Vachellia drepanolobium

(Redirected from Whistling thorn)

Vachellia drepanolobium, more commonly known as Acacia drepanolobium or whistling thorn,[1] is a swollen-thorn acacia native to East Africa. The whistling thorn grows up to 6 meters tall. It produces a pair of straight spines at each node, some of which have large bulbous bases. These swollen spines are naturally hollow and occupied by any one of several symbiotic ant species. The common name of the plant is derived from the observation that when wind blows over bulbous spines in which ants have made entry and exit holes, they produce a whistling noise.[3]

Whistling thorn
Scientific classification Edit this classification
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Eudicots
Clade: Rosids
Order: Fabales
Family: Fabaceae
Subfamily: Caesalpinioideae
Clade: Mimosoid clade
Genus: Vachellia
Species:
V. drepanolobium
Binomial name
Vachellia drepanolobium
(Harms ex Sjöstedt) P.J.H.Hurter[2]
Synonyms
  • Acacia drepanolobium Harms ex Sjöstedt

Whistling thorn is the dominant tree in some areas of upland East Africa, sometimes forming a nearly monoculture woodland, especially on "black cotton" soils of impeded drainage with high clay content.[4][5] It is browsed upon by giraffes and other large herbivores. It is apparently fire-adapted, coppicing readily after "top kill" by fire.[6]

Whistling thorn is used as fencing, tool handles, and other implements. The wood of the whistling thorn, although usually small in diameter, is hard and resistant to termites.[7] The branches can also be used for kindling, and its gum is sometimes collected and used as glue. The ability to coppice after cutting make it a possibly sustainable source for fuel wood and charcoal.[8] Conversely, whistling thorn also has been considered a weed of rangelands, and a bush encroachment species.[9][10]

Symbiosis with ants edit

Like other acacias, whistling thorns have leaves that contain tannins, which are thought to serve as deterrents to herbivory. Like all African acacias, they are defended by spines.[11] In addition, whistling thorn acacias are myrmecophytes that have formed a mutualistic relationship with some species of ants. In exchange for shelter in the bulbous spines (domatia) and nectar secretions, these ants appear to defend the tree against herbivores, such as elephants and giraffes,[12][13] as well as herbivorous insects.

At a site in Kenya, three Crematogaster and one Tetraponera ant species compete for exclusive possession of individual whistling thorn trees: Crematogaster mimosae, C. sjostedti, C. nigriceps, and Tetraponera penzigi.[4][5] Ant species vary in their level of mutualism with whistling thorn trees. The most common ant symbiote (~ 50% of trees), C. mimosae, has the strongest mutualistic relationship, aggressively defending trees from herbivores while relying on swollen-spines for shelter and feeding from nectar produced by glands near the base of leaves. (See also: Crematogaster peringueyi.)

3-Octanone and 3-Octanol have been identified as the alarm pheromones of Crematogaster negriceps and C. mimosa used in defending their tree. These chemicals are components of the ant’s mandibular gland secretion.[14] Later analysis of the mandibular gland secretion of these ants and of C. sjostedti showed distinct differences in the 28 volatile compounds that were identified.[15]

Because the ants compete for exclusive usage of a given tree, some species employ tactics to reduce the chance of a hostile ant invasion. Crematogaster nigriceps ants trim the buds of trees to reduce their lateral growth, thereby reducing chances of contact with a neighbouring tree occupied by a rival colony. Tetraponera penzigi, the only species which does not utilise the nectar produced by the trees, instead destroys the nectar glands to make a tree less appealing to other species.

The symbiotic relationship between the trees and the ants appears to be maintained by the effects of browsing by large herbivores. At the site in Kenya, when large herbivores were experimentally excluded, trees reduced the number of nectar glands and swollen spines they provided to ants. In response, the usually dominant C. mimosae increased their tending of parasitic sap-sucking insects as a replacement food source. In addition, the number of C. mimosae-occupied trees declined while twice as many become occupied by C. sjostedti, a much less aggressive defender of trees. Because C. sjostedti benefits from the holes made by boring beetle larvae, this species facilitates parasitism of trees by the beetles. As a result, the mutualistic relationship between whistling thorn trees and resident ants breaks down in the absence of large herbivores, and trees become paradoxically less healthy as a result,[5] and become much more vulnerable should herbivores be reintroduced.[16]

Gallery edit

References edit

  1. ^ a b Botanic Gardens Conservation International (BGCI).; IUCN SSC Global Tree Specialist Group (2018). "Vachellia drepanolobium". IUCN Red List of Threatened Species. 2018: e.T49277271A135815962. doi:10.2305/IUCN.UK.2018-2.RLTS.T49277271A135815962.en. Retrieved 19 November 2021.
  2. ^ Kyalangalilwa B, Boatwright JS, Daru BH, Maurin O, van der Bank M (2013). "Phylogenetic position and revised classification of Acacia s.l. (Fabaceae: Mimosoideae) in Africa, including new combinations in Vachellia and Senegalia". Bot J Linn Soc. 172 (4): 500–523. doi:10.1111/boj.12047. hdl:10566/3454.
  3. ^ "Whistling Thorn". Archived from the original on 26 January 2008. Retrieved 2008-01-18.
  4. ^ a b Young, T.P.; C.H. Stubblefield; L.A. Isbell (December 1996). "Ants on swollen-thorn acacias: Species coexistence in a simple system". Oecologia. 109 (1): 98–107. Bibcode:1997Oecol.109...98Y. doi:10.1007/s004420050063. PMID 28307618.
  5. ^ a b c Palmer, T.M.; M.L. Stanton; T.P. Young; J.R. Goheen; R.M. Pringle; R. Karban (January 2008). "Breakdown of an Ant–Plant Mutualism Follows the Loss of Large Herbivores from an African Savanna". Science. 319 (5860): 192–195. Bibcode:2008Sci...319..192P. doi:10.1126/science.1151579. PMID 18187652.
  6. ^ Okello, Bell; T.P. Young; C. Riginos; D. Kelly; T. O'Connor (2008). "Short-term survival and long-term mortality of Acacia drepanolobium after a controlled burn". African Journal of Ecology. 46 (3): 395–401. doi:10.1111/j.1365-2028.2007.00872.x.
  7. ^ "The Whistling Thorn". Retrieved 2008-01-18.
  8. ^ Okello, B.D.; O’Connor, T.G. & Young, T.P. (2001). "Growth, biomass estimates, and charcoal production of Acacia drepanolobium in Laikipia, Kenya". For. Ecol. Manag. 142 (1–3): 143–153. CiteSeerX 10.1.1.494.4621. doi:10.1016/S0378-1127(00)00346-7.
  9. ^ Pratt, D.J. & Gwynne, M.D. (1977). Rangeland Management and Ecology in East Africa. Hodder & Stoughton, London. ISBN 978-0-88275-525-0.
  10. ^ Dall, G.; Maass, B.L. & Isselstein, J. (2006). "Encroachment of woody plants and its impact on pastoral livestock production in the Borana lowlands, southern Oromia, Ethiopia". African Journal of Ecology. 44 (2): 237–246. doi:10.1111/j.1365-2028.2006.00638.x.
  11. ^ Ward, D. & T.P. Young (2002). "Effects of large mammalian herbivores and ant symbionts on condensed tannins of Acacia drepanolobium in Kenya". Journal of Chemical Ecology. 28 (5): 921–937. doi:10.1023/A:1015249431942. PMID 12049231.
  12. ^ Madden, D.; Young, T.P. (1992). "Symbiotic ants as an alternative defense against giraffe herbivory in spinescent Acacia drepanolobium". Oecologia. 91 (2): 235–238. Bibcode:1992Oecol..91..235M. doi:10.1007/bf00317789. PMID 28313462.
  13. ^ J.R. Goheen, and T.M. Palmer,"Defensive Plant-Ants Stabilize Megaherbivore-Driven Landscape Change in an African Savanna"[1], Current Biology,Available online 2 September 2010.
  14. ^ Wood, William F.; Chong, Berni (1975). "3-Octanone and 3-Octanol; Alarm Pheromones from East African Acacia Ants". Journal of the Georgia Entomological Society. 10: 332–334.
  15. ^ Wood, William F.; Palmer, Todd M.; Stanton, Maureen L. (2002). "A comparison of volatiles in mandibular glands from three Crematogaster ant symbionts of the whistling thorn acacia". journal Biochemical Systematics and Ecology. 30: 217–222. doi:10.1016/S0305-1978(01)00099-0.
  16. ^ Young, T.P. (2021). "Naïve plant communities and individuals may initially suffer in the face of reintroduced megafauna: an experimental exploration of rewilding from an African savanna rangeland". PLOS One. 16: e0248855.

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