Myrmelachista schumanni

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Myrmelachista schumanni
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Hymenoptera
Family: Formicidae
Subfamily: Formicinae
Genus: Myrmelachista
Species:
M. schumanni
Binomial name
Myrmelachista schumanni
Emery, 1890

Myrmelachista schumanni, also known as the lemon ant, is a species of ant from South America. It is notable for the creation of devil's gardens. Using its own herbicide, they kill off all the plants in an area except for the myrmecophytes, or ant-plants, in which they reside.

Contents

Ant–plant mutualism

M. schumanni live in large clearings in the rainforest, called devil's gardens, where there is little to no bio-diversity compared to the surrounding area. There are only one to three species of plants found in these areas consisting of Cordia nodosa, Tococa guianensis, Duroia hirsuta or Clidemia heterophylla. [1]

The few studies of the mutualism between M. schumanniD. hirsuta have incorrectly concluded that these clearings are formed by allelopathy on the part of D. hirsuta. It was later established that worker ants were injecting leaves with formic acid, a toxin commonly produced in ant species, and the plants started to die within 24 hours. Lemon ants are the only known insect to use formic acid as a herbicide. [2]

By killing other plants, the lemon ants provide themselves with a nest site, usually residing in D. hirsuta. Researchers estimate that the largest garden observed, contains 328 trees over 1,300 m2 (13,990 sq ft) and is around 800 years old. [3]

Name

Lemon ants get their name from the lemony taste of acids produced as part of a glandular chemical defense system. [4] When crushed or attacked, citronellal pheromones are created to communicate alarm to nearby individuals, which also produces a citrus odor. [5]

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<span class="mw-page-title-main">Ant</span> Family of insects

Ants are eusocial insects of the family Formicidae and, along with the related wasps and bees, belong to the order Hymenoptera. Ants evolved from vespoid wasp ancestors in the Cretaceous period. More than 13,800 of an estimated total of 22,000 species have been classified. They are easily identified by their geniculate (elbowed) antennae and the distinctive node-like structure that forms their slender waists.

<span class="mw-page-title-main">Mutualism (biology)</span> Mutually beneficial interaction between species

Mutualism describes the ecological interaction between two or more species where each species has a net benefit. Mutualism is a common type of ecological interaction. Prominent examples include most vascular plants engaged in mutualistic interactions with mycorrhizae, flowering plants being pollinated by animals, vascular plants being dispersed by animals, and corals with zooxanthellae, among many others. Mutualism can be contrasted with interspecific competition, in which each species experiences reduced fitness, and exploitation, or parasitism, in which one species benefits at the expense of the other.

<i>Cuscuta</i> Genus of parasitic plants

Cuscuta, commonly known as dodder or amarbel, is a genus of over 201 species of yellow, orange, or red parasitic plants. Formerly treated as the only genus in the family Cuscutaceae, it now is accepted as belonging in the morning glory family, Convolvulaceae, on the basis of the work of the Angiosperm Phylogeny Group. The genus is found throughout the temperate and tropical regions of the world, with the greatest species diversity in subtropical and tropical regions; the genus becomes rare in cool temperate climates, with only four species native to northern Europe.

<span class="mw-page-title-main">Niche construction</span> Process by which an organism shapes its environment

Niche construction is the process by which an organism alters its own local environment. These alterations can be a physical change to the organism’s environment or encompass when an organism actively moves from one habitat to another to experience a different environment. Examples of niche construction include the building of nests and burrows by animals, and the creation of shade, influencing of wind speed, and alternation of nutrient cycling by plants. Although these alterations are often beneficial to the constructor, they are not always.

<span class="mw-page-title-main">Fungus-growing ants</span> Tribe of ants

Fungus-growing ants comprise all the known fungus-growing ant species participating in ant–fungus mutualism. They are known for cutting grasses and leaves, carrying them to their colonies' nests, and using them to grow fungus on which they later feed.

<span class="mw-page-title-main">Myrmecophyte</span> Plants that live in association with ants

Myrmecophytes are plants that live in a mutualistic association with a colony of ants. There are over 100 different genera of myrmecophytes. These plants possess structural adaptations that provide ants with food and/or shelter. These specialized structures include domatia, food bodies, and extrafloral nectaries. In exchange for food and shelter, ants aid the myrmecophyte in pollination, seed dispersal, gathering of essential nutrients, and/or defense. Specifically, domatia adapted to ants may be called myrmecodomatia.

In myrmecology and forest ecology, a devil's garden is a large stand of trees in the Amazon rainforest consisting of at most three tree species and the ant Myrmelachista schumanni. Devil's gardens can reach up to sizes of 600 trees and are inhabited by a single ant colony, containing up to 3 million workers and 15,000 queens. In a 2002 to 2004 census of the Amazon, devil's gardens were shown to have grown by 0.7 % per year. The relationship between tree and ant may persist for more than 800 years. A devil's garden is considered an example of mutualism, a type of symbiotic relationship between species.

<span class="mw-page-title-main">Myrmecochory</span> Seed dispersal by ants

Myrmecochory ( ; from Ancient Greek: μύρμηξ, romanized: mýrmēks and χορεία khoreíā is seed dispersal by ants, an ecologically significant ant–plant interaction with worldwide distribution. Most myrmecochorous plants produce seeds with elaiosomes, a term encompassing various external appendages or "food bodies" rich in lipids, amino acids, or other nutrients that are attractive to ants. The seed with its attached elaiosome is collectively known as a diaspore. Seed dispersal by ants is typically accomplished when foraging workers carry diaspores back to the ant colony, after which the elaiosome is removed or fed directly to ant larvae. Once the elaiosome is consumed, the seed is usually discarded in underground middens or ejected from the nest. Although diaspores are seldom distributed far from the parent plant, myrmecochores also benefit from this predominantly mutualistic interaction through dispersal to favourable locations for germination, as well as escape from seed predation.

<i>Nepenthes hirsuta</i> Species of pitcher plant from Borneo

Nepenthes hirsuta, the hairy pitcher-plant, is a tropical pitcher plant endemic to Borneo. It is characterised by an indumentum of thick brown hairs, which is even present on the inflorescence. Pitchers are mostly green throughout with some having red blotches on the inside surfaces.

<span class="mw-page-title-main">Nectar</span> Sugar-rich liquid produced by many flowering plants, that attracts pollinators and insects

Nectar is a sugar-rich liquid produced by plants in glands called nectaries or nectarines, either within the flowers with which it attracts pollinating animals, or by extrafloral nectaries, which provide a nutrient source to animal mutualists, which in turn provide herbivore protection. Common nectar-consuming pollinators include mosquitoes, hoverflies, wasps, bees, butterflies and moths, hummingbirds, honeyeaters and bats. Nectar plays a crucial role in the foraging economics and evolution of nectar-eating species; for example, nectar foraging behavior is largely responsible for the divergent evolution of the African honey bee, A. m. scutellata and the western honey bee.

<span class="mw-page-title-main">Plant defense against herbivory</span> Plants defenses against being eaten

Plant defense against herbivory or host-plant resistance (HPR) is a range of adaptations evolved by plants which improve their survival and reproduction by reducing the impact of herbivores. Plants can sense being touched, and they can use several strategies to defend against damage caused by herbivores. Many plants produce secondary metabolites, known as allelochemicals, that influence the behavior, growth, or survival of herbivores. These chemical defenses can act as repellents or toxins to herbivores or reduce plant digestibility. Another defensive strategy of plants is changing their attractiveness. To prevent overconsumption by large herbivores, plants alter their appearance by changing their size or quality, reducing the rate at which they are consumed.

<i>Vachellia collinsii</i> Species of legume

Vachellia collinsii, previously Acacia collinsii, is a species of flowering plant native to Central America and parts of Africa.

<i>Oxalis pes-caprae</i> Species of flowering plant in the wood sorrel family

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<span class="mw-page-title-main">Seed predation</span> Feeding on seeds as a main or exclusive food source

Seed predation, often referred to as granivory, is a type of plant-animal interaction in which granivores feed on the seeds of plants as a main or exclusive food source, in many cases leaving the seeds damaged and not viable. Granivores are found across many families of vertebrates as well as invertebrates ; thus, seed predation occurs in virtually all terrestrial ecosystems. Seed predation is commonly divided into two distinctive temporal categories, pre-dispersal and post-dispersal predation, which affect the fitness of the parental plant and the dispersed offspring, respectively. Mitigating pre- and post-dispersal predation may involve different strategies. To counter seed predation, plants have evolved both physical defenses and chemical defenses. However, as plants have evolved seed defenses, seed predators have adapted to plant defenses. Thus, many interesting examples of coevolution arise from this dynamic relationship.

Devil's Garden or Devils Garden may refer to:

<i>Jalmenus evagoras</i> Species of butterfly

Jalmenus evagoras, the imperial hairstreak, imperial blue, or common imperial blue, is a small, metallic blue butterfly of the family Lycaenidae. It is commonly found in eastern coastal regions of Australia. This species is notable for its unique mutualism with ants of the genus Iridomyrmex. The ants provide protection for juveniles and cues for adult mating behavior. They are compensated with food secreted from J. evagoras larvae. The ants greatly enhance the survival and reproductive success of the butterflies. J. evagoras lives and feeds on Acacia plants, so butterfly populations are localized to areas with preferred species of both host plants and ants.

<i>Pseudomyrmex ferruginea</i> Species of ant

The acacia ant is a species of ant of the genus Pseudomyrmex. These arboreal, wasp-like ants have an orange-brown body around 3 mm in length and very large eyes. The acacia ant is best known and named for living in symbiosis with the bullhorn acacia throughout Central America.

Insects have a wide variety of predators, including birds, reptiles, amphibians, mammals, carnivorous plants, and other arthropods. The great majority (80–99.99%) of individuals born do not survive to reproductive age, with perhaps 50% of this mortality rate attributed to predation. In order to deal with this ongoing escapist battle, insects have evolved a wide range of defense mechanisms. The only restraint on these adaptations is that their cost, in terms of time and energy, does not exceed the benefit that they provide to the organism. The further that a feature tips the balance towards beneficial, the more likely that selection will act upon the trait, passing it down to further generations. The opposite also holds true; defenses that are too costly will have a little chance of being passed down. Examples of defenses that have withstood the test of time include hiding, escape by flight or running, and firmly holding ground to fight as well as producing chemicals and social structures that help prevent predation.

<i>Duroia</i> Genus of plants

Duroia is a genus of flowering plants in the family Rubiaceae. The genus is found from Costa Rica to tropical South America.

<i>Duroia hirsuta</i> Species of flowering plant

Duroia hirsuta is a myrmecophyte tree species from the Amazon Forest. It is one of some 37 species of Duroia, which are shrubs or canopy trees in the family Rubiaceae, favouring ants (myrmecophilous), and occurring in Central America as far north as Mexico, the Amazon Basin, the Guiana Shield, the Brazilian Atlantic coast and planalto.

References

  1. Edwards, David P.; Frederickson, Megan E.; Shepard, Glenn H. & Yu, Douglas W. (2009). "A plant needs ants like a dog needs fleas: Myrmelachista schumanni ants gall many tree species to create housing". The American Naturalist. 174 (5): 734–740. doi:10.1086/606022. PMID   19799500. S2CID   29447835.
  2. Roach, John. "Ants Use Acid to Make "Gardens" in Amazon, Study Says". National Geographic. Retrieved 25 October 2013.
  3. Ross, Alison (21 September 2005). "Devilish ants control the garden". BBC. Retrieved 26 October 2013.
  4. Sinberg, Stan. "Tracking the lemon ants of the Amazon". St. Petersburg Times Online Travel. Retrieved 28 October 2013.
  5. Wilson, Edward O. & Regnier, Fred E. (1971). "The evolution of the alarm-defense system in the formicine ants". The American Naturalist. 105 (943): 279–289. doi:10.1086/282724. ISSN   0003-0147. JSTOR   2459556. S2CID   84558392.