were observed feeding F. maxima fruit in Colombia.[32]

The interaction between figs and fig wasps is especially well-known (see section on reproduction, above). In addition to their pollinators, Ficus species are exploited by a group of non-pollinating chalcidoid wasps whose larvae develop in its figs. Both pollinating and non-pollinating wasps serve as hosts for parasitoid wasps.[23] In addition to T. americanus, F. maxima figs from Brazil were found to contain non-pollinating wasps belonging to the genus Critogaster, mites, ants, beetles, and dipteran and lepidopteran larvae.[33] Norwegian biologist Frode Ødegaard recorded a total of 78 phytophagous (plant-eating) insect species on a single F. maxima tree in Panamanian dry forest—59 wood eating insects, 12 which fed on green plant parts, and 7 flower visitors. It supported the fourth most specialised phytophagous insect fauna and the second largest wood-feeding insect fauna among the 24 tree species sampled.[34]

Uses

Ficus maxima is used by the Lacandon Maya to treat snakebite. Leaves are moistened by chewing and applied to the bite.[12] In the provinces of Loja and Zamora-Chinchipe in Ecuador, a leaf infusion is used to treat internal inflammations.[16] The Paya of Honduras use the species for firewood, and to treat gingivitis.[19] The Tacana of Bolivia use the latex to treat intestinal parasites,[17] as do people in Guatemala's Petén Department.[35] In Brazil it is used as an anthelmintic, antirheumatic, anti-anaemic and antipyretic.[13] The latex is also used to bind limestone soils to produce cal, an adobe cement.[35]

Gaspar Diaz M. and colleagues isolated four methoxyflavones from F. maxima leaves.[13] David Lentz and colleagues observed antimicrobial activity in Ficus maxima extracts.[15]

References

  1. 1 2 3 "Ficus maxima Mill. Synonyms". Tropicos.org. Missouri Botanical Garden. Retrieved 2008-06-27.
  2. 1 2 DeWolf, Gordon P., Jr. 1960. Ficus (Tourn.) L. In Lorin I. Nevling, Jr., Flora of Panama. Part IV. Fascicle II. Annals of the Missouri Botanical Garden, 47 (2):81–203
  3. 1 2 3 4 5 6 Jousselin, Emmanuelle; Finn Kjellberg; Edward Allen Herre (2004). "Flower specialization in a passively pollinated monoecious fig: A question of style and stigma?" (PDF). International Journal of Plant Sciences. 165 (4): 587–593. doi:10.1086/386558.
  4. Flora de Nicaragua database. Tropicos. (Spanish) Retrieved on 2008-07-05.
  5. Frodin, David G. (2004). "History and concepts of big plant genera". Taxon. Taxon, Vol. 53, No. 3. 53 (3): 753–776. doi:10.2307/4135449. JSTOR 4135449.
  6. 1 2 3 4 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. Taxon, Vol. 52, No. 2. 52 (2): 368–370. doi:10.2307/3647421. JSTOR 3647421.
  7. Berg, C. C. (2006). "The subdivision of Ficus subgenus Pharmacosycea Section Pharmacosycea (Moraceae)". Blumea. 51 (1): 147–151. doi:10.3767/000651906x622409.
  8. Rønsted, N.; G.D. Weiblen; W.L. Clement; N.J.C. Zerega; V. Savolainen (2008). "Reconstructing the phylogeny of figs (Ficus, Moraceae) to reveal the history of the fig pollination mutualism" (PDF). Symbiosis. 45 (1–3): 45–56.
  9. Miller, Philip (1768). The Gardeners Dictionary: Containing the Best and Newest Methods of Cultivating and Improving The Kitchen, Fruit, Flower Garden, and Nursery; As also for Performing The Practical Parts of Agriculture: Including the Management of Vineyards, With The Methods of Making and Preserving Wine, According to the present Practice of The most skilful Vignerons in the several Wine Countries in Europe. Together With Directions for Propagating and Improving, From Real Practice and Experience, All Sorts of Timber Trees (Eighth ed.). London: Printed for the Author.
  10. Grisebach, August (1859). Flora of the British West Indian Islands. 1. London: L. Reeve & Co. Retrieved 2008-07-02.
  11. Brummitt, R.K. (May 2005). "Report of the Committee for Spermatophyta: 56". Taxon. Taxon, Vol. 54, No. 2. 54 (2): 527–536. doi:10.2307/25065389. JSTOR 25065389.
  12. 1 2 3 Kashanipour, Ryan Amir; R. Jon McGee (2004). "Northern Lacandon Maya Medicinal Plant Use in the Communities of Lacanja Chan Sayab and Naha', Chiapas, Mexico" (PDF). Journal of Ecological Anthropology. 8: 47–66. doi:10.5038/2162-4593.8.1.3.
  13. 1 2 3 Diaz M., Gaspar; Alberto C. Arruda; Mara S. P. Arruda; Adolfo H. Müller (1997). "Methoxyflavones from Ficus maxima". Phytochemistry. 45 (8): 1697–99. doi:10.1016/S0031-9422(96)00729-7.
  14. Mars, Laura K.; Bette A. Loiselle (2003). "Recruitment of Black Howler Fruit Trees in Fragmented Forests of Northern Belize". International Journal of Primatology. 24 (1): 65–86. doi:10.1023/A:1021446512364.
  15. 1 2 Lentz, David L.; Alice M. Clark; Charles D. Hufford; Barbara Meurer-Grimes; Claus M. Passreiter; Javier Cordero; Omar Ibrahimi; Adewole L. Okunade (1998). "Antimicrobial properties of Honduran medicinal plants". Journal of Ethnopharmacology. 63 (3): 253–63. doi:10.1016/S0378-8741(98)00100-7. PMID 10030730.
  16. 1 2 Tene, Vicente; Omar Malagón; Paola Vita Finzi; Giovanni Vidari; Chabaco Armijos; Tomás Zaragoza (2007). "An ethnobotanical survey of medicinal plants used in Loja and Zamora-Chinchipe, Ecuador". Journal of Ethnopharmacology. 111 (1): 63–81. doi:10.1016/j.jep.2006.10.032. PMID 17137737.
  17. 1 2 Bourdy, G.; S. J. DeWalt; L. R. Chávez de Michel; A. Roca; E. Deharo; V. Muñoz; L. Balderrama; C. Quenevo; A. Gimenez (2000). "Medicinal plants uses of the Tacana, an Amazonian Bolivian ethnic group". Journal of Ethnopharmacology. 70 (2): 87–109. doi:10.1016/S0378-8741(99)00158-0. PMID 10771199.
  18. Homer, Floyd; Kishore Lal; Winston Johnson (1998). "Forest species regeneration and management options in the Melajo Nature Reserve, Trinidad and Tobago". Environmental Conservation. 25: 53–64. doi:10.1017/S0376892998000095.
  19. 1 2 Lentz, David L. (1993). "Medicinal and other economic plants of the Paya of Honduras". Economic Botany. 47 (4): 358–70. doi:10.1007/BF02907349.
  20. Pregill, Gregory K.; Ronald I. Crombie; David W. Steadman; Linda A. Gordon; Frank W. Davis; William B. Hilgartner (July 1991). "Living and late Holocene fossil vertebrates and the vegetation of the Cockpit Country, Jamaica" (PDF). Atoll Research Bulletin. 353: 1–19. doi:10.5479/si.00775630.353.1.
  21. Molbo, Drude; Carlos A. Machado; Jan G. Sevenster; Laurent Keller; Edward Allen Herre (2003). "Cryptic species of fig-pollinating wasps: Implications for the evolution of the fig–wasp mutualism, sex allocation, and precision of adaptation". Proceedings of the National Academy of Sciences USA. 100 (10): 5867–72. doi:10.1073/pnas.0930903100. PMC 156293Freely accessible. PMID 12714682.
  22. 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. ISSN 0066-4162.
  23. 1 2 3 Kjellberg, Finn; Emmanuelle Jousselin; Martine Hossaert-McKey; Jean-Yves Rasplus (2005). "Biology, ecology and evolution of fig-pollinating wasps (Chalcidoidea, Agaonidae)" (PDF). In A. Raman; Carl W. Schaefer; Toni M. Withers (eds.). Biology, Ecology, and Evolution of Gall-inducing Arthropods. Enfield (NH) USA, Plymouth, UK: Science publishers, Inc. pp. 539–572. ISBN 978-1-57808-262-9.
  24. Serrato, Alejandra; Guillermo Ibarra-Manríquez; Ken Oyama (March 2004). "Biogeography and conservation of the genus Ficus (Moraceae) in Mexico". Journal of Biogeography. 31 (3): 475–85. doi:10.1046/j.0305-0270.2003.01039.x.
  25. "Ficus maxima Mill.". U.S. National Plant Germplasm System. Beltsville, Maryland: National Germplasm Resources Laboratory. Retrieved 2008-06-28.
  26. Terborgh, John (1986). "Keystone plant resources in the tropical forests". In Michael E. Soulé (ed.). Conservation Biology: The Science of Scarcity and Diversity. Sunderland, Massachusetts: Sinauer Associates. pp. 330–44. ISBN 978-0-87893-795-0.
  27. Stevenson, Pablo (2005). "Potential Keystone Plant Species for the Frugivore Community at Tinigua Park, Colombia". In J. Lawrence Dew; Jean Philippe Boubli (eds.). Tropical Fruits and Frugivores: The Search for Strong Interactors. Springer Netherlands. pp. 37–57. doi:10.1007/1-4020-3833-X. ISBN 978-1-4020-3833-4.
  28. Jones, Matthew B. (April 1994). "Secondary Seed Removal by Ants, Beetles, and Rodents in a Neotropical Moist Forest". M.S. Thesis. University of Florida. Retrieved 2008-07-03.
  29. Wendeln, Marcia C.; James R. Runkle; Elisabeth K. V. Kalko (2000). "Nutritional Values of 14 Fig Species and Bat Feeding Preferences in Panama" (PDF). Biotropica. 32 (3): 489–501. doi:10.1646/0006-3606(2000)032[0489:NVOFSA]2.0.CO;2. ISSN 0006-3606.
  30. 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): 263–79. doi:10.1002/(SICI)1098-2345(1998)45:3<263::AID-AJP3>3.0.CO;2-U. PMID 9651649.
  31. Serio-Silva, Juan Carlos; Victor Rico-Gray; Laura Teresa Hernández-Salazar; Rene Espinosa-Gómez (2002). "The role of Ficus (Moraceae) in the diet and nutrition of a troop of Mexican howler monkeys, Alouatta palliata mexicana, released on an island in southern Veracruz, Mexico". Journal of Tropical Ecology. 18 (6): 913–28. doi:10.1017/S0266467402002596.
  32. Stevenson, Pablo R.; Maria Clara Castellanos; Juan Carlos Pizarro; Mariaximena Garavito (2002). "Effects of Seed Dispersal by Three Ateline Monkey Species on Seed Germination at Tinigua National Park, Colombia". International Journal of Primatology. 23 (6): 1187–1204. doi:10.1023/A:1021118618936.
  33. Nazareno, Alison G.; Ranyse B. Querino da Silva II; Rodrigo A. S. Pereira (2007). "Fauna de Hymenoptera em Ficus spp. (Moraceae) na Amazônia Central, Brasil". Iheringia. Série Zoologia, Porto Alegre (in Portuguese). 97 (4): 441–46. doi:10.1590/S0073-47212007000400013.
  34. Ødegaard, Frode (2000). "The relative importance of trees versus lianas as hosts for phytophagous beetles (Coleoptera) in tropical forests". Journal of Biogeography. 27 (2): 283–96. doi:10.1046/j.1365-2699.2000.00404.x.
  35. 1 2 Mutchnick, Patrice A.; Brian C. McCarthy (1997). "An ethnobotanical analysis of the tree species common to the subtropical moist forests of the Petén, Guatemala". Economic Botany. 52 (1): 158–83. doi:10.1007/BF02893110.

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