Exorista mella

Last updated

Exorista mella
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Diptera
Family: Tachinidae
Subfamily: Exoristinae
Tribe: Exoristini
Genus: Exorista
Species:
E. mella
Binomial name
Exorista mella
(Walker, 1849) [1]
Synonyms

Exorista mella is a tachinid fly of the genus Ezorista within the family Tachinidae of the order Diptera. [7] They are typically found in the United States and Canada. [8] Within the U.S in the state of Arizona they have been found in both mountainous and agricultural regions. E. mella is a parasitoid fly, a polyphagous generalist which parasitizes a variety of hosts.

Contents

Female E. mella flies are selective when deciding on what host to parasitize. Once a host is selected a female may oviposit her eggs on the surface of the host. Larvae then burrow into the host for the remainder of their development usually killing the host once they emerge during either prepupae or pupae stage of development. Experiments in these flies have suggested that they can learn from experience that influence certain behaviors as suggest them as candidates for biocontrol agents to control certain pests.[ clarification needed ]

Description

Physical characteristics include having a stigmal plate that is not elevated like their protuberance, as well as a sternopleuron pertaining to the thorax on the lateral side with three bristles. [9] Likewise, behavioral characteristics include their parasitoid tendencies. As parasitoids, E. mella typically spend most of their life growing in a host. Unlike other fly species born in a host, in E. mella, neither sex determination nor sex ratio divergence is related to host size. However, the size of adult E. mella is directly correlated with the size of the host from which the fly emerged. Thus, flies that were oviposited and burrowed alone into larger hosts were larger than those that emerged from a smaller host or one that was superparasitized. [10] A study shows that the sex of the emerging flies does not correspond to the host size or superparasitism of the host, though the two factors influence the size of adult flies, and the larger adult flies deposit a larger number of eggs than the smaller ones. [10] Additionally, host larvae activity has a larger impact on parasite oviposition than host larvae size. [10]

Distribution and habitat

E. mella is commonly found in the United States and in Canada. [8] In Arizona, E. mella have been found in the mountainous regions as well as agricultural regions of southern Arizona. [8] [10]

Life cycle

Larvae

On average, the larval development of E. mella lasts for 10 days. [11] Larvae emerge from their eggs on the surface of their hosts, after which they burrow into the host for the remainder of their development. [8] Delays in development occur when the host molts. [10] If the host does not molt, larvae are able to develop within an average of 6.4 days, as opposed to an average of 12.9 days if the host does molt. [12]

Pupae

E. mella larvae are able to emerge from any stage (i.e. prepupae and pupae) of their host during their development. [8]

Longevity

The lifespan of adult E. mella flies varies. Males typically have an average lifespan of about 29.5 days, while females survive an average of about 38.0 to 40.6 days. [10]

Parental care

Preoviposition

The earliest recorded viable eggs in a study were from females 48 to 72 hours old, which had immediately mated after emerging. [13] Even without having mated, newly emerged females have also been documented to be able to oviposit infertile and consequently unviable eggs. The gestation period lasts for an average of at least 2 days upon emergence from the host. [10]

Oviposition

Female E. mella flies extend their ovipositor onto the surface of their host of choice to lay their hard-shelled eggs. [7] On average, a female E. mella fly can oviposit about 150 eggs during her lifespan. [14] The most an E. mella fly has been recorded to oviposit on a single host for one study was 65 eggs. [13] Typically, the oviposition period lasts for about 24.8 days. E. mella typically oviposit on the cuticle of their host, but have also been documented to oviposit on the head capsule, setae, prolegs, and on the abdomen of hosts. [10] Though they prefer to oviposit on live hosts, females were also observed to oviposit on the surface of dead hosts. Larger females were also observed to oviposit a greater number of eggs than smaller females. [14]

Parasitism

Hosts

As a polyphagous and generalist fly, E. mella feeds on a variety of hosts. It has been recorded to parasitize the following families of caterpillars: Arctiidae, Noctuidae, Notodontidae, Lymantriidae, and Lasiocampidae. [8] E. mella has also been noted by one study to be one of the core three parasitoids to account for the mortality of a variety of caterpillars. [15] Some of these hosts, such as the Apantesis incorrupta moth, have been observed to be able to fight back against parasitism by E. mella through a particular diet of plants, as well as surviving through adulthood. [11]

Host selection

Female E. mella flies spend time browsing hosts by moving around habitats where they are likely to find hosts, such as in low shrubs and herbs that their hosts feed on. [14] When choosing a host, the flies usually drum their feet on its body to determine if it is an adequate and living host. [7] One experiment found that E. mella flies respond more strongly to certain characteristics of a host than others, one such characteristic being the movement of the host. The more the host moved, the faster the flies were observed to approach the host. [14] Female E. mella flies have been found to preferentially oviposit on larger hosts. [8] They have also been found to prefer host caterpillars that are in their late instar stage of development. [11]

Experiments

One experiment observed more experienced flies learning and behaving in a different way than inexperienced flies. Where more experienced flies typically oviposited more eggs onto a host, experienced females were also documented to be able to recognize suitable hosts faster than inexperienced hosts and tended to oviposit on live hosts more often. [14]

Another experiment looked into the potential of E. mella flies as biocontrol agents in agriculture for certain pests. Where parasitism of the host rarely lets the pest that is chosen as a host live. The study itself looked at the ability of flies to do so either by depositing their eggs into a host described as macro egg laying or on the plant which they feed off of described as micro egg laying. E. mella was one of a couple of flies in the study that could deposit on both the plant and the host, with parasitism having a greater percentage to occur within a host. [16]

Mating

E. mella flies have been found to mate shortly after emerging from their host, and the success rate of mating increases when the time before the formation of pairs after emergence is shorter. [10] Both sexes have been observed to show a decline in their ability to produce viable offspring after a certain amount of time after emergence. For males, this was on average 14 days, while for females it was after 16 days of emergence. [12] Males have been observed to have the ability to fertilize the eggs of more than one female. Thus, it is the usual case that pairs mate shortly after emerging from the host. [10]

Related Research Articles

<i>Lymantria dispar</i> Species of moth

Lymantria dispar, also known as the gypsy moth or the spongy moth, is a species of moth in the family Erebidae native to Europe and Asia. Lymantria dispar is subdivided into several subspecies, with subspecies such as L. d. dispar and L. d. japonica being clearly identifiable without ambiguity. Lymantria dispar has been introduced to several continents and is now additionally found as an invasive species in Africa, North America and South America. The polyphagous larvae live on a variety of deciduous and coniferous trees and can cause severe damage in years of mass reproduction. Due to these features, Lymantria dispar is listed among the world's 100 worst invasive alien species.

<span class="mw-page-title-main">Parasitoid</span> Organism that lives with its host and kills it

In evolutionary ecology, a parasitoid is an organism that lives in close association with its host at the host's expense, eventually resulting in the death of the host. Parasitoidism is one of six major evolutionary strategies within parasitism, distinguished by the fatal prognosis for the host, which makes the strategy close to predation.

<span class="mw-page-title-main">Luna moth</span> Species of insect

The luna moth, also called the American moon moth, is a Nearctic moth in the family Saturniidae, subfamily Saturniinae, a group commonly named the giant silk moths.

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

The Tachinidae are a large and variable family of true flies within the insect order Diptera, with more than 8,200 known species and many more to be discovered. Over 1,300 species have been described in North America alone. Insects in this family commonly are called tachinid flies or simply tachinids. As far as is known, they all are protelean parasitoids, or occasionally parasites, of arthropods, usually other insects. The family is known from many habitats in all zoogeographical regions and is especially diverse in South America.

<span class="mw-page-title-main">Ichneumonoidea</span> Superfamily of wasps

The superfamily Ichneumonoidea contains one extinct and three extant families, including the two largest families within Hymenoptera: Ichneumonidae and Braconidae. The group is thought to contain as many as 100,000 species, many of which have not yet been described. Like other parasitoid wasps, they were long placed in the "Parasitica", variously considered as an infraorder or an unranked clade, now known to be paraphyletic.

<span class="mw-page-title-main">Apple maggot</span> Species of fly

The apple maggot, also known as the railroad worm, is a species of fruit fly, and a pest of several types of fruits, especially apples. This species evolved about 150 years ago through a sympatric shift from the native host hawthorn to the domesticated apple species Malus domestica in the northeastern United States. This fly is believed to have been accidentally spread to the western United States from the endemic eastern United States region through contaminated apples at multiple points throughout the 20th century. The apple maggot uses Batesian mimicry as a method of defense, with coloration resembling that of the forelegs and pedipalps of a jumping spider.

<span class="mw-page-title-main">Codling moth</span> Species of moth that feeds on fruit (Cydia pomonella)

The codling moth is a member of the Lepidopteran family Tortricidae. They are major pests to agricultural crops, mainly fruits such as apples and pears, and a codling moth larva is often called an "apple worm". Because the larvae are not able to feed on leaves, they are highly dependent on fruits as a food source and thus have a significant impact on crops. The caterpillars bore into fruit and stop it from growing, which leads to premature ripening. Various means of control, including chemical, biological, and preventive, have been implemented. This moth has a widespread distribution, being found on six continents. Adaptive behavior such as diapause and multiple generations per breeding season have allowed this moth to persist even during years of bad climatic conditions.

Superparasitism is a form of parasitism in which the host is attacked more than once by a single species of parasitoid. Multiparasitism or coinfection, on the other hand, occurs when the host has been parasitized by more than one species. Host discrimination, whereby parasitoids can identify a host with parasites from an unparasitized host, is present in certain species of parasitoids and is used to avoid superparasitism and thus competition from other parasites. Superparasitism can result in transmission of viruses, and viruses may influence a parasitoid's behavior in favor of infecting already infected hosts, as is the case with Leptopilina boulardi.

<i>Antheraea polyphemus</i> Species of moth

Antheraea polyphemus, the Polyphemus moth, is a North American member of the family Saturniidae, the giant silk moths. It is a tan-colored moth, with an average wingspan of 15 cm (6 in). The most notable feature of the moth is its large, purplish eyespots on its two hindwings. The eyespots give it its name – from the Greek myth of the cyclops Polyphemus. The species was first described by Pieter Cramer in 1776. The species is widespread in continental North America, with local populations found throughout subarctic Canada and the United States. The caterpillar can eat 86,000 times its weight at emergence in a little less than two months. Polyphemus moths are considered to be very polyphagous, meaning they eat from a wide variety of plants.

<i>Hyalophora cecropia</i> Species of moth

Hyalophora cecropia, the cecropia moth, is North America's largest native moth. It is a member of the family Saturniidae, or giant silk moths. Females have been documented with a wingspan of five to seven inches or more. These moths can be found all across North America as far west as Washington and north into the majority of Canadian provinces. Cecropia moth larvae are most commonly found on maple trees, but they have also been found on cherry and birch trees among many others. The species was first described by Carl Linnaeus in his 1758 10th edition of Systema Naturae.

<span class="mw-page-title-main">Parasitoid wasp</span> Group of wasps

Parasitoid wasps are a large group of hymenopteran superfamilies, with all but the wood wasps (Orussoidea) being in the wasp-waisted Apocrita. As parasitoids, they lay their eggs on or in the bodies of other arthropods, sooner or later causing the death of these hosts. Different species specialise in hosts from different insect orders, most often Lepidoptera, though some select beetles, flies, or bugs; the spider wasps (Pompilidae) exclusively attack spiders.

<span class="mw-page-title-main">Eucharitidae</span> Family of wasps

The Eucharitidae are a family of parasitic wasps. Eucharitid wasps are members of the superfamily Chalcidoidea and consist of three subfamilies: Oraseminae, Eucharitinae, and Gollumiellinae. Most of the 55 genera and 417 species of Eucharitidae are members of the subfamilies Oraseminae and Eucharitinae, and are found in tropical regions of the world.

<i>Chloridea virescens</i> Species of moth

Chloridea virescens, commonly known as the tobacco budworm, is a moth of the family Noctuidae found throughout the eastern and southwestern United States along with parts of Central America and South America.

<i>Tachina fera</i> Species of fly

Tachina fera is a species of fly in the genus Tachina of the family Tachinidae. It was first described by Carl Linnaeus in 1761.

<i>Compsilura concinnata</i> Species of fly

Compsilura concinnata is a parasitoid native to Europe that was introduced to North America in 1906 to control the population of an exotic forest, univoltine, spongy moth named Lymantria dispar. It is an endoparasitoid of larvae and lives with its host for most of its life. Eventually the parasitoid ends up killing the host and occasionally eating it. It attacks over 200 host species, mainly insects from the Orders: Coleoptera, Lepidoptera and Hymenoptera. Since this parasite has the ability to attack many different types of hosts, the organism has spilled over from the intended forest systems into other areas, like agricultural fields, affecting cabbage pests including the cabbage looper (Trichoplusia); the cabbage worm ; and even other invasive species such as the brown-tail moth. However, it also attacks native, non-pest insects such as the Cecropia moth and American moon moth.

<i>Diabrotica balteata</i> Species of beetle

Diabrotica balteata is a species of cucumber beetle in the family Chrysomelidae known commonly as the banded cucumber beetle. It occurs in the Americas, where its distribution extends from the United States to Colombia and Venezuela in South America. It is also present in Cuba. It is a pest of a variety of agricultural crops.

Lespesia archippivora is a species of tachinid fly, which, like all tachinids, are parasitoids of other arthropods. L. archippivora lives in the body of its host resulting in its death. This is not uncommon since it is estimated that about 10% of all insects are parasitoids. L. archippivora is a generalist and able to infect at least 25 lepidopteran species in addition to one species of Hymenoptera. It is common in North America and other species exist worldwide. One study suggests the species is bivoltine.

<i>Hemileuca lucina</i> Species of moth

Hemileuca lucina, the New England buck moth, is a species of moth in the family Saturniidae. This moth species is only found in the New England region of the United States. Larvae in early stages mainly feed on broadleaf meadowsweet whereas larvae in later stages show variation in food sources such as blackberry and black cherry leaves. Larvae have a black body with orange/black spines on their back that are used to deter predators. Pupation occurs during the summer and adult moths come out around September.

<i>Zelia vertebrata</i> Species of fly

Zelia vertebrata is a species of bristle fly in the family Tachinidae. It is a long-bodied fly with strong abdominal bristles and a distinctive abdominal pattern that resembles vertebrae. It has a widespread North American range, with records stretching from east to west from Washington to Maine, north to south from Québec to Florida. Its larval stage parasitizes beetles. It is most active during the day.

<i>Aleochara bilineata</i> Species of beetle

Aleochara bilineata is a species of rove beetle that lives in sub-tropical and cold tolerant climates throughout the world. This beetle was first biologically described by Wadsworth in 1915. It is used by humans as crop pest control due to the variety of pests it consumes, including caterpillars, mealybugs, mites, maggots. These beetles have a larval phase that occurs over the winter and an adult phase that emerges in the spring. They are often found in moist environments, in compost, or near crops.

References

  1. 1 2 Walker, F. (1849). List of the specimens of dipterous insects in the collection of the British Museum. Part IV. London: British Museum. pp. [3] + 689–1172 + [2]. Retrieved 20 October 2022.
  2. Forbush, E.H.; Fernald, C.H. (1896). The gypsy moth. Porthetria dispar (Linn.). A report of the work of destroying the insect in the Commonwealth of Massachusetts, together with an account of its history and habits both in Massachusetts and Europe. Boston: Massachusetts State Board of Agriculture. pp. 495 pp. + c pp.
  3. Townsend, C.H.T. (1891). "Two new tachinids" (PDF). Psyche: A Journal of Entomology. 6 (181): 83–85. doi: 10.1155/1891/34809 . Retrieved 19 September 2023.
  4. LeBaron, W. (1871). "Insects injurious to the apple tree". State Ent. RPT. Noxious Beneficial Insects St. Ill (2): 13–46.
  5. Townsend, C.H.T. (1892). "The North American genera of calyptrate Muscidae. Paper IV. Sarcophagidae and Muscidae s. str". Transactions of the American Entomological Society. 19: 279–284. Retrieved 15 October 2023.
  6. Townsend, C.H.T. (1908). "The taxonomy of the muscoidean flies, including descriptions of new genera and species". Smithsonian Miscellaneous Collections. 51. Retrieved 9 June 2023.
  7. 1 2 3 Stireman, John O. (2002-09-01). "Learning in the Generalist Tachinid Parasitoid Exorista mella Walker (Diptera: Tachinidae)". Journal of Insect Behavior. 15 (5): 689–706. doi:10.1023/A:1020752024329. ISSN   1572-8889. S2CID   36686371.
  8. 1 2 3 4 5 6 7 Butler, G. D.; Bryan, D. E.; Jackson, C. G. (1968-02-01). "Development of the Salt-Marsh Caterpillar Parasite, Exorista mella at Controlled Constant and Variable Temperatures in the Laboratory". Journal of Economic Entomology. 61 (1): 161–162. doi:10.1093/jee/61.1.161. ISSN   0022-0493.
  9. Torgersen, Torolf R. (1997). Identification of Parasites of the Douglas-fir Tussock Moth, Based on Adults, Cocoons, and Puparia. Portland, Oregon: Pacific Northwest Forest and Range Experiment Station.
  10. 1 2 3 4 5 6 7 8 9 10 Adam, David S.; Watson, T. F. (1971-01-15). "Adult Biology of Exorista mella". Annals of the Entomological Society of America. 64 (1): 146–149. doi:10.1093/aesa/64.1.146. ISSN   0013-8746.
  11. 1 2 3 Singer, M. S.; Stireman, J. O. (2003). "Does anti-parasitoid defense explain host-plant selection by a polyphagous caterpillar?". Oikos. 100 (3): 554–562. Bibcode:2003Oikos.100..554S. doi:10.1034/j.1600-0706.2003.11720.x. ISSN   0030-1299. JSTOR   25681930.
  12. 1 2 Adam, David Stuart (1968). Certain biological relationships between the parasite Exorista mella, and its host Estigmene acrea (MS thesis). University of Arizona. hdl:10150/318219.
  13. 1 2 Taylor, Edgar A (1952). Parasitization of the salt-marsh caterpillar, Estigmene acraea. Drury, in the Salt River Valley, Arizona (MS thesis). University of Arizona. hdl:10150/191407.
  14. 1 2 3 4 5 Stireman, John O. (2002). "Host location and selection cues in a generalist tachinid parasitoid". Entomologia Experimentalis et Applicata. 103 (1): 23–34. Bibcode:2002EEApp.103...23S. doi:10.1046/j.1570-7458.2002.00958.x. ISSN   1570-7458. S2CID   85571111.
  15. Stireman, John O.; Singer, Michael S. (2002). "Spatial and temporal variation in the parasitoid assemblage of an exophytic polyphagous caterpillar". Ecological Entomology. 27 (5): 588–600. Bibcode:2002EcoEn..27..588S. doi: 10.1046/j.1365-2311.2002.00450.x . ISSN   1365-2311. S2CID   85128848.
  16. Shendage, Nilam; Sathe, T.V. (2016). "Tachinids as good biocontrol agents of agricultural pests". BioLife. 4. Global Science Publishing Group, USA.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.